Freescale MC9S08DZ16F1M32 8-bit hcs08 central processor unit (cpu) Datasheet

MC9S08DZ60
MC9S08DZ48
MC9S08DZ32
MC9S08DZ16
Data Sheet
HCS08
Microcontrollers
MC9S08DZ60
Rev. 4
6/2008
freescale.com
MC9S08DZ60 Series Features
8-Bit HCS08 Central Processor Unit (CPU)
• 40-MHz HCS08 CPU (20-MHz bus)
• HC08 instruction set with added BGND instruction
• Support for up to 32 interrupt/reset sources
On-Chip Memory
• Flash read/program/erase over full operating voltage and
temperature
— MC9S08DZ60 = 60K
— MC9S08DZ48 = 48K
— MC9S08DZ32 = 32K
— MC9S08DZ16 = 16K
• Up to 2K EEPROM in-circuit programmable memory;
8-byte single-page or 4-byte dual-page erase sector;
Program and Erase while executing Flash; Erase abort
• Up to 4K random-access memory (RAM)
Power-Saving Modes
• Two very low power stop modes
• Reduced power wait mode
• Very low power real time interrupt for use in run, wait,
and stop
Clock Source Options
• Oscillator (XOSC) — Loop-control Pierce oscillator;
Crystal or ceramic resonator range of 31.25 kHz to
38.4 kHz or 1 MHz to 16 MHz
• Multi-purpose Clock Generator (MCG) — PLL and
FLL modes (FLL capable of 1.5% deviation using
internal temperature compensation); Internal reference
clock with trim adjustment (trimmed at factory, with
trim value stored in flash); External reference with
oscillator/resonator options
System Protection
• Watchdog computer operating properly (COP) reset
with option to run from backup dedicated 1-kHz internal
clock source or bus clock
• Low-voltage detection with reset or interrupt; selectable
trip points
• Illegal opcode detection with reset
• Illegal address detection with reset
• Flash block protect
• Loss-of-lock protection
Development Support
• Single-wire background debug interface
• On-chip, in-circuit emulation (ICE) with real-time bus capture
Peripherals
• ADC — 24-channel, 12-bit resolution, 2.5 μs
conversion time, automatic compare function,
temperature sensor, internal bandgap reference channel
• ACMPx — Two analog comparators with selectable
interrupt on rising, falling, or either edge of comparator
output; compare option to fixed internal bandgap
reference voltage
• MSCAN — CAN protocol - Version 2.0 A, B; standard
and extended data frames; Support for remote frames;
Five receive buffers with FIFO storage scheme; Flexible
identifier acceptance filters programmable as: 2 x 32-bit,
4 x 16-bit, or 8 x 8-bit
• SCIx — Two SCIs supporting LIN 2.0 Protocol and
SAE J2602 protocols; Full duplex non-return to zero
(NRZ); Master extended break generation; Slave
extended break detection; Wakeup on active edge
• SPI — Full-duplex or single-wire bidirectional;
Double-buffered transmit and receive; Master or Slave
mode; MSB-first or LSB-first shifting
• IIC — Up to 100 kbps with maximum bus loading;
Multi-master operation; Programmable slave address;
General Call Address; Interrupt driven byte-by-byte data
transfer
• TPMx — One 6-channel (TPM1) and one 2-channel
(TPM2); Selectable input capture, output compare, or
buffered edge-aligned PWM on each channel
• RTC — (Real-time counter) 8-bit modulus counter with
binary or decimal based prescaler; Real-time clock
capabilities using external crystal and RTC for precise
time base, time-of-day, calendar or task scheduling
functions; Free running on-chip low power oscillator
(1 kHz) for cyclic wake-up without external components
Input/Output
• 53 general-purpose input/output (I/O) pins and 1
input-only pin
• 24 interrupt pins with selectable polarity on each pin
• Hysteresis and configurable pull device on all input pins.
• Configurable slew rate and drive strength on all output
pins.
Package Options
• 64-pin low-profile quad flat-pack (LQFP) — 10x10 mm
• 48-pin low-profile quad flat-pack (LQFP) — 7x7 mm
• 32-pin low-profile quad flat-pack (LQFP) — 7x7 mm
MC9S08DZ60 Data Sheet
Covers MC9S08DZ60
MC9S08DZ48
MC9S08DZ32
MC9S08DZ16
MC9S08DZ60
Rev. 4
6/2008
Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc.
© Freescale Semiconductor, Inc., 2007-2008. All rights reserved.
Revision History
To provide the most up-to-date information, the revision of our documents on the World Wide Web will be
the most current. Your printed copy may be an earlier revision. To verify you have the latest information
available, refer to:
http://freescale.com/
The following revision history table summarizes changes contained in this document.
Revision
Number
Revision
Date
1
6/2006
Advance Information for alpha samples customers
2
9/2007
Product Launch. Removed the 64-pin QFN package. Changed from standard to extended
mode for MSCAN registers in register summary. Corrected Block diagrams for SCI.
Updated the latest Temp Sensor information. Made FTSTMOD reserved. Updated device
to use the ADC 12-bit module. Revised the MCG module. Updated the CPU Instruction Set
table. Updated the TPM block module to version 3. Added the TPM block module version
2 as an appendix for devices using 3M05C (or earlier) mask sets. Heavily revised the
Electricals appendix.
3
10/2007
Removed two tables that were inadvertently included in the MC9S08DZ60 version of the
book.
4
6/2008
Sustaining update. Incorporated PS Issues # 2765, 3177, 3236, 3292, 3311, 3312, 3326,
3335, 3345, 3382, 2795, 3382 and 3386 PLL Jitter Spec update. Also, added internal
reference clock trim adjustment statement to Features page. Updated the TPM module to
the latest version. Adjusted values in Table A-13 Control Timing row 2 and in Table A-6 DC
Characteristics row 24 so that it references 5.0 V instead of 3.0 V.
Description of Changes
© Freescale Semiconductor, Inc., 2007-2008. All rights reserved.
This product incorporates SuperFlash® Technology licensed from SST.
MC9S08DZ60 Series Data Sheet, Rev. 4
6
Freescale Semiconductor
List of Chapters
Chapter
Title
Page
Chapter 1
Device Overview .............................................................................. 21
Chapter 2
Pins and Connections ..................................................................... 27
Chapter 3
Modes of Operation ......................................................................... 35
Chapter 4
Memory ............................................................................................. 41
Chapter 5
Resets, Interrupts, and General System Control.......................... 69
Chapter 6
Parallel Input/Output Control.......................................................... 85
Chapter 7
Central Processor Unit (S08CPUV3) ............................................ 115
Chapter 8
Multi-Purpose Clock Generator (S08MCGV1) ............................. 135
Chapter 9
Analog Comparator (S08ACMPV3) .............................................. 167
Chapter 10
Analog-to-Digital Converter (S08ADC12V1)................................ 173
Chapter 11
Inter-Integrated Circuit (S08IICV2) ............................................... 199
Chapter 12
Freescale Controller Area Network (S08MSCANV1) .................. 219
Chapter 13
Serial Peripheral Interface (S08SPIV3) ........................................ 273
Chapter 14
Serial Communications Interface (S08SCIV4)............................. 289
Chapter 15
Real-Time Counter (S08RTCV1) ................................................... 309
Chapter 16
Timer Pulse-Width Modulator (S08TPMV3) ................................. 319
Chapter 17
Development Support ................................................................... 347
Appendix A
Electrical Characteristics.............................................................. 369
Appendix B
Timer Pulse-Width Modulator (TPMV2) ....................................... 391
Appendix C
Ordering Information and Mechanical Drawings........................ 405
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
7
Contents
Section Number
Title
Page
Chapter 1
Device Overview
1.1
1.2
1.3
Devices in the MC9S08DZ60 Series................................................................................................21
MCU Block Diagram .......................................................................................................................22
System Clock Distribution ...............................................................................................................24
Chapter 2
Pins and Connections
2.1
2.2
Device Pin Assignment ....................................................................................................................27
Recommended System Connections ................................................................................................30
2.2.1 Power ................................................................................................................................31
2.2.2 Oscillator ...........................................................................................................................31
2.2.3 RESET ..............................................................................................................................31
2.2.4 Background / Mode Select (BKGD/MS) ..........................................................................32
2.2.5 ADC Reference Pins (VREFH, VREFL) ..............................................................................32
2.2.6 General-Purpose I/O and Peripheral Ports ........................................................................32
Chapter 3
Modes of Operation
3.1
3.2
3.3
3.4
3.5
3.6
Introduction ......................................................................................................................................35
Features ............................................................................................................................................35
Run Mode.........................................................................................................................................35
Active Background Mode.................................................................................................................35
Wait Mode ........................................................................................................................................36
Stop Modes.......................................................................................................................................37
3.6.1 Stop3 Mode .......................................................................................................................37
3.6.2 Stop2 Mode .......................................................................................................................38
3.6.3 On-Chip Peripheral Modules in Stop Modes ....................................................................39
Chapter 4
Memory
4.1
4.2
4.3
4.4
4.5
MC9S08DZ60 Series Memory Map ................................................................................................41
Reset and Interrupt Vector Assignments ..........................................................................................42
Register Addresses and Bit Assignments.........................................................................................44
RAM.................................................................................................................................................52
Flash and EEPROM .........................................................................................................................52
4.5.1 Features .............................................................................................................................52
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
9
Section Number
4.5.2
4.5.3
4.5.4
4.5.5
4.5.6
4.5.7
4.5.8
4.5.9
4.5.10
4.5.11
Title
Page
Program and Erase Times .................................................................................................53
Program and Erase Command Execution .........................................................................53
Burst Program Execution ..................................................................................................55
Sector Erase Abort ............................................................................................................57
Access Errors ....................................................................................................................58
Block Protection ................................................................................................................59
Vector Redirection ............................................................................................................59
Security .............................................................................................................................59
EEPROM Mapping ...........................................................................................................61
Flash and EEPROM Registers and Control Bits ...............................................................61
Chapter 5
Resets, Interrupts, and General System Control
5.1
5.2
5.3
5.4
5.5
5.6
5.7
5.8
Introduction ......................................................................................................................................69
Features ............................................................................................................................................69
MCU Reset.......................................................................................................................................69
Computer Operating Properly (COP) Watchdog..............................................................................70
Interrupts ..........................................................................................................................................71
5.5.1 Interrupt Stack Frame .......................................................................................................72
5.5.2 External Interrupt Request (IRQ) Pin ...............................................................................72
5.5.3 Interrupt Vectors, Sources, and Local Masks ....................................................................73
Low-Voltage Detect (LVD) System .................................................................................................75
5.6.1 Power-On Reset Operation ...............................................................................................75
5.6.2 Low-Voltage Detection (LVD) Reset Operation ...............................................................75
5.6.3 Low-Voltage Warning (LVW) Interrupt Operation ...........................................................75
MCLK Output ..................................................................................................................................75
Reset, Interrupt, and System Control Registers and Control Bits ....................................................76
5.8.1 Interrupt Pin Request Status and Control Register (IRQSC) ............................................77
5.8.2 System Reset Status Register (SRS) .................................................................................78
5.8.3 System Background Debug Force Reset Register (SBDFR) ............................................79
5.8.4 System Options Register 1 (SOPT1) ................................................................................80
5.8.5 System Options Register 2 (SOPT2) ................................................................................81
5.8.6 System Device Identification Register (SDIDH, SDIDL) ................................................82
5.8.7 System Power Management Status and Control 1 Register (SPMSC1) ...........................83
5.8.8 System Power Management Status and Control 2 Register (SPMSC2) ...........................84
Chapter 6
Parallel Input/Output Control
6.1
6.2
6.3
Port Data and Data Direction ...........................................................................................................85
Pull-up, Slew Rate, and Drive Strength............................................................................................86
Pin Interrupts ....................................................................................................................................87
6.3.1 Edge Only Sensitivity .......................................................................................................87
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Section Number
6.4
6.5
Title
Page
6.3.2 Edge and Level Sensitivity ................................................................................................88
6.3.3 Pull-up/Pull-down Resistors .............................................................................................88
6.3.4 Pin Interrupt Initialization .................................................................................................88
Pin Behavior in Stop Modes.............................................................................................................88
Parallel I/O and Pin Control Registers .............................................................................................89
6.5.1 Port A Registers ................................................................................................................90
6.5.2 Port B Registers ................................................................................................................94
6.5.3 Port C Registers ................................................................................................................98
6.5.4 Port D Registers ..............................................................................................................101
6.5.5 Port E Registers ...............................................................................................................105
6.5.6 Port F Registers ...............................................................................................................108
6.5.7 Port G Registers ..............................................................................................................111
Chapter 7
Central Processor Unit (S08CPUV3)
7.1
7.2
7.3
7.4
7.5
Introduction ....................................................................................................................................115
7.1.1 Features ...........................................................................................................................115
Programmer’s Model and CPU Registers ......................................................................................116
7.2.1 Accumulator (A) .............................................................................................................116
7.2.2 Index Register (H:X) .......................................................................................................116
7.2.3 Stack Pointer (SP) ...........................................................................................................117
7.2.4 Program Counter (PC) ....................................................................................................117
7.2.5 Condition Code Register (CCR) .....................................................................................117
Addressing Modes..........................................................................................................................119
7.3.1 Inherent Addressing Mode (INH) ...................................................................................119
7.3.2 Relative Addressing Mode (REL) ...................................................................................119
7.3.3 Immediate Addressing Mode (IMM) ..............................................................................119
7.3.4 Direct Addressing Mode (DIR) ......................................................................................119
7.3.5 Extended Addressing Mode (EXT) ................................................................................120
7.3.6 Indexed Addressing Mode ..............................................................................................120
Special Operations..........................................................................................................................121
7.4.1 Reset Sequence ...............................................................................................................121
7.4.2 Interrupt Sequence ..........................................................................................................121
7.4.3 Wait Mode Operation ......................................................................................................122
7.4.4 Stop Mode Operation ......................................................................................................122
7.4.5 BGND Instruction ...........................................................................................................123
HCS08 Instruction Set Summary ...................................................................................................124
Chapter 8
Multi-Purpose Clock Generator (S08MCGV1)
8.1
Introduction ....................................................................................................................................135
8.1.1 Features ...........................................................................................................................137
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
11
Section Number
8.2
8.3
8.4
8.5
Title
Page
8.1.2 Modes of Operation ........................................................................................................139
External Signal Description ...........................................................................................................139
Register Definition .........................................................................................................................140
8.3.1 MCG Control Register 1 (MCGC1) ...............................................................................140
8.3.2 MCG Control Register 2 (MCGC2) ...............................................................................141
8.3.3 MCG Trim Register (MCGTRM) ...................................................................................142
8.3.4 MCG Status and Control Register (MCGSC) .................................................................143
8.3.5 MCG Control Register 3 (MCGC3) ...............................................................................144
Functional Description ...................................................................................................................146
8.4.1 Operational Modes ..........................................................................................................146
8.4.2 Mode Switching ..............................................................................................................150
8.4.3 Bus Frequency Divider ...................................................................................................151
8.4.4 Low Power Bit Usage .....................................................................................................151
8.4.5 Internal Reference Clock ................................................................................................151
8.4.6 External Reference Clock ...............................................................................................151
8.4.7 Fixed Frequency Clock ...................................................................................................152
Initialization / Application Information .........................................................................................152
8.5.1 MCG Module Initialization Sequence ............................................................................152
8.5.2 MCG Mode Switching ....................................................................................................153
8.5.3 Calibrating the Internal Reference Clock (IRC) .............................................................164
Chapter 9
Analog Comparator (S08ACMPV3)
9.1
9.2
9.3
9.4
Introduction ....................................................................................................................................167
9.1.1 ACMP Configuration Information ..................................................................................167
9.1.2 Features ...........................................................................................................................169
9.1.3 Modes of Operation ........................................................................................................169
9.1.4 Block Diagram ................................................................................................................170
External Signal Description ...........................................................................................................170
Memory Map/Register Definition ..................................................................................................171
9.3.1 ACMPx Status and Control Register (ACMPxSC) .........................................................171
Functional Description ...................................................................................................................172
Chapter 10
Analog-to-Digital Converter (S08ADC12V1)
10.1 Introduction ....................................................................................................................................173
10.1.1 Analog Power and Ground Signal Names ......................................................................173
10.1.2 Channel Assignments ......................................................................................................173
10.1.3 Alternate Clock ...............................................................................................................174
10.1.4 Hardware Trigger ............................................................................................................174
10.1.5 Temperature Sensor ........................................................................................................175
10.1.6 Features ...........................................................................................................................177
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Section Number
Title
Page
10.1.7 ADC Module Block Diagram .........................................................................................177
10.2 External Signal Description ...........................................................................................................178
10.2.1 Analog Power (VDDAD) ..................................................................................................179
10.2.2 Analog Ground (VSSAD) .................................................................................................179
10.2.3 Voltage Reference High (VREFH) ...................................................................................179
10.2.4 Voltage Reference Low (VREFL) .....................................................................................179
10.2.5 Analog Channel Inputs (ADx) ........................................................................................179
10.3 Register Definition .........................................................................................................................179
10.3.1 Status and Control Register 1 (ADCSC1) ......................................................................179
10.3.2 Status and Control Register 2 (ADCSC2) ......................................................................181
10.3.3 Data Result High Register (ADCRH) .............................................................................181
10.3.4 Data Result Low Register (ADCRL) ..............................................................................182
10.3.5 Compare Value High Register (ADCCVH) ....................................................................182
10.3.6 Compare Value Low Register (ADCCVL) .....................................................................183
10.3.7 Configuration Register (ADCCFG) ................................................................................183
10.3.8 Pin Control 1 Register (APCTL1) ..................................................................................184
10.3.9 Pin Control 2 Register (APCTL2) ..................................................................................185
10.3.10Pin Control 3 Register (APCTL3) ..................................................................................186
10.4 Functional Description ...................................................................................................................187
10.4.1 Clock Select and Divide Control ....................................................................................188
10.4.2 Input Select and Pin Control ...........................................................................................188
10.4.3 Hardware Trigger ............................................................................................................188
10.4.4 Conversion Control .........................................................................................................188
10.4.5 Automatic Compare Function .........................................................................................191
10.4.6 MCU Wait Mode Operation ............................................................................................191
10.4.7 MCU Stop3 Mode Operation ..........................................................................................192
10.4.8 MCU Stop2 Mode Operation ..........................................................................................192
10.5 Initialization Information ...............................................................................................................193
10.5.1 ADC Module Initialization Example .............................................................................193
10.6 Application Information.................................................................................................................195
10.6.1 External Pins and Routing ..............................................................................................195
10.6.2 Sources of Error ..............................................................................................................196
Chapter 11
Inter-Integrated Circuit (S08IICV2)
11.1 Introduction ....................................................................................................................................199
11.1.1 Features ...........................................................................................................................201
11.1.2 Modes of Operation ........................................................................................................201
11.1.3 Block Diagram ................................................................................................................202
11.2 External Signal Description ...........................................................................................................202
11.2.1 SCL — Serial Clock Line ...............................................................................................202
11.2.2 SDA — Serial Data Line ................................................................................................202
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
13
Section Number
Title
Page
11.3 Register Definition .........................................................................................................................202
11.3.1 IIC Address Register (IICA) ...........................................................................................203
11.3.2 IIC Frequency Divider Register (IICF) ...........................................................................203
11.3.3 IIC Control Register (IICC1) ..........................................................................................206
11.3.4 IIC Status Register (IICS) ...............................................................................................207
11.3.5 IIC Data I/O Register (IICD) ..........................................................................................208
11.3.6 IIC Control Register 2 (IICC2) .......................................................................................208
11.4 Functional Description ...................................................................................................................209
11.4.1 IIC Protocol .....................................................................................................................209
11.4.2 10-bit Address .................................................................................................................213
11.4.3 General Call Address ......................................................................................................214
11.5 Resets .............................................................................................................................................214
11.6 Interrupts ........................................................................................................................................214
11.6.1 Byte Transfer Interrupt ....................................................................................................214
11.6.2 Address Detect Interrupt .................................................................................................214
11.6.3 Arbitration Lost Interrupt ................................................................................................214
11.7 Initialization/Application Information ...........................................................................................216
Chapter 12
Freescale Controller Area Network (S08MSCANV1)
12.1 Introduction ....................................................................................................................................219
12.1.1 Features ...........................................................................................................................221
12.1.2 Modes of Operation ........................................................................................................221
12.1.3 Block Diagram ................................................................................................................222
12.2 External Signal Description ...........................................................................................................222
12.2.1 RXCAN — CAN Receiver Input Pin .............................................................................222
12.2.2 TXCAN — CAN Transmitter Output Pin .....................................................................222
12.2.3 CAN System ...................................................................................................................222
12.3 Register Definition .........................................................................................................................223
12.3.1 MSCAN Control Register 0 (CANCTL0) ......................................................................223
12.3.2 MSCAN Control Register 1 (CANCTL1) ......................................................................226
12.3.3 MSCAN Bus Timing Register 0 (CANBTR0) ...............................................................227
12.3.4 MSCAN Bus Timing Register 1 (CANBTR1) ...............................................................228
12.3.5 MSCAN Receiver Interrupt Enable Register (CANRIER) .............................................231
12.3.6 MSCAN Transmitter Flag Register (CANTFLG) ..........................................................232
12.3.7 MSCAN Transmitter Interrupt Enable Register (CANTIER) ........................................233
12.3.8 MSCAN Transmitter Message Abort Request Register (CANTARQ) ...........................234
12.3.9 MSCAN Transmitter Message Abort Acknowledge Register (CANTAAK) .................235
12.3.10MSCAN Transmit Buffer Selection Register (CANTBSEL) .........................................235
12.3.11MSCAN Identifier Acceptance Control Register (CANIDAC) ......................................236
12.3.12MSCAN Miscellaneous Register (CANMISC) ..............................................................237
12.3.13MSCAN Receive Error Counter (CANRXERR) ............................................................238
MC9S08DZ60 Series Data Sheet, Rev. 4
14
Freescale Semiconductor
Section Number
Title
Page
12.3.14MSCAN Transmit Error Counter (CANTXERR) ..........................................................239
12.3.15MSCAN Identifier Acceptance Registers (CANIDAR0-7) ............................................239
12.3.16MSCAN Identifier Mask Registers (CANIDMR0–CANIDMR7) .................................240
12.4 Programmer’s Model of Message Storage .....................................................................................241
12.4.1 Identifier Registers (IDR0–IDR3) ...................................................................................244
12.4.2 IDR0–IDR3 for Standard Identifier Mapping .................................................................246
12.4.3 Data Segment Registers (DSR0-7) .................................................................................247
12.4.4 Data Length Register (DLR) ...........................................................................................248
12.4.5 Transmit Buffer Priority Register (TBPR) ......................................................................249
12.4.6 Time Stamp Register (TSRH–TSRL) .............................................................................249
12.5 Functional Description ...................................................................................................................250
12.5.1 General ............................................................................................................................250
12.5.2 Message Storage .............................................................................................................251
12.5.3 Identifier Acceptance Filter .............................................................................................254
12.5.4 Modes of Operation ........................................................................................................261
12.5.5 Low-Power Options ........................................................................................................262
12.5.6 Reset Initialization ..........................................................................................................268
12.5.7 Interrupts .........................................................................................................................268
12.6 Initialization/Application Information ...........................................................................................270
12.6.1 MSCAN initialization .....................................................................................................270
12.6.2 Bus-Off Recovery ...........................................................................................................271
Chapter 13
Serial Peripheral Interface (S08SPIV3)
13.1 Introduction ....................................................................................................................................273
13.1.1 Features ...........................................................................................................................275
13.1.2 Block Diagrams ..............................................................................................................275
13.1.3 SPI Baud Rate Generation ..............................................................................................277
13.2 External Signal Description ...........................................................................................................278
13.2.1 SPSCK — SPI Serial Clock ............................................................................................278
13.2.2 MOSI — Master Data Out, Slave Data In ......................................................................278
13.2.3 MISO — Master Data In, Slave Data Out ......................................................................278
13.2.4 SS — Slave Select ...........................................................................................................278
13.3 Modes of Operation........................................................................................................................279
13.3.1 SPI in Stop Modes ..........................................................................................................279
13.4 Register Definition .........................................................................................................................279
13.4.1 SPI Control Register 1 (SPIC1) ......................................................................................279
13.4.2 SPI Control Register 2 (SPIC2) ......................................................................................280
13.4.3 SPI Baud Rate Register (SPIBR) ....................................................................................281
13.4.4 SPI Status Register (SPIS) ..............................................................................................282
13.4.5 SPI Data Register (SPID) ................................................................................................283
13.5 Functional Description ...................................................................................................................284
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
15
Section Number
Title
Page
13.5.1 SPI Clock Formats ..........................................................................................................284
13.5.2 SPI Interrupts ..................................................................................................................287
13.5.3 Mode Fault Detection .....................................................................................................287
Chapter 14
Serial Communications Interface (S08SCIV4)
14.1 Introduction ....................................................................................................................................289
14.1.1 SCI2 Configuration Information .....................................................................................289
14.1.2 Features ...........................................................................................................................291
14.1.3 Modes of Operation ........................................................................................................291
14.1.4 Block Diagram ................................................................................................................292
14.2 Register Definition .........................................................................................................................294
14.2.1 SCI Baud Rate Registers (SCIxBDH, SCIxBDL) ..........................................................294
14.2.2 SCI Control Register 1 (SCIxC1) ...................................................................................295
14.2.3 SCI Control Register 2 (SCIxC2) ...................................................................................296
14.2.4 SCI Status Register 1 (SCIxS1) ......................................................................................297
14.2.5 SCI Status Register 2 (SCIxS2) ......................................................................................299
14.2.6 SCI Control Register 3 (SCIxC3) ...................................................................................300
14.2.7 SCI Data Register (SCIxD) .............................................................................................301
14.3 Functional Description ...................................................................................................................301
14.3.1 Baud Rate Generation .....................................................................................................301
14.3.2 Transmitter Functional Description ................................................................................302
14.3.3 Receiver Functional Description .....................................................................................303
14.3.4 Interrupts and Status Flags ..............................................................................................305
14.3.5 Additional SCI Functions ...............................................................................................306
Chapter 15
Real-Time Counter (S08RTCV1)
15.1 Introduction ....................................................................................................................................309
15.1.1 RTC Clock Signal Names ...............................................................................................309
15.1.2 Features ...........................................................................................................................311
15.1.3 Modes of Operation ........................................................................................................311
15.1.4 Block Diagram ................................................................................................................312
15.2 External Signal Description ...........................................................................................................312
15.3 Register Definition .........................................................................................................................312
15.3.1 RTC Status and Control Register (RTCSC) ....................................................................313
15.3.2 RTC Counter Register (RTCCNT) ..................................................................................314
15.3.3 RTC Modulo Register (RTCMOD) ................................................................................314
15.4 Functional Description ...................................................................................................................314
15.4.1 RTC Operation Example .................................................................................................315
15.5 Initialization/Application Information ...........................................................................................316
MC9S08DZ60 Series Data Sheet, Rev. 4
16
Freescale Semiconductor
Section Number
Title
Page
Chapter 16
Timer Pulse-Width Modulator (S08TPMV3)
16.1 Introduction ....................................................................................................................................319
16.1.1 Features ...........................................................................................................................321
16.1.2 Modes of Operation ........................................................................................................321
16.1.3 Block Diagram ................................................................................................................322
16.2 Signal Description ..........................................................................................................................324
16.2.1 Detailed Signal Descriptions ...........................................................................................324
16.3 Register Definition .........................................................................................................................328
16.3.1 TPM Status and Control Register (TPMxSC) ................................................................328
16.3.2 TPM-Counter Registers (TPMxCNTH:TPMxCNTL) ....................................................329
16.3.3 TPM Counter Modulo Registers (TPMxMODH:TPMxMODL) ....................................330
16.3.4 TPM Channel n Status and Control Register (TPMxCnSC) ..........................................331
16.3.5 TPM Channel Value Registers (TPMxCnVH:TPMxCnVL) ..........................................333
16.4 Functional Description ...................................................................................................................334
16.4.1 Counter ............................................................................................................................335
16.4.2 Channel Mode Selection .................................................................................................337
16.5 Reset Overview ..............................................................................................................................340
16.5.1 General ............................................................................................................................340
16.5.2 Description of Reset Operation .......................................................................................340
16.6 Interrupts ........................................................................................................................................340
16.6.1 General ............................................................................................................................340
16.6.2 Description of Interrupt Operation ..................................................................................341
16.7 The Differences from TPM v2 to TPM v3.....................................................................................342
Chapter 17
Development Support
17.1 Introduction ....................................................................................................................................347
17.1.1 Forcing Active Background ............................................................................................347
17.1.2 Features ...........................................................................................................................348
17.2 Background Debug Controller (BDC) ...........................................................................................348
17.2.1 BKGD Pin Description ...................................................................................................349
17.2.2 Communication Details ..................................................................................................350
17.2.3 BDC Commands .............................................................................................................354
17.2.4 BDC Hardware Breakpoint .............................................................................................356
17.3 On-Chip Debug System (DBG) .....................................................................................................357
17.3.1 Comparators A and B ......................................................................................................357
17.3.2 Bus Capture Information and FIFO Operation ...............................................................357
17.3.3 Change-of-Flow Information ..........................................................................................358
17.3.4 Tag vs. Force Breakpoints and Triggers .........................................................................358
17.3.5 Trigger Modes .................................................................................................................359
17.3.6 Hardware Breakpoints ....................................................................................................361
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
17
Section Number
Title
Page
17.4 Register Definition .........................................................................................................................361
17.4.1 BDC Registers and Control Bits .....................................................................................361
17.4.2 System Background Debug Force Reset Register (SBDFR) ..........................................363
17.4.3 DBG Registers and Control Bits .....................................................................................364
Appendix A
Electrical Characteristics
A.1
A.2
A.3
A.4
A.5
A.6
A.7
A.8
A.9
A.10
A.11
A.12
Introduction ...................................................................................................................................369
Parameter Classification ................................................................................................................369
Absolute Maximum Ratings ..........................................................................................................369
Thermal Characteristics .................................................................................................................370
ESD Protection and Latch-Up Immunity ......................................................................................372
DC Characteristics .........................................................................................................................373
Supply Current Characteristics ......................................................................................................375
Analog Comparator (ACMP) Electricals ......................................................................................376
ADC Characteristics ......................................................................................................................376
External Oscillator (XOSC) Characteristics .................................................................................380
MCG Specifications ......................................................................................................................381
AC Characteristics .........................................................................................................................383
A.12.1 Control Timing ...............................................................................................................383
A.12.2 Timer/PWM ....................................................................................................................384
A.12.3 MSCAN ..........................................................................................................................385
A.12.4 SPI ...................................................................................................................................386
A.13 Flash and EEPROM ......................................................................................................................389
A.14 EMC Performance .........................................................................................................................390
A.14.1 Radiated Emissions .........................................................................................................390
Appendix B
Timer Pulse-Width Modulator (TPMV2)
B.0.1 Features ...........................................................................................................................391
B.0.2 Block Diagram ................................................................................................................391
B.1 External Signal Description ...........................................................................................................393
B.1.1 External TPM Clock Sources ..........................................................................................393
B.1.2 TPMxCHn — TPMx Channel n I/O Pins .......................................................................393
B.2 Register Definition .........................................................................................................................393
B.2.1 Timer Status and Control Register (TPMxSC) ...............................................................394
B.2.2 Timer Counter Registers (TPMxCNTH:TPMxCNTL) ...................................................395
B.2.3 Timer Counter Modulo Registers (TPMxMODH:TPMxMODL) ..................................396
B.2.4 Timer Channel n Status and Control Register (TPMxCnSC) .........................................397
B.2.5 Timer Channel Value Registers (TPMxCnVH:TPMxCnVL) .........................................398
B.3 Functional Description ...................................................................................................................399
B.3.1 Counter ............................................................................................................................399
MC9S08DZ60 Series Data Sheet, Rev. 4
18
Freescale Semiconductor
Section Number
Title
Page
B.3.2 Channel Mode Selection .................................................................................................400
B.3.3 Center-Aligned PWM Mode ...........................................................................................402
B.4 TPM Interrupts ...............................................................................................................................403
B.4.1 Clearing Timer Interrupt Flags .......................................................................................403
B.4.2 Timer Overflow Interrupt Description ............................................................................403
B.4.3 Channel Event Interrupt Description ..............................................................................404
B.4.4 PWM End-of-Duty-Cycle Events ...................................................................................404
Appendix C
Ordering Information and Mechanical Drawings
C.1 Ordering Information ....................................................................................................................405
C.1.1 MC9S08DZ60 Series Devices ........................................................................................405
C.2 Mechanical Drawings ....................................................................................................................405
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
19
Chapter 1
Device Overview
MC9S08DZ60 Series devices provide significant value to customers looking to combine Controller Area
Network (CAN) and embedded EEPROM in their applications. This combination will provide lower costs,
enhanced performance, and higher quality.
1.1
Devices in the MC9S08DZ60 Series
This data sheet covers members of the MC9S08DZ60 Series of MCUs:
• MC9S08DZ60
• MC9S08DZ48
• MC9S08DZ32
• MC9S08DZ16
Table 1-1 summarizes the feature set available in the MC9S08DZ60 Series.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
21
Chapter 1 Device Overview
t
Table 1-1. MC9S08DZ60 Series Features by MCU and Pin Count
Feature
MC9S08DZ60
MC9S08DZ48
MC9S08DZ32
MC9S08DZ16
Flash size
(bytes)
60032
49152
33792
16896
RAM size (bytes)
4096
3072
2048
1024
EEPROM size
(bytes)
2048
1536
1024
512
Pin quantity
64
48
32
64
48
no
yes
yes1
10
24
16
ACMP1
32
64
48
32
48
32
no
yes
yes1
no
yes1
no
10
24
16
10
16
10
6
6
4
6
4
yes
1
ACMP2
yes
yes
ADC channels
24
16
DBG
yes
IIC
yes
IRQ
yes
MCG
yes
MSCAN
yes
RTC
yes
SCI1
yes
SCI2
yes
SPI
yes
TPM1 channels
6
6
4
TPM2 channels
6
6
4
2
XOSC
yes
COP Watchdog
yes
1
1.2
ACMP2O is not available.
MCU Block Diagram
Figure 1-1 is the MC9S08DZ60 Series system-level block diagram.
MC9S08DZ60 Series Data Sheet, Rev. 4
22
Freescale Semiconductor
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 1 Device Overview
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER Flash
MC9S08DZ60 = 60K
MC9S08DZ48 = 48K
MC9S08DZ32 = 32K
MC9S08DZ16 = 16K
USER EEPROM
MC9S08DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S08DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TXCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 1-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
23
Chapter 1 Device Overview
Table 1-2 provides the functional version of the on-chip modules.
Table 1-2. Module Versions
Module
Central Processor Unit
(CPU)
3
Multi-Purpose Clock Generator
(MCG)
1
Analog Comparator
(ACMP)
3
Analog-to-Digital Converter
(ADC)
1
Inter-Integrated Circuit
(IIC)
2
Freescale’s CAN
(MSCAN)
1
Serial Peripheral Interface
(SPI)
3
Serial Communications Interface
(SCI)
4
Real-Time Counter
(RTC)
1
Timer Pulse Width Modulator
(TPM)
31
Debug Module
(DBG)
2
1
1.3
Version
3M05C and older masks have TPM version 2.
System Clock Distribution
Figure 1-2 shows a simplified clock connection diagram. Some modules in the MCU have selectable clock
inputs as shown. The clock inputs to the modules indicate the clock(s) that are used to drive the module
function.
The following are the clocks used in this MCU:
• BUSCLK — The frequency of the bus is always half of MCGOUT.
• LPO — Independent 1-kHz clock that can be selected as the source for the COP and RTC modules.
• MCGOUT — Primary output of the MCG and is twice the bus frequency.
• MCGLCLK — Development tools can select this clock source to speed up BDC communications
in systems where BUSCLK is configured to run at a very slow frequency.
• MCGERCLK — External reference clock can be selected as the RTC clock source. It can also be
used as the alternate clock for the ADC and MSCAN.
• MCGIRCLK — Internal reference clock can be selected as the RTC clock source.
• MCGFFCLK — Fixed frequency clock can be selected as clock source for the TPM1 and TPM2.
• TPM1CLK — External input clock source for TPM1.
• TPM2CLK — External input clock source for TPM2.
MC9S08DZ60 Series Data Sheet, Rev. 4
24
Freescale Semiconductor
Chapter 1 Device Overview
1 kHZ
LPO
COP
RTC
TPM1CLK
TPM2CLK
TPM1
TPM2
IIC
SCI1
SCI2
SPI
MCGERCLK
MCGIRCLK
MCGFFCLKVALID
MCG
MCGFFCLK
÷2
FFCLK*
1
0
MCGOUT
÷2
BUSCLK
MCGLCLK
XOSC
CPU
EXTAL
BDC
XTAL
* The fixed frequency clock (FFCLK) is internally
synchronized to the bus clock and must not exceed one half
of the bus clock frequency.
ADC
MSCAN
ADC has min and
max frequency
requirements.See
the ADC chapter and
electricals appendix
for details.
FLASH
EEPROM
Flash and
EEPROM have
frequency
requirements for
program and
erase operation.
See the
electricals
appendix for
details.
Figure 1-2. MC9S08DZ60 System Clock Distribution Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
25
Chapter 1 Device Overview
MC9S08DZ60 Series Data Sheet, Rev. 4
26
Freescale Semiconductor
Chapter 2
Pins and Connections
This section describes signals that connect to package pins. It includes pinout diagrams, recommended
system connections, and detailed discussions of signals.
2.1
Device Pin Assignment
64-Pin
LQFP
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
PTB1/PIB1/ADP9
PTC2/ADP18
PTA0/PIA0/ADP0/MCLK
PTC1/ADP17
PTB0/PIB0/ADP8
PTC0/ADP16
BKGD/MS
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
VDD
VSS
PTF7
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTE2/SS
PTE3/SPSCK
PTE4/SCL/MOSI
PTE5/SDA/MISO
PTG2
PTG3
PTF0/TxD2
PTF1/RxD2
PTF2/TPM1CLK/SCL
PTF3/TPM2CLK/SDA
PTG4
PTG5
PTE6/TxD2/TXCAN
PTE7/RxD2/RXCAN
PTD0/PID0/TPM2CH0
PTD1/PID1/TPM2CH1
PTB6/PIB6/ADP14
PTC5/ADP21
PTA7/PIA7/ADP7/IRQ
PTC6/ADP22
PTB7/PIB7/ADP15
PTC7/ADP23
VDD
VSS
PTG0/EXTAL
PTG1/XTAL
RESET
PTF4/ACMP2+
PTF5/ACMP2PTF6/ACMP2O
PTE0/TxD1
PTE1/RxD1
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
PTA6/PIA6/ADP6
PTB5/PIB5/ADP13
PTA5/PIA5/ADP5
PTC4/ADP20
PTB4/PIB4/ADP12
PTA4/PIA4/ADP4
VDDA
VREFH
VREFL
VSSA
PTA3/PIA3/ADP3/ACMP1O
PTB3/PIB3/ADP11
PTC3/ADP19
PTA2/PIA2/ADP2/ACMP1PTB2/PIB2/ADP10
PTA1/PIA1/ADP1/ACMP1+
This section shows the pin assignments for MC9S08DZ60 Series MCUs in the available packages.
Figure 2-1. 64-Pin LQFP
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
27
48-Pin LQFP
13
14
15
16
17
18
19
20
21
22
23
24
1
2
3
4
5
6
7
8
9
10
11
12
36
35
34
33
32
31
30
29
28
27
26
25
PTB1/PIB1/ADP9
PTA0/PIA0/ADP0/MCLK
PTB0/PIB0/ADP8
BKGD/MS
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
VDD
VSS
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTE2/SS
PTE3/SPSCK
PTE4/SCL/MOSI
PTE5/SDA/MISO
PTF0/TxD2
PTF1/RxD2
PTF2/TPM1CLK/SCL
PTF3/TPM2CLK/SDA
PTE6/TxD2/TXCAN
PTE7/RxD2/RXCAN
PTD0/PID0/TPM2CH0
PTD1/PID1/TPM2CH1
PTB6/PIB6/ADP14
PTA7/PIA7/ADP7/IRQ
PTB7/PIB7/ADP15
VDD
VSS
PTG0/EXTAL
PTG1/XTAL
RESET
PTF4/ACMP2+
PTF5/ACMP2PTE0/TxD1
PTE1/RxD1
48
47
46
45
44
43
42
41
40
39
38
37
PTA6/PIA6/ADP6
PTB5/PIB5/ADP13
PTA5/PIA5/ADP5
PTB4/PIB4/ADP12
PTA4/PIA4/ADP4
VDDA/VREFH
VSSA/VREFL
PTA3/PIA3/ADP3/ACMP1O
PTB3/PIB3/ADP11
PTA2/PIA2/ADP2/ACMP1PTB2/PIB2/ADP10
PTA1/PIA1/ADP1/ACMP1+
Chapter 2 Pins and Connections
VREFH and VREFL are internally connected to VDDA and VSSA, respectively.
Figure 2-2. 48-Pin LQFP
MC9S08DZ60 Series Data Sheet, Rev. 4
28
Freescale Semiconductor
PTA4/PIA4/ADP4
VDDA/VREFH
VSSA/VREFL
PTA3/ADP3/ACMPO
PTA2/ADP2/ACMP-
31
30
29
28
27
26
25
32
PTA7/PIA7/ADP7/IRQ 1
PTA1/ADP1/ACMP+
PTA5/PIA5/ADP5
PTA6/PIA6/ADP6
Chapter 2 Pins and Connections
24 PTB1/PIB1/ADP9
VDD
2
23
PTA0/PIA0/ADP0/MCLK
VSS
3
22
PTB0/PIB0/ADP8
PTG0/EXTAL
4
21
BKGD/MS
PTG1/XTAL
5
20
PTD5/PID5/TPM1CH3
RESET
6
19
PTD4/PID4/TPM1CH2
PTE0/TxD1
7
18
PTD3/PID3/TPM1CH1
8
10
11
12
13
14
9
PTD0/PID0/TPM2CH0
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
16
PTE3/SPSCK
PTE2/SS
17 PTD2/PID2/TPM1CH0
15
PTD1/PID1/TPM2CH1
PTE1/RxD1
32-Pin LQFP
VREFH and VREFL are internally connected to VDDA and VSSA, respectively.
Figure 2-3. 32-Pin LQFP
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
29
Chapter 2 Pins and Connections
2.2
Recommended System Connections
Figure 2-4 shows pin connections that are common to MC9S08DZ60 Series application systems.
MC9S08DZ60
PTA0/PIA0/ADP0/MCLK
VDD
+
PTA1/PIA1/ADP1/ACMP1+
CBY
0.1 μF
CBLK +
10 μF
5V
PTA2/PIA2/ADP2/ACMP1VSS
SYSTEM
POWER
CBY
0.1 μF
PORT
A
VDDA
VREFH
VREFL
VSSA
PTA3/PIA3/ADP3/ACMP1O
PTA4/PIA4/ADP4
PTA5/PIA5/ADP5
PTA6/PIA6/ADP6
IRQ
PTA7/PIA7/ADP7/IRQ
PTB0/PIB0/ADP8
PTB1/PIB1/ADP9
BACKGROUND HEADER
VDD
BKGD/MS
VDD
PORT
B
4.7 kΩ–10 kΩ
PTB2/PIB2/ADP10
PTB3/PIB3/ADP11
PTB4/PIB4/ADP12
PTB5/PIB5/ADP13
PTB6/PIB6/ADP14
PTB7/PIB7/ADP15
RESET
OPTIONAL
MANUAL
RESET
0.1 μF
PORT
C
RF
C1
X1
NOTES:
1. External crystal circuit not
required if using the
internal clock option.
2. RESET pin can only be
used to reset into user
mode, you can not enter
BDM using RESET pin.
BDM can be entered by
holding MS low during
POR or writing a 1 to
BDFR in SBDFR with MS
low after issuing BDM
command.
3. RC filter on RESET pin
recommended for noisy
environments.
4. For 32-pin and 48-pin
packages: VDDA and VSSA
are double bonded to
VREFH and VREFL
respectively.
PTC0/ADP16
PTC1/ADP17
PTC2/ADP18
PTC3/ADP19
PTC4/ADP20
PTC5/ADP21
PTC6/ADP22
PTC7/ADP23
RS
PTD0/PID0/TPM2CH0
PTD1/PID1/TPM2CH1
C2
PTG0/EXTAL
PTG1/XTAL
PTG2
PTG3
PTD2/PID2/TPM1CH0
PORT
G
PORT
D
PTD4/PID4/TPM1CH2
PTD5/PID5/TPM1CH3
PTD6/PID6/TPM1CH4
PTD7/PID7/TPM1CH5
PTG4
PTG5
PTF0/TxD2
PTF1/RxD2
PTF2/TPM1CLK/SCL
PTF3/TPM2CLK/SDA
PTF4/ACMP2+
PTF5/ACMP2–
PTF6/ACMP2O
PTF7
PTD3/PID3/TPM1CH1
PORT
F
PORT
E
PTE0/TxD1
PTE1/RxD1
PTE2/SS
PTE3/SPSCK
PTE4/SCL/MOSI
PTE5/SDA/MISO
PTE6/TxD2/TXCAN
PTE7/RxD2/RXCAN
Figure 2-4. Basic System Connections (Shown in 64-Pin Package)
MC9S08DZ60 Series Data Sheet, Rev. 4
30
Freescale Semiconductor
Chapter 2 Pins and Connections
2.2.1
Power
VDD and VSS are the primary power supply pins for the MCU. This voltage source supplies power to all
I/O buffer circuitry and to an internal voltage regulator. The internal voltage regulator provides regulated
lower-voltage source to the CPU and other internal circuitry of the MCU.
Typically, application systems have two separate capacitors across the power pins. In this case, there
should be a bulk electrolytic capacitor, such as a 10-μF tantalum capacitor, to provide bulk charge storage
for the overall system and a 0.1-μF ceramic bypass capacitor located as near to the MCU power pins as
practical to suppress high-frequency noise. The MC9S08DZ60 Series has two VDD pins except on the
32-pin package. Each pin must have a bypass capacitor for best noise suppression.
VDDA and VSSA are the analog power supply pins for the MCU. This voltage source supplies power to the
ADC module. A 0.1-μF ceramic bypass capacitor should be located as near to the MCU power pins as
practical to suppress high-frequency noise.
2.2.2
Oscillator
Immediately after reset, the MCU uses an internally generated clock provided by the multi-purpose clock
generator (MCG) module. For more information on the MCG, see Chapter 8, “Multi-Purpose Clock
Generator (S08MCGV1).”
The oscillator (XOSC) in this MCU is a Pierce oscillator that can accommodate a crystal or ceramic
resonator. Rather than a crystal or ceramic resonator, an external oscillator can be connected to the EXTAL
input pin.
Refer to Figure 2-4 for the following discussion. RS (when used) and RF should be low-inductance
resistors such as carbon composition resistors. Wire-wound resistors and some metal film resistors have
too much inductance. C1 and C2 normally should be high-quality ceramic capacitors that are specifically
designed for high-frequency applications.
RF is used to provide a bias path to keep the EXTAL input in its linear range during crystal startup; its value
is not generally critical. Typical systems use 1 MΩ to 10 MΩ. Higher values are sensitive to humidity, and
lower values reduce gain and (in extreme cases) could prevent startup.
C1 and C2 are typically in the 5-pF to 25-pF range and are chosen to match the requirements of a specific
crystal or resonator. Be sure to take into account printed circuit board (PCB) capacitance and MCU pin
capacitance when selecting C1 and C2. The crystal manufacturer typically specifies a load capacitance
which is the series combination of C1 and C2 (which are usually the same size). As a first-order
approximation, use 10 pF as an estimate of combined pin and PCB capacitance for each oscillator pin
(EXTAL and XTAL).
2.2.3
RESET
RESET is a dedicated pin with a pull-up device built in. It has input hysteresis, a high current output driver,
and no output slew rate control. Internal power-on reset and low-voltage reset circuitry typically make
external reset circuitry unnecessary. This pin is normally connected to the standard 6-pin background
debug connector so a development system can directly reset the MCU system. If desired, a manual external
reset can be added by supplying a simple switch to ground (pull reset pin low to force a reset).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
31
Chapter 2 Pins and Connections
Whenever any reset is initiated (whether from an external signal or from an internal system), the RESET
pin is driven low for about 34 bus cycles. The reset circuitry decodes the cause of reset and records it by
setting a corresponding bit in the system reset status register (SRS).
2.2.4
Background / Mode Select (BKGD/MS)
While in reset, the BKGD/MS pin functions as a mode select pin. Immediately after reset rises, the pin
functions as the background pin and can be used for background debug communication. While functioning
as a background or mode select pin, the pin includes an internal pull-up device, input hysteresis, a standard
output driver, and no output slew rate control.
If nothing is connected to this pin, the MCU will enter normal operating mode at the rising edge of reset.
If a debug system is connected to the 6-pin standard background debug header, it can hold BKGD low
during the rising edge of reset which forces the MCU to active background mode.
The BKGD/MS pin is used primarily for background debug controller (BDC) communications using a
custom protocol that uses 16 clock cycles of the target MCU’s BDC clock per bit time. The target MCU’s
BDC clock could be as fast as the bus clock rate, so there should never be any significant capacitance
connected to the BKGD/MS pin that could interfere with background serial communications.
Although the BKGD/MS pin is a pseudo open-drain pin, the background debug communication protocol
provides brief, actively driven, high speedup pulses to ensure fast rise times. Small capacitances from
cables and the absolute value of the internal pull-up device play almost no role in determining rise and fall
times on the BKGD/MS pin.
2.2.5
ADC Reference Pins (VREFH, VREFL)
The VREFH and VREFL pins are the voltage reference high and voltage reference low inputs, respectively,
for the ADC module.
2.2.6
General-Purpose I/O and Peripheral Ports
The MC9S08DZ60 Series series of MCUs support up to 53 general-purpose I/O pins and 1 input-only pin,
which are shared with on-chip peripheral functions (timers, serial I/O, ADC, MSCAN, etc.).
When a port pin is configured as a general-purpose output or a peripheral uses the port pin as an output,
software can select one of two drive strengths and enable or disable slew rate control. When a port pin is
configured as a general-purpose input or a peripheral uses the port pin as an input, software can enable a
pull-up device. Immediately after reset, all of these pins are configured as high-impedance general-purpose
inputs with internal pull-up devices disabled.
When an on-chip peripheral system is controlling a pin, data direction control bits still determine what is
read from port data registers even though the peripheral module controls the pin direction by controlling
the enable for the pin’s output buffer. For information about controlling these pins as general-purpose I/O
pins, see Chapter 6, “Parallel Input/Output Control.”
MC9S08DZ60 Series Data Sheet, Rev. 4
32
Freescale Semiconductor
Chapter 2 Pins and Connections
NOTE
To avoid extra current drain from floating input pins, the reset initialization
routine in the application program should either enable on-chip pull-up
devices or change the direction of unused or non-bonded pins to outputs so
they do not float.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
33
Chapter 2 Pins and Connections
Table 2-1. Pin Availability by Package Pin-Count
3
Pin
Number
<-- Lowest
64 48 32
Port
Pin/Interrupt
1
1
— PTB6
2
— — PTC5
3
2
1 PTA7
4
— — PTC6
5
3
— PTB7
6
— — PTC7
7
4
PIB6
PIA7
PIB7
Priority
Alt 1
5
3
9
6
4 PTG0
10
7
5 PTG1
11
8
6
Alt 2
Pin
Number
<-- Lowest
64 48 32
Port
Pin/Interrupt
TPM1CH0
ADP21
34 26 18 PTD3
PID3
TPM1CH1
ADP7
35 27 19 PTD4
PID4
TPM1CH2
ADP22
36 28 20 PTD5
PID5
TPM1CH3
ADP15
37 — — PTF7
ADP23
38 29 —
IRQ
VSS
VDD
39 30 —
VSS
40 31 — PTD6
PID6
EXTAL
41 32 — PTD7
PID7
XTAL
42 33 21
— PTF4
ACMP2+
44 34 22 PTB0
13 10 — PTF5
ACMP2-
45 — — PTC1
14 — — PTF6
ACMP2O
46 35 23 PTA0
VDD
TPM1CH4
TPM1CH5
BKGD
ADP8
ADP17
PIA0
ADP0
15 11
7 PTE0
TxD1
16 12
8 PTE12
RxD12
48 36 24 PTB1
PIB1
ADP9
SS
49 37 25 PTA1
PIA1
ADP11
9 PTE2
SPSCK
50 38 — PTB2
PIB2
ADP10
19 15 11 PTE4
SCL
MOSI
51 39 26 PTA2
PIA2
ADP21
20 16 12 PTE5
SDA3
MISO
52 — — PTC3
53 40 — PTB3
PIB3
ADP11
22 — — PTG3
54 41 27 PTA3
PIA3
ADP3
23 17 — PTF0
TxD2
55
24 18 — PTF1
RxD24
56
25 19 — PTF2
TPM1CLK SCL3
57
26 20 — PTF3
SDA3
58
TPM2CLK
27 — — PTG4
28 — — PTG5
VREFH
VDDA
59 44 30 PTA4
PIA4
60 45 — PTB4
PIB4
ADP4
ADP12
29 21 13 PTE6
4
TxD2
TXCAN
61 — — PTC4
30 22 14 PTE7
RxD24
RxCAN
62 46 31 PTA5
PIA5
ADP5
PIB5
ADP13
PIA6
ADP6
PID0
TPM2CH0
32 24 16 PTD1
PID1
TPM2CH1
64 48 32 PTA6
ACMP1O
VREFL
43 29
31 23 15 PTD0
ACMP1-1
VSSA
42 28
63 47 — PTB5
ACMP1+1
ADP19
21 — — PTG2
4
MCLK
ADP18
3
18 14 10 PTE3
MS
ADP16
PIB0
47 — — PTC2
17 13
Alt 2
PID2
43 — — PTC0
9
Alt 1
--> Highest
33 25 17 PTD2
RESET
12
Priority
ADP14
2
8
--> Highest
ADP20
1. If both of these analog modules are enabled, they both will have access to the pin.
2. Pin does not contain a clamp diode to VDD and should not be driven above VDD. The voltage measured on this pin when internal
pull-up is enabled may be as low as VDD – 0.7 V. The internal gates connected to this pin are pulled to VDD.
3. The IIC module pins can be repositioned using IICPS bit in the SOPT1 register. The default reset locations are on PTF2 and PTF3.
4. The SCI2 module pins can be repositioned using SCI2PS bit in the SOPT1 register. The default reset locations are on PTF0 and
PTF1.
MC9S08DZ60 Series Data Sheet, Rev. 4
34
Freescale Semiconductor
Chapter 3
Modes of Operation
3.1
Introduction
The operating modes of the MC9S08DZ60 Series are described in this chapter. Entry into each mode, exit
from each mode, and functionality while in each of the modes are described.
3.2
•
•
•
3.3
Features
Active background mode for code development
Wait mode — CPU shuts down to conserve power; system clocks are running and full regulation
is maintained
Stop modes — System clocks are stopped and voltage regulator is in standby
— Stop3 — All internal circuits are powered for fast recovery
— Stop2 — Partial power down of internal circuits; RAM content is retained
Run Mode
This is the normal operating mode for the MC9S08DZ60 Series. This mode is selected when the
BKGD/MS pin is high at the rising edge of reset. In this mode, the CPU executes code from internal
memory with execution beginning at the address fetched from memory at 0xFFFE–0xFFFF after reset.
3.4
Active Background Mode
The active background mode functions are managed through the background debug controller (BDC) in
the HCS08 core. The BDC, together with the on-chip debug module (DBG), provide the means for
analyzing MCU operation during software development.
Active background mode is entered in any of five ways:
• When the BKGD/MS pin is low at the rising edge of reset
• When a BACKGROUND command is received through the BKGD/MS pin
• When a BGND instruction is executed
• When encountering a BDC breakpoint
• When encountering a DBG breakpoint
After entering active background mode, the CPU is held in a suspended state waiting for serial background
commands rather than executing instructions from the user application program.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
35
Chapter 3 Modes of Operation
Background commands are of two types:
• Non-intrusive commands, defined as commands that can be issued while the user program is
running. Non-intrusive commands can be issued through the BKGD/MS pin while the MCU is in
run mode; non-intrusive commands can also be executed when the MCU is in the active
background mode. Non-intrusive commands include:
— Memory access commands
— Memory-access-with-status commands
— BDC register access commands
— The BACKGROUND command
• Active background commands, which can only be executed while the MCU is in active background
mode. Active background commands include commands to:
— Read or write CPU registers
— Trace one user program instruction at a time
— Leave active background mode to return to the user application program (GO)
The active background mode is used to program a bootloader or user application program into the Flash
program memory before the MCU is operated in run mode for the first time. When the MC9S08DZ60
Series is shipped from the Freescale Semiconductor factory, the Flash program memory is erased by
default unless specifically noted so there is no program that could be executed in run mode until the Flash
memory is initially programmed. The active background mode can also be used to erase and reprogram
the Flash memory after it has been previously programmed.
For additional information about the active background mode, refer to the Development Support chapter.
3.5
Wait Mode
Wait mode is entered by executing a WAIT instruction. Upon execution of the WAIT instruction, the CPU
enters a low-power state in which it is not clocked. The I bit in CCR is cleared when the CPU enters the
wait mode, enabling interrupts. When an interrupt request occurs, the CPU exits the wait mode and
resumes processing, beginning with the stacking operations leading to the interrupt service routine.
While the MCU is in wait mode, there are some restrictions on which background debug commands can
be used. Only the BACKGROUND command and memory-access-with-status commands are available
when the MCU is in wait mode. The memory-access-with-status commands do not allow memory access,
but they report an error indicating that the MCU is in either stop or wait mode. The BACKGROUND
command can be used to wake the MCU from wait mode and enter active background mode.
MC9S08DZ60 Series Data Sheet, Rev. 4
36
Freescale Semiconductor
Chapter 3 Modes of Operation
3.6
Stop Modes
One of two stop modes is entered upon execution of a STOP instruction when the STOPE bit in SOPT1
register is set. In both stop modes, all internal clocks are halted. The MCG module can be configured to
leave the reference clocks running. See Chapter 8, “Multi-Purpose Clock Generator (S08MCGV1),” for
more information.
Table 3-1 shows all of the control bits that affect stop mode selection and the mode selected under various
conditions. The selected mode is entered following the execution of a STOP instruction.
Table 3-1. Stop Mode Selection
STOPE
ENBDM 1
0
x
1
LVDE
LVDSE
PPDC
Stop Mode
x
x
Stop modes disabled; illegal opcode reset if STOP instruction executed
1
x
x
Stop3 with BDM enabled 2
1
0
Both bits must be 1
x
Stop3 with voltage regulator active
1
0
Either bit a 0
0
Stop3
1
0
Either bit a 0
1
Stop2
1
ENBDM is located in the BDCSCR, which is only accessible through BDC commands, see Section 17.4.1.1, “BDC Status and
Control Register (BDCSCR)”.
2 When in Stop3 mode with BDM enabled, The S
IDD will be near RIDD levels because internal clocks are enabled.
3.6.1
Stop3 Mode
Stop3 mode is entered by executing a STOP instruction under the conditions as shown in Table 3-1. The
states of all of the internal registers and logic, RAM contents, and I/O pin states are maintained.
Exit from stop3 is done by asserting RESET or an asynchronous interrupt pin. The asynchronous interrupt
pins are IRQ, PIA0–PIA7, PIB0–PIB7, and PID0–PID7. Exit from stop3 can also be done by the
low-voltage detect (LVD) reset, low-voltage warning (LVW) interrupt, ADC conversion complete
interrupt, real-time clock (RTC) interrupt, MSCAN wake-up interrupt, or SCI receiver interrupt.
If stop3 is exited by means of the RESET pin, the MCU will be reset and operation will resume after
fetching the reset vector. Exit by means of an interrupt will result in the MCU fetching the appropriate
interrupt vector.
3.6.1.1
LVD Enabled in Stop3 Mode
The LVD system is capable of generating either an interrupt or a reset when the supply voltage drops below
the LVD voltage. If the LVD is enabled in stop (LVDE and LVDSE bits in SPMSC1 both set) at the time
the CPU executes a STOP instruction, then the voltage regulator remains active during stop mode.
For the ADC to operate the LVD must be left enabled when entering stop3.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
37
Chapter 3 Modes of Operation
3.6.1.2
Active BDM Enabled in Stop3 Mode
Entry into the active background mode from run mode is enabled if ENBDM in BDCSCR is set. This
register is described in Chapter 17, “Development Support.” If ENBDM is set when the CPU executes a
STOP instruction, the system clocks to the background debug logic remain active when the MCU enters
stop mode. Because of this, background debug communication remains possible. In addition, the voltage
regulator does not enter its low-power standby state but maintains full internal regulation.
Most background commands are not available in stop mode. The memory-access-with-status commands
do not allow memory access, but they report an error indicating that the MCU is in either stop or wait
mode. The BACKGROUND command can be used to wake the MCU from stop and enter active
background mode if the ENBDM bit is set. After entering background debug mode, all background
commands are available.
3.6.2
Stop2 Mode
Stop2 mode is entered by executing a STOP instruction under the conditions as shown in Table 3-1. Most
of the internal circuitry of the MCU is powered off in stop2 with the exception of the RAM. Upon entering
stop2, all I/O pin control signals are latched so that the pins retain their states during stop2.
Exit from stop2 is performed by asserting RESET. On 3M05C or older masksets only, exit from stop2 can
also be performed by asserting PTA7/ADP7/IRQ.
NOTE
On 3M05C or older masksets only, PTA7/ADP7/IRQ is an active low
wake-up and must be configured as an input prior to executing a STOP
instruction to avoid an immediate exit from stop2. PTA7/ADP7/IRQ can be
disabled as a wake-up if it is configured as a high driven output. For lowest
power consumption in stop2, this pin should not be left open when
configured as input (enable the internal pullup; or tie an external
pullup/down device; or set pin as output).
In addition, the real-time counter (RTC) can wake the MCU from stop2, if enabled.
Upon wake-up from stop2 mode, the MCU starts up as from a power-on reset (POR):
• All module control and status registers are reset
• The LVD reset function is enabled and the MCU remains in the reset state if VDD is below the LVD
trip point (low trip point selected due to POR)
• The CPU takes the reset vector
In addition to the above, upon waking up from stop2, the PPDF bit in SPMSC2 is set. This flag is used to
direct user code to go to a stop2 recovery routine. PPDF remains set and the I/O pin states remain latched
until a 1 is written to PPDACK in SPMSC2.
MC9S08DZ60 Series Data Sheet, Rev. 4
38
Freescale Semiconductor
Chapter 3 Modes of Operation
To maintain I/O states for pins that were configured as general-purpose I/O before entering stop2, the user
must restore the contents of the I/O port registers, which have been saved in RAM, to the port registers
before writing to the PPDACK bit. If the port registers are not restored from RAM before writing to
PPDACK, then the pins will switch to their reset states when PPDACK is written.
For pins that were configured as peripheral I/O, the user must reconfigure the peripheral module that
interfaces to the pin before writing to the PPDACK bit. If the peripheral module is not enabled before
writing to PPDACK, the pins will be controlled by their associated port control registers when the I/O
latches are opened.
3.6.3
On-Chip Peripheral Modules in Stop Modes
When the MCU enters any stop mode, system clocks to the internal peripheral modules are stopped. Even
in the exception case (ENBDM = 1), where clocks to the background debug logic continue to operate,
clocks to the peripheral systems are halted to reduce power consumption. Refer to Section 3.6.2, “Stop2
Mode” and Section 3.6.1, “Stop3 Mode” for specific information on system behavior in stop modes.
Table 3-2. Stop Mode Behavior
Mode
Peripheral
Stop2
Stop3
CPU
Off
Standby
RAM
Standby
Standby
Flash/EEPROM
Off
Standby
Parallel Port Registers
Off
Standby
ACMP
Off
Off
ADC
Off
Optionally On1
IIC
Off
Standby
MCG
Off
Optionally On2
MSCAN
Off
RTC
Optionally
Standby
On3
Optionally On3
SCI
Off
Standby
SPI
Off
Standby
TPM
Off
Standby
Voltage Regulator
Off
Optionally On4
XOSC
Off
Optionally On5
States Held
States Held
I/O Pins
BDM
LVD/LVW
Off
6
Optionally On
Off
7
Optionally On
1
Requires the asynchronous ADC clock and LVD to be enabled, else in standby.
IRCLKEN and IREFSTEN set in MCGC1, else in standby.
3 Requires the RTC to be enabled, else in standby.
4
Requires the LVD or BDC to be enabled.
2
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
39
Chapter 3 Modes of Operation
5
ERCLKEN and EREFSTEN set in MCGC2 for, else in standby. For high frequency
range (RANGE in MCGC2 set) requires the LVD to also be enabled in stop3.
6
If ENBDM is set when entering stop2, the MCU will actually enter stop3.
7
If LVDSE is set when entering stop2, the MCU will actually enter stop3.
MC9S08DZ60 Series Data Sheet, Rev. 4
40
Freescale Semiconductor
Chapter 4
Memory
4.1
MC9S08DZ60 Series Memory Map
On-chip memory in the MC9S08DZ60 Series consists of RAM, EEPROM, and Flash program memory
for nonvolatile data storage, and I/O and control/status registers. The registers are divided into three
groups:
• Direct-page registers (0x0000 through 0x007F)
• High-page registers (0x1800 through 0x18FF)
• Nonvolatile registers (0xFFB0 through 0xFFBF)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
41
Chapter 4 Memory
0x0000
DIRECT PAGE REGISTERS
128 BYTES
0x007F
0x0080
RAM
4096 BYTES
2 x 1024 BYTES
0x17FF
0x1800
HIGH PAGE REGISTERS
256 BYTES
0x18FF
0x1900
UNIMPLEMENTED
3456 BYTES
UNIMPLEMENTED
2176 BYTES
FLASH
896 BYTES
EEPROM1
0x0000
DIRECT PAGE REGISTERS
128 BYTES
0x007F
0x0080
RAM
2048 BYTES
0x087F
0x0880
0x0C7F
0x0C80
0x107F
0x1080
0x13FF
0x1400
0x0000
DIRECT PAGE REGISTERS
128 BYTES
0x007F
0x0080
RAM
3072 BYTES
0x14FF
0x1500
0x15FF
0x1600
EEPROM1
2 x 768 BYTES
0x17FF
0x1800
HIGH PAGE REGISTERS
256 BYTES
0x18FF
0x1900
EEPROM1
2 x 512 BYTES
0x17FF
0x1800
HIGH PAGE REGISTERS
256 BYTES
0x18FF
0x1900
UNIMPLEMENTED
25,344 BYTES
UNIMPLEMENTED
9984 BYTES
0x3FFF
0x4000
0x0000
DIRECT PAGE REGISTERS
128 BYTES
0x007F
0x0080
RAM
1024 BYTES
0x047F
0x0480
UNIMPLEMENTED
4736 BYTES
0x16FF
0x1700
EEPROM1
0x17FF 2 x 256 BYTES
0x1800
HIGH PAGE REGISTERS
256 BYTES
0x18FF
0x1900
UNIMPLEMENTED
42,240 BYTES
0x7BFF
0x7C00
0xBDFF
0xBE00
FLASH
59136 BYTES
0xFFFF
FLASH
49152 BYTES
0xFFFF
MC9S08DZ60
1
FLASH
16896 BYTES
FLASH
33792 BYTES
0xFFFF
0xFFFF
MC9S08DZ48
MC9S08DZ16
MC9S08DZ32
EEPROM address range shows half the total EEPROM. See Section 4.5.10, “EEPROM Mapping” for more details.
Figure 4-1. MC9S08DZ60 Memory Map
4.2
Reset and Interrupt Vector Assignments
Table 4-1 shows address assignments for reset and interrupt vectors. The vector names shown in this table
are the labels used in the MC9S08DZ60 Series equate file provided by Freescale Semiconductor.
Table 4-1. Reset and Interrupt Vectors
Address
(High/Low)
Vector
Vector Name
0xFFC0:0xFFC1
ACMP2
Vacmp2
0xFFC2:0xFFC3
ACMP1
Vacmp1
0xFFC4:0xFFC5
MSCAN Transmit
Vcantx
0xFFC6:0xFFC7
MSCAN Receive
Vcanrx
0xFFC8:0xFFC9
MSCAN errors
Vcanerr
0xFFCA:0xFFCB
MSCAN wake up
Vcanwu
MC9S08DZ60 Series Data Sheet, Rev. 4
42
Freescale Semiconductor
Chapter 4 Memory
Table 4-1. Reset and Interrupt Vectors
Address
(High/Low)
Vector
Vector Name
0xFFCC:0xFFCD
RTC
Vrtc
0xFFCE:0xFFCF
IIC
Viic
0xFFD0:0xFFD1
ADC Conversion
Vadc
0xFFD2:0xFFD3
Port A, Port B, Port D
Vport
0xFFD4:0xFFD5
SCI2 Transmit
Vsci2tx
0xFFD6:0xFFD7
SCI2 Receive
Vsci2rx
0xFFD8:0xFFD9
SCI2 Error
Vsci2err
0xFFDA:0xFFDB
SCI1 Transmit
Vsci1tx
0xFFDC:0xFFDD
SCI1 Receive
Vsci1rx
0xFFDE:0xFFDF
SCI1 Error
Vsci1err
0xFFE0:0xFFE1
SPI
Vspi
0xFFE2:0xFFE3
TPM2 Overflow
Vtpm2ovf
0xFFE4:0xFFE5
TPM2 Channel 1
Vtpm2ch1
0xFFE6:0xFFE7
TPM2 Channel 0
Vtpm2ch0
0xFFE8:0xFFE9
TPM1 Overflow
Vtpm1ovf
0xFFEA:0xFFEB
TPM1 Channel 5
Vtpm1ch5
0xFFEC:0xFFED
TPM1 Channel 4
Vtpm1ch4
0xFFEE:0xFFEF
TPM1 Channel 3
Vtpm1ch3
0xFFF0:0xFFF1
TPM1 Channel 2
Vtpm1ch2
0xFFF2:0xFFF3
TPM1 Channel 1
Vtpm1ch1
0xFFF4:0xFFF5
TPM1 Channel 0
Vtpm1ch0
0xFFF6:0xFFF7
MCG Loss of lock
Vlol
0xFFF8:0xFFF9
Low-Voltage Detect
Vlvd
0xFFFA:0xFFFB
IRQ
Virq
0xFFFC:0xFFFD
SWI
Vswi
0xFFFE:0xFFFF
Reset
Vreset
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
43
Chapter 4 Memory
4.3
Register Addresses and Bit Assignments
The registers in the MC9S08DZ60 Series are divided into these groups:
• Direct-page registers are located in the first 128 locations in the memory map; these are accessible
with efficient direct addressing mode instructions.
• High-page registers are used much less often, so they are located above 0x1800 in the memory
map. This leaves more room in the direct page for more frequently used registers and RAM.
• The nonvolatile register area consists of a block of 16 locations in Flash memory at
0xFFB0–0xFFBF. Nonvolatile register locations include:
— NVPROT and NVOPT are loaded into working registers at reset
— An 8-byte backdoor comparison key that optionally allows a user to gain controlled access to
secure memory
Because the nonvolatile register locations are Flash memory, they must be erased and programmed
like other Flash memory locations.
Direct-page registers can be accessed with efficient direct addressing mode instructions. Bit manipulation
instructions can be used to access any bit in any direct-page register. Table 4-2 is a summary of all
user-accessible direct-page registers and control bits.
The direct page registers in Table 4-2 can use the more efficient direct addressing mode, which requires
only the lower byte of the address. Because of this, the lower byte of the address in column one is shown
in bold text. In Table 4-3 and Table 4-5, the whole address in column one is shown in bold. In Table 4-2,
Table 4-3, and Table 4-5, the register names in column two are shown in bold to set them apart from the
bit names to the right. Cells that are not associated with named bits are shaded. A shaded cell with a 0
indicates this unused bit always reads as a 0. Shaded cells with dashes indicate unused or reserved bit
locations that could read as 1s or 0s.
MC9S08DZ60 Series Data Sheet, Rev. 4
44
Freescale Semiconductor
Chapter 4 Memory
Table 4-2. Direct-Page Register Summary (Sheet 1 of 3)
Address
Register
Name
0x0000
0x0001
0x0002
0x0003
0x0004
0x0005
0x0006
0x0007
0x0008
0x0009
0x000A
PTAD
PTADD
PTBD
PTBDD
PTCD
PTCDD
PTDD
PTDDD
PTED
PTEDD
PTFD
0x000B
0x000C
0x000D
0x000E
0x000F
0x0010
0x0011
0x0012
0x0013
0x0014
0x0015
0x0016
0x0017
0x0018
0x0019
0x001A–
0x001B
0x001C
0x001D–
0x001F
0x0020
0x0021
0x0022
0x0023
0x0024
0x0025
0x0026
0x0027
PTFDD
PTGD
PTGDD
ACMP1SC
ACMP2SC
ADCSC1
ADCSC2
ADCRH
ADCRL
ADCCVH
ADCCVL
ADCCFG
APCTL1
APCTL2
APCTL3
Bit 7
6
5
4
3
2
1
Bit 0
PTAD7
PTAD6
PTAD5
PTAD4
PTAD3
PTAD2
PTAD1
PTAD0
PTADD7
PTADD6
PTADD5
PTADD4
PTADD3
PTADD2
PTADD1
PTADD0
PTBD7
PTBD6
PTBD5
PTBD4
PTBD3
PTBD2
PTBD1
PTBD0
PTBDD7
PTBDD6
PTBDD5
PTBDD4
PTBDD3
PTBDD2
PTBDD1
PTBDD0
PTCD7
PTCD6
PTCD5
PTCD4
PTCD3
PTCD2
PTCD1
PTCD0
PTCDD7
PTCDD6
PTCDD5
PTCDD4
PTCDD3
PTCDD2
PTCDD1
PTCDD0
PTDD7
PTDD6
PTDD5
PTDD4
PTDD3
PTDD2
PTDD1
PTDD0
PTDDD7
PTDDD6
PTDDD5
PTDDD4
PTDDD3
PTDDD2
PTDDD1
PTDDD0
PTED7
PTED6
PTED5
PTED4
PTED3
PTED2
PTED1
PTED0
PTEDD7
PTEDD6
PTEDD5
PTEDD4
PTEDD3
PTEDD2
PTEDD1
PTEDD0
PTFD7
PTFD6
PTFD5
PTFD4
PTFD3
PTFD2
PTFD1
PTFD0
PTFDD7
PTFDD6
PTFDD5
PTFDD4
PTFDD3
PTFDD2
PTFDD1
PTFDD0
0
0
PTGD5
PTGD4
PTGD3
PTGD2
PTGD1
PTGD0
0
0
PTGDD5
PTGDD4
PTGDD3
PTGDD2
PTGDD1
PTGDD0
ACME
ACBGS
ACF
ACIE
ACO
ACOPE
ACMOD1
ACMOD0
ACME
ACBGS
ACF
ACIE
ACO
ACOPE
ACMOD1
ACMOD0
COCO
AIEN
ADCO
ADACT
ADTRG
ACFE
ACFGT
0
0
—
—
0
0
0
0
ADR11
ADR10
ADR9
ADR8
ADR7
ADR6
ADR5
ADR4
ADR3
ADR2
ADR1
ADR0
0
0
0
0
ADCV11
ADCV10
ADCV9
ADCV8
ADCV7
ADCV6
ADCV4
ADCV3
ADCV2
ADCV1
ADCV0
ADLPC
ADCV5
ADIV
ADCH
ADLSMP
MODE
ADICLK
ADPC7
ADPC6
ADPC5
ADPC4
ADPC3
ADPC2
ADPC1
ADPC0
ADPC15
ADPC14
ADPC13
ADPC12
ADPC11
ADPC10
ADPC9
ADPC8
ADPC23
ADPC22
ADPC21
ADPC20
ADPC19
ADPC18
ADPC17
ADPC16
Reserved
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
IRQSC
0
IRQPDD
IRQEDG
IRQPE
IRQF
IRQACK
IRQIE
IRQMOD
Reserved
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
TPM1SC
TPM1CNTH
TPM1CNTL
TPM1MODH
TPM1MODL
TPM1C0SC
TPM1C0VH
TPM1C0VL
TOF
TOIE
CPWMS
CLKSB
CLKSA
PS2
PS1
PS0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
CH0F
CH0IE
MS0B
MS0A
ELS0B
ELS0A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
45
Chapter 4 Memory
Table 4-2. Direct-Page Register Summary (Sheet 2 of 3)
Address
Register
Name
Bit 7
6
5
4
3
2
1
Bit 0
0x0028
0x0029
0x002A
0x002B
0x002C
0x002D
0x002E
0x002F
0x0030
0x0031
0x0032
TPM1C1SC
TPM1C1VH
TPM1C1VL
TPM1C2SC
TPM1C2VH
TPM1C2VL
TPM1C3SC
TPM1C3VH
TPM1C3VL
TPM1C4SC
TPM1C4VH
CH1F
CH1IE
MS1B
MS1A
ELS1B
ELS1A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
CH2F
CH2IE
MS2B
MS2A
ELS2B
ELS2A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
0x0033
0x0034
0x0035
0x0036
0x0037
0x0038
0x0039
0x003A
0x003B
0x003C
0x003D
0x003E
0x003F
0x0040
0x0041
0x0042
0x0043
0x0044
0x0045
0x0046
0x0047
0x0048
0x0049
0x004A
0x004B
0x004C
0x004D–
0x004F
TPM1C4VL
TPM1C5SC
TPM1C5VH
TPM1C5VL
Reserved
SCI1BDH
SCI1BDL
SCI1C1
SCI1C2
SCI1S1
SCI1S2
SCI1C3
SCI1D
SCI2BDH
SCI2BDL
SCI2C1
SCI2C2
SCI2S1
SCI2S2
SCI2C3
SCI2D
MCGC1
MCGC2
MCGTRM
MCGSC
MCGC3
Reserved
Bit 7
6
5
4
3
2
1
Bit 0
CH3F
CH3IE
MS3B
MS3A
ELS3B
ELS3A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
CH4F
CH4IE
MS4B
MS4A
ELS4B
ELS4A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
CH5F
CH5IE
MS5B
MS5A
ELS5B
ELS5A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
—
—
—
—
—
—
—
—
LBKDIE
RXEDGIE
0
SBR12
SBR11
SBR10
SBR9
SBR8
SBR7
SBR6
SBR5
SBR4
SBR3
SBR2
SBR1
SBR0
LOOPS
SCISWAI
RSRC
M
WAKE
ILT
PE
PT
TIE
TCIE
RIE
ILIE
TE
RE
RWU
SBK
TDRE
TC
RDRF
IDLE
OR
NF
FE
PF
LBKDIF
RXEDGIF
0
RXINV
RWUID
BRK13
LBKDE
RAF
R8
T8
TXDIR
TXINV
ORIE
NEIE
FEIE
PEIE
Bit 7
6
5
4
3
2
1
Bit 0
LBKDIE
RXEDGIE
0
SBR12
SBR11
SBR10
SBR9
SBR8
SBR7
SBR6
SBR5
SBR4
SBR3
SBR2
SBR1
SBR0
LOOPS
SCISWAI
RSRC
M
WAKE
ILT
PE
PT
TIE
TCIE
RIE
ILIE
TE
RE
RWU
SBK
TDRE
TC
RDRF
IDLE
OR
NF
FE
PF
LBKDIF
RXEDGIF
0
RXINV
RWUID
BRK13
LBKDE
RAF
R8
T8
TXDIR
TXINV
ORIE
NEIE
FEIE
PEIE
Bit 7
6
5
4
3
2
1
Bit 0
IREFS
IRCLKEN
IREFSTEN
EREFS
ERCLKEN EREFSTEN
CLKS
RDIV
BDIV
RANGE
HGO
LP
TRIM
LOLS
LOCK
PLLST
IREFST
LOLIE
PLLS
CME
0
—
—
—
—
—
—
—
—
CLKST
OSCINIT
FTRIM
VDIV
—
—
—
—
—
—
—
—
MC9S08DZ60 Series Data Sheet, Rev. 4
46
Freescale Semiconductor
Chapter 4 Memory
Table 4-2. Direct-Page Register Summary (Sheet 3 of 3)
Address
Register
Name
0x0050
0x0051
0x0052
0x0053
0x0054
0x0055
0x0056–
0x0057
SPIC1
SPIC2
SPIBR
SPIS
Reserved
SPID
0x0058
0x0059
0x005A
0x005B
0x005C
0x005D
0x005E–
0x005F
0x0060
0x0061
0x0062
0x0063
0x0064
0x0065
0x0066
0x0067
0x0068
0x0069
0x006A
0x006B
0x006C
0x006D
0x006E
0x006F
0x0070–
0x007F
Bit 7
6
5
4
3
2
1
Bit 0
SPIE
SPE
SPTIE
MSTR
CPOL
CPHA
SSOE
LSBFE
0
0
0
MODFEN
BIDIROE
0
SPISWAI
SPC0
0
SPPR2
SPPR1
SPPR0
0
SPR2
SPR1
SPR0
SPRF
0
SPTEF
MODF
0
0
0
0
0
0
0
0
0
0
0
0
Bit 7
6
5
4
3
2
1
Bit 0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
IICA
IICF
AD7
AD6
AD5
AD4
AD3
AD2
AD1
0
IICC1
IICS
IICD
IICC2
IICEN
IICIE
MST
TX
TXAK
RSTA
0
0
TCF
IAAS
BUSY
ARBL
0
SRW
IICIF
RXAK
Reserved
Reserved
TPM2SC
TPM2CNTH
TPM2CNTL
TPM2MODH
TPM2MODL
TPM2C0SC
TPM2C0VH
TPM2C0VL
TPM2C1SC
TPM2C1VH
TPM2C1VL
Reserved
RTCSC
RTCCNT
RTCMOD
Reserved
Reserved
MULT
ICR
DATA
GCAEN
ADEXT
0
0
0
AD10
AD9
AD8
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
TOF
TOIE
CPWMS
CLKSB
CLKSA
PS2
PS1
PS0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
CH0F
CH0IE
MS0B
MS0A
ELS0B
ELS0A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
CH1F
CH1IE
MS1B
MS1A
ELS1B
ELS1A
0
0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
—
—
—
—
—
—
—
RTIF
—
RTCLKS
RTIE
RTCPS
RTCCNT
RTCMOD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
High-page registers, shown in Table 4-3, are accessed much less often than other I/O and control registers
so they have been located outside the direct addressable memory space, starting at 0x1800.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
47
Chapter 4 Memory
Table 4-3. High-Page Register Summary (Sheet 1 of 3)
Address
0x1800
0x1801
0x1802
0x1803
0x1804 –
0x1805
0x1806
0x1807
0x1808
0x1809
0x180A
0x180B–
0x180F
0x1810
0x1811
0x1812
0x1813
0x1814
0x1815
0x1816
0x1817
0x1818
0x1819–
0x181F
0x1820
0x1821
0x1822
0x1823
0x1824
0x1825
0x1826
0x1827–
0x183F
0x1840
0x1841
0x1842
0x1843
0x1844
0x1845
0x1846
Register Name
SRS
SBDFR
SOPT1
SOPT2
Reserved
SDIDH
SDIDL
Reserved
SPMSC1
SPMSC2
Reserved
DBGCAH
DBGCAL
DBGCBH
DBGCBL
DBGFH
DBGFL
DBGC
DBGT
DBGS
Reserved
FCDIV
FOPT
Reserved
FCNFG
FPROT
FSTAT
FCMD
Reserved
PTAPE
PTASE
PTADS
Reserved
PTASC
PTAPS
PTAES
Bit 7
6
5
4
3
2
1
POR
PIN
COP
ILOP
ILAD
LOCS
LVD
0
0
0
0
0
0
0
0
BDFR
STOPE
SCI2PS
IICPS
0
0
0
COPT
Bit 0
COPCLKS
COPW
0
ADHTS
0
MCSEL
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
ID11
ID10
ID9
ID8
ID7
ID6
ID5
ID4
ID3
ID2
ID1
ID0
—
—
—
—
—
—
—
—
LVWF
LVWACK
LVWIE
LVDRE
LVDSE
LVDE
0
BGBE
0
0
LVDV
LVWV
PPDF
PPDACK
0
PPDC
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
Bit 15
14
13
12
11
10
9
Bit 8
Bit 7
6
5
4
3
2
1
Bit 0
DBGEN
ARM
TAG
BRKEN
RWA
RWAEN
RWB
RWBEN
TRGSEL
BEGIN
0
0
TRG3
TRG2
TRG1
TRG0
AF
BF
ARMF
0
CNT3
CNT2
CNT1
CNT0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
DIVLD
PRDIV8
KEYEN
FNORED
EPGMOD
0
0
0
—
—
—
—
—
—
—
—
KEYACC
Reserved1
0
0
0
1
0
FBLANK
0
0
0
EPGSEL
DIV
EPS
FCBEF
SEC
FPS
FCCF
FPVIOL
FACCERR
FCMD
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
PTAPE7
PTAPE6
PTAPE5
PTAPE4
PTAPE3
PTAPE2
PTAPE1
PTAPE0
PTASE7
PTASE6
PTASE5
PTASE4
PTASE3
PTASE2
PTASE1
PTASE0
PTADS7
PTADS6
PTADS5
PTADS4
PTADS3
PTADS2
PTADS1
PTADS0
—
—
—
—
—
—
—
—
0
0
0
0
PTAIF
PTAACK
PTAIE
PTAMOD
PTAPS7
PTAPS6
PTAPS5
PTAPS4
PTAPS3
PTAPS2
PTAPS1
PTAPS0
PTAES7
PTAES6
PTAES5
PTAES4
PTAES3
PTAES2
PTAES1
PTAES0
MC9S08DZ60 Series Data Sheet, Rev. 4
48
Freescale Semiconductor
Chapter 4 Memory
Table 4-3. High-Page Register Summary (Sheet 2 of 3)
Address
0x1847
0x1848
0x1849
0x184A
0x184B
0x184C
0x184D
0x184E
0x184F
0x1850
0x1851
0x1852
0x1853–
0x1857
0x1858
0x1859
0x185A
0x185B
0x185C
0x185D
0x185E
0x185F
0x1860
0x1861
0x1862
0x1863–
0x1867
0x1868
0x1869
0x186A
0x186B–
0x186F
0x1870
0x1871
0x1872
0x1873–
0x187F
0x1880
0x1881
0x1882
Register Name
Reserved
PTBPE
PTBSE
PTBDS
Reserved
PTBSC
PTBPS
PTBES
Reserved
PTCPE
PTCSE
PTCDS
Reserved
PTDPE
PTDSE
PTDDS
Reserved
PTDSC
PTDPS
PTDES
Reserved
PTEPE
PTESE
PTEDS
Reserved
PTFPE
PTFSE
PTFDS
Reserved
PTGPE
PTGSE
PTGDS
Reserved
CANCTL0
CANCTL1
CANBTR0
Bit 7
6
5
4
3
2
1
Bit 0
—
—
—
—
—
—
—
—
PTBPE7
PTBPE6
PTBPE5
PTBPE4
PTBPE3
PTBPE2
PTBPE1
PTBPE0
PTBSE7
PTBSE6
PTBSE5
PTBSE4
PTBSE3
PTBSE2
PTBSE1
PTBSE0
PTBDS7
PTBDS6
PTBDS5
PTBDS4
PTBDS3
PTBDS2
PTBDS1
PTBDS0
—
—
—
—
—
—
—
—
0
0
0
0
PTBIF
PTBACK
PTBIE
PTBMOD
PTBPS7
PTBPS6
PTBPS5
PTBPS4
PTBPS3
PTBPS2
PTBPS1
PTBPS0
PTBES7
PTBES6
PTBES5
PTBES4
PTBES3
PTBES2
PTBES1
PTBES0
—
—
—
—
—
—
—
—
PTCPE7
PTCPE6
PTCPE5
PTCPE4
PTCPE3
PTCPE2
PTCPE1
PTCPE0
PTCSE7
PTCSE6
PTCSE5
PTCSE4
PTCSE3
PTCSE2
PTCSE1
PTCSE0
PTCDS7
PTCDS6
PTCDS5
PTCDS4
PTCDS3
PTCDS2
PTCDS1
PTCDS0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
PTDPE7
PTDPE6
PTDPE5
PTDPE4
PTDPE3
PTDPE2
PTDPE1
PTDPE0
PTDSE7
PTDSE6
PTDSE5
PTDSE4
PTDSE3
PTDSE2
PTDSE1
PTDSE0
PTDDS7
PTDDS6
PTDDS5
PTDDS4
PTDDS3
PTDDS2
PTDDS1
PTDDS0
—
—
—
—
—
—
—
—
0
0
0
0
PTDIF
PTDACK
PTDIE
PTDMOD
PTDPS7
PTDPS6
PTDPS5
PTDPS4
PTDPS3
PTDPS2
PTDPS1
PTDPS0
PTDES7
PTDES6
PTDES5
PTDES4
PTDES3
PTDES2
PTDES1
PTDES0
—
—
—
—
—
—
—
—
PTEPE7
PTEPE6
PTEPE5
PTEPE4
PTEPE3
PTEPE2
PTEPE1
PTEPE0
PTESE7
PTESE6
PTESE5
PTESE4
PTESE3
PTESE2
PTESE1
PTESE0
PTEDS7
PTEDS6
PTEDS5
PTEDS4
PTEDS3
PTEDS2
PTEDS1
PTEDS0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
PTFPE7
PTFPE6
PTFPE5
PTFPE4
PTFPE3
PTFPE2
PTFPE1
PTFPE0
PTFSE7
PTFSE6
PTFSE5
PTFSE4
PTFSE3
PTFSE2
PTFSE1
PTFSE0
PTFDS7
PTFDS6
PTFDS5
PTFDS4
PTFDS3
PTFDS2
PTFDS1
PTFDS0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0
0
PTGPE5
PTGPE4
PTGPE3
PTGPE2
PTGPE1
PTGPE0
0
0
PTGSE5
PTGSE4
PTGSE3
PTGSE2
PTGSE1
PTGSE0
0
0
PTGDS5
PTGDS4
PTGDS3
PTGDS2
PTGDS1
PTGDS0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
RXFRM
RXACT
CSWAI
SYNCH
TIME
WUPE
SLPRQ
INITRQ
CANE
CLKSRC
LOOPB
LISTEN
BORM
WUPM
SLPAK
INITAK
SJW1
SJW0
BRP5
BRP4
BRP3
BRP2
BRP1
BRP0
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
49
Chapter 4 Memory
Table 4-3. High-Page Register Summary (Sheet 3 of 3)
Address
Register Name
0x1883
0x1884
0x1885
0x1886
0x1887
0x1888
0x1889
0x188A
0x188B
0x188C
0x188D
0x188E
CANBTR1
CANRFLG
CANRIER
CANTFLG
CANTIER
CANTARQ
CANTAAK
CANTBSEL
CANIDAC
Reserved
CANMISC
CANRXERR
0x188F
0x1890 –
0x1893
0x1894 –
0x1897
0x1898 –
0x189B
0x189C–
0x189F
0x18BE
0x18BF
0x18C0–
0x18FF
CANTXERR
CANIDAR0 –
CANIDAR3
CANIDMR0 –
CANIDMR3
CANIDAR4 –
CANIDAR7
CANIDMR4 –
CANIDMR7
CANTTSRH
CANTTSRL
1
Reserved
Bit 7
6
5
4
3
2
1
Bit 0
SAMP
TSEG22
TSEG21
TSEG20
TSEG13
TSEG12
TSEG11
TSEG10
WUPIF
CSCIF
RSTAT1
RSTAT0
TSTAT1
TSTAT0
OVRIF
RXF
WUPIE
CSCIE
RSTATE1
RSTATE0
TSTATE1
TSTATE0
OVRIE
RXFIE
0
0
0
0
0
TXE2
TXE1
TXE0
0
0
0
0
0
TXEIE2
TXEIE1
TXEIE0
0
0
0
0
0
ABTRQ2
ABTRQ1
ABTRQ0
0
0
0
0
0
ABTAK2
ABTAK1
ABTAK0
0
0
0
0
0
TX2
TX1
TX0
0
0
IDAM1
IDAM0
0
IDHIT2
IDHIT1
IDHIT0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
BOHOLD
RXERR7
RXERR6
RXERR5
RXERR4
RXERR3
RXERR2
RXERR1
RXERR0
TXERR7
TXERR6
TXERR5
TXERR4
TXERR3
TXERR2
TXERR1
TXERR0
AC7
AC6
AC5
AC4
AC3
AC2
AC1
AC0
AM7
AM6
AM5
AM4
AM3
AM2
AM1
AM0
AC7
AC6
AC5
AC4
AC3
AC2
AC1
AC0
AM7
AM6
AM5
AM4
AM3
AM2
AM1
AM0
TSR15
TSR14
TSR13
TSR12
TSR11
TSR10
TSR9
TSR8
TSR7
TSR6
TSR5
TSR4
TSR3
TSR2
TSR1
TSR0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
This bit is reserved. User must write a 1 to this bit. Failing to do so may result in unexpected behavior.
Figure 4-4 shows the structure of receive and transmit buffers for extended identifier mapping. These
registers vary depending on whether standard or extended mapping is selected. See Chapter 12, “Freescale
Controller Area Network (S08MSCANV1),” for details on extended and standard identifier mapping.
Table 4-4. MSCAN Foreground Receive and Transmit Buffer Layouts — Extended Mapping Shown
0x18A0
0x18A1
0x18A2
0x18A3
0x18A4 –
0x18AB
0x18AC
0x18AD
0x18AE
CANRIDR0
CANRIDR1
CANRIDR2
CANRIDR3
CANRDSR0 –
CANRDSR7
CANRDLR
Reserved
CANRTSRH
ID28
ID27
ID26
ID25
ID24
ID23
ID22
ID21
IDE(1)
ID20
ID19
ID18
SRR(1)
ID17
ID16
ID15
ID14
ID13
ID12
ID11
ID10
ID9
ID8
ID7
ID6
ID5
ID4
ID3
ID2
ID1
ID0
RTR2
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
—
—
—
—
DLC3
DLC2
DLC1
DLC0
—
—
—
—
—
—
—
—
TSR15
TSR14
TSR13
TSR12
TSR11
TSR10
TSR9
TSR8
MC9S08DZ60 Series Data Sheet, Rev. 4
50
Freescale Semiconductor
Chapter 4 Memory
Table 4-4. MSCAN Foreground Receive and Transmit Buffer Layouts — Extended Mapping Shown
0x18AF
0x18B0
0x18B1
0x18B2
0x18B3
0x18B4 –
0x18BB
0x18BC
0x18BD
1
2
CANRTSRL
CANTIDR0
CANTIDR1
CANTIDR2
CANTIDR3
CANTDSR0 –
CANTDSR7
CANTDLR
CANTTBPR
TSR7
TSR6
TSR5
TSR4
TSR3
TSR2
TSR1
TSR0
ID10
ID9
ID8
ID7
ID6
ID5
ID4
ID3
ID2
ID1
ID0
RTR
IDE
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
—
—
—
—
DLC3
DLC2
DLC1
DLC0
PRIO7
PRIO6
PRIO5
PRIO4
PRIO3
PRIO2
PRIO1
PRIO0
SRR and IDE are both 1s.
The position of RTR differs between extended and standard identifier mapping.
Nonvolatile Flash registers, shown in Table 4-5, are located in the Flash memory. These registers include
an 8-byte backdoor key, NVBACKKEY, which can be used to gain access to secure memory resources.
During reset events, the contents of NVPROT and NVOPT in the nonvolatile register area of the Flash
memory are transferred into corresponding FPROT and FOPT working registers in the high-page registers
to control security and block protection options.
Table 4-5. Nonvolatile Register Summary
Address
Register Name
Bit 7
6
5
4
3
2
1
Bit 0
0xFFAE
Reserved for
storage of FTRIM
0
0
0
0
0
0
0
FTRIM
0xFFAF
Res. for storage of
MCGTRM
0xFFB0–
0xFFB7
0xFFB8–
0xFFBC
0xFFBD
0xFFBE
0xFFBF
NVBACKKEY
—
—
—
—
—
—
—
—
Reserved
NVPROT
Reserved
NVOPT
TRIM
8-Byte Comparison Key
—
—
—
—
—
—
—
—
—
—
EPS
FPS
—
—
—
—
—
—
KEYEN
FNORED
EPGMOD
0
0
0
SEC
Provided the key enable (KEYEN) bit is 1, the 8-byte comparison key can be used to temporarily
disengage memory security. This key mechanism can be accessed only through user code running in secure
memory. (A security key cannot be entered directly through background debug commands.) This security
key can be disabled completely by programming the KEYEN bit to 0. If the security key is disabled, the
only way to disengage security is by mass erasing the Flash if needed (normally through the background
debug interface) and verifying that Flash is blank. To avoid returning to secure mode after the next reset,
program the security bits (SEC) to the unsecured state (1:0).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
51
Chapter 4 Memory
4.4
RAM
The MC9S08DZ60 Series includes static RAM. The locations in RAM below 0x0100 can be accessed
using the more efficient direct addressing mode, and any single bit in this area can be accessed with the bit
manipulation instructions (BCLR, BSET, BRCLR, and BRSET). Locating the most frequently accessed
program variables in this area of RAM is preferred.
The RAM retains data while the MCU is in low-power wait, stop2, or stop3 mode. At power-on the
contents of RAM are uninitialized. RAM data is unaffected by any reset if the supply voltage does not drop
below the minimum value for RAM retention (VRAM).
For compatibility with M68HC05 MCUs, the HCS08 resets the stack pointer to 0x00FF. In the
MC9S08DZ60 Series, it is usually best to reinitialize the stack pointer to the top of the RAM so the direct
page RAM can be used for frequently accessed RAM variables and bit-addressable program variables.
Include the following 2-instruction sequence in your reset initialization routine (where RamLast is equated
to the highest address of the RAM in the Freescale Semiconductor equate file).
LDHX
TXS
#RamLast+1
;point one past RAM
;SP<-(H:X-1)
When security is enabled, the RAM is considered a secure memory resource and is not accessible through
BDM or code executing from non-secure memory. See Section 4.5.9, “Security”, for a detailed description
of the security feature.
4.5
Flash and EEPROM
MC9S08DZ60 Series devices include Flash and EEPROM memory intended primarily for program and
data storage. In-circuit programming allows the operating program and data to be loaded into Flash and
EEPROM, respectively, after final assembly of the application product. It is possible to program the arrays
through the single-wire background debug interface. Because no special voltages are needed for erase and
programming operations, in-application programming is also possible through other software-controlled
communication paths. For a more detailed discussion of in-circuit and in-application programming, refer
to the HCS08 Family Reference Manual, Volume I, Freescale Semiconductor document order number
HCS08RMv1.
4.5.1
Features
Features of the Flash and EEPROM memory include:
• Array size (see Table 1-1 for exact array sizes)
• Flash sector size: 768 bytes
• EEPROM sector size: selectable 4-byte or 8-byte sector mapping operation
• Single power supply program and erase
• Command interface for fast program and erase operation
• Up to 100,000 program/erase cycles at typical voltage and temperature
• Flexible block protection and vector redirection
• Security feature for Flash, EEPROM, and RAM
MC9S08DZ60 Series Data Sheet, Rev. 4
52
Freescale Semiconductor
Chapter 4 Memory
•
•
4.5.2
Burst programming capability
Sector erase abort
Program and Erase Times
Before any program or erase command can be accepted, the Flash and EEPROM clock divider register
(FCDIV) must be written to set the internal clock for the Flash and EEPROM module to a frequency
(fFCLK) between 150 kHz and 200 kHz (see Section 4.5.11.1, “Flash and EEPROM Clock Divider
Register (FCDIV)”). This register can be written only once, so normally this write is performed during
reset initialization. The user must ensure that FACCERR is not set before writing to the FCDIV register.
One period of the resulting clock (1/fFCLK) is used by the command processor to time program and erase
pulses. An integer number of these timing pulses is used by the command processor to complete a program
or erase command.
Table 4-6 shows program and erase times. The bus clock frequency and FCDIV determine the frequency
of FCLK (fFCLK). The time for one cycle of FCLK is tFCLK = 1/fFCLK. The times are shown as a number
of cycles of FCLK and as an absolute time for the case where tFCLK = 5 μs. Program and erase times
shown include overhead for the command state machine and enabling and disabling of program and erase
voltages.
Table 4-6. Program and Erase Times
1
4.5.3
Parameter
Cycles of FCLK
Time if FCLK = 200 kHz
Byte program
9
45 μs
Burst program
4
20 μs1
Sector erase
4000
20 ms
Mass erase
20,000
100 ms
Sector erase abort
4
20 μs1
Excluding start/end overhead
Program and Erase Command Execution
The FCDIV register must be initialized after any reset and any error flag is cleared before beginning
command execution. The command execution steps are:
1. Write a data value to an address in the Flash or EEPROM array. The address and data information
from this write is latched into the Flash and EEPROM interface. This write is a required first step
in any command sequence. For erase and blank check commands, the value of the data is not
important. For sector erase commands, the address can be any address in the sector of Flash or
EEPROM to be erased. For mass erase and blank check commands, the address can be any address
in the Flash or EEPROM memory. Flash and EEPROM erase independently of each other.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
53
Chapter 4 Memory
NOTE
Before programming a particular byte in the Flash or EEPROM, the sector
in which that particular byte resides must be erased by a mass or sector erase
operation. Reprogramming bits in an already programmed byte without first
performing an erase operation may disturb data stored in the Flash or
EEPROM memory.
2. Write the command code for the desired command to FCMD. The six valid commands are blank
check (0x05), byte program (0x20), burst program (0x25), sector erase (0x40), mass erase1 (0x41),
and sector erase abort (0x47). The command code is latched into the command buffer.
3. Write a 1 to the FCBEF bit in FSTAT to clear FCBEF and launch the command (including its
address and data information).
A partial command sequence can be aborted manually by writing a 0 to FCBEF any time after the
write to the memory array and before writing the 1 that clears FCBEF and launches the complete
command. Aborting a command in this way sets the FACCERR access error flag which must be
cleared before starting a new command.
A strictly monitored procedure must be obeyed or the command will not be accepted. This
minimizes the possibility of any unintended changes to the memory contents. The command
complete flag (FCCF) indicates when a command is complete. The command sequence must be
completed by clearing FCBEF to launch the command. Figure 4-2 is a flowchart for executing all
of the commands except for burst programming and sector erase abort.
4. Wait until the FCCF bit in FSTAT is set. As soon as FCCF= 1, the operation has completed
successfully.
1. A mass erase is possible only when the Flash block is fully unprotected.
MC9S08DZ60 Series Data Sheet, Rev. 4
54
Freescale Semiconductor
Chapter 4 Memory
(1) Required only once
WRITE TO FCDIV(1)
after reset.
PROGRAM AND
ERASE FLOW
START
0
FACCERR?
CLEAR ERROR
WRITE TO FLASH OR EEPROM TO
BUFFER ADDRESS AND DATA
WRITE COMMAND TO FCMD
WRITE 1 TO FCBEF
TO LAUNCH COMMAND
AND CLEAR FCBEF (2)
FPVIOL OR
FACCERR?
(2)
Wait at least four bus cycles
before checking FCBEF or FCCF.
YES
ERROR EXIT
NO
0
FCCF?
1
DONE
Figure 4-2. Program and Erase Flowchart
4.5.4
Burst Program Execution
The burst program command is used to program sequential bytes of data in less time than would be
required using the standard program command. This is possible because the high voltage to the Flash array
does not need to be disabled between program operations. Ordinarily, when a program or erase command
is issued, an internal charge pump associated with the Flash memory must be enabled to supply high
voltage to the array. Upon completion of the command, the charge pump is turned off. When a burst
program command is issued, the charge pump is enabled and remains enabled after completion of the burst
program operation if these two conditions are met:
• The next burst program command sequence has begun before the FCCF bit is set.
• The next sequential address selects a byte on the same burst block as the current byte being
programmed. A burst block in this Flash memory consists of 32 bytes. A new burst block begins
at each 32-byte address boundary.
The first byte of a series of sequential bytes being programmed in burst mode will take the same amount
of time to program as a byte programmed in standard mode. Subsequent bytes will program in the burst
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
55
Chapter 4 Memory
program time provided that the conditions above are met. If the next sequential address is the beginning of
a new row, the program time for that byte will be the standard time instead of the burst time. This is because
the high voltage to the array must be disabled and then enabled again. If a new burst command has not been
queued before the current command completes, then the charge pump will be disabled and high voltage
removed from the array.
A flowchart to execute the burst program operation is shown in Figure 4-3.
(1) Required only once
WRITE TO FCDIV(1)
BURST PROGRAM
FLOW
after reset.
START
0
FACCERR?
1
CLEAR ERROR
FCBEF?
0
1
WRITE TO Flash
TO BUFFER ADDRESS AND DATA
WRITE COMMAND TO FCMD
WRITE 1 TO FCBEF
TO LAUNCH COMMAND
AND CLEAR FCBEF (2)
FPVIOL OR
FACCERR?
(2)
Wait at least four bus cycles
before checking FCBEF or FCCF.
YES
ERROR EXIT
NO
YES
NEW BURST COMMAND?
NO
0
FCCF?
1
DONE
Figure 4-3. Burst Program Flowchart
MC9S08DZ60 Series Data Sheet, Rev. 4
56
Freescale Semiconductor
Chapter 4 Memory
4.5.5
Sector Erase Abort
The sector erase abort operation will terminate the active sector erase operation so that other sectors are
available for read and program operations without waiting for the sector erase operation to complete.
The sector erase abort command write sequence is as follows:
1. Write to any Flash or EEPROM address to start the command write sequence for the sector erase
abort command. The address and data written are ignored.
2. Write the sector erase abort command, 0x47, to the FCMD register.
3. Clear the FCBEF flag in the FSTAT register by writing a 1 to FCBEF to launch the sector erase
abort command.
If the sector erase abort command is launched resulting in the early termination of an active sector erase
operation, the FACCERR flag will set once the operation completes as indicated by the FCCF flag being
set. The FACCERR flag sets to inform the user that the Flash sector may not be fully erased and a new
sector erase command must be launched before programming any location in that specific sector.
If the sector erase abort command is launched but the active sector erase operation completes normally,
the FACCERR flag will not set upon completion of the operation as indicated by the FCCF flag being set.
Therefore, if the FACCERR flag is not set after the sector erase abort command has completed, a sector
being erased when the abort command was launched will be fully erased.
A flowchart to execute the sector erase abort operation is shown in Figure 4-4.
SECTOR ERASE
ABORT FLOW
START
1
FCCF?
0
WRITE TO Flash
TO BUFFER ADDRESS AND DATA
WRITE 0x47 TO FCMD
WRITE 1 TO FCBEF
TO LAUNCH COMMAND
AND CLEAR FCBEF (2)
(2) Wait at least four bus cycles
before checking FCBEF or FCCF.
0
FCCF?
1
SECTOR ERASE COMPLETED
0
FACCERR?
1
SECTOR ERASE ABORTED
Figure 4-4. Sector Erase Abort Flowchart
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
57
Chapter 4 Memory
NOTE
The FCBEF flag will not set after launching the sector erase abort command.
If an attempt is made to start a new command write sequence with a sector
erase abort operation active, the FACCERR flag in the FSTAT register will
be set. A new command write sequence may be started after clearing the
ACCERR flag, if set.
NOTE
The sector erase abort command should be used sparingly since a sector
erase operation that is aborted counts as a complete program/erase cycle.
4.5.6
Access Errors
An access error occurs whenever the command execution protocol is violated.
Any of the following specific actions will cause the access error flag (FACCERR) in FSTAT to be set.
FACCERR must be cleared by writing a 1 to FACCERR in FSTAT before any command can be processed.
• Writing to a Flash address before the internal Flash and EEPROM clock frequency has been set by
writing to the FCDIV register.
• Writing to a Flash address while FCBEF is not set. (A new command cannot be started until the
command buffer is empty.)
• Writing a second time to a Flash address before launching the previous command. (There is only
one write to Flash for every command.)
• Writing a second time to FCMD before launching the previous command. (There is only one write
to FCMD for every command.)
• Writing to any Flash control register other than FCMD after writing to a Flash address.
• Writing any command code other than the six allowed codes (0x05, 0x20, 0x25, 0x40, 0x41, or
0x47) to FCMD.
• Writing any Flash control register other than to write to FSTAT (to clear FCBEF and launch the
command) after writing the command to FCMD.
• The MCU enters stop mode while a program or erase command is in progress. (The command is
aborted.)
• Writing the byte program, burst program, sector erase or sector erase abort command code (0x20,
0x25, 0x40, or 0x47) with a background debug command while the MCU is secured. (The
background debug controller can do blank check and mass erase commands only when the MCU
is secure.)
• Writing 0 to FCBEF to cancel a partial command.
MC9S08DZ60 Series Data Sheet, Rev. 4
58
Freescale Semiconductor
Chapter 4 Memory
4.5.7
Block Protection
The block protection feature prevents the protected region of Flash or EEPROM from program or erase
changes. Block protection is controlled through the Flash and EEPROM protection register (FPROT). The
EPS bits determine the protected region of EEPROM and the FPS bits determine the protected region of
Flash. See Section 4.5.11.4, “Flash and EEPROM Protection Register (FPROT and NVPROT).”
After exit from reset, FPROT is loaded with the contents of the NVPROT location, which is in the
nonvolatile register block of the Flash memory. Any FPROT write that attempts to decrease the size of the
protected region will be ignored. Because NVPROT is within the last sector of Flash, if any amount of
memory is protected, NVPROT is itself protected and cannot be unprotected (intentionally or
unintentionally) by the application software. FPROT can be written through background debug
commands, which provides a way to erase and reprogram protected Flash memory.
One use for block protection is to block protect an area of Flash memory for a bootloader program. this
bootloader program can call a routine outside of Flash that can be used to sector erase the rest of the Flash
memory and reprogram it. The bootloader is protected even if MCU power is lost during an erase and
reprogram operation.
4.5.8
Vector Redirection
While any Flash is block protected, the reset and interrupt vectors will be protected. Vector redirection
allows users to modify interrupt vector information without unprotecting bootloader and reset vector
space. Vector redirection is enabled by programming the FNORED bit in the NVOPT register located at
address 0xFFBF to 0. For redirection to occur, at least some portion of the Flash memory must be block
protected by programming the NVPROT register located at address 0xFFBD. All interrupt vectors
(memory locations 0xFFC0–0xFFFD) are redirected, though the reset vector (0xFFFE:0xFFFF) is not.
For example, if 1536 bytes of Flash are protected, the protected address region is from 0xFA00 through
0xFFFF. The interrupt vectors (0xFFC0–0xFFFD) are redirected to the locations 0xF9C0–0xF9FD. If
vector redirection is enabled and an interrupt occurs, the values in the locations 0xF9E0:0xF9E1 are used
for the vector instead of the values in the locations 0xFFE0:0xFFE1. This allows the user to reprogram the
unprotected portion of the Flash with new program code including new interrupt vector values while
leaving the protected area, which includes the default vector locations, unchanged.
4.5.9
Security
The MC9S08DZ60 Series includes circuitry to prevent unauthorized access to the contents of Flash,
EEPROM, and RAM memory. When security is engaged, Flash, EEPROM, and RAM are considered
secure resources. Direct-page registers, high-page registers, and the background debug controller are
considered unsecured resources. Programs executing within secure memory have normal access to any
MCU memory locations and resources. Attempts to access a secure memory location with a program
executing from an unsecured memory space or through the background debug interface are blocked (writes
are ignored and reads return all 0s).
Security is engaged or disengaged based on the state of two register bits (SEC[1:0]) in the FOPT register.
During reset, the contents of the nonvolatile location NVOPT are copied from Flash into the working
FOPT register in high-page register space. A user engages security by programming the NVOPT location,
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
59
Chapter 4 Memory
which can be performed at the same time the Flash memory is programmed. The 1:0 state disengages
security; the other three combinations engage security. Notice the erased state (1:1) makes the MCU
secure. During development, whenever the Flash is erased, it is good practice to immediately program the
SEC0 bit to 0 in NVOPT so SEC = 1:0. This would allow the MCU to remain unsecured after a subsequent
reset.
The on-chip debug module cannot be enabled while the MCU is secure. The separate background debug
controller can be used for background memory access commands, but the MCU cannot enter active
background mode except by holding BKGD low at the rising edge of reset.
A user can choose to allow or disallow a security unlocking mechanism through an 8-byte backdoor
security key. If the nonvolatile KEYEN bit in NVOPT/FOPT is 0, the backdoor key is disabled and there
is no way to disengage security without completely erasing all Flash locations. If KEYEN is 1, a secure
user program can temporarily disengage security by:
1. Writing 1 to KEYACC in the FCNFG register. This makes the Flash module interpret writes to the
backdoor comparison key locations (NVBACKKEY through NVBACKKEY+7) as values to be
compared against the key rather than as the first step in a Flash program or erase command.
2. Writing the user-entered key values to the NVBACKKEY through NVBACKKEY+7 locations.
These writes must be performed in order starting with the value for NVBACKKEY and ending
with NVBACKKEY+7. STHX must not be used for these writes because these writes cannot be
performed on adjacent bus cycles. User software normally would get the key codes from outside
the MCU system through a communication interface such as a serial I/O.
3. Writing 0 to KEYACC in the FCNFG register. If the 8-byte key that was written matches the key
stored in the Flash locations, SEC bits are automatically changed to 1:0 and security will be
disengaged until the next reset.
The security key can be written only from secure memory (either RAM, EEPROM, or Flash), so it cannot
be entered through background commands without the cooperation of a secure user program.
The backdoor comparison key (NVBACKKEY through NVBACKKEY+7) is located in Flash memory
locations in the nonvolatile register space so users can program these locations exactly as they would
program any other Flash memory location. The nonvolatile registers are in the same 768-byte block of
Flash as the reset and interrupt vectors, so block protecting that space also block protects the backdoor
comparison key. Block protects cannot be changed from user application programs, so if the vector space
is block protected, the backdoor security key mechanism cannot permanently change the block protect,
security settings, or the backdoor key.
Security can always be disengaged through the background debug interface by taking these steps:
1. Disable any block protections by writing FPROT. FPROT can be written only with background
debug commands, not from application software.
2. Mass erase Flash if necessary.
3. Blank check Flash. Provided Flash is completely erased, security is disengaged until the next reset.
To avoid returning to secure mode after the next reset, program NVOPT so SEC = 1:0.
MC9S08DZ60 Series Data Sheet, Rev. 4
60
Freescale Semiconductor
Chapter 4 Memory
4.5.10
EEPROM Mapping
Only half of the EEPROM is in the memory map. The EPGSEL bit in FCNFG register selects which half
of the array can be accessed in foreground while the other half can not be accessed in background. There
are two mapping mode options that can be selected to configure the 8-byte EEPROM sectors: 4-byte mode
and 8-byte mode. Each mode is selected by the EPGMOD bit in the FOPT register.
In 4-byte sector mode (EPGMOD = 0), each 8-byte sector splits four bytes on foreground and four bytes
on background but on the same addresses. The EPGSEL bit selects which four bytes can be accessed.
During a sector erase, the entire 8-byte sector (four bytes in foreground and four bytes in background) is
erased.
In 8-byte sector mode (EPGMOD = 1), each entire 8-byte sector is in a single page. The EPGSEL bit
selects which sectors are on background. During a sector erase, the entire 8-byte sector in foreground is
erased.
4.5.11
Flash and EEPROM Registers and Control Bits
The Flash and EEPROM modules have seven 8-bit registers in the high-page register space and three
locations in the nonvolatile register space in Flash memory. Two of those locations are copied into two
corresponding high-page control registers at reset. There is also an 8-byte comparison key in Flash
memory. Refer to Table 4-3 and Table 4-5 for the absolute address assignments for all Flash and EEPROM
registers. This section refers to registers and control bits only by their names. A Freescale
Semiconductor-provided equate or header file normally is used to translate these names into the
appropriate absolute addresses.
4.5.11.1
Flash and EEPROM Clock Divider Register (FCDIV)
Bit 7 of this register is a read-only flag. Bits 6:0 may be read at any time but can be written only one time.
Before any erase or programming operations are possible, write to this register to set the frequency of the
clock for the nonvolatile memory system within acceptable limits.
7
R
6
5
4
3
2
1
0
0
0
0
DIVLD
PRDIV8
DIV
W
Reset
0
0
0
0
0
= Unimplemented or Reserved
Figure 4-5. Flash and EEPROM Clock Divider Register (FCDIV)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
61
Chapter 4 Memory
Table 4-7. FCDIV Register Field Descriptions
Field
Description
7
DIVLD
Divisor Loaded Status Flag — When set, this read-only status flag indicates that the FCDIV register has been
written since reset. Reset clears this bit and the first write to this register causes this bit to become set regardless
of the data written.
0 FCDIV has not been written since reset; erase and program operations disabled for Flash and EEPROM.
1 FCDIV has been written since reset; erase and program operations enabled for Flash and EEPROM.
6
PRDIV8
5:0
DIV
Prescale (Divide) Flash and EEPROM Clock by 8 (This bit is write once.)
0 Clock input to the Flash and EEPROM clock divider is the bus rate clock.
1 Clock input to the Flash and EEPROM clock divider is the bus rate clock divided by 8.
Divisor for Flash and EEPROM Clock Divider — These bits are write once. The Flash and EEPROM clock
divider divides the bus rate clock (or the bus rate clock divided by 8 if PRDIV8 = 1) by the value in the 6-bit DIV
field plus one. The resulting frequency of the internal Flash and EEPROM clock must fall within the range of
200 kHz to 150 kHz for proper Flash and EEPROM operations. Program/Erase timing pulses are one cycle of
this internal Flash and EEPROM clock which corresponds to a range of 5 μs to 6.7 μs. The automated
programming logic uses an integer number of these pulses to complete an erase or program operation. See
Equation 4-1 and Equation 4-2.
if PRDIV8 = 0 — fFCLK = fBus ÷ (DIV + 1)
Eqn. 4-1
if PRDIV8 = 1 — fFCLK = fBus ÷ (8 × (DIV + 1))
Eqn. 4-2
Table 4-8 shows the appropriate values for PRDIV8 and DIV for selected bus frequencies.
Table 4-8. Flash and EEPROM Clock Divider Settings
4.5.11.2
fBus
PRDIV8
(Binary)
DIV
(Decimal)
fFCLK
Program/Erase Timing Pulse
(5 μs Min, 6.7 μs Max)
20 MHz
1
12
192.3 kHz
5.2 μs
10 MHz
0
49
200 kHz
5 μs
8 MHz
0
39
200 kHz
5 μs
4 MHz
0
19
200 kHz
5 μs
2 MHz
0
9
200 kHz
5 μs
1 MHz
0
4
200 kHz
5 μs
200 kHz
0
0
200 kHz
5 μs
150 kHz
0
0
150 kHz
6.7 μs
Flash and EEPROM Options Register (FOPT and NVOPT)
During reset, the contents of the nonvolatile location NVOPT are copied from Flash into FOPT. To change
the value in this register, erase and reprogram the NVOPT location in Flash memory as usual and then issue
a new MCU reset.
MC9S08DZ60 Series Data Sheet, Rev. 4
62
Freescale Semiconductor
Chapter 4 Memory
R
7
6
5
4
3
2
KEYEN
FNORED
EPGMOD
0
0
0
F
F
F
0
0
0
1
0
SEC
W
Reset
= Unimplemented or Reserved
F
F
F = loaded from nonvolatile location NVOPT during reset
Figure 4-6. Flash and EEPROM Options Register (FOPT)
Table 4-9. FOPT Register Field Descriptions
Field
Description
7
KEYEN
Backdoor Key Mechanism Enable — When this bit is 0, the backdoor key mechanism cannot be used to
disengage security. The backdoor key mechanism is accessible only from user (secured) firmware. BDM
commands cannot be used to write key comparison values that would unlock the backdoor key. For more detailed
information about the backdoor key mechanism, refer to Section 4.5.9, “Security.”
0 No backdoor key access allowed.
1 If user firmware writes an 8-byte value that matches the nonvolatile backdoor key (NVBACKKEY through
NVBACKKEY+7 in that order), security is temporarily disengaged until the next MCU reset.
6
FNORED
Vector Redirection Disable — When this bit is 1, then vector redirection is disabled.
0 Vector redirection enabled.
1 Vector redirection disabled.
5
EPGMOD
EEPROM Sector Mode — When this bit is 0, each sector is split into two pages (4-byte mode). When this bit is
1, each sector is in a single page (8-byte mode).
0 Half of each EEPROM sector is in Page 0 and the other half is in Page 1.
1 Each sector is in a single page.
1:0
SEC
Security State Code — This 2-bit field determines the security state of the MCU as shown in Table 4-10. When
the MCU is secure, the contents of RAM, EEPROM and Flash memory cannot be accessed by instructions from
any unsecured source including the background debug interface. SEC changes to 1:0 after successful backdoor
key entry or a successful blank check of Flash. For more detailed information about security, refer to Section
4.5.9, “Security.”
Table 4-10. Security States1
1
SEC[1:0]
Description
0:0
secure
0:1
secure
1:0
unsecured
1:1
secure
SEC changes to 1:0 after successful backdoor key entry
or a successful blank check of Flash.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
63
Chapter 4 Memory
4.5.11.3
Flash and EEPROM Configuration Register (FCNFG)
7
R
6
5
4
EPGSEL
KEYACC
Reserved1
0
0
1
0
3
2
1
0
0
0
0
1
0
0
0
1
W
Reset
0
= Unimplemented or Reserved
Figure 4-7. Flash Configuration Register (FCNFG)
1
User must write a 1 to this bit. Failing to do so may result in unexpected behavior.
Table 4-11. FCNFG Register Field Descriptions
Field
Description
6
EPGSEL
EEPROM Page Select — This bit selects which EEPROM page is accessed in the memory map.
0 Page 0 is in foreground of memory map. Page 1 is in background and can not be accessed.
1 Page 1 is in foreground of memory map. Page 0 is in background and can not be accessed.
5
KEYACC
Enable Writing of Access Key — This bit enables writing of the backdoor comparison key. For more detailed
information about the backdoor key mechanism, refer to Section 4.5.9, “Security.”
0 Writes to 0xFFB0–0xFFB7 are interpreted as the start of a Flash programming or erase command.
1 Writes to NVBACKKEY (0xFFB0–0xFFB7) are interpreted as comparison key writes.
4.5.11.4
Flash and EEPROM Protection Register (FPROT and NVPROT)
The FPROT register defines which Flash and EEPROM sectors are protected against program and erase
operations.
During the reset sequence, the FPROT register is loaded from the nonvolatile location NVPROT. To
change the protection that will be loaded during the reset sequence, the sector containing NVPROT must
be unprotected and erased, then NVPROT can be reprogrammed.
FPROT bits are readable at any time and writable as long as the size of the protected region is being
increased. Any write to FPROT that attempts to decrease the size of the protected memory will be ignored.
Trying to alter data in any protected area will result in a protection violation error and the FPVIOL flag
will be set in the FSTAT register. Mass erase is not possible if any one of the sectors is protected.
7
R
6
EPS1
5
4
3
2
1
0
FPS1
W
Reset
1
This register is loaded from nonvolatile location NVPROT during reset.
Background commands can be used to change the contents of these bits in FPROT.
Figure 4-8. Flash and EEPROM Protection Register (FPROT)
MC9S08DZ60 Series Data Sheet, Rev. 4
64
Freescale Semiconductor
Chapter 4 Memory
Table 4-12. FPROT Register Field Descriptions
Field
Description
7:6
EPS
EEPROM Protect Select Bits — This 2-bit field determines the protected EEPROM locations that cannot be
erased or programmed. See Table 4-13.
5:0
FPS
Flash Protect Select Bits — This 6-bit field determines the protected Flash locations that cannot be erased or
programmed. SeeTable 4-14.
Table 4-13. EEPROM Block Protection
EPS
Address Area Protected
Memory Size Protected (bytes)
Number of Sectors Protected
0x3
N/A
0
0
0x2
0x17F0 - 0x17FF
32
4
0x1
0x17E0 - 0x17FF
64
8
0x0
0x17C0–0x17FF
128
16
Table 4-14. Flash Block Protection
FPS
Address Area Protected
Memory Size Protected (bytes)
Number of Sectors Protected
0x3F
N/A
0
0
0x3E
0xFA00–0xFFFF
1.5K
2
0x3D
0xF400–0xFFFF
3K
4
0x3C
0xEE00–0xFFFF
4.5K
6
0x3B
0xE800–0xFFFF
6K
8
...
...
...
...
0x37
0xD000–0xFFFF
12K
16
0x36
0xCA00–0xFFFF
13.5K
18
0x35
0xC400–0xFFFF
15K
20
0x34
0xBE00–0xFFFF
16.5K
22
...
...
...
...
0x2C
0x8E00–0xFFFF
28.5K
38
0x2B
0x8800–0xFFFF
30K
40
0x2A
0x8200–0xFFFF
31.5K
42
0x29
0x7C00–0xFFFF
33K
44
...
...
...
...
0x22
0x5200–0xFFFF
43.5K
58
0x21
0x4C00–0xFFFF
45K
60
0x20
0x4600–0xFFFF
46.5K
62
0x1F
0x4000–0xFFFF
48K
64
...
...
...
...
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
65
Chapter 4 Memory
Table 4-14. Flash Block Protection (continued)
FPS
Address Area Protected
Memory Size Protected (bytes)
Number of Sectors Protected
0x1B
0x2800–0xFFFF
54K
72
0x1A
0x2200–0xFFFF
55.5K
74
0x19
0x1C00–0xFFFF
57K
76
0x18–0x00
0x0000–0xFFFF
64K
86
4.5.11.5
Flash and EEPROM Status Register (FSTAT)
7
R
6
5
4
FPVIOL
FACCERR
0
0
FCCF
FCBEF
3
2
1
0
0
FBLANK
0
0
0
0
0
0
W
Reset
1
1
= Unimplemented or Reserved
Figure 4-9. Flash and EEPROM Status Register (FSTAT)
Table 4-15. FSTAT Register Field Descriptions
Field
Description
7
FCBEF
Command Buffer Empty Flag — The FCBEF bit is used to launch commands. It also indicates that the
command buffer is empty so that a new command sequence can be executed when performing burst
programming. The FCBEF bit is cleared by writing a 1 to it or when a burst program command is transferred to
the array for programming. Only burst program commands can be buffered.
0 Command buffer is full (not ready for additional commands).
1 A new burst program command can be written to the command buffer.
6
FCCF
Command Complete Flag — FCCF is set automatically when the command buffer is empty and no command
is being processed. FCCF is cleared automatically when a new command is started (by writing 1 to FCBEF to
register a command). Writing to FCCF has no meaning or effect.
0 Command in progress
1 All commands complete
5
FPVIOL
Protection Violation Flag — FPVIOL is set automatically when a command that attempts to erase or program
a location in a protected block is launched (the erroneous command is ignored). FPVIOL is cleared by writing a
1 to FPVIOL.
0 No protection violation.
1 An attempt was made to erase or program a protected location.
MC9S08DZ60 Series Data Sheet, Rev. 4
66
Freescale Semiconductor
Chapter 4 Memory
Table 4-15. FSTAT Register Field Descriptions (continued)
Field
Description
4
FACCERR
Access Error Flag — FACCERR is set automatically when the proper command sequence is not obeyed exactly
(the erroneous command is ignored), if a program or erase operation is attempted before the FCDIV register has
been initialized, or if the MCU enters stop while a command was in progress. For a more detailed discussion of
the exact actions that are considered access errors, see Section 4.5.6, “Access Errors.” FACCERR is cleared by
writing a 1 to FACCERR. Writing a 0 to FACCERR has no meaning or effect.
0 No access error.
1 An access error has occurred.
2
FBLANK
Verified as All Blank (erased) Flag — FBLANK is set automatically at the conclusion of a blank check command
if the entire Flash or EEPROM array was verified to be erased. FBLANK is cleared by clearing FCBEF to write a
new valid command. Writing to FBLANK has no meaning or effect.
0 After a blank check command is completed and FCCF = 1, FBLANK = 0 indicates the Flash or EEPROM array
is not completely erased.
1 After a blank check command is completed and FCCF = 1, FBLANK = 1 indicates the Flash or EEPROM array
is completely erased (all 0xFFFF).
4.5.11.6
Flash and EEPROM Command Register (FCMD)
Only six command codes are recognized in normal user modes, as shown in Table 4-16. All other
command codes are illegal and generate an access error. Refer to Section 4.5.3, “Program and Erase
Command Execution,” for a detailed discussion of Flash and EEPROM programming and erase
operations.
R
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
W
Reset
FCMD
0
0
0
0
Figure 4-10. Flash and EEPROM Command Register (FCMD)
Table 4-16. Flash and EEPROM Commands
Command
FCMD
Equate File Label
Blank check
0x05
mBlank
Byte program
0x20
mByteProg
Burst program
0x25
mBurstProg
Sector erase
0x40
mSectorErase
Mass erase
0x41
mMassErase
Sector erase abort
0x47
mEraseAbort
It is not necessary to perform a blank check command after a mass erase operation. Only blank check is
required as part of the security unlocking mechanism.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
67
Chapter 4 Memory
MC9S08DZ60 Series Data Sheet, Rev. 4
68
Freescale Semiconductor
Chapter 5
Resets, Interrupts, and General System Control
5.1
Introduction
This section discusses basic reset and interrupt mechanisms and their various sources in the MC9S08DZ60
Series. Some interrupt sources from peripheral modules are discussed in greater detail within other
sections of this data sheet. This section gathers basic information about all reset and interrupt sources in
one place for easy reference. A few reset and interrupt sources, including the computer operating properly
(COP) watchdog, are not part of on-chip peripheral systems with their own chapters.
5.2
Features
Reset and interrupt features include:
• Multiple sources of reset for flexible system configuration and reliable operation
• Reset status register (SRS) to indicate source of most recent reset
• Separate interrupt vector for each module (reduces polling overhead); see Table 5-1
5.3
MCU Reset
Resetting the MCU provides a way to start processing from a known set of initial conditions. During reset,
most control and status registers are forced to initial values and the program counter is loaded from the
reset vector (0xFFFE:0xFFFF). On-chip peripheral modules are disabled and I/O pins are initially
configured as general-purpose high-impedance inputs with pull-up devices disabled. The I bit in the
condition code register (CCR) is set to block maskable interrupts so the user program has a chance to
initialize the stack pointer (SP) and system control settings. (See the CPU chapter for information on the
Interrupt (I) bit.) SP is forced to 0x00FF at reset.
The MC9S08DZ60 Series has eight sources for reset:
• Power-on reset (POR)
• External pin reset (PIN)
• Computer operating properly (COP) timer
• Illegal opcode detect (ILOP)
• Illegal address detect (ILAD)
• Low-voltage detect (LVD)
• Loss of clock (LOC)
• Background debug forced reset (BDFR)
Each of these sources, with the exception of the background debug forced reset, has an associated bit in
the system reset status register (SRS).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
69
Chapter 5 Resets, Interrupts, and General System Control
5.4
Computer Operating Properly (COP) Watchdog
The COP watchdog is intended to force a system reset when the application software fails to execute as
expected. To prevent a system reset from the COP timer (when it is enabled), application software must
reset the COP counter periodically. If the application program gets lost and fails to reset the COP counter
before it times out, a system reset is generated to force the system back to a known starting point.
After any reset, the COP watchdog is enabled (see Section 5.8.4, “System Options Register 1 (SOPT1),”
for additional information). If the COP watchdog is not used in an application, it can be disabled by
clearing COPT bits in SOPT1.
The COP counter is reset by writing 0x55 and 0xAA (in this order) to the address of SRS during the
selected timeout period. Writes do not affect the data in the read-only SRS. As soon as the write sequence
is done, the COP timeout period is restarted. If the program fails to do this during the time-out period, the
MCU will reset. Also, if any value other than 0x55 or 0xAA is written to SRS, the MCU is immediately
reset.
The COPCLKS bit in SOPT2 (see Section 5.8.5, “System Options Register 2 (SOPT2),” for additional
information) selects the clock source used for the COP timer. The clock source options are either the bus
clock or an internal 1-kHz clock source. With each clock source, there are three associated time-outs
controlled by the COPT bits in SOPT1. Table 5-6 summaries the control functions of the COPCLKS and
COPT bits. The COP watchdog defaults to operation from the 1-kHz clock source and the longest time-out
(210 cycles).
When the bus clock source is selected, windowed COP operation is available by setting COPW in the
SOPT2 register. In this mode, writes to the SRS register to clear the COP timer must occur in the last 25%
of the selected timeout period. A premature write immediately resets the MCU. When the 1-kHz clock
source is selected, windowed COP operation is not available.
The COP counter is initialized by the first writes to the SOPT1 and SOPT2 registers and after any system
reset. Subsequent writes to SOPT1 and SOPT2 have no effect on COP operation. Even if the application
will use the reset default settings of COPT, COPCLKS, and COPW bits, the user should write to the
write-once SOPT1 and SOPT2 registers during reset initialization to lock in the settings. This will prevent
accidental changes if the application program gets lost.
The write to SRS that services (clears) the COP counter should not be placed in an interrupt service routine
(ISR) because the ISR could continue to be executed periodically even if the main application program
fails.
If the bus clock source is selected, the COP counter does not increment while the MCU is in background
debug mode or while the system is in stop mode. The COP counter resumes when the MCU exits
background debug mode or stop mode.
If the 1-kHz clock source is selected, the COP counter is re-initialized to zero upon entry to either
background debug mode or stop mode and begins from zero upon exit from background debug mode or
stop mode.
MC9S08DZ60 Series Data Sheet, Rev. 4
70
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
5.5
Interrupts
Interrupts provide a way to save the current CPU status and registers, execute an interrupt service routine
(ISR), and then restore the CPU status so processing resumes where it left off before the interrupt. Other
than the software interrupt (SWI), which is a program instruction, interrupts are caused by hardware events
such as an edge on the IRQ pin or a timer-overflow event. The debug module can also generate an SWI
under certain circumstances.
If an event occurs in an enabled interrupt source, an associated read-only status flag will become set. The
CPU will not respond unless the local interrupt enable is a 1 to enable the interrupt and the I bit in the CCR
is 0 to allow interrupts. The global interrupt mask (I bit) in the CCR is initially set after reset which
prevents all maskable interrupt sources. The user program initializes the stack pointer and performs other
system setup before clearing the I bit to allow the CPU to respond to interrupts.
When the CPU receives a qualified interrupt request, it completes the current instruction before responding
to the interrupt. The interrupt sequence obeys the same cycle-by-cycle sequence as the SWI instruction and
consists of:
•
•
•
•
Saving the CPU registers on the stack
Setting the I bit in the CCR to mask further interrupts
Fetching the interrupt vector for the highest-priority interrupt that is currently pending
Filling the instruction queue with the first three bytes of program information starting from the
address fetched from the interrupt vector locations
While the CPU is responding to the interrupt, the I bit is automatically set to avoid the possibility of another
interrupt interrupting the ISR itself (this is called nesting of interrupts). Normally, the I bit is restored to 0
when the CCR is restored from the value stacked on entry to the ISR. In rare cases, the I bit can be cleared
inside an ISR (after clearing the status flag that generated the interrupt) so that other interrupts can be
serviced without waiting for the first service routine to finish. This practice is not recommended for anyone
other than the most experienced programmers because it can lead to subtle program errors that are difficult
to debug.
The interrupt service routine ends with a return-from-interrupt (RTI) instruction which restores the CCR,
A, X, and PC registers to their pre-interrupt values by reading the previously saved information from the
stack.
NOTE
For compatibility with M68HC08 devices, the H register is not
automatically saved and restored. It is good programming practice to push
H onto the stack at the start of the interrupt service routine (ISR) and restore
it immediately before the RTI that is used to return from the ISR.
If more than one interrupt is pending when the I bit is cleared, the highest priority source is serviced first
(see Table 5-1).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
71
Chapter 5 Resets, Interrupts, and General System Control
5.5.1
Interrupt Stack Frame
Figure 5-1 shows the contents and organization of a stack frame. Before the interrupt, the stack pointer
(SP) points at the next available byte location on the stack. The current values of CPU registers are stored
on the stack starting with the low-order byte of the program counter (PCL) and ending with the CCR. After
stacking, the SP points at the next available location on the stack which is the address that is one less than
the address where the CCR was saved. The PC value that is stacked is the address of the instruction in the
main program that would have executed next if the interrupt had not occurred.
UNSTACKING
ORDER
TOWARD LOWER ADDRESSES
7
0
SP AFTER
INTERRUPT STACKING
5
1
4
2
ACCUMULATOR
3
3
INDEX REGISTER (LOW BYTE X)*
2
4
PROGRAM COUNTER HIGH
1
5
PROGRAM COUNTER LOW
CONDITION CODE REGISTER
STACKING
ORDER
SP BEFORE
THE INTERRUPT
TOWARD HIGHER ADDRESSES
* High byte (H) of index register is not automatically stacked.
Figure 5-1. Interrupt Stack Frame
When an RTI instruction is executed, these values are recovered from the stack in reverse order. As part of
the RTI sequence, the CPU fills the instruction pipeline by reading three bytes of program information,
starting from the PC address recovered from the stack.
The status flag corresponding to the interrupt source must be acknowledged (cleared) before returning
from the ISR. Typically, the flag is cleared at the beginning of the ISR so that if another interrupt is
generated by this same source, it will be registered so it can be serviced after completion of the current ISR.
5.5.2
External Interrupt Request (IRQ) Pin
External interrupts are managed by the IRQ status and control register, IRQSC. When the IRQ function is
enabled, synchronous logic monitors the pin for edge-only or edge-and-level events. When the MCU is in
stop mode and system clocks are shut down, a separate asynchronous path is used so the IRQ (if enabled)
can wake the MCU.
5.5.2.1
Pin Configuration Options
The IRQ pin enable (IRQPE) control bit in IRQSC must be 1 in order for the IRQ pin to act as the interrupt
request (IRQ) input. As an IRQ input, the user can choose the polarity of edges or levels detected
(IRQEDG), whether the pin detects edges-only or edges and levels (IRQMOD), and whether an event
causes an interrupt or only sets the IRQF flag which can be polled by software.
MC9S08DZ60 Series Data Sheet, Rev. 4
72
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
The IRQ pin, when enabled, defaults to use an internal pull device (IRQPDD = 0), the device is a pull-up
or pull-down depending on the polarity chosen. If the user desires to use an external pull-up or pull-down,
the IRQPDD can be written to a 1 to turn off the internal device.
BIH and BIL instructions may be used to detect the level on the IRQ pin when the pin is configured to act
as the IRQ input.
5.5.2.2
Edge and Level Sensitivity
The IRQMOD control bit reconfigures the detection logic so it detects edge events and pin levels. In the
edge and level detection mode, the IRQF status flag becomes set when an edge is detected (when the IRQ
pin changes from the deasserted to the asserted level), but the flag is continuously set (and cannot be
cleared) as long as the IRQ pin remains at the asserted level.
5.5.3
Interrupt Vectors, Sources, and Local Masks
Table 5-1 provides a summary of all interrupt sources. Higher-priority sources are located toward the
bottom of the table. The high-order byte of the address for the interrupt service routine is located at the
first address in the vector address column, and the low-order byte of the address for the interrupt service
routine is located at the next higher address.
When an interrupt condition occurs, an associated flag bit becomes set. If the associated local interrupt
enable is 1, an interrupt request is sent to the CPU. Within the CPU, if the global interrupt mask (I bit in
the CCR) is 0, the CPU will finish the current instruction; stack the PCL, PCH, X, A, and CCR CPU
registers; set the I bit; and then fetch the interrupt vector for the highest priority pending interrupt.
Processing then continues in the interrupt service routine.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
73
Chapter 5 Resets, Interrupts, and General System Control
Table 5-1. Vector Summary1
1
Vector
No.
Address
(High/Low)
Vector
Name
Module
31
30
29
28
27
26
25
24
23
22
0xFFC0/0xFFC1
0xFFC2/0xFFC3
0xFFC4/0xFFC5
0xFFC6/0xFFC7
0xFFC8/0xFFC9
0xFFCA/0xFFCB
0xFFCC/0xFFCD
0xFFCE/0xFFCF
0xFFD0/0xFFD1
0xFFD2/0xFFD3
Vacmp2
Vacmp1
Vcantx
Vcanrx
Vcanerr
Vcanwu
Vrtc
Viic
Vadc
Vport
ACMP2
ACMP1
MSCAN
MSCAN
MSCAN
MSCAN
RTC
IIC
ADC
Port A,B,D
21
20
0xFFD4/0xFFD5
0xFFD6/0xFFD7
Vsci2tx
Vsci2rx
SCI2
SCI2
19
0xFFD8/0xFFD9
Vsci2err
SCI2
18
17
0xFFDA/0xFFDB
0xFFDC/0xFFDD
Vsci1tx
Vsci1rx
SCI1
SCI1
16
0xFFDE/0xFFDF
Vsci1err
SCI1
15
0xFFE0/0xFFE1
Vspi
SPI
14
13
12
11
10
9
8
7
6
5
4
3
0xFFE2/0xFFE3
0xFFE4/0xFFE5
0xFFE6/0xFFE7
0xFFE8/0xFFE9
0xFFEA/0xFFEB
0xFFEC/0xFFED
0xFFEE/0xFFEF
0xFFF0/0xFFF1
0xFFF2/0xFFF3
0xFFF4/0xFFF5
0xFFF6/0xFFF7
0xFFF8/0xFFF9
Vtpm2ovf
Vtpm2ch1
Vtpm2ch0
Vtpm1ovf
Vtpm1ch5
Vtpm1ch4
Vtpm1ch3
Vtpm1ch2
Vtpm1ch1
Vtpm1ch0
Vlol
Vlvd
2
1
0
0xFFFA/0xFFFB
0xFFFC/0xFFFD
0xFFFE/0xFFFF
Virq
Vswi
Vreset
TPM2
TPM2
TPM2
TPM1
TPM1
TPM1
TPM1
TPM1
TPM1
TPM1
MCG
System
control
IRQ
Core
System
control
Source
Enable
Description
ACF
ACIE
ACF
ACIE
TXE[2:0]
TXEIE[2:0]
RXF
RXFIE
CSCIF, OVRIF
CSCIE, OVRIE
WUPIF
WUPIE
RTIF
RTIE
IICIS
IICIE
COCO
AIEN
PTAIF, PTBIF, PTAIE, PTBIE, PTDIE
PTDIF
TDRE, TC
TIE, TCIE
IDLE, LBKDIF,
ILIE, LBKDIE, RIE,
RDRF, RXEDGIF
RXEDGIE
OR, NF
ORIE, NFIE,
FE, PF
FEIE, PFIE
TDRE, TC
TIE, TCIE
IDLE, LBKDIF,
ILIE, LBKDIE, RIE,
RDRF, RXEDGIF
RXEDGIE
OR, NF,
ORIE, NFIE,
FE, PF
FEIE, PFIE
SPIF, MODF,
SPIE, SPIE, SPTIE
SPTEF
TOF
TOIE
CH1F
CH1IE
CH0F
CH0IE
TOF
TOIE
CH5F
CH5IE
CH4F
CH4IE
CH3F
CH3IE
CH2F
CH2IE
CH1F
CH1IE
CH0F
CH0IE
LOLS
LOLIE
LVWF
LVWIE
IRQF
SWI Instruction
COP,
LOC,
LVD,
RESET,
ILOP,
ILAD,
POR,
BDFR
IRQIE
—
COPE
CME
LVDRE
—
—
—
—
—
Analog comparator 2
Analog comparator 1
CAN transmit
CAN receive
CAN errors
CAN wake-up
Real-time interrupt
IIC control
ADC
Port Pins
SCI2 transmit
SCI2 receive
SCI2 error
SCI1 transmit
SCI1 receive
SCI1 error
SPI
TPM2 overflow
TPM2 channel 1
TPM2 channel 0
TPM1 overflow
TPM1 channel 5
TPM1 channel 4
TPM1 channel 3
TPM1 channel 2
TPM1 channel 1
TPM1 channel 0
MCG loss of lock
Low-voltage warning
IRQ pin
Software interrupt
Watchdog timer
Loss-of-clock
Low-voltage detect
External pin
Illegal opcode
Illegal address
Power-on-reset
BDM-forced reset
Vector priority is shown from lowest (first row) to highest (last row). For example, Vreset is the highest priority vector.
MC9S08DZ60 Series Data Sheet, Rev. 4
74
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
5.6
Low-Voltage Detect (LVD) System
The MC9S08DZ60 Series includes a system to protect against low-voltage conditions in order to protect
memory contents and control MCU system states during supply voltage variations. The system is
comprised of a power-on reset (POR) circuit and a LVD circuit with trip voltages for warning and
detection. The LVD circuit is enabled when LVDE in SPMSC1 is set to 1. The LVD is disabled upon
entering any of the stop modes unless LVDSE is set in SPMSC1. If LVDSE and LVDE are both set, then
the MCU cannot enter stop2 (it will enter stop3 instead), and the current consumption in stop3 with the
LVD enabled will be higher.
5.6.1
Power-On Reset Operation
When power is initially applied to the MCU, or when the supply voltage drops below the power-on reset
rearm voltage level, VPOR, the POR circuit will cause a reset condition. As the supply voltage rises, the
LVD circuit will hold the MCU in reset until the supply has risen above the low-voltage detection low
threshold, VLVDL. Both the POR bit and the LVD bit in SRS are set following a POR.
5.6.2
Low-Voltage Detection (LVD) Reset Operation
The LVD can be configured to generate a reset upon detection of a low-voltage condition by setting
LVDRE to 1. The low-voltage detection threshold is determined by the LVDV bit. After an LVD reset has
occurred, the LVD system will hold the MCU in reset until the supply voltage has risen above the
low-voltage detection threshold. The LVD bit in the SRS register is set following either an LVD reset or
POR.
5.6.3
Low-Voltage Warning (LVW) Interrupt Operation
The LVD system has a low-voltage warning flag to indicate to the user that the supply voltage is
approaching the low-voltage condition. When a low-voltage warning condition is detected and is
configured for interrupt operation (LVWIE set to 1), LVWF in SPMSC1 will be set and an LVW interrupt
request will occur.
5.7
MCLK Output
The PTA0 pin is shared with the MCLK clock output. If the MCSEL bits are all zeroes, the MCLK clock
is disabled. Setting any of the MCSEL bits causes the PTA0 pin to output a divided version of the internal
MCU bus clock regardless of the state of the port data direction control bit for the pin. The divide ratio is
determined by the MCSEL bits. The slew rate and drive strength for the pin are controlled by PTASE0 and
PTADS0, respectively. The maximum clock output frequency is limited if slew rate control is enabled, see
the electrical specifications for the maximum frequency under different conditions.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
75
Chapter 5 Resets, Interrupts, and General System Control
5.8
Reset, Interrupt, and System Control Registers and Control Bits
One 8-bit register in the direct page register space and eight 8-bit registers in the high-page register space
are related to reset and interrupt systems.
Refer to Table 4-2 and Table 4-3 in Chapter 4, “Memory,” of this data sheet for the absolute address
assignments for all registers. This section refers to registers and control bits only by their names. A
Freescale-provided equate or header file is used to translate these names into the appropriate absolute
addresses.
Some control bits in the SOPT1 and SPMSC2 registers are related to modes of operation. Although brief
descriptions of these bits are provided here, the related functions are discussed in greater detail in
Chapter 3, “Modes of Operation.”
MC9S08DZ60 Series Data Sheet, Rev. 4
76
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
5.8.1
Interrupt Pin Request Status and Control Register (IRQSC)
This direct page register includes status and control bits which are used to configure the IRQ function,
report status, and acknowledge IRQ events.
7
R
6
5
4
IRQPDD
IRQEDG
IRQPE
0
3
2
IRQF
0
W
Reset
1
0
IRQIE
IRQMOD
0
0
IRQACK
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 5-2. Interrupt Request Status and Control Register (IRQSC)
Table 5-2. IRQSC Register Field Descriptions
Field
Description
6
IRQPDD
Interrupt Request (IRQ) Pull Device Disable— This read/write control bit is used to disable the internal
pull-up/pull-down device when the IRQ pin is enabled (IRQPE = 1) allowing for an external device to be used.
0 IRQ pull device enabled if IRQPE = 1.
1 IRQ pull device disabled if IRQPE = 1.
5
IRQEDG
Interrupt Request (IRQ) Edge Select — This read/write control bit is used to select the polarity of edges or
levels on the IRQ pin that cause IRQF to be set. The IRQMOD control bit determines whether the IRQ pin is
sensitive to both edges and levels or only edges. When the IRQ pin is enabled as the IRQ input and is configured
to detect rising edges, it has a pull-down. When the IRQ pin is enabled as the IRQ input and is configured to
detect falling edges, it has a pull-up.
0 IRQ is falling edge or falling edge/low-level sensitive.
1 IRQ is rising edge or rising edge/high-level sensitive.
4
IRQPE
IRQ Pin Enable — This read/write control bit enables the IRQ pin function. When this bit is set the IRQ pin can
be used as an interrupt request.
0 IRQ pin function is disabled.
1 IRQ pin function is enabled.
3
IRQF
2
IRQACK
1
IRQIE
0
IRQMOD
IRQ Flag — This read-only status bit indicates when an interrupt request event has occurred.
0 No IRQ request.
1 IRQ event detected.
IRQ Acknowledge — This write-only bit is used to acknowledge interrupt request events (write 1 to clear IRQF).
Writing 0 has no meaning or effect. Reads always return 0. If edge-and-level detection is selected (IRQMOD = 1),
IRQF cannot be cleared while the IRQ pin remains at its asserted level.
IRQ Interrupt Enable — This read/write control bit determines whether IRQ events generate an interrupt
request.
0 Interrupt request when IRQF set is disabled (use polling).
1 Interrupt requested whenever IRQF = 1.
IRQ Detection Mode — This read/write control bit selects either edge-only detection or edge-and-level
detection. The IRQEDG control bit determines the polarity of edges and levels that are detected as interrupt
request events. See Section 5.5.2.2, “Edge and Level Sensitivity” for more details.
0 IRQ event on falling edges or rising edges only.
1 IRQ event on falling edges and low levels or on rising edges and high levels.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
77
Chapter 5 Resets, Interrupts, and General System Control
5.8.2
System Reset Status Register (SRS)
This high page register includes read-only status flags to indicate the source of the most recent reset. When
a debug host forces reset by writing 1 to BDFR in the SBDFR register, none of the status bits in SRS will
be set. Writing any value to this register address causes a COP reset when the COP is enabled except the
values 0x55 and 0xAA. Writing a 0x55-0xAA sequence to this address clears the COP watchdog timer
without affecting the contents of this register. The reset state of these bits depends on what caused the
MCU to reset.
R
7
6
5
4
3
2
1
0
POR
PIN
COP
ILOP
ILAD
LOC
LVD
0
W
Writing 0x55, 0xAA to SRS address clears COP watchdog timer.
POR:
1
0
0
0
0
0
1
0
LVD:
u
0
0
0
0
0
1
0
Any other
reset:
0
Note(1)
Note(1)
Note(1)
Note(1)
0
0
0
1
Any of these reset sources that are active at the time of reset entry will cause the corresponding bit(s) to be set; bits
corresponding to sources that are not active at the time of reset entry will be cleared.
Figure 5-3. System Reset Status (SRS)
Table 5-3. SRS Register Field Descriptions
Field
Description
7
POR
Power-On Reset — Reset was caused by the power-on detection logic. Because the internal supply voltage was
ramping up at the time, the low-voltage reset (LVD) status bit is also set to indicate that the reset occurred while
the internal supply was below the LVD threshold.
0 Reset not caused by POR.
1 POR caused reset.
6
PIN
External Reset Pin — Reset was caused by an active-low level on the external reset pin.
0 Reset not caused by external reset pin.
1 Reset came from external reset pin.
5
COP
Computer Operating Properly (COP) Watchdog — Reset was caused by the COP watchdog timer timing out.
This reset source can be blocked by COPE = 0.
0 Reset not caused by COP timeout.
1 Reset caused by COP timeout.
4
ILOP
Illegal Opcode — Reset was caused by an attempt to execute an unimplemented or illegal opcode. The STOP
instruction is considered illegal if stop is disabled by STOPE = 0 in the SOPT register. The BGND instruction is
considered illegal if active background mode is disabled by ENBDM = 0 in the BDCSC register.
0 Reset not caused by an illegal opcode.
1 Reset caused by an illegal opcode.
3
ILAD
Illegal Address — Reset was caused by an attempt to access either data or an instruction at an unimplemented
memory address.
0 Reset not caused by an illegal address.
1 Reset caused by an illegal address.
MC9S08DZ60 Series Data Sheet, Rev. 4
78
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
Table 5-3. SRS Register Field Descriptions
Field
Description
2
LOC
Loss of Clock — Reset was caused by a loss of external clock.
0 Reset not caused by loss of external clock
1 Reset caused by loss of external clock
1
LVD
Low-Voltage Detect — If the LVDRE bit is set and the supply drops below the LVD trip voltage, an LVD reset will
occur. This bit is also set by POR.
0 Reset not caused by LVD trip or POR.
1 Reset caused by LVD trip or POR.
5.8.3
System Background Debug Force Reset Register (SBDFR)
This high page register contains a single write-only control bit. A serial background command such as
WRITE_BYTE must be used to write to SBDFR. Attempts to write this register from a user program are
ignored. Reads always return 0x00.
R
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
BDFR1
W
Reset:
0
0
0
0
0
0
0
0
= Unimplemented or Reserved
1
BDFR is writable only through serial background debug commands, not from user programs.
Figure 5-4. System Background Debug Force Reset Register (SBDFR)
Table 5-4. SBDFR Register Field Descriptions
Field
Description
0
BDFR
Background Debug Force Reset — A serial background command such as WRITE_BYTE can be used to allow
an external debug host to force a target system reset. Writing 1 to this bit forces an MCU reset. This bit cannot
be written from a user program.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
79
Chapter 5 Resets, Interrupts, and General System Control
5.8.4
System Options Register 1 (SOPT1)
This high page register is a write-once register so only the first write after reset is honored. It can be read
at any time. Any subsequent attempt to write to SOPT1 (intentionally or unintentionally) is ignored to
avoid accidental changes to these sensitive settings. This register should be written during the user’s reset
initialization program to set the desired controls even if the desired settings are the same as the reset
settings.
7
6
5
4
3
STOPE
SCI2PS
IICPS
0
0
0
R
COPT
2
1
0
0
0
0
0
0
0
W
Reset:
1
1
= Unimplemented or Reserved
Figure 5-5. System Options Register 1 (SOPT1)
Table 5-5. SOPT1 Register Field Descriptions
Field
Description
7:6
COPT[1:0]
COP Watchdog Timeout — These write-once bits select the timeout period of the COP. COPT along with
COPCLKS in SOPT2 defines the COP timeout period. See Table 5-6.
5
STOPE
Stop Mode Enable — This write-once bit is used to enable stop mode. If stop mode is disabled and a user
program attempts to execute a STOP instruction, an illegal opcode reset is forced.
0 Stop mode disabled.
1 Stop mode enabled.
4
SCI2PS
SCI2 Pin Select— This write-once bit selects the location of the RxD2 and TxD2 pins of the SCI2 module.
0 TxD2 on PTF0, RxD2 on PTF1.
1 TxD2 on PTE6, RxD2 on PTE7.
3
IICPS
IIC Pin Select— This write-once bit selects the location of the SCL and SDA pins of the IIC module.
0 SCL on PTF2, SDA on PTF3.
1 SCL on PTE4, SDA on PTE5.
Table 5-6. COP Configuration Options
Control Bits
Clock Source
COP Window1 Opens
(COPW = 1)
N/A
N/A
COP Overflow Count
COPCLKS
COPT[1:0]
N/A
0:0
0
0:1
1 kHz
N/A
25
0
1:0
1 kHz
N/A
28 cycles (256 ms1)
0
1:1
1 kHz
N/A
210 cycles (1.024 s1)
1
0:1
Bus
6144 cycles
213 cycles
1
1:0
Bus
49,152 cycles
216 cycles
1
1:1
Bus
196,608 cycles
218 cycles
COP is disabled
cycles (32 ms2)
1
Windowed COP operation requires the user to clear the COP timer in the last 25% of the selected timeout period. This column
displays the minimum number of clock counts required before the COP timer can be reset when in windowed COP mode
(COPW = 1).
2 Values shown in milliseconds based on t
LPO = 1 ms. See tLPO in the appendix Section A.12.1, “Control Timing,” for the
tolerance of this value.
MC9S08DZ60 Series Data Sheet, Rev. 4
80
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
5.8.5
System Options Register 2 (SOPT2)
This high page register contains bits to configure MCU specific features on the MC9S08DZ60 Series
devices.
R
7
6
5
COPCLKS1
COPW1
0
0
4
3
0
2
1
0
0
ADHTS
MCSEL
W
Reset:
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 5-6. System Options Register 2 (SOPT2)
1
This bit can be written only one time after reset. Additional writes are ignored.
Table 5-7. SOPT2 Register Field Descriptions
Field
7
COPCLKS
Description
COP Watchdog Clock Select — This write-once bit selects the clock source of the COP watchdog. See
Table 5-6 for details.
0 Internal 1-kHz clock is source to COP.
1 Bus clock is source to COP.
6
COPW
COP Window — This write-once bit selects the COP operation mode. When set, the 0x55-0xAA write sequence
to the SRS register must occur in the last 25% of the selected period. Any write to the SRS register during the
first 75% of the selected period will reset the MCU.
0 Normal COP operation.
1 Window COP operation.
4
ADHTS
ADC Hardware Trigger Select — This bit selects which hardware trigger initiates conversion for the analog to
digital converter when the ADC hardware trigger is enabled (ADCTRG is set in ADCSC2 register).
0 Real Time Counter (RTC) overflow.
1 External Interrupt Request (IRQ) pin.
2:0
MCSEL
MCLK Divide Select— These bits enable the MCLK output on PTA0 pin and select the divide ratio for the MCLK
output according to the formula below when the MCSEL bits are not equal to all zeroes. In case that the MCSEL
bits are all zeroes, the MCLK output is disabled.
MCLK frequency = Bus Clock frequency ÷ (2 * MCSEL)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
81
Chapter 5 Resets, Interrupts, and General System Control
5.8.6
System Device Identification Register (SDIDH, SDIDL)
These high page read-only registers are included so host development systems can identify the HCS08
derivative and revision number. This allows the development software to recognize where specific memory
blocks, registers, and control bits are located in a target MCU.
7
6
R
5
4
Reserved
3
2
1
0
ID11
ID10
ID9
ID8
0
0
0
0
W
Reset:
01
01
01
01
= Unimplemented or Reserved
1
The revision number that is hard coded into these bits reflects the current silicon revision level.
Figure 5-7. System Device Identification Register — High (SDIDH)
Table 5-8. SDIDH Register Field Descriptions
Field
Description
3:0
ID[11:8]
Part Identification Number — MC9S08DZ60 Series MCUs are hard-coded to the value 0x00E. See also ID bits
in Table 5-9.
R
7
6
5
4
3
2
1
0
ID7
ID6
ID5
ID4
ID3
ID2
ID1
ID0
0
0
0
0
1
1
1
0
W
Reset:
= Unimplemented or Reserved
Figure 5-8. System Device Identification Register — Low (SDIDL)
Table 5-9. SDIDL Register Field Descriptions
Field
Description
7:0
ID[7:0]
Part Identification Number — MC9S08DZ60 Series MCUs are hard-coded to the value 0x00E. See also ID bits
in Table 5-8.
MC9S08DZ60 Series Data Sheet, Rev. 4
82
Freescale Semiconductor
Chapter 5 Resets, Interrupts, and General System Control
5.8.7
System Power Management Status and Control 1 Register
(SPMSC1)
This high page register contains status and control bits to support the low-voltage detect function, and to
enable the bandgap voltage reference for use by the ADC and ACMP modules. This register should be
written during the user’s reset initialization program to set the desired controls even if the desired settings
are the same as the reset settings.
7
R
LVWF
6
1
4
3
2
LVWIE
LVDRE2
LVDSE
LVDE2
0
1
1
1
0
W
Reset:
5
1
0
0
BGBE
LVWACK
0
0
0
0
= Unimplemented or Reserved
1
2
LVWF will be set in the case when VSupply transitions below the trip point or after reset and VSupply is already below VLVW.
This bit can be written only one time after reset. Additional writes are ignored.
Figure 5-9. System Power Management Status and Control 1 Register (SPMSC1)
Table 5-10. SPMSC1 Register Field Descriptions
Field
7
LVWF
6
LVWACK
Description
Low-Voltage Warning Flag — The LVWF bit indicates the low-voltage warning status.
0 low-voltage warning is not present.
1 low-voltage warning is present or was present.
Low-Voltage Warning Acknowledge — If LVWF = 1, a low-voltage condition has occurred. To acknowledge this
low-voltage warning, write 1 to LVWACK, which will automatically clear LVWF to 0 if the low-voltage warning is
no longer present.
5
LVWIE
Low-Voltage Warning Interrupt Enable — This bit enables hardware interrupt requests for LVWF.
0 Hardware interrupt disabled (use polling).
1 Request a hardware interrupt when LVWF = 1.
4
LVDRE
Low-Voltage Detect Reset Enable — This write-once bit enables LVD events to generate a hardware reset
(provided LVDE = 1).
0 LVD events do not generate hardware resets.
1 Force an MCU reset when an enabled low-voltage detect event occurs.
3
LVDSE
Low-Voltage Detect Stop Enable — Provided LVDE = 1, this read/write bit determines whether the low-voltage
detect function operates when the MCU is in stop mode.
0 Low-voltage detect disabled during stop mode.
1 Low-voltage detect enabled during stop mode.
2
LVDE
Low-Voltage Detect Enable — This write-once bit enables low-voltage detect logic and qualifies the operation
of other bits in this register.
0 LVD logic disabled.
1 LVD logic enabled.
0
BGBE
Bandgap Buffer Enable — This bit enables an internal buffer for the bandgap voltage reference for use by the
ADC and ACMP modules on one of its internal channels.
0 Bandgap buffer disabled.
1 Bandgap buffer enabled.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
83
Chapter 5 Resets, Interrupts, and General System Control
5.8.8
System Power Management Status and Control 2 Register
(SPMSC2)
This register is used to report the status of the low-voltage warning function, and to configure the stop
mode behavior of the MCU. This register should be written during the user’s reset initialization program
to set the desired controls even if the desired settings are the same as the reset settings.
R
7
6
0
0
5
4
LVDV1
LVWV
3
2
1
PPDF
0
0
W
0
PPDC2
PPDACK
Power-on Reset:
0
0
0
0
0
0
0
0
LVD Reset:
0
0
u
u
0
0
0
0
Any other Reset:
0
0
u
u
0
0
0
0
= Unimplemented or Reserved
1
2
u = Unaffected by reset
This bit can be written only one time after power-on reset. Additional writes are ignored.
This bit can be written only one time after reset. Additional writes are ignored.
Figure 5-10. System Power Management Status and Control 2 Register (SPMSC2)
Table 5-11. SPMSC2 Register Field Descriptions
Field
Description
5
LVDV
Low-Voltage Detect Voltage Select — This write-once bit selects the low-voltage detect (LVD) trip point setting.
It also selects the warning voltage range. See Table 5-12.
4
LVWV
Low-Voltage Warning Voltage Select — This bit selects the low-voltage warning (LVW) trip point voltage. See
Table 5-12.
3
PPDF
Partial Power Down Flag — This read-only status bit indicates that the MCU has recovered from stop2 mode.
0 MCU has not recovered from stop2 mode.
1 MCU recovered from stop2 mode.
2
PPDACK
0
PPDC
Partial Power Down Acknowledge — Writing a 1 to PPDACK clears the PPDF bit.
Partial Power Down Control — This write-once bit controls whether stop2 or stop3 mode is selected.
0 Stop3 mode enabled.
1 Stop2, partial power down, mode enabled.
Table 5-12. LVD and LVW Trip Point Typical Values1
1
LVDV:LVWV
LVW Trip Point
LVD Trip Point
0:0
VLVW0 = 2.74 V
VLVD0 = 2.56 V
0:1
VLVW1 = 2.92 V
1:0
VLVW2 = 4.3 V
1:1
VLVW3 = 4.6 V
VLVD1 = 4.0 V
See Electrical Characteristics appendix for minimum and maximum values.
MC9S08DZ60 Series Data Sheet, Rev. 4
84
Freescale Semiconductor
Chapter 6
Parallel Input/Output Control
This section explains software controls related to parallel input/output (I/O) and pin control. The
MC9S08DZ60 Series has seven parallel I/O ports which include a total of up to 53 I/O pins and one
input-only pin. See Chapter 2, “Pins and Connections,” for more information about pin assignments and
external hardware considerations of these pins.
Many of these pins are shared with on-chip peripherals such as timer systems, communication systems, or
pin interrupts as shown in Table 2-1. The peripheral modules have priority over the general-purpose I/O
functions so that when a peripheral is enabled, the I/O functions associated with the shared pins are
disabled.
After reset, the shared peripheral functions are disabled and the pins are configured as inputs
(PTxDDn = 0). The pin control functions for each pin are configured as follows: slew rate control enabled
(PTxSEn = 1), low drive strength selected (PTxDSn = 0), and internal pull-ups disabled (PTxPEn = 0).
•
•
6.1
NOTE
Not all general-purpose I/O pins are available on all packages. To avoid
extra current drain from floating input pins, the user’s reset initialization
routine in the application program must either enable on-chip pull-up
devices or change the direction of unconnected pins to outputs so the
pins do not float.
The PTE1 pin does not contain a clamp diode to VDD and should not be
driven above VDD. The voltage measured on the internally pulled up
PTE1 pin may be as low as VDD – 0.7 V. The internal gates connected
to this pin are pulled all the way to VDD.
Port Data and Data Direction
Reading and writing of parallel I/Os are performed through the port data registers. The direction, either
input or output, is controlled through the port data direction registers. The parallel I/O port function for an
individual pin is illustrated in the block diagram shown in Figure 6-1.
The data direction control bit (PTxDDn) determines whether the output buffer for the associated pin is
enabled, and also controls the source for port data register reads. The input buffer for the associated pin is
always enabled unless the pin is enabled as an analog function or is an output-only pin.
When a shared digital function is enabled for a pin, the output buffer is controlled by the shared function.
However, the data direction register bit will continue to control the source for reads of the port data register.
When a shared analog function is enabled for a pin, both the input and output buffers are disabled. A value
of 0 is read for any port data bit where the bit is an input (PTxDDn = 0) and the input buffer is disabled.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
85
Chapter 6 Parallel Input/Output Control
In general, whenever a pin is shared with both an alternate digital function and an analog function, the
analog function has priority such that if both the digital and analog functions are enabled, the analog
function controls the pin.
It is a good programming practice to write to the port data register before changing the direction of a port
pin to become an output. This ensures that the pin will not be driven momentarily with an old data value
that happened to be in the port data register.
PTxDDn
D
Output Enable
Q
PTxDn
D
Output Data
Q
1
Port Read
Data
0
Input Data
Synchronizer
BUSCLK
Figure 6-1. Parallel I/O Block Diagram
6.2
Pull-up, Slew Rate, and Drive Strength
Associated with the parallel I/O ports is a set of registers located in the high page register space that operate
independently of the parallel I/O registers. These registers are used to control pull-ups, slew rate, and drive
strength for the pins.
An internal pull-up device can be enabled for each port pin by setting the corresponding bit in the pull-up
enable register (PTxPEn). The pull-up device is disabled if the pin is configured as an output by the parallel
I/O control logic or any shared peripheral function regardless of the state of the corresponding pull-up
enable register bit. The pull-up device is also disabled if the pin is controlled by an analog function.
Slew rate control can be enabled for each port pin by setting the corresponding bit in the slew rate control
register (PTxSEn). When enabled, slew control limits the rate at which an output can transition in order to
reduce EMC emissions. Slew rate control has no effect on pins that are configured as inputs.
NOTE
Slew rate reset default values may differ between engineering samples and
final production parts. Always initialize slew rate control to the desired
value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
86
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
An output pin can be selected to have high output drive strength by setting the corresponding bit in the
drive strength select register (PTxDSn). When high drive is selected, a pin is capable of sourcing and
sinking greater current. Even though every I/O pin can be selected as high drive, the user must ensure that
the total current source and sink limits for the MCU are not exceeded. Drive strength selection is intended
to affect the DC behavior of I/O pins. However, the AC behavior is also affected. High drive allows a pin
to drive a greater load with the same switching speed as a low drive enabled pin into a smaller load.
Because of this, the EMC emissions may be affected by enabling pins as high drive.
6.3
Pin Interrupts
Port A, port B, and port D pins can be configured as external interrupt inputs and as an external means of
waking the MCU from stop or wait low-power modes.
The block diagram for each port interrupt logic is shown Figure 6-2.
BUSCLK
PTxACK
VDD
1
PTxn
0
S
RESET
PTxIF
D CLR Q
PTxPS0
SYNCHRONIZER
CK
PTxES0
PORT
INTERRUPT FF
1
PTxn
0
S
STOP
STOP BYPASS
PTx
INTERRUPT
REQUEST
PTxMOD
PTxPSn
PTxIE
PTxESn
Figure 6-2. Port Interrupt Block Diagram
Writing to the PTxPSn bits in the port interrupt pin select register (PTxPS) independently enables or
disables each port pin. Each port can be configured as edge sensitive or edge and level sensitive based on
the PTxMOD bit in the port interrupt status and control register (PTxSC). Edge sensitivity can be software
programmed to be either falling or rising; the level can be either low or high. The polarity of the edge or
edge and level sensitivity is selected using the PTxESn bits in the port interrupt edge select register
(PTxES).
Synchronous logic is used to detect edges. Prior to detecting an edge, enabled port inputs must be at the
deasserted logic level. A falling edge is detected when an enabled port input signal is seen as a logic 1 (the
deasserted level) during one bus cycle and then a logic 0 (the asserted level) during the next cycle. A rising
edge is detected when the input signal is seen as a logic 0 during one bus cycle and then a logic 1 during
the next cycle.
6.3.1
Edge Only Sensitivity
A valid edge on an enabled port pin will set PTxIF in PTxSC. If PTxIE in PTxSC is set, an interrupt request
will be presented to the CPU. Clearing of PTxIF is accomplished by writing a 1 to PTxACK in PTxSC.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
87
Chapter 6 Parallel Input/Output Control
6.3.2
Edge and Level Sensitivity
A valid edge or level on an enabled port pin will set PTxIF in PTxSC. If PTxIE in PTxSC is set, an interrupt
request will be presented to the CPU. Clearing of PTxIF is accomplished by writing a 1 to PTxACK in
PTxSC provided all enabled port inputs are at their deasserted levels. PTxIF will remain set if any enabled
port pin is asserted while attempting to clear by writing a 1 to PTxACK.
6.3.3
Pull-up/Pull-down Resistors
The port interrupt pins can be configured to use an internal pull-up/pull-down resistor using the associated
I/O port pull-up enable register. If an internal resistor is enabled, the PTxES register is used to select
whether the resistor is a pull-up (PTxESn = 0) or a pull-down (PTxESn = 1).
6.3.4
Pin Interrupt Initialization
When an interrupt pin is first enabled, it is possible to get a false interrupt flag. To prevent a false interrupt
request during pin interrupt initialization, the user should do the following:
1. Mask interrupts by clearing PTxIE in PTxSC.
2. Select the pin polarity by setting the appropriate PTxESn bits in PTxES.
3. If using internal pull-up/pull-down device, configure the associated pull enable bits in PTxPE.
4. Enable the interrupt pins by setting the appropriate PTxPSn bits in PTxPS.
5. Write to PTxACK in PTxSC to clear any false interrupts.
6. Set PTxIE in PTxSC to enable interrupts.
6.4
Pin Behavior in Stop Modes
Pin behavior following execution of a STOP instruction depends on the stop mode that is entered. An
explanation of pin behavior for the various stop modes follows:
• Stop2 mode is a partial power-down mode, whereby I/O latches are maintained in their state as
before the STOP instruction was executed. CPU register status and the state of I/O registers should
be saved in RAM before the STOP instruction is executed to place the MCU in stop2 mode. Upon
recovery from stop2 mode, before accessing any I/O, the user should examine the state of the PPDF
bit in the SPMSC2 register. If the PPDF bit is 0, I/O must be initialized as if a power on reset had
occurred. If the PPDF bit is 1, peripherals may require initialization to be restored to their pre-stop
condition. This can be done using data previously stored in RAM if it was saved before the STOP
instruction was executed. The user must then write a 1 to the PPDACK bit in the SPMSC2 register.
Access to I/O is now permitted again in the user application program.
• In stop3 mode, all I/O is maintained because internal logic circuity stays powered up. Upon
recovery, normal I/O function is available to the user.
MC9S08DZ60 Series Data Sheet, Rev. 4
88
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5
Parallel I/O and Pin Control Registers
This section provides information about the registers associated with the parallel I/O ports. The data and
data direction registers are located in page zero of the memory map. The pull up, slew rate, drive strength,
and interrupt control registers are located in the high page section of the memory map.
Refer to tables in Chapter 4, “Memory,” for the absolute address assignments for all parallel I/O and their
pin control registers. This section refers to registers and control bits only by their names. A Freescale
Semiconductor-provided equate or header file normally is used to translate these names into the
appropriate absolute addresses.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
89
Chapter 6 Parallel Input/Output Control
6.5.1
Port A Registers
Port A is controlled by the registers listed below.
6.5.1.1
Port A Data Register (PTAD)
7
6
5
4
3
2
1
0
PTAD7
PTAD6
PTAD5
PTAD4
PTAD3
PTAD2
PTAD1
PTAD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-3. Port A Data Register (PTAD)
Table 6-1. PTAD Register Field Descriptions
Field
Description
7:0
PTAD[7:0]
Port A Data Register Bits — For port A pins that are inputs, reads return the logic level on the pin. For port A
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port A pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTAD to all 0s, but these 0s are not driven out the corresponding pins because reset also configures
all port pins as high-impedance inputs with pull-ups/pull-downs disabled.
6.5.1.2
Port A Data Direction Register (PTADD)
7
6
5
4
3
2
1
0
PTADD7
PTADD6
PTADD5
PTADD4
PTADD3
PTADD2
PTADD1
PTADD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-4. Port A Data Direction Register (PTADD)
Table 6-2. PTADD Register Field Descriptions
Field
Description
7:0
Data Direction for Port A Bits — These read/write bits control the direction of port A pins and what is read for
PTADD[7:0] PTAD reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port A bit n and PTAD reads return the contents of PTADn.
MC9S08DZ60 Series Data Sheet, Rev. 4
90
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.1.3
Port A Pull Enable Register (PTAPE)
7
6
5
4
3
2
1
0
PTAPE7
PTAPE6
PTAPE5
PTAPE4
PTAPE3
PTAPE2
PTAPE1
PTAPE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-5. Internal Pull Enable for Port A Register (PTAPE)
Table 6-3. PTAPE Register Field Descriptions
Field
Description
7:0
Internal Pull Enable for Port A Bits — Each of these control bits determines if the internal pull-up or pull-down
PTAPE[7:0] device is enabled for the associated PTA pin. For port A pins that are configured as outputs, these bits have no
effect and the internal pull devices are disabled.
0 Internal pull-up/pull-down device disabled for port A bit n.
1 Internal pull-up/pull-down device enabled for port A bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.1.4
Port A Slew Rate Enable Register (PTASE)
7
6
5
4
3
2
1
0
PTASE7
PTASE6
PTASE5
PTASE4
PTASE3
PTASE2
PTASE1
PTASE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-6. Slew Rate Enable for Port A Register (PTASE)
Table 6-4. PTASE Register Field Descriptions
Field
Description
7:0
Output Slew Rate Enable for Port A Bits — Each of these control bits determines if the output slew rate control
PTASE[7:0] is enabled for the associated PTA pin. For port A pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port A bit n.
1 Output slew rate control enabled for port A bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
91
Chapter 6 Parallel Input/Output Control
6.5.1.5
Port A Drive Strength Selection Register (PTADS)
7
6
5
4
3
2
1
0
PTADS7
PTADS6
PTADS5
PTADS4
PTADS3
PTADS2
PTADS1
PTADS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-7. Drive Strength Selection for Port A Register (PTADS)
Table 6-5. PTADS Register Field Descriptions
Field
Description
7:0
Output Drive Strength Selection for Port A Bits — Each of these control bits selects between low and high
PTADS[7:0] output drive for the associated PTA pin. For port A pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port A bit n.
1 High output drive strength selected for port A bit n.
6.5.1.6
R
Port A Interrupt Status and Control Register (PTASC)
7
6
5
4
3
2
0
0
0
0
PTAIF
0
W
Reset:
1
0
PTAIE
PTAMOD
0
0
PTAACK
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 6-8. Port A Interrupt Status and Control Register (PTASC)
Table 6-6. PTASC Register Field Descriptions
Field
Description
3
PTAIF
Port A Interrupt Flag — PTAIF indicates when a port A interrupt is detected. Writes have no effect on PTAIF.
0 No port A interrupt detected.
1 Port A interrupt detected.
2
PTAACK
1
PTAIE
0
PTAMOD
Port A Interrupt Acknowledge — Writing a 1 to PTAACK is part of the flag clearing mechanism. PTAACK
always reads as 0.
Port A Interrupt Enable — PTAIE determines whether a port A interrupt is requested.
0 Port A interrupt request not enabled.
1 Port A interrupt request enabled.
Port A Detection Mode — PTAMOD (along with the PTAES bits) controls the detection mode of the port A
interrupt pins.
0 Port A pins detect edges only.
1 Port A pins detect both edges and levels.
MC9S08DZ60 Series Data Sheet, Rev. 4
92
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.1.7
Port A Interrupt Pin Select Register (PTAPS)
7
6
5
4
3
2
1
0
PTAPS7
PTAPS6
PTAPS5
PTAPS4
PTAPS3
PTAPS2
PTAPS1
PTAPS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-9. Port A Interrupt Pin Select Register (PTAPS)
Table 6-7. PTAPS Register Field Descriptions
Field
Description
7:0
Port A Interrupt Pin Selects — Each of the PTAPSn bits enable the corresponding port A interrupt pin.
PTAPS[7:0] 0 Pin not enabled as interrupt.
1 Pin enabled as interrupt.
6.5.1.8
Port A Interrupt Edge Select Register (PTAES)
7
6
5
4
3
2
1
0
PTAES7
PTAES6
PTAES5
PTAES4
PTAES3
PTAES2
PTAES1
PTAES0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-10. Port A Edge Select Register (PTAES)
Table 6-8. PTAES Register Field Descriptions
Field
Description
7:0
Port A Edge Selects — Each of the PTAESn bits serves a dual purpose by selecting the polarity of the active
PTAES[7:0] interrupt edge as well as selecting a pull-up or pull-down device if enabled.
0 A pull-up device is connected to the associated pin and detects falling edge/low level for interrupt generation.
1 A pull-down device is connected to the associated pin and detects rising edge/high level for interrupt
generation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
93
Chapter 6 Parallel Input/Output Control
6.5.2
Port B Registers
Port B is controlled by the registers listed below.
6.5.2.1
Port B Data Register (PTBD)
7
6
5
4
3
2
1
0
PTBD7
PTBD6
PTBD5
PTBD4
PTBD3
PTBD2
PTBD1
PTBD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-11. Port B Data Register (PTBD)
Table 6-9. PTBD Register Field Descriptions
Field
Description
7:0
PTBD[7:0]
Port B Data Register Bits — For port B pins that are inputs, reads return the logic level on the pin. For port B
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port B pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTBD to all 0s, but these 0s are not driven out the corresponding pins because reset also configures
all port pins as high-impedance inputs with pull-ups/pull-downs disabled.
6.5.2.2
Port B Data Direction Register (PTBDD)
7
6
5
4
3
2
1
0
PTBDD7
PTBDD6
PTBDD5
PTBDD4
PTBDD3
PTBDD2
PTBDD1
PTBDD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-12. Port B Data Direction Register (PTBDD)
Table 6-10. PTBDD Register Field Descriptions
Field
Description
7:0
Data Direction for Port B Bits — These read/write bits control the direction of port B pins and what is read for
PTBDD[7:0] PTBD reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port B bit n and PTBD reads return the contents of PTBDn.
MC9S08DZ60 Series Data Sheet, Rev. 4
94
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.2.3
Port B Pull Enable Register (PTBPE)
7
6
5
4
3
2
1
0
PTBPE7
PTBPE6
PTBPE5
PTBPE4
PTBPE3
PTBPE2
PTBPE1
PTBPE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-13. Internal Pull Enable for Port B Register (PTBPE)
Table 6-11. PTBPE Register Field Descriptions
Field
Description
7:0
Internal Pull Enable for Port B Bits — Each of these control bits determines if the internal pull-up or pull-down
PTBPE[7:0] device is enabled for the associated PTB pin. For port B pins that are configured as outputs, these bits have no
effect and the internal pull devices are disabled.
0 Internal pull-up/pull-down device disabled for port B bit n.
1 Internal pull-up/pull-down device enabled for port B bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.2.4
Port B Slew Rate Enable Register (PTBSE)
7
6
5
4
3
2
1
0
PTBSE7
PTBSE6
PTBSE5
PTBSE4
PTBSE3
PTBSE2
PTBSE1
PTBSE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-14. Slew Rate Enable for Port B Register (PTBSE)
Table 6-12. PTBSE Register Field Descriptions
Field
Description
7:0
Output Slew Rate Enable for Port B Bits — Each of these control bits determines if the output slew rate control
PTBSE[7:0] is enabled for the associated PTB pin. For port B pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port B bit n.
1 Output slew rate control enabled for port B bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
95
Chapter 6 Parallel Input/Output Control
6.5.2.5
Port B Drive Strength Selection Register (PTBDS)
7
6
5
4
3
2
1
0
PTBDS7
PTBDS6
PTBDS5
PTBDS4
PTBDS3
PTBDS2
PTBDS1
PTBDS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-15. Drive Strength Selection for Port B Register (PTBDS)
Table 6-13. PTBDS Register Field Descriptions
Field
Description
7:0
Output Drive Strength Selection for Port B Bits — Each of these control bits selects between low and high
PTBDS[7:0] output drive for the associated PTB pin. For port B pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port B bit n.
1 High output drive strength selected for port B bit n.
6.5.2.6
R
Port B Interrupt Status and Control Register (PTBSC)
7
6
5
4
3
2
0
0
0
0
PTBIF
0
W
Reset:
1
0
PTBIE
PTBMOD
0
0
PTBACK
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 6-16. Port B Interrupt Status and Control Register (PTBSC)
Table 6-14. PTBSC Register Field Descriptions
Field
Description
3
PTBIF
Port B Interrupt Flag — PTBIF indicates when a Port B interrupt is detected. Writes have no effect on PTBIF.
0 No Port B interrupt detected.
1 Port B interrupt detected.
2
PTBACK
1
PTBIE
0
PTBMOD
Port B Interrupt Acknowledge — Writing a 1 to PTBACK is part of the flag clearing mechanism. PTBACK
always reads as 0.
Port B Interrupt Enable — PTBIE determines whether a port B interrupt is requested.
0 Port B interrupt request not enabled.
1 Port B interrupt request enabled.
Port B Detection Mode — PTBMOD (along with the PTBES bits) controls the detection mode of the port B
interrupt pins.
0 Port B pins detect edges only.
1 Port B pins detect both edges and levels.
MC9S08DZ60 Series Data Sheet, Rev. 4
96
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.2.7
Port B Interrupt Pin Select Register (PTBPS)
7
6
5
4
3
2
1
0
PTBPS7
PTBPS6
PTBPS5
PTBPS4
PTBPS3
PTBPS2
PTBPS1
PTBPS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-17. Port B Interrupt Pin Select Register (PTBPS)
Table 6-15. PTBPS Register Field Descriptions
Field
Description
7:0
Port B Interrupt Pin Selects — Each of the PTBPSn bits enable the corresponding port B interrupt pin.
PTBPS[7:0] 0 Pin not enabled as interrupt.
1 Pin enabled as interrupt.
6.5.2.8
Port B Interrupt Edge Select Register (PTBES)
7
6
5
4
3
2
1
0
PTBES7
PTBES6
PTBES5
PTBES4
PTBES3
PTBES2
PTBES1
PTBES0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-18. Port B Edge Select Register (PTBES)
Table 6-16. PTBES Register Field Descriptions
Field
Description
7:0
Port B Edge Selects — Each of the PTBESn bits serves a dual purpose by selecting the polarity of the active
PTBES[7:0] interrupt edge as well as selecting a pull-up or pull-down device if enabled.
0 A pull-up device is connected to the associated pin and detects falling edge/low level for interrupt generation.
1 A pull-down device is connected to the associated pin and detects rising edge/high level for interrupt
generation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
97
Chapter 6 Parallel Input/Output Control
6.5.3
Port C Registers
Port C is controlled by the registers listed below.
6.5.3.1
Port C Data Register (PTCD)
7
6
5
4
3
2
1
0
PTCD7
PTCD6
PTCD5
PTCD4
PTCD3
PTCD2
PTCD1
PTCD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-19. Port C Data Register (PTCD)
Table 6-17. PTCD Register Field Descriptions
Field
Description
7:0
PTCD[7:0]
Port C Data Register Bits — For port C pins that are inputs, reads return the logic level on the pin. For port C
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port C pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTCD to all 0s, but these 0s are not driven out the corresponding pins because reset also
configures all port pins as high-impedance inputs with pull-ups disabled.
6.5.3.2
Port C Data Direction Register (PTCDD)
7
6
5
4
3
2
1
0
PTCDD7
PTCDD6
PTCDD5
PTCDD4
PTCDD3
PTCDD2
PTCDD1
PTCDD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-20. Port C Data Direction Register (PTCDD)
Table 6-18. PTCDD Register Field Descriptions
Field
Description
7:0
Data Direction for Port C Bits — These read/write bits control the direction of port C pins and what is read for
PTCDD[7:0] PTCD reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port C bit n and PTCD reads return the contents of PTCDn.
MC9S08DZ60 Series Data Sheet, Rev. 4
98
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.3.3
Port C Pull Enable Register (PTCPE)
7
6
5
4
3
2
1
0
PTCPE7
PTCPE6
PTCPE5
PTCPE4
PTCPE3
PTCPE2
PTCPE1
PTCPE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-21. Internal Pull Enable for Port C Register (PTCPE)
Table 6-19. PTCPE Register Field Descriptions
Field
Description
7:0
Internal Pull Enable for Port C Bits — Each of these control bits determines if the internal pull-up device is
PTCPE[7:0] enabled for the associated PTC pin. For port C pins that are configured as outputs, these bits have no effect and
the internal pull devices are disabled.
0 Internal pull-up device disabled for port C bit n.
1 Internal pull-up device enabled for port C bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.3.4
Port C Slew Rate Enable Register (PTCSE)
7
6
5
4
3
2
1
0
PTCSE7
PTCSE6
PTCSE5
PTCSE4
PTCSE3
PTCSE2
PTCSE1
PTCSE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-22. Slew Rate Enable for Port C Register (PTCSE)
Table 6-20. PTCSE Register Field Descriptions
Field
Description
7:0
Output Slew Rate Enable for Port C Bits — Each of these control bits determines if the output slew rate control
PTCSE[7:0] is enabled for the associated PTC pin. For port C pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port C bit n.
1 Output slew rate control enabled for port C bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
99
Chapter 6 Parallel Input/Output Control
6.5.3.5
Port C Drive Strength Selection Register (PTCDS)
7
6
5
4
3
2
1
0
PTCDS7
PTCDS6
PTCDS5
PTCDS4
PTCDS3
PTCDS2
PTCDS1
PTCDS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-23. Drive Strength Selection for Port C Register (PTCDS)
Table 6-21. PTCDS Register Field Descriptions
Field
Description
7:0
Output Drive Strength Selection for Port C Bits — Each of these control bits selects between low and high
PTCDS[7:0] output drive for the associated PTC pin. For port C pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port C bit n.
1 High output drive strength selected for port C bit n.
MC9S08DZ60 Series Data Sheet, Rev. 4
100
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.4
Port D Registers
Port D is controlled by the registers listed below.
6.5.4.1
Port D Data Register (PTDD)
7
6
5
4
3
2
1
0
PTDD7
PTDD6
PTDD5
PTDD4
PTDD3
PTDD2
PTDD1
PTDD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-24. Port D Data Register (PTDD)
Table 6-22. PTDD Register Field Descriptions
Field
Description
7:0
PTDD[7:0]
Port D Data Register Bits — For port D pins that are inputs, reads return the logic level on the pin. For port D
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port D pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTDD to all 0s, but these 0s are not driven out the corresponding pins because reset also
configures all port pins as high-impedance inputs with pull-ups/pull-downs disabled.
6.5.4.2
Port D Data Direction Register (PTDDD)
7
6
5
4
3
2
1
0
PTDDD7
PTDDD6
PTDDD5
PTDDD4
PTDDD3
PTDDD2
PTDDD1
PTDDD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-25. Port D Data Direction Register (PTDDD)
Table 6-23. PTDDD Register Field Descriptions
Field
Description
7:0
Data Direction for Port D Bits — These read/write bits control the direction of port D pins and what is read for
PTDDD[7:0] PTDD reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port D bit n and PTDD reads return the contents of PTDDn.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
101
Chapter 6 Parallel Input/Output Control
6.5.4.3
Port D Pull Enable Register (PTDPE)
7
6
5
4
3
2
1
0
PTDPE7
PTDPE6
PTDPE5
PTDPE4
PTDPE3
PTDPE2
PTDPE1
PTDPE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-26. Internal Pull Enable for Port D Register (PTDPE)
Table 6-24. PTDPE Register Field Descriptions
Field
Description
7:0
Internal Pull Enable for Port D Bits — Each of these control bits determines if the internal pull-up or pull-down
PTDPE[7:0] device is enabled for the associated PTD pin. For port D pins that are configured as outputs, these bits have no
effect and the internal pull devices are disabled.
0 Internal pull-up/pull-down device disabled for port D bit n.
1 Internal pull-up/pull-down device enabled for port D bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.4.4
Port D Slew Rate Enable Register (PTDSE)
7
6
5
4
3
2
1
0
PTDSE7
PTDSE6
PTDSE5
PTDSE4
PTDSE3
PTDSE2
PTDSE1
PTDSE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-27. Slew Rate Enable for Port D Register (PTDSE)
Table 6-25. PTDSE Register Field Descriptions
Field
Description
7:0
Output Slew Rate Enable for Port D Bits — Each of these control bits determines if the output slew rate control
PTDSE[7:0] is enabled for the associated PTD pin. For port D pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port D bit n.
1 Output slew rate control enabled for port D bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
102
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.4.5
Port D Drive Strength Selection Register (PTDDS)
7
6
5
4
3
2
1
0
PTDDS7
PTDDS6
PTDDS5
PTDDS4
PTDDS3
PTDDS2
PTDDS1
PTDDS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-28. Drive Strength Selection for Port D Register (PTDDS)
Table 6-26. PTDDS Register Field Descriptions
Field
Description
7:0
Output Drive Strength Selection for Port D Bits — Each of these control bits selects between low and high
PTDDS[7:0] output drive for the associated PTD pin. For port D pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port D bit n.
1 High output drive strength selected for port D bit n.
6.5.4.6
R
Port D Interrupt Status and Control Register (PTDSC)
7
6
5
4
3
2
0
0
0
0
PTDIF
0
W
Reset:
1
0
PTDIE
PTDMOD
0
0
PTDACK
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 6-29. Port D Interrupt Status and Control Register (PTDSC)
Table 6-27. PTDSC Register Field Descriptions
Field
Description
3
PTDIF
Port D Interrupt Flag — PTDIF indicates when a port D interrupt is detected. Writes have no effect on PTDIF.
0 No port D interrupt detected.
1 Port D interrupt detected.
2
PTDACK
1
PTDIE
0
PTDMOD
Port D Interrupt Acknowledge — Writing a 1 to PTDACK is part of the flag clearing mechanism. PTDACK
always reads as 0.
Port D Interrupt Enable — PTDIE determines whether a port D interrupt is requested.
0 Port D interrupt request not enabled.
1 Port D interrupt request enabled.
Port A Detection Mode — PTDMOD (along with the PTDES bits) controls the detection mode of the port D
interrupt pins.
0 Port D pins detect edges only.
1 Port D pins detect both edges and levels.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
103
Chapter 6 Parallel Input/Output Control
6.5.4.7
Port D Interrupt Pin Select Register (PTDPS)
7
6
5
4
3
2
1
0
PTDPS7
PTDPS6
PTDPS5
PTDPS4
PTDPS3
PTDPS2
PTDPS1
PTDPS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-30. Port D Interrupt Pin Select Register (PTDPS)
Table 6-28. PTDPS Register Field Descriptions
Field
Description
7:0
Port D Interrupt Pin Selects — Each of the PTDPSn bits enable the corresponding port D interrupt pin.
PTDPS[7:0] 0 Pin not enabled as interrupt.
1 Pin enabled as interrupt.
6.5.4.8
Port D Interrupt Edge Select Register (PTDES)
7
6
5
4
3
2
1
0
PTDES7
PTDES6
PTDES5
PTDES4
PTDES3
PTDES2
PTDES1
PTDES0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-31. Port D Edge Select Register (PTDES)
Table 6-29. PTDES Register Field Descriptions
Field
Description
7:0
Port D Edge Selects — Each of the PTDESn bits serves a dual purpose by selecting the polarity of the active
PTDES[7:0] interrupt edge as well as selecting a pull-up or pull-down device if enabled.
0 A pull-up device is connected to the associated pin and detects falling edge/low level for interrupt generation.
1 A pull-down device is connected to the associated pin and detects rising edge/high level for interrupt
generation.
MC9S08DZ60 Series Data Sheet, Rev. 4
104
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.5
Port E Registers
Port E is controlled by the registers listed below.
6.5.5.1
Port E Data Register (PTED)
7
6
5
4
3
2
1
0
PTED7
PTED6
PTED5
PTED4
PTED3
PTED2
PTED11
PTED0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-32. Port E Data Register (PTED)
1
Reads of this bit always return the pin value of the associated pin, regardless of the value stored in the port data direction bit.
Table 6-30. PTED Register Field Descriptions
Field
Description
7:0
PTED[7:0]
Port E Data Register Bits — For port E pins that are inputs, reads return the logic level on the pin. For port E
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port E pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTED to all 0s, but these 0s are not driven out the corresponding pins because reset also configures
all port pins as high-impedance inputs with pull-ups disabled.
6.5.5.2
Port E Data Direction Register (PTEDD)
7
6
5
4
3
2
1
0
PTEDD7
PTEDD6
PTEDD5
PTEDD4
PTEDD3
PTEDD2
PTEDD11
PTEDD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-33. Port E Data Direction Register (PTEDD)
1
PTEDD1 has no effect on the input-only PTE1 pin.
Table 6-31. PTEDD Register Field Descriptions
Field
Description
7:0
Data Direction for Port E Bits — These read/write bits control the direction of port E pins and what is read for
PTEDD[7:0] PTED reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port E bit n and PTED reads return the contents of PTEDn.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
105
Chapter 6 Parallel Input/Output Control
6.5.5.3
Port E Pull Enable Register (PTEPE)
7
6
5
4
3
2
1
0
PTEPE7
PTEPE6
PTEPE5
PTEPE4
PTEPE3
PTEPE2
PTEPE1
PTEPE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-34. Internal Pull Enable for Port E Register (PTEPE)
Table 6-32. PTEPE Register Field Descriptions
Field
Description
7:0
Internal Pull Enable for Port E Bits — Each of these control bits determines if the internal pull-up device is
PTEPE[7:0] enabled for the associated PTE pin. For port E pins that are configured as outputs, these bits have no effect and
the internal pull devices are disabled.
0 Internal pull-up device disabled for port E bit n.
1 Internal pull-up device enabled for port E bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.5.4
Port E Slew Rate Enable Register (PTESE)
7
6
5
4
3
2
1
0
PTESE7
PTESE6
PTESE5
PTESE4
PTESE3
PTESE2
PTESE11
PTESE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-35. Slew Rate Enable for Port E Register (PTESE)
1
PTESE1 has no effect on the input-only PTE1 pin.
Table 6-33. PTESE Register Field Descriptions
Field
Description
7:0
Output Slew Rate Enable for Port E Bits — Each of these control bits determines if the output slew rate control
PTESE[7:0] is enabled for the associated PTE pin. For port E pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port E bit n.
1 Output slew rate control enabled for port E bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
106
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.5.5
Port E Drive Strength Selection Register (PTEDS)
7
6
5
4
3
2
1
0
PTEDS7
PTEDS6
PTEDS5
PTEDS4
PTEDS3
PTEDS2
PTEDS11
PTEDS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-36. Drive Strength Selection for Port E Register (PTEDS)
1
PTEDS1 has no effect on the input-only PTE1 pin.
Table 6-34. PTEDS Register Field Descriptions
Field
Description
7:0
Output Drive Strength Selection for Port E Bits — Each of these control bits selects between low and high
PTEDS[7:0] output drive for the associated PTE pin. For port E pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port E bit n.
1 High output drive strength selected for port E bit n.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
107
Chapter 6 Parallel Input/Output Control
6.5.6
Port F Registers
Port F is controlled by the registers listed below.
6.5.6.1
Port F Data Register (PTFD)
7
6
5
4
3
2
1
0
PTFD7
PTFD6
PTFD5
PTFD4
PTFD3
PTFD2
PTFD1
PTFD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-37. Port F Data Register (PTFD)
Table 6-35. PTFD Register Field Descriptions
Field
Description
7:0
PTFD[7:0]
Port F Data Register Bits — For port F pins that are inputs, reads return the logic level on the pin. For port F
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port F pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTFD to all 0s, but these 0s are not driven out the corresponding pins because reset also configures
all port pins as high-impedance inputs with pull-ups disabled.
6.5.6.2
Port F Data Direction Register (PTFDD)
7
6
5
4
3
2
1
0
PTFDD7
PTFDD6
PTFDD5
PTFDD4
PTFDD3
PTFDD2
PTFDD1
PTFDD0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-38. Port F Data Direction Register (PTFDD)
Table 6-36. PTFDD Register Field Descriptions
Field
Description
7:0
Data Direction for Port F Bits — These read/write bits control the direction of port F pins and what is read for
PTFDD[7:0] PTFD reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port F bit n and PTFD reads return the contents of PTFDn.
MC9S08DZ60 Series Data Sheet, Rev. 4
108
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.6.3
Port F Pull Enable Register (PTFPE)
7
6
5
4
3
2
1
0
PTFPE7
PTFPE6
PTFPE5
PTFPE4
PTFPE3
PTFPE2
PTFPE1
PTFPE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-39. Internal Pull Enable for Port F Register (PTFPE)
Table 6-37. PTFPE Register Field Descriptions
Field
Description
7:0
Internal Pull Enable for Port F Bits — Each of these control bits determines if the internal pull-up device is
PTFPE[7:0] enabled for the associated PTF pin. For port F pins that are configured as outputs, these bits have no effect and
the internal pull devices are disabled.
0 Internal pull-up device disabled for port F bit n.
1 Internal pull-up device enabled for port F bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.6.4
Port F Slew Rate Enable Register (PTFSE)
7
6
5
4
3
2
1
0
PTFSE7
PTFSE6
PTFSE5
PTFSE4
PTFSE3
PTFSE2
PTFSE1
PTFSE0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-40. Slew Rate Enable for Port F Register (PTFSE)
Table 6-38. PTFSE Register Field Descriptions
Field
Description
7:0
Output Slew Rate Enable for Port F Bits — Each of these control bits determines if the output slew rate control
PTFSE[7:0] is enabled for the associated PTF pin. For port F pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port F bit n.
1 Output slew rate control enabled for port F bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
109
Chapter 6 Parallel Input/Output Control
6.5.6.5
Port F Drive Strength Selection Register (PTFDS)
7
6
5
4
3
2
1
0
PTFDS7
PTFDS6
PTFDS5
PTFDS4
PTFDS3
PTFDS2
PTFDS1
PTFDS0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 6-41. Drive Strength Selection for Port F Register (PTFDS)
Table 6-39. PTFDS Register Field Descriptions
Field
Description
7:0
Output Drive Strength Selection for Port F Bits — Each of these control bits selects between low and high
PTFDS[7:0] output drive for the associated PTF pin. For port F pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port F bit n.
1 High output drive strength selected for port F bit n.
MC9S08DZ60 Series Data Sheet, Rev. 4
110
Freescale Semiconductor
Chapter 6 Parallel Input/Output Control
6.5.7
Port G Registers
Port G is controlled by the registers listed below.
6.5.7.1
R
Port G Data Register (PTGD)
7
6
0
0
5
4
3
2
1
0
PTGD5
PTGD4
PTGD3
PTGD2
PTGD1
PTGD0
0
0
0
0
0
0
W
Reset:
0
0
= Unimplemented or Reserved
Figure 6-42. Port G Data Register (PTGD)
Table 6-40. PTGD Register Field Descriptions
Field
Description
5:0
PTGD[5:0]
Port G Data Register Bits — For port G pins that are inputs, reads return the logic level on the pin. For port G
pins that are configured as outputs, reads return the last value written to this register.
Writes are latched into all bits of this register. For port G pins that are configured as outputs, the logic level is
driven out the corresponding MCU pin.
Reset forces PTGD to all 0s, but these 0s are not driven out the corresponding pins because reset also
configures all port pins as high-impedance inputs with pull-ups disabled.
6.5.7.2
R
Port G Data Direction Register (PTGDD)
7
6
0
0
5
4
3
2
1
0
PTGDD5
PTGDD4
PTGDD3
PTGDD2
PTGDD1
PTGDD0
0
0
0
0
0
0
W
Reset:
0
0
= Unimplemented or Reserved
Figure 6-43. Port G Data Direction Register (PTGDD)
Table 6-41. PTGDD Register Field Descriptions
Field
Description
5:0
Data Direction for Port G Bits — These read/write bits control the direction of port G pins and what is read for
PTGDD[5:0] PTGD reads.
0 Input (output driver disabled) and reads return the pin value.
1 Output driver enabled for port G bit n and PTGD reads return the contents of PTGDn.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
111
Chapter 6 Parallel Input/Output Control
6.5.7.3
R
Port G Pull Enable Register (PTGPE)
7
6
0
0
5
4
3
2
1
0
PTGPE5
PTGPE4
PTGPE3
PTGPE2
PTGPE1
PTGPE0
0
0
0
0
0
0
W
Reset:
0
0
= Unimplemented or Reserved
Figure 6-44. Internal Pull Enable for Port G Register (PTGPE)
Table 6-42. PTGPE Register Field Descriptions
Field
Description
5:0
Internal Pull Enable for Port G Bits — Each of these control bits determines if the internal pull-up device is
PTGPE[5:0] enabled for the associated PTG pin. For port G pins that are configured as outputs, these bits have no effect and
the internal pull devices are disabled.
0 Internal pull-up device disabled for port G bit n.
1 Internal pull-up device enabled for port G bit n.
NOTE
Pull-down devices only apply when using pin interrupt functions, when
corresponding edge select and pin select functions are configured.
6.5.7.4
R
Port G Slew Rate Enable Register (PTGSE)
7
6
0
0
5
4
3
2
1
0
PTGSE5
PTGSE4
PTGSE3
PTGSE2
PTGSE1
PTGSE0
0
0
0
0
0
0
W
Reset:
0
0
= Unimplemented or Reserved
Figure 6-45. Slew Rate Enable for Port G Register (PTGSE)
Table 6-43. PTGSE Register Field Descriptions
Field
Description
5:0
Output Slew Rate Enable for Port G Bits — Each of these control bits determines if the output slew rate control
PTGSE[5:0] is enabled for the associated PTG pin. For port G pins that are configured as inputs, these bits have no effect.
0 Output slew rate control disabled for port G bit n.
1 Output slew rate control enabled for port G bit n.
Note: Slew rate reset default values may differ between engineering samples and final production parts. Always initialize slew
rate control to the desired value to ensure correct operation.
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Chapter 6 Parallel Input/Output Control
6.5.7.5
R
Port G Drive Strength Selection Register (PTGDS)
7
6
0
0
5
4
3
2
1
0
PTGDS5
PTGDS4
PTGDS3
PTGDS2
PTGDS1
PTGDS0
0
0
0
0
0
0
W
Reset:
0
0
= Unimplemented or Reserved
Figure 6-46. Drive Strength Selection for Port G Register (PTGDS)
Table 6-44. PTGDS Register Field Descriptions
Field
Description
5:0
Output Drive Strength Selection for Port G Bits — Each of these control bits selects between low and high
PTGDS[5:0 output drive for the associated PTG pin. For port G pins that are configured as inputs, these bits have no effect.
0 Low output drive strength selected for port G bit n.
1 High output drive strength selected for port G bit n.
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Chapter 7
Central Processor Unit (S08CPUV3)
7.1
Introduction
This section provides summary information about the registers, addressing modes, and instruction set of
the CPU of the HCS08 Family. For a more detailed discussion, refer to the HCS08 Family Reference
Manual, volume 1, Freescale Semiconductor document order number HCS08RMV1/D.
The HCS08 CPU is fully source- and object-code-compatible with the M68HC08 CPU. Several
instructions and enhanced addressing modes were added to improve C compiler efficiency and to support
a new background debug system which replaces the monitor mode of earlier M68HC08 microcontrollers
(MCU).
7.1.1
Features
Features of the HCS08 CPU include:
• Object code fully upward-compatible with M68HC05 and M68HC08 Families
• All registers and memory are mapped to a single 64-Kbyte address space
• 16-bit stack pointer (any size stack anywhere in 64-Kbyte address space)
• 16-bit index register (H:X) with powerful indexed addressing modes
• 8-bit accumulator (A)
• Many instructions treat X as a second general-purpose 8-bit register
• Seven addressing modes:
— Inherent — Operands in internal registers
— Relative — 8-bit signed offset to branch destination
— Immediate — Operand in next object code byte(s)
— Direct — Operand in memory at 0x0000–0x00FF
— Extended — Operand anywhere in 64-Kbyte address space
— Indexed relative to H:X — Five submodes including auto increment
— Indexed relative to SP — Improves C efficiency dramatically
• Memory-to-memory data move instructions with four address mode combinations
• Overflow, half-carry, negative, zero, and carry condition codes support conditional branching on
the results of signed, unsigned, and binary-coded decimal (BCD) operations
• Efficient bit manipulation instructions
• Fast 8-bit by 8-bit multiply and 16-bit by 8-bit divide instructions
• STOP and WAIT instructions to invoke low-power operating modes
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7.2
Programmer’s Model and CPU Registers
Figure 7-1 shows the five CPU registers. CPU registers are not part of the memory map.
7
0
ACCUMULATOR
A
16-BIT INDEX REGISTER H:X
H INDEX REGISTER (HIGH)
8
15
INDEX REGISTER (LOW)
7
X
0
SP
STACK POINTER
0
15
PROGRAM COUNTER
7
0
CONDITION CODE REGISTER V 1 1 H I N Z C
PC
CCR
CARRY
ZERO
NEGATIVE
INTERRUPT MASK
HALF-CARRY (FROM BIT 3)
TWO’S COMPLEMENT OVERFLOW
Figure 7-1. CPU Registers
7.2.1
Accumulator (A)
The A accumulator is a general-purpose 8-bit register. One operand input to the arithmetic logic unit
(ALU) is connected to the accumulator and the ALU results are often stored into the A accumulator after
arithmetic and logical operations. The accumulator can be loaded from memory using various addressing
modes to specify the address where the loaded data comes from, or the contents of A can be stored to
memory using various addressing modes to specify the address where data from A will be stored.
Reset has no effect on the contents of the A accumulator.
7.2.2
Index Register (H:X)
This 16-bit register is actually two separate 8-bit registers (H and X), which often work together as a 16-bit
address pointer where H holds the upper byte of an address and X holds the lower byte of the address. All
indexed addressing mode instructions use the full 16-bit value in H:X as an index reference pointer;
however, for compatibility with the earlier M68HC05 Family, some instructions operate only on the
low-order 8-bit half (X).
Many instructions treat X as a second general-purpose 8-bit register that can be used to hold 8-bit data
values. X can be cleared, incremented, decremented, complemented, negated, shifted, or rotated. Transfer
instructions allow data to be transferred from A or transferred to A where arithmetic and logical operations
can then be performed.
For compatibility with the earlier M68HC05 Family, H is forced to 0x00 during reset. Reset has no effect
on the contents of X.
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7.2.3
Stack Pointer (SP)
This 16-bit address pointer register points at the next available location on the automatic last-in-first-out
(LIFO) stack. The stack may be located anywhere in the 64-Kbyte address space that has RAM and can
be any size up to the amount of available RAM. The stack is used to automatically save the return address
for subroutine calls, the return address and CPU registers during interrupts, and for local variables. The
AIS (add immediate to stack pointer) instruction adds an 8-bit signed immediate value to SP. This is most
often used to allocate or deallocate space for local variables on the stack.
SP is forced to 0x00FF at reset for compatibility with the earlier M68HC05 Family. HCS08 programs
normally change the value in SP to the address of the last location (highest address) in on-chip RAM
during reset initialization to free up direct page RAM (from the end of the on-chip registers to 0x00FF).
The RSP (reset stack pointer) instruction was included for compatibility with the M68HC05 Family and
is seldom used in new HCS08 programs because it only affects the low-order half of the stack pointer.
7.2.4
Program Counter (PC)
The program counter is a 16-bit register that contains the address of the next instruction or operand to be
fetched.
During normal program execution, the program counter automatically increments to the next sequential
memory location every time an instruction or operand is fetched. Jump, branch, interrupt, and return
operations load the program counter with an address other than that of the next sequential location. This
is called a change-of-flow.
During reset, the program counter is loaded with the reset vector that is located at 0xFFFE and 0xFFFF.
The vector stored there is the address of the first instruction that will be executed after exiting the reset
state.
7.2.5
Condition Code Register (CCR)
The 8-bit condition code register contains the interrupt mask (I) and five flags that indicate the results of
the instruction just executed. Bits 6 and 5 are set permanently to 1. The following paragraphs describe the
functions of the condition code bits in general terms. For a more detailed explanation of how each
instruction sets the CCR bits, refer to the HCS08 Family Reference Manual, volume 1, Freescale
Semiconductor document order number HCS08RMv1.
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7
0
CONDITION CODE REGISTER V 1 1 H I N Z C
CCR
CARRY
ZERO
NEGATIVE
INTERRUPT MASK
HALF-CARRY (FROM BIT 3)
TWO’S COMPLEMENT OVERFLOW
Figure 7-2. Condition Code Register
Table 7-1. CCR Register Field Descriptions
Field
Description
7
V
Two’s Complement Overflow Flag — The CPU sets the overflow flag when a two’s complement overflow occurs.
The signed branch instructions BGT, BGE, BLE, and BLT use the overflow flag.
0 No overflow
1 Overflow
4
H
Half-Carry Flag — The CPU sets the half-carry flag when a carry occurs between accumulator bits 3 and 4 during
an add-without-carry (ADD) or add-with-carry (ADC) operation. The half-carry flag is required for binary-coded
decimal (BCD) arithmetic operations. The DAA instruction uses the states of the H and C condition code bits to
automatically add a correction value to the result from a previous ADD or ADC on BCD operands to correct the
result to a valid BCD value.
0 No carry between bits 3 and 4
1 Carry between bits 3 and 4
3
I
Interrupt Mask Bit — When the interrupt mask is set, all maskable CPU interrupts are disabled. CPU interrupts
are enabled when the interrupt mask is cleared. When a CPU interrupt occurs, the interrupt mask is set
automatically after the CPU registers are saved on the stack, but before the first instruction of the interrupt service
routine is executed.
Interrupts are not recognized at the instruction boundary after any instruction that clears I (CLI or TAP). This
ensures that the next instruction after a CLI or TAP will always be executed without the possibility of an intervening
interrupt, provided I was set.
0 Interrupts enabled
1 Interrupts disabled
2
N
Negative Flag — The CPU sets the negative flag when an arithmetic operation, logic operation, or data
manipulation produces a negative result, setting bit 7 of the result. Simply loading or storing an 8-bit or 16-bit value
causes N to be set if the most significant bit of the loaded or stored value was 1.
0 Non-negative result
1 Negative result
1
Z
Zero Flag — The CPU sets the zero flag when an arithmetic operation, logic operation, or data manipulation
produces a result of 0x00 or 0x0000. Simply loading or storing an 8-bit or 16-bit value causes Z to be set if the
loaded or stored value was all 0s.
0 Non-zero result
1 Zero result
0
C
Carry/Borrow Flag — The CPU sets the carry/borrow flag when an addition operation produces a carry out of bit
7 of the accumulator or when a subtraction operation requires a borrow. Some instructions — such as bit test and
branch, shift, and rotate — also clear or set the carry/borrow flag.
0 No carry out of bit 7
1 Carry out of bit 7
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7.3
Addressing Modes
Addressing modes define the way the CPU accesses operands and data. In the HCS08, all memory, status
and control registers, and input/output (I/O) ports share a single 64-Kbyte linear address space so a 16-bit
binary address can uniquely identify any memory location. This arrangement means that the same
instructions that access variables in RAM can also be used to access I/O and control registers or nonvolatile
program space.
Some instructions use more than one addressing mode. For instance, move instructions use one addressing
mode to specify the source operand and a second addressing mode to specify the destination address.
Instructions such as BRCLR, BRSET, CBEQ, and DBNZ use one addressing mode to specify the location
of an operand for a test and then use relative addressing mode to specify the branch destination address
when the tested condition is true. For BRCLR, BRSET, CBEQ, and DBNZ, the addressing mode listed in
the instruction set tables is the addressing mode needed to access the operand to be tested, and relative
addressing mode is implied for the branch destination.
7.3.1
Inherent Addressing Mode (INH)
In this addressing mode, operands needed to complete the instruction (if any) are located within CPU
registers so the CPU does not need to access memory to get any operands.
7.3.2
Relative Addressing Mode (REL)
Relative addressing mode is used to specify the destination location for branch instructions. A signed 8-bit
offset value is located in the memory location immediately following the opcode. During execution, if the
branch condition is true, the signed offset is sign-extended to a 16-bit value and is added to the current
contents of the program counter, which causes program execution to continue at the branch destination
address.
7.3.3
Immediate Addressing Mode (IMM)
In immediate addressing mode, the operand needed to complete the instruction is included in the object
code immediately following the instruction opcode in memory. In the case of a 16-bit immediate operand,
the high-order byte is located in the next memory location after the opcode, and the low-order byte is
located in the next memory location after that.
7.3.4
Direct Addressing Mode (DIR)
In direct addressing mode, the instruction includes the low-order eight bits of an address in the direct page
(0x0000–0x00FF). During execution a 16-bit address is formed by concatenating an implied 0x00 for the
high-order half of the address and the direct address from the instruction to get the 16-bit address where
the desired operand is located. This is faster and more memory efficient than specifying a complete 16-bit
address for the operand.
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7.3.5
Extended Addressing Mode (EXT)
In extended addressing mode, the full 16-bit address of the operand is located in the next two bytes of
program memory after the opcode (high byte first).
7.3.6
Indexed Addressing Mode
Indexed addressing mode has seven variations including five that use the 16-bit H:X index register pair and
two that use the stack pointer as the base reference.
7.3.6.1
Indexed, No Offset (IX)
This variation of indexed addressing uses the 16-bit value in the H:X index register pair as the address of
the operand needed to complete the instruction.
7.3.6.2
Indexed, No Offset with Post Increment (IX+)
This variation of indexed addressing uses the 16-bit value in the H:X index register pair as the address of
the operand needed to complete the instruction. The index register pair is then incremented
(H:X = H:X + 0x0001) after the operand has been fetched. This addressing mode is only used for MOV
and CBEQ instructions.
7.3.6.3
Indexed, 8-Bit Offset (IX1)
This variation of indexed addressing uses the 16-bit value in the H:X index register pair plus an unsigned
8-bit offset included in the instruction as the address of the operand needed to complete the instruction.
7.3.6.4
Indexed, 8-Bit Offset with Post Increment (IX1+)
This variation of indexed addressing uses the 16-bit value in the H:X index register pair plus an unsigned
8-bit offset included in the instruction as the address of the operand needed to complete the instruction.
The index register pair is then incremented (H:X = H:X + 0x0001) after the operand has been fetched. This
addressing mode is used only for the CBEQ instruction.
7.3.6.5
Indexed, 16-Bit Offset (IX2)
This variation of indexed addressing uses the 16-bit value in the H:X index register pair plus a 16-bit offset
included in the instruction as the address of the operand needed to complete the instruction.
7.3.6.6
SP-Relative, 8-Bit Offset (SP1)
This variation of indexed addressing uses the 16-bit value in the stack pointer (SP) plus an unsigned 8-bit
offset included in the instruction as the address of the operand needed to complete the instruction.
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7.3.6.7
SP-Relative, 16-Bit Offset (SP2)
This variation of indexed addressing uses the 16-bit value in the stack pointer (SP) plus a 16-bit offset
included in the instruction as the address of the operand needed to complete the instruction.
7.4
Special Operations
The CPU performs a few special operations that are similar to instructions but do not have opcodes like
other CPU instructions. In addition, a few instructions such as STOP and WAIT directly affect other MCU
circuitry. This section provides additional information about these operations.
7.4.1
Reset Sequence
Reset can be caused by a power-on-reset (POR) event, internal conditions such as the COP (computer
operating properly) watchdog, or by assertion of an external active-low reset pin. When a reset event
occurs, the CPU immediately stops whatever it is doing (the MCU does not wait for an instruction
boundary before responding to a reset event). For a more detailed discussion about how the MCU
recognizes resets and determines the source, refer to the Resets, Interrupts, and System Configuration
chapter.
The reset event is considered concluded when the sequence to determine whether the reset came from an
internal source is done and when the reset pin is no longer asserted. At the conclusion of a reset event, the
CPU performs a 6-cycle sequence to fetch the reset vector from 0xFFFE and 0xFFFF and to fill the
instruction queue in preparation for execution of the first program instruction.
7.4.2
Interrupt Sequence
When an interrupt is requested, the CPU completes the current instruction before responding to the
interrupt. At this point, the program counter is pointing at the start of the next instruction, which is where
the CPU should return after servicing the interrupt. The CPU responds to an interrupt by performing the
same sequence of operations as for a software interrupt (SWI) instruction, except the address used for the
vector fetch is determined by the highest priority interrupt that is pending when the interrupt sequence
started.
The CPU sequence for an interrupt is:
1. Store the contents of PCL, PCH, X, A, and CCR on the stack, in that order.
2. Set the I bit in the CCR.
3. Fetch the high-order half of the interrupt vector.
4. Fetch the low-order half of the interrupt vector.
5. Delay for one free bus cycle.
6. Fetch three bytes of program information starting at the address indicated by the interrupt vector
to fill the instruction queue in preparation for execution of the first instruction in the interrupt
service routine.
After the CCR contents are pushed onto the stack, the I bit in the CCR is set to prevent other interrupts
while in the interrupt service routine. Although it is possible to clear the I bit with an instruction in the
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interrupt service routine, this would allow nesting of interrupts (which is not recommended because it
leads to programs that are difficult to debug and maintain).
For compatibility with the earlier M68HC05 MCUs, the high-order half of the H:X index register pair (H)
is not saved on the stack as part of the interrupt sequence. The user must use a PSHH instruction at the
beginning of the service routine to save H and then use a PULH instruction just before the RTI that ends
the interrupt service routine. It is not necessary to save H if you are certain that the interrupt service routine
does not use any instructions or auto-increment addressing modes that might change the value of H.
The software interrupt (SWI) instruction is like a hardware interrupt except that it is not masked by the
global I bit in the CCR and it is associated with an instruction opcode within the program so it is not
asynchronous to program execution.
7.4.3
Wait Mode Operation
The WAIT instruction enables interrupts by clearing the I bit in the CCR. It then halts the clocks to the
CPU to reduce overall power consumption while the CPU is waiting for the interrupt or reset event that
will wake the CPU from wait mode. When an interrupt or reset event occurs, the CPU clocks will resume
and the interrupt or reset event will be processed normally.
If a serial BACKGROUND command is issued to the MCU through the background debug interface while
the CPU is in wait mode, CPU clocks will resume and the CPU will enter active background mode where
other serial background commands can be processed. This ensures that a host development system can still
gain access to a target MCU even if it is in wait mode.
7.4.4
Stop Mode Operation
Usually, all system clocks, including the crystal oscillator (when used), are halted during stop mode to
minimize power consumption. In such systems, external circuitry is needed to control the time spent in
stop mode and to issue a signal to wake up the target MCU when it is time to resume processing. Unlike
the earlier M68HC05 and M68HC08 MCUs, the HCS08 can be configured to keep a minimum set of
clocks running in stop mode. This optionally allows an internal periodic signal to wake the target MCU
from stop mode.
When a host debug system is connected to the background debug pin (BKGD) and the ENBDM control
bit has been set by a serial command through the background interface (or because the MCU was reset into
active background mode), the oscillator is forced to remain active when the MCU enters stop mode. In this
case, if a serial BACKGROUND command is issued to the MCU through the background debug interface
while the CPU is in stop mode, CPU clocks will resume and the CPU will enter active background mode
where other serial background commands can be processed. This ensures that a host development system
can still gain access to a target MCU even if it is in stop mode.
Recovery from stop mode depends on the particular HCS08 and whether the oscillator was stopped in stop
mode. Refer to the Modes of Operation chapter for more details.
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7.4.5
BGND Instruction
The BGND instruction is new to the HCS08 compared to the M68HC08. BGND would not be used in
normal user programs because it forces the CPU to stop processing user instructions and enter the active
background mode. The only way to resume execution of the user program is through reset or by a host
debug system issuing a GO, TRACE1, or TAGGO serial command through the background debug
interface.
Software-based breakpoints can be set by replacing an opcode at the desired breakpoint address with the
BGND opcode. When the program reaches this breakpoint address, the CPU is forced to active background
mode rather than continuing the user program.
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7.5
HCS08 Instruction Set Summary
Table 7-2 provides a summary of the HCS08 instruction set in all possible addressing modes. The table
shows operand construction, execution time in internal bus clock cycles, and cycle-by-cycle details for
each addressing mode variation of each instruction.
ADC
ADC
ADC
ADC
ADC
ADC
ADC
ADC
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
ADD
ADD
ADD
ADD
ADD
ADD
ADD
ADD
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
Operation
Add with Carry
A ← (A) + (M) + (C)
Add without Carry
A ← (A) + (M)
Object Code
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A9
B9
C9
D9
E9
F9
9E D9
9E E9
ii
dd
hh ll
ee ff
ff
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
AB
BB
CB
DB
EB
FB
9E DB
9E EB
ii
dd
hh ll
ee ff
ff
ee ff
ff
ee ff
ff
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 1 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
↕ 1 1 ↕ – ↕ ↕ ↕
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
↕ 1 1 ↕ – ↕ ↕ ↕
AIS #opr8i
Add Immediate Value (Signed) to
Stack Pointer
SP ← (SP) + (M)
IMM
A7 ii
2
pp
– 1 1 – – – – –
AIX #opr8i
Add Immediate Value (Signed) to
Index Register (H:X)
H:X ← (H:X) + (M)
IMM
AF ii
2
pp
– 1 1 – – – – –
Logical AND
A ← (A) & (M)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A4
B4
C4
D4
E4
F4
9E D4
9E E4
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
0 1 1 – – ↕ ↕ –
DIR
INH
INH
IX1
IX
SP1
38 dd
48
58
68 ff
78
9E 68 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ ↕
DIR
INH
INH
IX1
IX
SP1
37 dd
47
57
67 ff
77
9E 67 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ ↕
AND
AND
AND
AND
AND
AND
AND
AND
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
ASL opr8a
ASLA
ASLX
ASL oprx8,X
ASL ,X
ASL oprx8,SP
ASR opr8a
ASRA
ASRX
ASR oprx8,X
ASR ,X
ASR oprx8,SP
Arithmetic Shift Left
C
0
b7
b0
(Same as LSL)
Arithmetic Shift Right
C
b7
b0
ii
dd
hh ll
ee ff
ff
ee ff
ff
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Operation
Object Code
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 2 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
Branch if Carry Bit Clear
(if C = 0)
REL
24 rr
3
ppp
– 1 1 – – – – –
BCLR n,opr8a
Clear Bit n in Memory
(Mn ← 0)
DIR (b0)
DIR (b1)
DIR (b2)
DIR (b3)
DIR (b4)
DIR (b5)
DIR (b6)
DIR (b7)
11
13
15
17
19
1B
1D
1F
dd
dd
dd
dd
dd
dd
dd
dd
5
5
5
5
5
5
5
5
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
– 1 1 – – – – –
BCS rel
Branch if Carry Bit Set (if C = 1)
(Same as BLO)
REL
25 rr
3
ppp
– 1 1 – – – – –
BEQ rel
Branch if Equal (if Z = 1)
REL
27 rr
3
ppp
– 1 1 – – – – –
BGE rel
Branch if Greater Than or Equal To
(if N ⊕ V = 0) (Signed)
REL
90 rr
3
ppp
– 1 1 – – – – –
BGND
Enter active background if ENBDM=1
Waits for and processes BDM commands
until GO, TRACE1, or TAGGO
INH
82
5+
fp...ppp
– 1 1 – – – – –
BGT rel
Branch if Greater Than (if Z | (N ⊕ V) = 0)
(Signed)
REL
92 rr
3
ppp
– 1 1 – – – – –
BHCC rel
Branch if Half Carry Bit Clear (if H = 0)
REL
28 rr
3
ppp
– 1 1 – – – – –
BHCS rel
Branch if Half Carry Bit Set (if H = 1)
REL
29 rr
3
ppp
– 1 1 – – – – –
BHI rel
Branch if Higher (if C | Z = 0)
REL
22 rr
3
ppp
– 1 1 – – – – –
BHS rel
Branch if Higher or Same (if C = 0)
(Same as BCC)
REL
24 rr
3
ppp
– 1 1 – – – – –
BIH rel
Branch if IRQ Pin High (if IRQ pin = 1)
REL
2F rr
3
ppp
– 1 1 – – – – –
BIL rel
Branch if IRQ Pin Low (if IRQ pin = 0)
REL
2E rr
3
ppp
– 1 1 – – – – –
Bit Test
(A) & (M)
(CCR Updated but Operands Not Changed)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
0 1 1 – – ↕ ↕ –
BCC rel
BIT
BIT
BIT
BIT
BIT
BIT
BIT
BIT
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
A5
B5
C5
D5
E5
F5
9E D5
9E E5
ii
dd
hh ll
ee ff
ff
ee ff
ff
BLE rel
Branch if Less Than or Equal To
(if Z | (N ⊕ V) = 1) (Signed)
REL
93 rr
3
ppp
– 1 1 – – – – –
BLO rel
Branch if Lower (if C = 1) (Same as BCS)
REL
25 rr
3
ppp
– 1 1 – – – – –
BLS rel
Branch if Lower or Same (if C | Z = 1)
REL
23 rr
3
ppp
– 1 1 – – – – –
BLT rel
Branch if Less Than (if N ⊕ V = 1) (Signed)
REL
91 rr
3
ppp
– 1 1 – – – – –
BMC rel
Branch if Interrupt Mask Clear (if I = 0)
REL
2C rr
3
ppp
– 1 1 – – – – –
BMI rel
Branch if Minus (if N = 1)
REL
2B rr
3
ppp
– 1 1 – – – – –
BMS rel
Branch if Interrupt Mask Set (if I = 1)
REL
2D rr
3
ppp
– 1 1 – – – – –
BNE rel
Branch if Not Equal (if Z = 0)
REL
26 rr
3
ppp
– 1 1 – – – – –
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
125
Chapter 7 Central Processor Unit (S08CPUV3)
Operation
Object Code
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 3 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
BPL rel
Branch if Plus (if N = 0)
REL
2A rr
3
ppp
– 1 1 – – – – –
BRA rel
Branch Always (if I = 1)
REL
20 rr
3
ppp
– 1 1 – – – – –
BRCLR n,opr8a,rel
Branch if Bit n in Memory Clear (if (Mn) = 0)
DIR (b0)
DIR (b1)
DIR (b2)
DIR (b3)
DIR (b4)
DIR (b5)
DIR (b6)
DIR (b7)
01
03
05
07
09
0B
0D
0F
5
5
5
5
5
5
5
5
rpppp
rpppp
rpppp
rpppp
rpppp
rpppp
rpppp
rpppp
– 1 1 – – – – ↕
BRN rel
Branch Never (if I = 0)
REL
21 rr
3
ppp
– 1 1 – – – – –
Branch if Bit n in Memory Set (if (Mn) = 1)
DIR (b0)
DIR (b1)
DIR (b2)
DIR (b3)
DIR (b4)
DIR (b5)
DIR (b6)
DIR (b7)
00
02
04
06
08
0A
0C
0E
dd
dd
dd
dd
dd
dd
dd
dd
5
5
5
5
5
5
5
5
rpppp
rpppp
rpppp
rpppp
rpppp
rpppp
rpppp
rpppp
– 1 1 – – – – ↕
BSET n,opr8a
Set Bit n in Memory (Mn ← 1)
DIR (b0)
DIR (b1)
DIR (b2)
DIR (b3)
DIR (b4)
DIR (b5)
DIR (b6)
DIR (b7)
10
12
14
16
18
1A
1C
1E
dd
dd
dd
dd
dd
dd
dd
dd
5
5
5
5
5
5
5
5
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
rfwpp
– 1 1 – – – – –
BSR rel
Branch to Subroutine
PC ← (PC) + $0002
push (PCL); SP ← (SP) – $0001
push (PCH); SP ← (SP) – $0001
PC ← (PC) + rel
REL
AD rr
5
ssppp
– 1 1 – – – – –
5
4
4
5
5
6
rpppp
pppp
pppp
rpppp
rfppp
prpppp
– 1 1 – – – – –
BRSET n,opr8a,rel
Branch if (A) = (M)
Branch if (A) = (M)
Branch if (X) = (M)
Branch if (A) = (M)
Branch if (A) = (M)
Branch if (A) = (M)
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
rr
CBEQ opr8a,rel
CBEQA #opr8i,rel
CBEQX #opr8i,rel
CBEQ oprx8,X+,rel
CBEQ ,X+,rel
CBEQ oprx8,SP,rel
Compare and...
CLC
Clear Carry Bit (C ← 0)
INH
98
1
p
– 1 1 – – – – 0
CLI
Clear Interrupt Mask Bit (I ← 0)
INH
9A
1
p
– 1 1 – 0 – – –
CLR opr8a
CLRA
CLRX
CLRH
CLR oprx8,X
CLR ,X
CLR oprx8,SP
Clear
DIR
INH
INH
INH
IX1
IX
SP1
3F dd
4F
5F
8C
6F ff
7F
9E 6F ff
5
1
1
1
5
4
6
rfwpp
p
p
p
rfwpp
rfwp
prfwpp
0 1 1 – – 0 1 –
M ← $00
A ← $00
X ← $00
H ← $00
M ← $00
M ← $00
M ← $00
DIR
IMM
IMM
IX1+
IX+
SP1
dd
dd
dd
dd
dd
dd
dd
dd
31
41
51
61
71
9E 61
dd
ii
ii
ff
rr
ff
rr
rr
rr
rr
rr
MC9S08DZ60 Series Data Sheet, Rev. 4
126
Freescale Semiconductor
Chapter 7 Central Processor Unit (S08CPUV3)
CMP
CMP
CMP
CMP
CMP
CMP
CMP
CMP
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
Operation
Compare Accumulator with Memory
A–M
(CCR Updated But Operands Not Changed)
Object Code
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A1
B1
C1
D1
E1
F1
9E D1
9E E1
ii
dd
hh ll
ee ff
ff
ee ff
ff
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 4 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
↕ 1 1 – – ↕ ↕ ↕
COM opr8a
COMA
COMX
COM oprx8,X
COM ,X
COM oprx8,SP
Complement
M ← (M)= $FF – (M)
(One’s Complement) A ← (A) = $FF – (A)
X ← (X) = $FF – (X)
M ← (M) = $FF – (M)
M ← (M) = $FF – (M)
M ← (M) = $FF – (M)
DIR
INH
INH
IX1
IX
SP1
33 dd
43
53
63 ff
73
9E 63 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
0 1 1 – – ↕ ↕ 1
CPHX opr16a
CPHX #opr16i
CPHX opr8a
CPHX oprx8,SP
Compare Index Register (H:X) with Memory
(H:X) – (M:M + $0001)
(CCR Updated But Operands Not Changed)
EXT
IMM
DIR
SP1
3E
65
75
9E F3
hh ll
jj kk
dd
ff
6
3
5
6
prrfpp
ppp
rrfpp
prrfpp
↕ 1 1 – – ↕ ↕ ↕
Compare X (Index Register Low) with
Memory
X–M
(CCR Updated But Operands Not Changed)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A3
B3
C3
D3
E3
F3
9E D3
9E E3
ii
dd
hh ll
ee ff
ff
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
↕ 1 1 – – ↕ ↕ ↕
1
p
U 1 1 – – ↕ ↕ ↕
7
4
4
7
6
8
rfwpppp
fppp
fppp
rfwpppp
rfwppp
prfwpppp
– 1 1 – – – – –
CPX
CPX
CPX
CPX
CPX
CPX
CPX
CPX
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
DAA
Decimal Adjust Accumulator
After ADD or ADC of BCD Values
INH
72
DBNZ opr8a,rel
DBNZA rel
DBNZX rel
DBNZ oprx8,X,rel
DBNZ ,X,rel
DBNZ oprx8,SP,rel
DIR
INH
Decrement A, X, or M and Branch if Not Zero
INH
(if (result) ≠ 0)
IX1
DBNZX Affects X Not H
IX
SP1
3B
4B
5B
6B
7B
9E 6B
DEC opr8a
DECA
DECX
DEC oprx8,X
DEC ,X
DEC oprx8,SP
Decrement
Divide
A ← (H:A)÷(X); H ← Remainder
DIV
EOR
EOR
EOR
EOR
EOR
EOR
EOR
EOR
M ← (M) – $01
A ← (A) – $01
X ← (X) – $01
M ← (M) – $01
M ← (M) – $01
M ← (M) – $01
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
Exclusive OR Memory with Accumulator
A ← (A ⊕ M)
ee ff
ff
dd rr
rr
rr
ff rr
rr
ff rr
DIR
INH
INH
IX1
IX
SP1
3A dd
4A
5A
6A ff
7A
9E 6A ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ –
INH
52
6
fffffp
– 1 1 – – – ↕ ↕
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A8
B8
C8
D8
E8
F8
9E D8
9E E8
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
0 1 1 – – ↕ ↕ –
ii
dd
hh ll
ee ff
ff
ee ff
ff
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
127
Chapter 7 Central Processor Unit (S08CPUV3)
INC opr8a
INCA
INCX
INC oprx8,X
INC ,X
INC oprx8,SP
Operation
Increment
M ← (M) + $01
A ← (A) + $01
X ← (X) + $01
M ← (M) + $01
M ← (M) + $01
M ← (M) + $01
Object Code
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 5 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
DIR
INH
INH
IX1
IX
SP1
3C dd
4C
5C
6C ff
7C
9E 6C ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ –
BC
CC
DC
EC
FC
dd
hh ll
ee ff
ff
3
4
4
3
3
ppp
pppp
pppp
ppp
ppp
– 1 1 – – – – –
JMP
JMP
JMP
JMP
JMP
opr8a
opr16a
oprx16,X
oprx8,X
,X
Jump
PC ← Jump Address
DIR
EXT
IX2
IX1
IX
JSR
JSR
JSR
JSR
JSR
opr8a
opr16a
oprx16,X
oprx8,X
,X
Jump to Subroutine
PC ← (PC) + n (n = 1, 2, or 3)
Push (PCL); SP ← (SP) – $0001
Push (PCH); SP ← (SP) – $0001
PC ← Unconditional Address
DIR
EXT
IX2
IX1
IX
BD
CD
DD
ED
FD
dd
hh ll
ee ff
ff
5
6
6
5
5
ssppp
pssppp
pssppp
ssppp
ssppp
– 1 1 – – – – –
LDA
LDA
LDA
LDA
LDA
LDA
LDA
LDA
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
Load Accumulator from Memory
A ← (M)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A6
B6
C6
D6
E6
F6
9E D6
9E E6
ii
dd
hh ll
ee ff
ff
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
0 1 1 – – ↕ ↕ –
Load Index Register (H:X)
H:X ← (M:M + $0001)
IMM
DIR
EXT
IX
IX2
IX1
SP1
jj kk
dd
hh ll
9E
9E
9E
9E
45
55
32
AE
BE
CE
FE
3
4
5
5
6
5
5
ppp
rrpp
prrpp
prrfp
pprrpp
prrpp
prrpp
0 1 1 – – ↕ ↕ –
Load X (Index Register Low) from Memory
X ← (M)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
AE
BE
CE
DE
EE
FE
9E DE
9E EE
ii
dd
hh ll
ee ff
ff
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
0 1 1 – – ↕ ↕ –
DIR
INH
INH
IX1
IX
SP1
38 dd
48
58
68 ff
78
9E 68 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ ↕
DIR
INH
INH
IX1
IX
SP1
34 dd
44
54
64 ff
74
9E 64 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – 0 ↕ ↕
LDHX
LDHX
LDHX
LDHX
LDHX
LDHX
LDHX
LDX
LDX
LDX
LDX
LDX
LDX
LDX
LDX
#opr16i
opr8a
opr16a
,X
oprx16,X
oprx8,X
oprx8,SP
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
LSL opr8a
LSLA
LSLX
LSL oprx8,X
LSL ,X
LSL oprx8,SP
LSR opr8a
LSRA
LSRX
LSR oprx8,X
LSR ,X
LSR oprx8,SP
Logical Shift Left
C
0
b7
b0
(Same as ASL)
Logical Shift Right
0
C
b7
b0
ee ff
ff
ee ff
ff
ff
ee ff
ff
MC9S08DZ60 Series Data Sheet, Rev. 4
128
Freescale Semiconductor
Chapter 7 Central Processor Unit (S08CPUV3)
Operation
Object Code
MOV opr8a,opr8a
MOV opr8a,X+
MOV #opr8i,opr8a
MOV ,X+,opr8a
Move
(M)destination ← (M)source
In IX+/DIR and DIR/IX+ Modes,
H:X ← (H:X) + $0001
DIR/DIR
DIR/IX+
IMM/DIR
IX+/DIR
4E
5E
6E
7E
MUL
Unsigned multiply
X:A ← (X) × (A)
INH
NEG opr8a
NEGA
NEGX
NEG oprx8,X
NEG ,X
NEG oprx8,SP
Negate
M ← – (M) = $00 – (M)
(Two’s Complement) A ← – (A) = $00 – (A)
X ← – (X) = $00 – (X)
M ← – (M) = $00 – (M)
M ← – (M) = $00 – (M)
M ← – (M) = $00 – (M)
NOP
NSA
ORA
ORA
ORA
ORA
ORA
ORA
ORA
ORA
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 6 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
5
5
4
5
rpwpp
rfwpp
pwpp
rfwpp
0 1 1 – – ↕ ↕ –
42
5
ffffp
– 1 1 0 – – – 0
DIR
INH
INH
IX1
IX
SP1
30 dd
40
50
60 ff
70
9E 60 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ ↕
No Operation — Uses 1 Bus Cycle
INH
9D
1
p
– 1 1 – – – – –
Nibble Swap Accumulator
A ← (A[3:0]:A[7:4])
INH
62
1
p
– 1 1 – – – – –
Inclusive OR Accumulator and Memory
A ← (A) | (M)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
AA
BA
CA
DA
EA
FA
9E DA
9E EA
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
0 1 1 – – ↕ ↕ –
dd dd
dd
ii dd
dd
ii
dd
hh ll
ee ff
ff
ee ff
ff
PSHA
Push Accumulator onto Stack
Push (A); SP ← (SP) – $0001
INH
87
2
sp
– 1 1 – – – – –
PSHH
Push H (Index Register High) onto Stack
Push (H); SP ← (SP) – $0001
INH
8B
2
sp
– 1 1 – – – – –
PSHX
Push X (Index Register Low) onto Stack
Push (X); SP ← (SP) – $0001
INH
89
2
sp
– 1 1 – – – – –
PULA
Pull Accumulator from Stack
SP ← (SP + $0001); Pull (A)
INH
86
3
ufp
– 1 1 – – – – –
PULH
Pull H (Index Register High) from Stack
SP ← (SP + $0001); Pull (H)
INH
8A
3
ufp
– 1 1 – – – – –
PULX
Pull X (Index Register Low) from Stack
SP ← (SP + $0001); Pull (X)
INH
88
3
ufp
– 1 1 – – – – –
DIR
INH
INH
IX1
IX
SP1
39 dd
49
59
69 ff
79
9E 69 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ ↕
DIR
INH
INH
IX1
IX
SP1
36 dd
46
56
66 ff
76
9E 66 ff
5
1
1
5
4
6
rfwpp
p
p
rfwpp
rfwp
prfwpp
↕ 1 1 – – ↕ ↕ ↕
ROL opr8a
ROLA
ROLX
ROL oprx8,X
ROL ,X
ROL oprx8,SP
Rotate Left through Carry
ROR opr8a
RORA
RORX
ROR oprx8,X
ROR ,X
ROR oprx8,SP
Rotate Right through Carry
C
b7
b0
C
b7
b0
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
129
Chapter 7 Central Processor Unit (S08CPUV3)
Operation
Object Code
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 7 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
RSP
Reset Stack Pointer (Low Byte)
SPL ← $FF
(High Byte Not Affected)
INH
9C
1
p
– 1 1 – – – – –
RTI
Return from Interrupt
SP ← (SP) + $0001; Pull (CCR)
SP ← (SP) + $0001; Pull (A)
SP ← (SP) + $0001; Pull (X)
SP ← (SP) + $0001; Pull (PCH)
SP ← (SP) + $0001; Pull (PCL)
INH
80
9
uuuuufppp
↕ 1 1 ↕
RTS
Return from Subroutine
SP ← SP + $0001; Pull (PCH)
SP ← SP + $0001; Pull (PCL)
INH
81
5
ufppp
– 1 1 – – – – –
Subtract with Carry
A ← (A) – (M) – (C)
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A2
B2
C2
D2
E2
F2
9E D2
9E E2
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
↕ 1 1 – – ↕ ↕ ↕
SBC
SBC
SBC
SBC
SBC
SBC
SBC
SBC
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
ii
dd
hh ll
ee ff
ff
ee ff
ff
↕ ↕ ↕ ↕
SEC
Set Carry Bit
(C ← 1)
INH
99
1
p
– 1 1 – – – – 1
SEI
Set Interrupt Mask Bit
(I ← 1)
INH
9B
1
p
– 1 1 – 1 – – –
Store Accumulator in Memory
M ← (A)
DIR
EXT
IX2
IX1
IX
SP2
SP1
B7
C7
D7
E7
F7
9E D7
9E E7
wpp
pwpp
pwpp
wpp
wp
ppwpp
pwpp
0 1 1 – – ↕ ↕ –
ee ff
ff
3
4
4
3
2
5
4
35 dd
96 hh ll
9E FF ff
4
5
5
wwpp
pwwpp
pwwpp
0 1 1 – – ↕ ↕ –
2
fp...
– 1 1 – 0 – – –
3
4
4
3
2
5
4
wpp
pwpp
pwpp
wpp
wp
ppwpp
pwpp
0 1 1 – – ↕ ↕ –
STA
STA
STA
STA
STA
STA
STA
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
STHX opr8a
STHX opr16a
STHX oprx8,SP
Store H:X (Index Reg.)
(M:M + $0001) ← (H:X)
DIR
EXT
SP1
STOP
Enable Interrupts: Stop Processing
Refer to MCU Documentation
I bit ← 0; Stop Processing
INH
8E
Store X (Low 8 Bits of Index Register)
in Memory
M ← (X)
DIR
EXT
IX2
IX1
IX
SP2
SP1
BF
CF
DF
EF
FF
9E DF
9E EF
STX
STX
STX
STX
STX
STX
STX
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
dd
hh ll
ee ff
ff
dd
hh ll
ee ff
ff
ee ff
ff
MC9S08DZ60 Series Data Sheet, Rev. 4
130
Freescale Semiconductor
Chapter 7 Central Processor Unit (S08CPUV3)
SUB
SUB
SUB
SUB
SUB
SUB
SUB
SUB
#opr8i
opr8a
opr16a
oprx16,X
oprx8,X
,X
oprx16,SP
oprx8,SP
Operation
Object Code
IMM
DIR
EXT
IX2
IX1
IX
SP2
SP1
A0
B0
C0
D0
E0
F0
9E D0
9E E0
SWI
Software Interrupt
PC ← (PC) + $0001
Push (PCL); SP ← (SP) – $0001
Push (PCH); SP ← (SP) – $0001
Push (X); SP ← (SP) – $0001
Push (A); SP ← (SP) – $0001
Push (CCR); SP ← (SP) – $0001
I ← 1;
PCH ← Interrupt Vector High Byte
PCL ← Interrupt Vector Low Byte
INH
TAP
Transfer Accumulator to CCR
CCR ← (A)
TAX
TPA
TST opr8a
TSTA
TSTX
TST oprx8,X
TST ,X
TST oprx8,SP
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 8 of 9)
Cyc-by-Cyc
Details
Affect
on CCR
V11H INZC
2
3
4
4
3
3
5
4
pp
rpp
prpp
prpp
rpp
rfp
pprpp
prpp
↕ 1 1 – – ↕ ↕ ↕
83
11
sssssvvfppp
– 1 1 – 1 – – –
INH
84
1
p
↕ 1 1 ↕
Transfer Accumulator to X (Index Register
Low)
X ← (A)
INH
97
1
p
– 1 1 – – – – –
Transfer CCR to Accumulator
A ← (CCR)
INH
85
1
p
– 1 1 – – – – –
DIR
INH
INH
IX1
IX
SP1
3D dd
4D
5D
6D ff
7D
9E 6D ff
4
1
1
4
3
5
rfpp
p
p
rfpp
rfp
prfpp
0 1 1 – – ↕ ↕ –
Subtract
A ← (A) – (M)
Test for Negative or Zero
(M) – $00
(A) – $00
(X) – $00
(M) – $00
(M) – $00
(M) – $00
ii
dd
hh ll
ee ff
ff
ee ff
ff
↕ ↕ ↕ ↕
TSX
Transfer SP to Index Reg.
H:X ← (SP) + $0001
INH
95
2
fp
– 1 1 – – – – –
TXA
Transfer X (Index Reg. Low) to Accumulator
A ← (X)
INH
9F
1
p
– 1 1 – – – – –
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
131
Chapter 7 Central Processor Unit (S08CPUV3)
Operation
Object Code
Cycles
Source
Form
Address
Mode
Table 7-2. Instruction Set Summary (Sheet 9 of 9)
Affect
on CCR
Cyc-by-Cyc
Details
V11H INZC
TXS
Transfer Index Reg. to SP
SP ← (H:X) – $0001
INH
94
2
fp
– 1 1 – – – – –
WAIT
Enable Interrupts; Wait for Interrupt
I bit ← 0; Halt CPU
INH
8F
2+
fp...
– 1 1 – 0 – – –
Source Form: Everything in the source forms columns, except expressions in italic characters, is literal information which must appear in the
assembly source file exactly as shown. The initial 3- to 5-letter mnemonic and the characters (#, ( ) and +) are always a literal characters.
n
Any label or expression that evaluates to a single integer in the range 0-7.
opr8i
Any label or expression that evaluates to an 8-bit immediate value.
opr16i Any label or expression that evaluates to a 16-bit immediate value.
opr8a
Any label or expression that evaluates to an 8-bit direct-page address ($00xx).
opr16a Any label or expression that evaluates to a 16-bit address.
oprx8
Any label or expression that evaluates to an unsigned 8-bit value, used for indexed addressing.
oprx16 Any label or expression that evaluates to a 16-bit value, used for indexed addressing.
rel
Any label or expression that refers to an address that is within –128 to +127 locations from the start of the next instruction.
Operation Symbols:
A
Accumulator
CCR Condition code register
H
Index register high byte
M
Memory location
n
Any bit
opr
Operand (one or two bytes)
PC
Program counter
PCH Program counter high byte
PCL Program counter low byte
rel
Relative program counter offset byte
SP
Stack pointer
SPL Stack pointer low byte
X
Index register low byte
&
Logical AND
|
Logical OR
⊕
Logical EXCLUSIVE OR
()
Contents of
+
Add
–
Subtract, Negation (two’s complement)
×
Multiply
÷
Divide
#
Immediate value
←
Loaded with
:
Concatenated with
Addressing Modes:
DIR Direct addressing mode
EXT Extended addressing mode
IMM Immediate addressing mode
INH Inherent addressing mode
IX
Indexed, no offset addressing mode
IX1
Indexed, 8-bit offset addressing mode
IX2
Indexed, 16-bit offset addressing mode
IX+
Indexed, no offset, post increment addressing mode
IX1+ Indexed, 8-bit offset, post increment addressing mode
REL Relative addressing mode
SP1 Stack pointer, 8-bit offset addressing mode
SP2 Stack pointer 16-bit offset addressing mode
CCR Bits:
V
Overflow bit
H
Half-carry bit
I
Interrupt mask
N
Negative bit
Z
Zero bit
C
Carry/borrow bit
CCR Effects:
↕
Set or cleared
–
Not affected
U
Undefined
Cycle-by-Cycle Codes:
f
Free cycle. This indicates a cycle where the CPU
does not require use of the system buses. An f
cycle is always one cycle of the system bus clock
and is always a read cycle.
p
Program fetch; read from next consecutive
location in program memory
r
Read 8-bit operand
s
Push (write) one byte onto stack
u
Pop (read) one byte from stack
v
Read vector from $FFxx (high byte first)
w
Write 8-bit operand
MC9S08DZ60 Series Data Sheet, Rev. 4
132
Freescale Semiconductor
Chapter 7 Central Processor Unit (S08CPUV3)
Table 7-3. Opcode Map (Sheet 1 of 2)
Bit-Manipulation
00
5 10
5
BRSET0
3
01
BRCLR1
3
04
BRSET2
3
05
3
07
BRSET4
3
09
BRSET5
3
0B
BRSET6
3
0D
BRCLR6
3
0E
BRSET7
3
0F
BRCLR7
3
INH
IMM
DIR
EXT
DD
IX+D
INC
DIR 2
5 2F
TST
REL 2
3 3E
CPHX
REL 3
3 3F
BIH
CLR
DIR 1
ASR
INH 2
1 68
INH 1
Relative
Indexed, No Offset
Indexed, 8-Bit Offset
Indexed, 16-Bit Offset
IMM to DIR
DIR to IX+
ROL
DEC
ROL
DEC
DBNZ
INH 3
1 6C
DBNZ
INC
INH 2
1 6D
INC
IX1 1
4 7D
TST
INH 2
5 6E
MOV
CLRX
IX1 1
CLR
ADD
INH 2
1
INH 1
2
BD
BSR
Page 2
WAIT
5
1
JSR
REL 2
2 BE
LDX
2
AF
TXA
INH 2
AIX
LDX
DIR 3
3 CF
STX
IMM 2
EXT 3
4 DF
STX
DIR 3
EXT 3
Opcode in
Hexadecimal F0
EOR
ADC
IX2 2
IX
2
STA
IX
3
EOR
IX
3
ADC
IX1 1
3 FA
ORA
IX
3
ORA
IX1 1
3 FB
ADD
JSR
LDX
IX1 1
3 FF
IX
5
JSR
IX1 1
3 FE
IX1 1
IX
3
JMP
IX1 1
5 FD
STX
IX
3
ADD
IX1 1
3 FC
JMP
IX2 2
4 EF
STX
IX
3
LDA
IX1 1
3 F9
IX2 2
4 EE
LDX
BIT
IX1 1
3 F8
IX2 2
6 ED
JSR
EXT 3
4 DE
IX
3
STA
IX2 2
4 EC
JMP
EXT 3
6 DD
JSR
DIR 3
3 CE
LDX
IMM 2
2 BF
Stack Pointer, 8-Bit Offset
Stack Pointer, 16-Bit Offset
Indexed, No Offset with
Post Increment
Indexed, 1-Byte Offset with
Post Increment
JMP
DIR 3
5 CD
AND
IX1 1
3 F7
IX2 2
4 EB
ADD
EXT 3
4 DC
IX
3
LDA
IX2 2
4 EA
ORA
EXT 3
4 DB
ADD
JMP
INH 2
AE
INH
2+ 9F
ORA
CPX
IX1 1
3 F6
IX2 2
4 E9
ADC
EXT 3
4 DA
IX
3
BIT
IX2 2
4 E8
EOR
IX
3
SBC
IX1 1
3 F5
STA
ADC
DIR 3
3 CC
AND
IX2 2
4 E7
EXT 3
4 D9
CMP
IX1 1
3 F4
IX2 2
4 E6
EXT 3
4 D8
EOR
DIR 3
3 CB
ADD
IMM 2
BC
INH
1 AD
NOP
IX 1
IMM 2
2 BB
CPX
LDA
STA
IX
3
IX1 1
3 F3
IX2 2
4 E5
EXT 3
4 D7
DIR 3
3 CA
ORA
RSP
1
2+ 9E
STOP
ADC
SBC
BIT
LDA
DIR 3
3 C9
IMM 2
2 BA
ORA
SEI
INH 1
9D
IX
5 8E
MOV
ADC
INH 2
1 AB
INH 1
1 9C
CLRH
IX 1
3
IMD 2
IX+D 1
5 7F
4 8F
CLR
INH 2
INH 1
2 9B
EOR
AND
3
SUB
IX1 1
3 F2
IX2 2
4 E4
EXT 3
4 D6
DIR 3
3 C8
IMM 2
2 B9
INH 2
1 AA
CLI
TST
IX1 1
4 7E
MOV
SEC
INH 1
3 9A
PSHH
IX 1
4 8C
EOR
CPX
BIT
STA
CMP
IX2 2
4 E3
EXT 3
4 D5
DIR 3
3 C7
IMM 2
2 B8
INH 2
1 A9
PULH
IX 1
6 8B
IX1 2
5 7C
CLC
INH 1
2 99
AND
LDA
AIS
INH 2
1 A8
SBC
F0
IX1 1
3 F1
IX2 2
4 E2
EXT 3
4 D4
DIR 3
3 C6
IMM 2
2 B7
TAX
CPX
BIT
LDA
CMP
EXT 3
4 D3
DIR 3
3 C5
IMM 2
2 B6
EXT 2
1 A7
INH 1
3 98
PSHX
IX 1
4 8A
IX1 1
7 7B
INH 3
2 97
PULX
IX 1
4 89
IX1 1
5 7A
INH 2
4 6B
IX1+
LSL
STHX
PSHA
IX 1
4 88
IX1 1
5 79
INH 2
1 6A
SP1
SP2
IX+
ASR
LSL
INH 2
1 69
PULA
IX 1
4 87
IX1 1
5 78
DD 2
DIX+ 3
1 5F
1 6F
CLRA
ROR
AND
BIT
INH 2
5 A6
SBC
3
SUB
IX2 2
4 E1
EXT 3
4 D2
DIR 3
3 C4
IMM 2
2 B5
TSX
INH 1
3 96
CPX
AND
CMP
E0
SUB
EXT 3
4 D1
DIR 3
3 C3
IMM 2
2 B4
INH 2
2 A5
TPA
DIR 1
4 86
IX1 1
5 77
TSTX
INH 1
5 5E
MOV
EXT 3
5 4F
REL 2
REL
IX
IX1
IX2
IMD
DIX+
TSTA
DIR 1
6 4E
INH 2
1 67
INCX
INH 1
1 5D
CPHX
TXS
INH 1
1 95
SBC
CPX
SUB
DIR 3
3 C2
IMM 2
2 B3
REL 2
2 A4
TAP
IX 1
5 85
IMM 2
5 76
ROR
DBNZX
INH 2
1 5C
INCA
DIR 1
4 4D
CPHX
DIR 3
1 66
DECX
INH 1
4 5B
DBNZA
DIR 2
5 4C
REL 2
3 3D
BIL
DECA
DIR 1
7 4B
DBNZ
BMS
DIR 2
5 2E
Inherent
Immediate
Direct
Extended
DIR to DIR
IX+ to DIR
DEC
LSR
CMP
SBC
BLE
Register/Memory
C0
4 D0
4
DIR 3
3 C1
IMM 2
2 B2
REL 2
3 A3
INH 2
1 94
3
SUB
CMP
BGT
SWI
B0
IMM 2
2 B1
REL 2
3 A2
INH 2
11 93
IX 1
4 84
2
SUB
BLT
INH 2
5+ 92
BGND
COM
A0
REL 2
3 A1
RTS
INH 1
4 83
IX1 1
3 75
ROLX
INH 1
1 5A
DAA
3
BGE
INH 2
6 91
IX+ 1
1 82
LSR
LSLX
INH 1
1 59
CBEQ
IX1 1
5 74
INH 2
4 65
ASRX
INH 1
1 58
ROLA
DIR 1
5 4A
BMC
DIR 2
5 2D
DIR 2
ROL
REL 3
3 3C
INH 1
1 57
LSLA
DIR 1
5 49
REL 2
3 3B
BMI
DIR 2
5 2C
BCLR7
DIR 2
LSL
COM
RTI
IX 1
5 81
INH 1
5 73
INH 2
1 64
RORX
ASRA
DIR 1
5 48
REL 2
3 3A
DIR 2
5 2B
BSET7
DIR 2
5 1F
ASR
BHCS
BPL
RORA
DIR 1
5 47
REL 2
3 39
DIR 2
5 2A
BCLR6
DIR 2
5 1E
ROR
INH 1
1 63
Control
9 90
80
NEG
NSA
LDHX
IMM 2
1 56
4
IX1+ 2
1 72
LSRX
INH 1
3 55
LDHX
DIR 3
5 46
BHCC
DIR 2
5 29
BSET6
DIR 2
5 1D
STHX
CBEQ
COMX
INH 1
1 54
LSRA
DIR 1
4 45
REL 2
3 38
BCLR5
DIR 2
5 1C
LSR
BEQ
INH 1
1 53
70
IX1 1
5 71
IMM 3
6 62
DIV
COMA
DIR 1
5 44
REL 2
3 37
BSET5
DIR 2
5 1B
BRCLR5
3
0C
BNE
DIR 2
5 28
BCLR4
DIR 2
5 1A
COM
REL 2
3 36
DIR 2
5 27
BSET4
DIR 2
5 19
BRCLR4
3
0A
BCS
MUL
5
NEG
INH 2
4 61
CBEQX
IMM 3
5 52
EXT 1
5 43
REL 2
3 35
DIR 2
5 26
CBEQA
LDHX
NEGX
INH 1
4 51
DIR 3
5 42
BCC
BCLR3
DIR 2
5 18
CBEQ
REL 2
3 34
DIR 2
5 25
BSET3
DIR 2
5 17
BRCLR3
3
08
BLS
NEGA
DIR 1
5 41
REL 3
3 33
DIR 2
5 24
BCLR2
DIR 2
5 16
BRSET3
DIR 2
5 23
Read-Modify-Write
1 50
1 60
40
NEG
REL 3
3 32
BHI
BSET2
DIR 2
5 15
BRCLR2
3
06
BRN
DIR 2
5 22
BCLR1
DIR 2
5 14
5
REL 2
3 31
BSET1
DIR 2
5 13
30
BRA
DIR 2
5 21
BCLR0
DIR 2
5 12
BRSET1
3
03
BSET0
DIR 2
5 11
BRCLR0
3
02
Branch
20
3
IX
3
LDX
IX
2
STX
IX
3 HCS08 Cycles
Instruction Mnemonic
IX Addressing Mode
SUB
Number of Bytes 1
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
133
Chapter 7 Central Processor Unit (S08CPUV3)
Table 7-3. Opcode Map (Sheet 2 of 2)
Bit-Manipulation
Branch
Read-Modify-Write
9E60
Control
Register/Memory
9ED0 5
6
NEG
CMP
SP1
CMP
4
SP2 3
SP1
9ED2 5 9EE2 4
SBC
9E63
SBC
4
SP2 3
SP1
9ED3 5 9EE3 4 9EF3
6
COM
CPX
3
SP1
9E64
6
CPX
AND
SP1
SP1
AND
4
SP2 3
SP1
9ED5 5 9EE5 4
BIT
BIT
6
4
SP2 3
SP1
9ED6 5 9EE6 4
3
SP1
9E67
6
4
SP2 3
SP1
9ED7 5 9EE7 4
9E66
6
CPHX
4
SP2 3
SP1 3
9ED4 5 9EE4 4
LSR
3
4
SUB
4
SP2 3
SP1
9ED1 5 9EE1 4
CBEQ
4
9EE0
SUB
3
SP1
9E61
6
ROR
LDA
ASR
LDA
STA
3
SP1
9E68
6
STA
4
SP2 3
SP1
9ED8 5 9EE8 4
LSL
EOR
3
SP1
9E69
6
EOR
4
SP2 3
SP1
9ED9 5 9EE9 4
ROL
ADC
3
SP1
9E6A 6
ADC
4
SP2 3
SP1
9EDA 5 9EEA 4
DEC
ORA
3
SP1
9E6B 8
ORA
4
SP2 3
SP1
9EDB 5 9EEB 4
DBNZ
ADD
4
SP1
9E6C 6
4
ADD
SP2 3
SP1
INC
3
SP1
9E6D 5
TST
3
SP1
9EAE
5
9EBE
LDHX
2
9E6F
IX 4
6
9ECE
LDHX
5
9EDE
LDHX
IX2 3
6
CLR
3
INH
IMM
DIR
EXT
DD
IX+D
Inherent
Immediate
Direct
Extended
DIR to DIR
IX+ to DIR
REL
IX
IX1
IX2
IMD
DIX+
Relative
Indexed, No Offset
Indexed, 8-Bit Offset
Indexed, 16-Bit Offset
IMM to DIR
DIR to IX+
SP1
SP2
IX+
IX1+
Note: All Sheet 2 Opcodes are Preceded by the Page 2 Prebyte (9E)
5
9EEE
LDX
4
9EFE
LDX
5
LDHX
IX1 4
SP2 3
SP1 3
SP1
9EDF 5 9EEF 4 9EFF 5
STX
SP1
4
SP2 3
STX
SP1 3
STHX
SP1
Stack Pointer, 8-Bit Offset
Stack Pointer, 16-Bit Offset
Indexed, No Offset with
Post Increment
Indexed, 1-Byte Offset with
Post Increment
Prebyte (9E) and Opcode in
Hexadecimal 9E60
6
HCS08 Cycles
Instruction Mnemonic
SP1 Addressing Mode
NEG
Number of Bytes 3
MC9S08DZ60 Series Data Sheet, Rev. 4
134
Freescale Semiconductor
Chapter 8
Multi-Purpose Clock Generator (S08MCGV1)
8.1
Introduction
The multi-purpose clock generator (MCG) module provides several clock source choices for the MCU.
The module contains a frequency-locked loop (FLL) and a phase-locked loop (PLL) that are controllable
by either an internal or an external reference clock. The module can select either of the FLL or PLL clocks,
or either of the internal or external reference clocks as a source for the MCU system clock. Whichever
clock source is chosen, it is passed through a reduced bus divider which allows a lower output clock
frequency to be derived. The MCG also controls an external oscillator (XOSC) for the use of a crystal or
resonator as the external reference clock.
All devices in the MC9S08DZ60 Series feature the MCG module.
NOTE
Refer to Section 1.3, “System Clock Distribution,” for detailed view of the
distribution clock sources throughout the chip.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
135
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 8-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
136
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.1.1
Features
Key features of the MCG module are:
• Frequency-locked loop (FLL)
— 0.2% resolution using internal 32-kHz reference
— 2% deviation over voltage and temperature using internal 32-kHz reference
— Internal or external reference can be used to control the FLL
• Phase-locked loop (PLL)
— Voltage-controlled oscillator (VCO)
— Modulo VCO frequency divider
— Phase/Frequency detector
— Integrated loop filter
— Lock detector with interrupt capability
• Internal reference clock
— Nine trim bits for accuracy
— Can be selected as the clock source for the MCU
• External reference clock
— Control for external oscillator
— Clock monitor with reset capability
— Can be selected as the clock source for the MCU
• Reference divider is provided
• Clock source selected can be divided down by 1, 2, 4, or 8
• BDC clock (MCGLCLK) is provided as a constant divide by 2 of the DCO output whether in an
FLL or PLL mode.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
137
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
External Oscillator
(XOSC)
RANGE
EREFS
ERCLKEN
MCGERCLK
HGO
EREFSTEN
IRCLKEN
MCGIRCLK
CME
IREFSTEN
CLKS
Clock
Monitor
LOC
BDIV
/ 2n
Internal
Reference
Clock
OSCINIT
9
IREFS
MCGOUT
n=0-3
LP
DCO
DCOOUT
TRIM
PLLS
/
2n
RDIV_CLK
Lock
Detector
Filter
n=0-7
FLL
RDIV
LOLS LOCK
MCGFFCLK
MCGFFCLKVALID
MCGLCLK
LP
VCOOUT
Phase
Detector
Charge
Pump
VDIV
Internal
Filter
/2
VCO
PLL
/(4,8,12,...,40)
Multi-purpose Clock Generator (MCG)
Figure 8-2. Multi-Purpose Clock Generator (MCG) Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
138
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.1.2
Modes of Operation
There are nine modes of operation for the MCG:
• FLL Engaged Internal (FEI)
• FLL Engaged External (FEE)
• FLL Bypassed Internal (FBI)
• FLL Bypassed External (FBE)
• PLL Engaged External (PEE)
• PLL Bypassed External (PBE)
• Bypassed Low Power Internal (BLPI)
• Bypassed Low Power External (BLPE)
• Stop
For details see Section 8.4.1, “Operational Modes.
8.2
External Signal Description
There are no MCG signals that connect off chip.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
139
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.3
Register Definition
8.3.1
MCG Control Register 1 (MCGC1)
7
6
5
4
3
2
1
0
IREFS
IRCLKEN
IREFSTEN
1
0
0
R
CLKS
RDIV
W
Reset:
0
0
0
0
0
Figure 8-3. MCG Control Register 1 (MCGC1)
Table 8-1. MCG Control Register 1 Field Descriptions
Field
Description
7:6
CLKS
Clock Source Select — Selects the system clock source.
00 Encoding 0 — Output of FLL or PLL is selected.
01 Encoding 1 — Internal reference clock is selected.
10 Encoding 2 — External reference clock is selected.
11 Encoding 3 — Reserved, defaults to 00.
5:3
RDIV
Reference Divider — Selects the amount to divide down the reference clock selected by the IREFS bit. If the
FLL is selected, the resulting frequency must be in the range 31.25 kHz to 39.0625 kHz. If the PLL is selected,
the resulting frequency must be in the range 1 MHz to 2 MHz.
000 Encoding 0 — Divides reference clock by 1 (reset default)
001 Encoding 1 — Divides reference clock by 2
010 Encoding 2 — Divides reference clock by 4
011 Encoding 3 — Divides reference clock by 8
100 Encoding 4 — Divides reference clock by 16
101 Encoding 5 — Divides reference clock by 32
110 Encoding 6 — Divides reference clock by 64
111 Encoding 7 — Divides reference clock by 128
2
IREFS
Internal Reference Select — Selects the reference clock source.
1 Internal reference clock selected
0 External reference clock selected
1
IRCLKEN
0
IREFSTEN
Internal Reference Clock Enable — Enables the internal reference clock for use as MCGIRCLK.
1 MCGIRCLK active
0 MCGIRCLK inactive
Internal Reference Stop Enable — Controls whether or not the internal reference clock remains enabled when
the MCG enters stop mode.
1 Internal reference clock stays enabled in stop if IRCLKEN is set or if MCG is in FEI, FBI, or BLPI mode before
entering stop
0 Internal reference clock is disabled in stop
MC9S08DZ60 Series Data Sheet, Rev. 4
140
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.3.2
MCG Control Register 2 (MCGC2)
7
6
5
4
3
2
RANGE
HGO
LP
EREFS
0
0
0
0
1
0
R
BDIV
ERCLKEN EREFSTEN
W
Reset:
0
1
0
0
Figure 8-4. MCG Control Register 2 (MCGC2)
Table 8-2. MCG Control Register 2 Field Descriptions
Field
Description
7:6
BDIV
Bus Frequency Divider — Selects the amount to divide down the clock source selected by the CLKS bits in the
MCGC1 register. This controls the bus frequency.
00 Encoding 0 — Divides selected clock by 1
01 Encoding 1 — Divides selected clock by 2 (reset default)
10 Encoding 2 — Divides selected clock by 4
11 Encoding 3 — Divides selected clock by 8
5
RANGE
Frequency Range Select — Selects the frequency range for the external oscillator or external clock source.
1 High frequency range selected for the external oscillator of 1 MHz to 16 MHz (1 MHz to 40 MHz for external
clock source)
0 Low frequency range selected for the external oscillator of 32 kHz to 100 kHz (32 kHz to 1 MHz for external
clock source)
4
HGO
3
LP
2
EREFS
1
ERCLKEN
High Gain Oscillator Select — Controls the external oscillator mode of operation.
1 Configure external oscillator for high gain operation
0 Configure external oscillator for low power operation
Low Power Select — Controls whether the FLL (or PLL) is disabled in bypassed modes.
1 FLL (or PLL) is disabled in bypass modes (lower power).
0 FLL (or PLL) is not disabled in bypass modes.
External Reference Select — Selects the source for the external reference clock.
1 Oscillator requested
0 External Clock Source requested
External Reference Enable — Enables the external reference clock for use as MCGERCLK.
1 MCGERCLK active
0 MCGERCLK inactive
0
External Reference Stop Enable — Controls whether or not the external reference clock remains enabled when
EREFSTEN the MCG enters stop mode.
1 External reference clock stays enabled in stop if ERCLKEN is set or if MCG is in FEE, FBE, PEE, PBE, or
BLPE mode before entering stop
0 External reference clock is disabled in stop
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
141
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.3.3
MCG Trim Register (MCGTRM)
7
6
5
4
3
2
1
0
R
TRIM
W
POR:
1
0
0
0
0
0
0
0
Reset:
U
U
U
U
U
U
U
U
Figure 8-5. MCG Trim Register (MCGTRM)
Table 8-3. MCG Trim Register Field Descriptions
Field
Description
7:0
TRIM
MCG Trim Setting — Controls the internal reference clock frequency by controlling the internal reference clock
period. The TRIM bits are binary weighted (i.e., bit 1 will adjust twice as much as bit 0). Increasing the binary
value in TRIM will increase the period, and decreasing the value will decrease the period.
An additional fine trim bit is available in MCGSC as the FTRIM bit.
If a TRIM[7:0] value stored in nonvolatile memory is to be used, it’s the user’s responsibility to copy that value
from the nonvolatile memory location to this register.
MC9S08DZ60 Series Data Sheet, Rev. 4
142
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.3.4
MCG Status and Control Register (MCGSC)
R
7
6
5
4
3
LOLS
LOCK
PLLST
IREFST
2
CLKST
1
0
OSCINIT
FTRIM
W
POR:
Reset:
0
0
0
0
0
0
1
1
0
0
0
0
0
0
0
U
Figure 8-6. MCG Status and Control Register (MCGSC)
Table 8-4. MCG Status and Control Register Field Descriptions
Field
Description
7
LOLS
Loss of Lock Status — This bit is a sticky indication of lock status for the FLL or PLL. LOLS is set when lock
detection is enabled and after acquiring lock, the FLL or PLL output frequency has fallen outside the lock exit
frequency tolerance, Dunl. LOLIE determines whether an interrupt request is made when set. LOLS is cleared by
reset or by writing a logic 1 to LOLS when LOLS is set. Writing a logic 0 to LOLS has no effect.
0 FLL or PLL has not lost lock since LOLS was last cleared.
1 FLL or PLL has lost lock since LOLS was last cleared.
6
LOCK
Lock Status — Indicates whether the FLL or PLL has acquired lock. Lock detection is disabled when both the
FLL and PLL are disabled. If the lock status bit is set then changing the value of any of the following bits IREFS,
PLLS, RDIV[2:0], TRIM[7:0] (if in FEI or FBI modes), or VDIV[3:0] (if in PBE or PEE modes), will cause the lock
status bit to clear and stay cleared until the FLL or PLL has reacquired lock. Stop mode entry will also cause the
lock status bit to clear and stay cleared until the FLL or PLL has reacquired lock. Entry into BLPI or BLPE mode
will also cause the lock status bit to clear and stay cleared until the MCG has exited these modes and the FLL
or PLL has reacquired lock.
0 FLL or PLL is currently unlocked.
1 FLL or PLL is currently locked.
5
PLLST
PLL Select Status — The PLLST bit indicates the current source for the PLLS clock. The PLLST bit does not
update immediately after a write to the PLLS bit due to internal synchronization between clock domains.
0 Source of PLLS clock is FLL clock.
1 Source of PLLS clock is PLL clock.
4
IREFST
Internal Reference Status — The IREFST bit indicates the current source for the reference clock. The IREFST
bit does not update immediately after a write to the IREFS bit due to internal synchronization between clock
domains.
0 Source of reference clock is external reference clock (oscillator or external clock source as determined by the
EREFS bit in the MCGC2 register).
1 Source of reference clock is internal reference clock.
3:2
CLKST
Clock Mode Status — The CLKST bits indicate the current clock mode. The CLKST bits do not update
immediately after a write to the CLKS bits due to internal synchronization between clock domains.
00 Encoding 0 — Output of FLL is selected.
01 Encoding 1 — Internal reference clock is selected.
10 Encoding 2 — External reference clock is selected.
11 Encoding 3 — Output of PLL is selected.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
143
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
Table 8-4. MCG Status and Control Register Field Descriptions (continued)
Field
Description
1
OSCINIT
OSC Initialization — If the external reference clock is selected by ERCLKEN or by the MCG being in FEE, FBE,
PEE, PBE, or BLPE mode, and if EREFS is set, then this bit is set after the initialization cycles of the external
oscillator clock have completed. This bit is only cleared when either EREFS is cleared or when the MCG is in
either FEI, FBI, or BLPI mode and ERCLKEN is cleared.
0
FTRIM
MCG Fine Trim — Controls the smallest adjustment of the internal reference clock frequency. Setting FTRIM
will increase the period and clearing FTRIM will decrease the period by the smallest amount possible.
If an FTRIM value stored in nonvolatile memory is to be used, it’s the user’s responsibility to copy that value from
the nonvolatile memory location to this register’s FTRIM bit.
8.3.5
MCG Control Register 3 (MCGC3)
7
6
5
LOLIE
PLLS
CME
0
0
0
R
4
3
2
1
0
0
1
0
VDIV
W
Reset:
0
0
0
Figure 8-7. MCG PLL Register (MCGPLL)
Table 8-5. MCG PLL Register Field Descriptions
Field
Description
7
LOLIE
Loss of Lock Interrupt Enable — Determines if an interrupt request is made following a loss of lock indication.
The LOLIE bit only has an effect when LOLS is set.
0 No request on loss of lock.
1 Generate an interrupt request on loss of lock.
6
PLLS
PLL Select — Controls whether the PLL or FLL is selected. If the PLLS bit is clear, the PLL is disabled in all
modes. If the PLLS is set, the FLL is disabled in all modes.
1 PLL is selected
0 FLL is selected
MC9S08DZ60 Series Data Sheet, Rev. 4
144
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
Table 8-5. MCG PLL Register Field Descriptions (continued)
Field
Description
5
CME
Clock Monitor Enable — Determines if a reset request is made following a loss of external clock indication. The
CME bit should only be set to a logic 1 when either the MCG is in an operational mode that uses the external
clock (FEE, FBE, PEE, PBE, or BLPE) or the external reference is enabled (ERCLKEN=1 in the MCGC2
register). Whenever the CME bit is set to a logic 1, the value of the RANGE bit in the MCGC2 register should not
be changed.
0 Clock monitor is disabled.
1 Generate a reset request on loss of external clock.
3:0
VDIV
VCO Divider — Selects the amount to divide down the VCO output of PLL. The VDIV bits establish the
multiplication factor (M) applied to the reference clock frequency.
0000 Encoding 0 — Reserved.
0001 Encoding 1 — Multiply by 4.
0010 Encoding 2 — Multiply by 8.
0011 Encoding 3 — Multiply by 12.
0100 Encoding 4 — Multiply by 16.
0101 Encoding 5 — Multiply by 20.
0110 Encoding 6 — Multiply by 24.
0111 Encoding 7 — Multiply by 28.
1000 Encoding 8 — Multiply by 32.
1001 Encoding 9 — Multiply by 36.
1010 Encoding 10 — Multiply by 40.
1011 Encoding 11 — Reserved (default to M=40).
11xx Encoding 12-15 — Reserved (default to M=40).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
145
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.4
Functional Description
8.4.1
Operational Modes
IREFS=1
CLKS=00
PLLS=0
IREFS=1
CLKS=01
PLLS=0
BDM Enabled
or LP=0
IREFS=1
CLKS=01
PLLS=0
BDM Disabled
and LP=1
FLL Engaged
Internal (FEI)
FLL Engaged
External (FEE)
FLL Bypassed
Internal (FBI)
FLL Bypassed
External (FBE)
IREFS=0
CLKS=10
PLLS=0
BDM Enabled
or LP=0
Bypassed
IREFS=0
Low Power
CLKS=10
External (BLPE) BDM Disabled
and LP=1
Bypassed
Low Power
Internal (BLPI)
Entered from any state
when MCU enters stop
IREFS=0
CLKS=00
PLLS=0
Stop
PLL Bypassed
External (PBE)
IREFS=0
CLKS=10
PLLS=1
BDM Enabled
or LP=0
PLL Engaged
External (PEE)
IREFS=0
CLKS=00
PLLS=1
Returns to state that was active
before MCU entered stop, unless
RESET occurs while in stop.
Figure 8-8. Clock Switching Modes
MC9S08DZ60 Series Data Sheet, Rev. 4
146
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
The nine states of the MCG are shown as a state diagram and are described below. The arrows indicate the
allowed movements between the states.
8.4.1.1
FLL Engaged Internal (FEI)
FLL engaged internal (FEI) is the default mode of operation and is entered when all the following
conditions occur:
• CLKS bits are written to 00
• IREFS bit is written to 1
• PLLS bit is written to 0
• RDIV bits are written to 000. Since the internal reference clock frequency should already be in the
range of 31.25 kHz to 39.0625 kHz after it is trimmed, no further frequency divide is necessary.
In FLL engaged internal mode, the MCGOUT clock is derived from the FLL clock, which is controlled by
the internal reference clock. The FLL clock frequency locks to 1024 times the reference frequency, as
selected by the RDIV bits. The MCGLCLK is derived from the FLL and the PLL is disabled in a low power
state.
8.4.1.2
FLL Engaged External (FEE)
The FLL engaged external (FEE) mode is entered when all the following conditions occur:
•
•
•
•
CLKS bits are written to 00
IREFS bit is written to 0
PLLS bit is written to 0
RDIV bits are written to divide reference clock to be within the range of 31.25 kHz to 39.0625 kHz
In FLL engaged external mode, the MCGOUT clock is derived from the FLL clock which is controlled by
the external reference clock. The external reference clock which is enabled can be an external
crystal/resonator or it can be another external clock source.The FLL clock frequency locks to 1024 times
the reference frequency, as selected by the RDIV bits. The MCGLCLK is derived from the FLL and the
PLL is disabled in a low power state.
8.4.1.3
FLL Bypassed Internal (FBI)
In FLL bypassed internal (FBI) mode, the MCGOUT clock is derived from the internal reference clock
and the FLL is operational but its output clock is not used. This mode is useful to allow the FLL to acquire
its target frequency while the MCGOUT clock is driven from the internal reference clock.
The FLL bypassed internal mode is entered when all the following conditions occur:
• CLKS bits are written to 01
• IREFS bit is written to 1
• PLLS bit is written to 0
• RDIV bits are written to 000. Since the internal reference clock frequency should already be in the
range of 31.25 kHz to 39.0625 kHz after it is trimmed, no further frequency divide is necessary.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
147
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
•
LP bit is written to 0
In FLL bypassed internal mode, the MCGOUT clock is derived from the internal reference clock. The FLL
clock is controlled by the internal reference clock, and the FLL clock frequency locks to 1024 times the
reference frequency, as selected by the RDIV bits. The MCGLCLK is derived from the FLL and the PLL
is disabled in a low power state.
8.4.1.4
FLL Bypassed External (FBE)
In FLL bypassed external (FBE) mode, the MCGOUT clock is derived from the external reference clock
and the FLL is operational but its output clock is not used. This mode is useful to allow the FLL to acquire
its target frequency while the MCGOUT clock is driven from the external reference clock.
The FLL bypassed external mode is entered when all the following conditions occur:
• CLKS bits are written to 10
• IREFS bit is written to 0
• PLLS bit is written to 0
• RDIV bits are written to divide reference clock to be within the range of 31.25 kHz to 39.0625 kHz
• LP bit is written to 0
In FLL bypassed external mode, the MCGOUT clock is derived from the external reference clock. The
external reference clock which is enabled can be an external crystal/resonator or it can be another external
clock source.The FLL clock is controlled by the external reference clock, and the FLL clock frequency
locks to 1024 times the reference frequency, as selected by the RDIV bits. The MCGLCLK is derived from
the FLL and the PLL is disabled in a low power state.
NOTE
It is possible to briefly operate in FBE mode with an FLL reference clock
frequency that is greater than the specified maximum frequency. This can be
necessary in applications that operate in PEE mode using an external crystal
with a frequency above 5 MHz. Please see 8.5.2.4, “Example # 4: Moving
from FEI to PEE Mode: External Crystal = 8 MHz, Bus Frequency = 8 MHz
for a detailed example.
8.4.1.5
PLL Engaged External (PEE)
The PLL engaged external (PEE) mode is entered when all the following conditions occur:
•
•
•
•
CLKS bits are written to 00
IREFS bit is written to 0
PLLS bit is written to 1
RDIV bits are written to divide reference clock to be within the range of 1 MHz to 2 MHz
In PLL engaged external mode, the MCGOUT clock is derived from the PLL clock which is controlled by
the external reference clock. The external reference clock which is enabled can be an external
crystal/resonator or it can be another external clock source The PLL clock frequency locks to a
MC9S08DZ60 Series Data Sheet, Rev. 4
148
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
multiplication factor, as selected by the VDIV bits, times the reference frequency, as selected by the RDIV
bits. If BDM is enabled then the MCGLCLK is derived from the DCO (open-loop mode) divided by two.
If BDM is not enabled then the FLL is disabled in a low power state.
8.4.1.6
PLL Bypassed External (PBE)
In PLL bypassed external (PBE) mode, the MCGOUT clock is derived from the external reference clock
and the PLL is operational but its output clock is not used. This mode is useful to allow the PLL to acquire
its target frequency while the MCGOUT clock is driven from the external reference clock.
The PLL bypassed external mode is entered when all the following conditions occur:
• CLKS bits are written to 10
• IREFS bit is written to 0
• PLLS bit is written to 1
• RDIV bits are written to divide reference clock to be within the range of 1 MHz to 2 MHz
• LP bit is written to 0
In PLL bypassed external mode, the MCGOUT clock is derived from the external reference clock. The
external reference clock which is enabled can be an external crystal/resonator or it can be another external
clock source. The PLL clock frequency locks to a multiplication factor, as selected by the VDIV bits, times
the reference frequency, as selected by the RDIV bits. If BDM is enabled then the MCGLCLK is derived
from the DCO (open-loop mode) divided by two. If BDM is not enabled then the FLL is disabled in a low
power state.
8.4.1.7
Bypassed Low Power Internal (BLPI)
The bypassed low power internal (BLPI) mode is entered when all the following conditions occur:
• CLKS bits are written to 01
• IREFS bit is written to 1
• PLLS bit is written to 0
• LP bit is written to 1
• BDM mode is not active
In bypassed low power internal mode, the MCGOUT clock is derived from the internal reference clock.
The PLL and the FLL are disabled at all times in BLPI mode and the MCGLCLK will not be available for
BDC communications If the BDM becomes active the mode will switch to FLL bypassed internal (FBI)
mode.
8.4.1.8
Bypassed Low Power External (BLPE)
The bypassed low power external (BLPE) mode is entered when all the following conditions occur:
• CLKS bits are written to 10
• IREFS bit is written to 0
• PLLS bit is written to 0 or 1
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
149
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
•
•
LP bit is written to 1
BDM mode is not active
In bypassed low power external mode, the MCGOUT clock is derived from the external reference clock.
The external reference clock which is enabled can be an external crystal/resonator or it can be another
external clock source.
The PLL and the FLL are disabled at all times in BLPE mode and the MCGLCLK will not be available
for BDC communications. If the BDM becomes active the mode will switch to one of the bypassed
external modes as determined by the state of the PLLS bit.
8.4.1.9
Stop
Stop mode is entered whenever the MCU enters a STOP state. In this mode, the FLL and PLL are disabled
and all MCG clock signals are static except in the following cases:
MCGIRCLK will be active in stop mode when all the following conditions occur:
• IRCLKEN = 1
• IREFSTEN = 1
MCGERCLK will be active in stop mode when all the following conditions occur:
• ERCLKEN = 1
• EREFSTEN = 1
8.4.2
Mode Switching
When switching between engaged internal and engaged external modes the IREFS bit can be changed at
anytime, but the RDIV bits must be changed simultaneously so that the reference frequency stays in the
range required by the state of the PLLS bit (31.25 kHz to 39.0625 kHz if the FLL is selected, or 1 MHz to
2 MHz if the PLL is selected). After a change in the IREFS value the FLL or PLL will begin locking again
after the switch is completed. The completion of the switch is shown by the IREFST bit .
For the special case of entering stop mode immediately after switching to FBE mode, if the external clock
and the internal clock are disabled in stop mode, (EREFSTEN = 0 and IREFSTEN = 0), it is necessary to
allow 100us after the IREFST bit is cleared to allow the internal reference to shutdown. For most cases the
delay due to instruction execution times will be sufficient.
The CLKS bits can also be changed at anytime, but in order for the MCGLCLK to be configured correctly
the RDIV bits must be changed simultaneously so that the reference frequency stays in the range required
by the state of the PLLS bit (31.25 kHz to 39.0625 kHz if the FLL is selected, or 1 MHz to 2MHz if the
PLL is selected). The actual switch to the newly selected clock will be shown by the CLKST bits. If the
newly selected clock is not available, the previous clock will remain selected.
For details see Figure 8-8.
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8.4.3
Bus Frequency Divider
The BDIV bits can be changed at anytime and the actual switch to the new frequency will occur
immediately.
8.4.4
Low Power Bit Usage
The low power bit (LP) is provided to allow the FLL or PLL to be disabled and thus conserve power when
these systems are not being used. However, in some applications it may be desirable to enable the FLL or
PLL and allow it to lock for maximum accuracy before switching to an engaged mode. Do this by writing
the LP bit to 0.
8.4.5
Internal Reference Clock
When IRCLKEN is set the internal reference clock signal will be presented as MCGIRCLK, which can be
used as an additional clock source. The MCGIRCLK frequency can be re-targeted by trimming the period
of the internal reference clock. This can be done by writing a new value to the TRIM bits in the MCGTRM
register. Writing a larger value will decrease the MCGIRCLK frequency, and writing a smaller value to
the MCGTRM register will increase the MCGIRCLK frequency. The TRIM bits will effect the MCGOUT
frequency if the MCG is in FLL engaged internal (FEI), FLL bypassed internal (FBI), or bypassed low
power internal (BLPI) mode. The TRIM and FTRIM value is initialized by POR but is not affected by other
resets.
Until MCGIRCLK is trimmed, programming low reference divider (RDIV) factors may result in
MCGOUT frequencies that exceed the maximum chip-level frequency and violate the chip-level clock
timing specifications (see the Device Overview chapter).
If IREFSTEN and IRCLKEN bits are both set, the internal reference clock will keep running during stop
mode in order to provide a fast recovery upon exiting stop.
8.4.6
External Reference Clock
The MCG module can support an external reference clock with frequencies between 31.25 kHz to 5 MHz
in FEE and FBE modes, 1 MHz to 16 MHz in PEE and PBE modes, and 0 to 40 MHz in BLPE mode.
When ERCLKEN is set, the external reference clock signal will be presented as MCGERCLK, which can
be used as an additional clock source. When IREFS = 1, the external reference clock will not be used by
the FLL or PLL and will only be used as MCGERCLK. In these modes, the frequency can be equal to the
maximum frequency the chip-level timing specifications will support (see the Device Overview chapter).
If EREFSTEN and ERCLKEN bits are both set or the MCG is in FEE, FBE, PEE, PBE or BLPE mode,
the external reference clock will keep running during stop mode in order to provide a fast recovery upon
exiting stop.
If CME bit is written to 1, the clock monitor is enabled. If the external reference falls below a certain
frequency (floc_high or floc_low depending on the RANGE bit in the MCGC2), the MCU will reset. The LOC
bit in the System Reset Status (SRS) register will be set to indicate the error.
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8.4.7
Fixed Frequency Clock
The MCG presents the divided reference clock as MCGFFCLK for use as an additional clock source. The
MCGFFCLK frequency must be no more than 1/4 of the MCGOUT frequency to be valid. Because of this
requirement, the MCGFFCLK is not valid in bypass modes for the following combinations of BDIV and
RDIV values:
• BDIV=00 (divide by 1), RDIV < 010
• BDIV=01 (divide by 2), RDIV < 011
When MCGFFCLK is valid then MCGFFCLKVALID is set to 1. When MCGFFCLK is not valid then
MCGFFCLKVALID is set to 0.
8.5
Initialization / Application Information
This section describes how to initialize and configure the MCG module in application. The following
sections include examples on how to initialize the MCG and properly switch between the various available
modes.
8.5.1
MCG Module Initialization Sequence
The MCG comes out of reset configured for FEI mode with the BDIV set for divide-by-2. The internal
reference will stabilize in tirefst microseconds before the FLL can acquire lock. As soon as the internal
reference is stable, the FLL will acquire lock in tfll_lock milliseconds.
Upon POR, the internal reference will require trimming to guarantee an accurate clock. Freescale
recommends using FLASH location 0xFFAE for storing the fine trim bit, FTRIM in the MCGSC register,
and 0xFFAF for storing the 8-bit trim value in the MCGTRM register. The MCU will not automatically
copy the values in these FLASH locations to the respective registers. Therefore, user code must copy these
values from FLASH to the registers.
NOTE
The BDIV value should not be changed to divide-by-1 without first
trimming the internal reference. Failure to do so could result in the MCU
running out of specification.
8.5.1.1
Initializing the MCG
Because the MCG comes out of reset in FEI mode, the only MCG modes which can be directly switched
to upon reset are FEE, FBE, and FBI modes (see Figure 8-8). Reaching any of the other modes requires
first configuring the MCG for one of these three initial modes. Care must be taken to check relevant status
bits in the MCGSC register reflecting all configuration changes within each mode.
To change from FEI mode to FEE or FBE modes, follow this procedure:
1. Enable the external clock source by setting the appropriate bits in MCGC2.
2. Write to MCGC1 to select the clock mode.
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— If entering FEE, set RDIV appropriately, clear the IREFS bit to switch to the external reference,
and leave the CLKS bits at %00 so that the output of the FLL is selected as the system clock
source.
— If entering FBE, clear the IREFS bit to switch to the external reference and change the CLKS
bits to %10 so that the external reference clock is selected as the system clock source. The
RDIV bits should also be set appropriately here according to the external reference frequency
because although the FLL is bypassed, it is still on in FBE mode.
— The internal reference can optionally be kept running by setting the IRCLKEN bit. This is
useful if the application will switch back and forth between internal and external modes. For
minimum power consumption, leave the internal reference disabled while in an external clock
mode.
3. After the proper configuration bits have been set, wait for the affected bits in the MCGSC register
to be changed appropriately, reflecting that the MCG has moved into the proper mode.
— If ERCLKEN was set in step 1 or the MCG is in FEE, FBE, PEE, PBE, or BLPE mode, and
EREFS was also set in step 1, wait here for the OSCINIT bit to become set indicating that the
external clock source has finished its initialization cycles and stabilized. Typical crystal startup
times are given in Appendix A, “Electrical Characteristics”.
— If in FEE mode, check to make sure the IREFST bit is cleared and the LOCK bit is set before
moving on.
— If in FBE mode, check to make sure the IREFST bit is cleared, the LOCK bit is set, and the
CLKST bits have changed to %10 indicating the external reference clock has been
appropriately selected. Although the FLL is bypassed in FBE mode, it is still on and will lock
in FBE mode.
To change from FEI clock mode to FBI clock mode, follow this procedure:
1. Change the CLKS bits to %01 so that the internal reference clock is selected as the system clock
source.
2. Wait for the CLKST bits in the MCGSC register to change to %01, indicating that the internal
reference clock has been appropriately selected.
8.5.2
MCG Mode Switching
When switching between operational modes of the MCG, certain configuration bits must be changed in
order to properly move from one mode to another. Each time any of these bits are changed (PLLS, IREFS,
CLKS, or EREFS), the corresponding bits in the MCGSC register (PLLST, IREFST, CLKST, or
OSCINIT) must be checked before moving on in the application software.
Additionally, care must be taken to ensure that the reference clock divider (RDIV) is set properly for the
mode being switched to. For instance, in PEE mode, if using a 4 MHz crystal, RDIV must be set to %001
(divide-by-2) or %010 (divide -by-4) in order to divide the external reference down to the required
frequency between 1 and 2 MHz.
The RDIV and IREFS bits should always be set properly before changing the PLLS bit so that the FLL or
PLL clock has an appropriate reference clock frequency to switch to.
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The table below shows MCGOUT frequency calculations using RDIV, BDIV, and VDIV settings for each
clock mode. The bus frequency is equal to MCGOUT divided by 2.
Table 8-6. MCGOUT Frequency Calculation Options
fMCGOUT1
Clock Mode
Note
FEI (FLL engaged internal)
(fint * 1024) / B
Typical fMCGOUT = 16 MHz
immediately after reset. RDIV
bits set to %000.
FEE (FLL engaged external)
(fext / R *1024) / B
fext / R must be in the range of
31.25 kHz to 39.0625 kHz
FBE (FLL bypassed external)
fext / B
fext / R must be in the range of
31.25 kHz to 39.0625 kHz
FBI (FLL bypassed internal)
fint / B
Typical fint = 32 kHz
PEE (PLL engaged external)
[(fext / R) * M] / B
fext / R must be in the range of 1
MHz to 2 MHz
PBE (PLL bypassed external)
fext / B
fext / R must be in the range of 1
MHz to 2 MHz
BLPI (Bypassed low power internal)
fint / B
BLPE (Bypassed low power external)
fext / B
1
R is the reference divider selected by the RDIV bits, B is the bus frequency divider selected by the BDIV bits,
and M is the multiplier selected by the VDIV bits.
This section will include 3 mode switching examples using a 4 MHz external crystal. If using an external
clock source less than 1 MHz, the MCG should not be configured for any of the PLL modes (PEE and
PBE).
8.5.2.1
Example # 1: Moving from FEI to PEE Mode: External Crystal = 4 MHz,
Bus Frequency = 8 MHz
In this example, the MCG will move through the proper operational modes from FEI to PEE mode until
the 4 MHz crystal reference frequency is set to achieve a bus frequency of 8 MHz. Because the MCG is in
FEI mode out of reset, this example also shows how to initialize the MCG for PEE mode out of reset. First,
the code sequence will be described. Then a flowchart will be included which illustrates the sequence.
1. First, FEI must transition to FBE mode:
a) MCGC2 = 0x36 (%00110110)
– BDIV (bits 7 and 6) set to %00, or divide-by-1
– RANGE (bit 5) set to 1 because the frequency of 4 MHz is within the high frequency range
– HGO (bit 4) set to 1 to configure external oscillator for high gain operation
– EREFS (bit 2) set to 1, because a crystal is being used
– ERCLKEN (bit 1) set to 1 to ensure the external reference clock is active
b) Loop until OSCINIT (bit 1) in MCGSC is 1, indicating the crystal selected by the EREFS bit
has been initialized.
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c) MCGC1 = 0xB8 (%10111000)
– CLKS (bits 7 and 6) set to %10 in order to select external reference clock as system clock
source
– RDIV (bits 5-3) set to %111, or divide-by-128 because 4 MHz / 128 = 31.25 kHz which is
in the 31.25 kHz to 39.0625 kHz range required by the FLL
– IREFS (bit 2) cleared to 0, selecting the external reference clock
d) Loop until IREFST (bit 4) in MCGSC is 0, indicating the external reference is the current
source for the reference clock
e) Loop until CLKST (bits 3 and 2) in MCGSC are %10, indicating that the external reference
clock is selected to feed MCGOUT
2. Then, FBE must transition either directly to PBE mode or first through BLPE mode and then to
PBE mode:
a) BLPE: If a transition through BLPE mode is desired, first set LP (bit 3) in MCGC2 to 1.
b) BLPE/PBE: MCGC1 = 0x90 (%10010000)
– RDIV (bits 5-3) set to %010, or divide-by-4 because 4 MHz / 4 = 1 MHz which is in the 1
MHz to 2 MHz range required by the PLL. In BLPE mode, the configuration of the RDIV
does not matter because both the FLL and PLL are disabled. Changing them only sets up the
the dividers for PLL usage in PBE mode
c) BLPE/PBE: MCGC3 = 0x44 (%01000100)
– PLLS (bit 6) set to 1, selects the PLL. In BLPE mode, changing this bit only prepares the
MCG for PLL usage in PBE mode
– VDIV (bits 3-0) set to %0100, or multiply-by-16 because 1 MHz reference * 16 = 16 MHz.
In BLPE mode, the configuration of the VDIV bits does not matter because the PLL is
disabled. Changing them only sets up the multiply value for PLL usage in PBE mode
d) BLPE: If transitioning through BLPE mode, clear LP (bit 3) in MCGC2 to 0 here to switch to
PBE mode
e) PBE: Loop until PLLST (bit 5) in MCGSC is set, indicating that the current source for the
PLLS clock is the PLL
f) PBE: Then loop until LOCK (bit 6) in MCGSC is set, indicating that the PLL has acquired lock
3. Last, PBE mode transitions into PEE mode:
a) MCGC1 = 0x10 (%00010000)
– CLKS (bits7 and 6) in MCGSC1 set to %00 in order to select the output of the PLL as the
system clock source
b) Loop until CLKST (bits 3 and 2) in MCGSC are %11, indicating that the PLL output is selected
to feed MCGOUT in the current clock mode
– Now, With an RDIV of divide-by-4, a BDIV of divide-by-1, and a VDIV of multiply-by-16,
MCGOUT = [(4 MHz / 4) * 16] / 1 = 16 MHz, and the bus frequency is MCGOUT / 2, or 8
MHz
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START
IN FEI MODE
MCGC2 = $36
IN
BLPE MODE ?
(LP=1)
CHECK
NO
NO
YES
OSCINIT = 1 ?
MCGC2 = $36
(LP = 0)
YES
MCGC1 = $B8
CHECK
PLLST = 1?
CHECK
NO
NO
YES
IREFST = 0?
YES
CHECK
LOCK = 1?
CHECK
CLKST = %10?
NO
NO
YES
MCGC1 = $10
YES
ENTER
BLPE MODE ?
NO
CHECK
CLKST = %11?
NO
YES
YES
MCGC2 = $3E
(LP = 1)
CONTINUE
IN PEE MODE
MCGC1 = $90
MCGC3 = $44
Figure 8-9. Flowchart of FEI to PEE Mode Transition using a 4 MHz crystal
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Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.5.2.2
Example # 2: Moving from PEE to BLPI Mode: External Crystal = 4 MHz,
Bus Frequency =16 kHz
In this example, the MCG will move through the proper operational modes from PEE mode with a 4 MHz
crystal configured for an 8 MHz bus frequency (see previous example) to BLPI mode with a 16 kHz bus
frequency.First, the code sequence will be described. Then a flowchart will be included which illustrates
the sequence.
1. First, PEE must transition to PBE mode:
a) MCGC1 = 0x90 (%10010000)
– CLKS (bits 7 and 6) set to %10 in order to switch the system clock source to the external
reference clock
b) Loop until CLKST (bits 3 and 2) in MCGSC are %10, indicating that the external reference
clock is selected to feed MCGOUT
2. Then, PBE must transition either directly to FBE mode or first through BLPE mode and then to
FBE mode:
a) BLPE: If a transition through BLPE mode is desired, first set LP (bit 3) in MCGC2 to 1
b) BLPE/FBE: MCGC1 = 0xB8 (%10111000)
– RDIV (bits 5-3) set to %111, or divide-by-128 because 4 MHz / 128 = 31.25 kHz which is
in the 31.25 kHz to 39.0625 kHz range required by the FLL. In BLPE mode, the
configuration of the RDIV does not matter because both the FLL and PLL are disabled.
Changing them only sets up the dividers for FLL usage in FBE mode
c) BLPE/FBE: MCGC3 = 0x04 (%00000100)
– PLLS (bit 6) clear to 0 to select the FLL. In BLPE mode, changing this bit only prepares the
MCG for FLL usage in FBE mode. With PLLS = 0, the VDIV value does not matter.
d) BLPE: If transitioning through BLPE mode, clear LP (bit 3) in MCGC2 to 0 here to switch to
FBE mode
e) FBE: Loop until PLLST (bit 5) in MCGSC is clear, indicating that the current source for the
PLLS clock is the FLL
f) FBE: Optionally, loop until LOCK (bit 6) in the MCGSC is set, indicating that the FLL has
acquired lock. Although the FLL is bypassed in FBE mode, it is still enabled and running.
3. Next, FBE mode transitions into FBI mode:
a) MCGC1 = 0x44 (%01000100)
– CLKS (bits7 and 6) in MCGSC1 set to %01 in order to switch the system clock to the
internal reference clock
– IREFS (bit 2) set to 1 to select the internal reference clock as the reference clock source
– RDIV (bits 5-3) set to %000, or divide-by-1 because the trimmed internal reference should
be within the 31.25 kHz to 39.0625 kHz range required by the FLL
b) Loop until IREFST (bit 4) in MCGSC is 1, indicating the internal reference clock has been
selected as the reference clock source
c) Loop until CLKST (bits 3 and 2) in MCGSC are %01, indicating that the internal reference
clock is selected to feed MCGOUT
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4. Lastly, FBI transitions into BLPI mode.
a) MCGC2 = 0x08 (%00001000)
– LP (bit 3) in MCGSC is 1
START
IN PEE MODE
MCGC1 = $90
CHECK
PLLST = 0?
CHECK
NO
CLKST = %10 ?
YES
YES
OPTIONAL:
CHECK LOCK
= 1?
ENTER
NO
NO
NO
BLPE MODE ?
YES
MCGC1 = $44
YES
MCGC2 = $3E
CHECK
IREFST = 0?
MCGC1 = $B8
MCGC3 = $04
IN
BLPE MODE ?
(LP=1)
NO
YES
NO
CHECK
CLKST = %01?
NO
YES
YES
MCGC2 = $36
(LP = 0)
MCGC2 = $08
CONTINUE
IN BLPI MODE
Figure 8-10. Flowchart of PEE to BLPI Mode Transition using a 4 MHz crystal
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8.5.2.3
Example #3: Moving from BLPI to FEE Mode: External Crystal = 4 MHz,
Bus Frequency = 16 MHz
In this example, the MCG will move through the proper operational modes from BLPI mode at a 16 kHz
bus frequency running off of the internal reference clock (see previous example) to FEE mode using a 4
MHz crystal configured for a 16 MHz bus frequency. First, the code sequence will be described. Then a
flowchart will be included which illustrates the sequence.
1. First, BLPI must transition to FBI mode.
a) MCGC2 = 0x00 (%00000000)
– LP (bit 3) in MCGSC is 0
b) Optionally, loop until LOCK (bit 6) in the MCGSC is set, indicating that the FLL has acquired
lock. Although the FLL is bypassed in FBI mode, it is still enabled and running.
2. Next, FBI will transition to FEE mode.
a) MCGC2 = 0x36 (%00110110)
– RANGE (bit 5) set to 1 because the frequency of 4 MHz is within the high frequency range
– HGO (bit 4) set to 1 to configure external oscillator for high gain operation
– EREFS (bit 2) set to 1, because a crystal is being used
– ERCLKEN (bit 1) set to 1 to ensure the external reference clock is active
b) Loop until OSCINIT (bit 1) in MCGSC is 1, indicating the crystal selected by the EREFS bit
has been initialized.
c) MCGC1 = 0x38 (%00111000)
– CLKS (bits 7 and 6) set to %00 in order to select the output of the FLL as system clock
source
– RDIV (bits 5-3) set to %111, or divide-by-128 because 4 MHz / 128 = 31.25 kHz which is
in the 31.25 kHz to 39.0625 kHz range required by the FLL
– IREFS (bit 1) cleared to 0, selecting the external reference clock
d) Loop until IREFST (bit 4) in MCGSC is 0, indicating the external reference clock is the current
source for the reference clock
e) Optionally, loop until LOCK (bit 6) in the MCGSC is set, indicating that the FLL has
reacquired lock.
f) Loop until CLKST (bits 3 and 2) in MCGSC are %00, indicating that the output of the FLL is
selected to feed MCGOUT
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START
IN BLPI MODE
CHECK
NO
IREFST = 0?
MCGC2 = $00
YES
OPTIONAL:
CHECK LOCK
= 1?
NO
OPTIONAL:
CHECK LOCK
= 1?
NO
YES
YES
MCGC2 = $36
CHECK
CLKST = %00?
CHECK
NO
NO
YES
OSCINIT = 1 ?
CONTINUE
YES
IN FEE MODE
MCGC1 = $38
Figure 8-11. Flowchart of BLPI to FEE Mode Transition using a 4 MHz crystal
8.5.2.4
Example # 4: Moving from FEI to PEE Mode: External Crystal = 8 MHz,
Bus Frequency = 8 MHz
In this example, the MCG will move through the proper operational modes from FEI to PEE mode until
the 8 MHz crystal reference frequency is set to achieve a bus frequency of 8 MHz.
This example is similar to example number one except that in this case the frequency of the external crystal
is 8 MHz instead of 4 MHz. Special consideration must be taken with this case since there is a period of
time along the way from FEI mode to PEE mode where the FLL operates based on a reference clock with
a frequency that is greater than the maximum allowed for the FLL. This occurs because with an 8 MHz
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external crystal and a maximum reference divider factor of 128, the resulting frequency of the reference
clock for the FLL is 62.5 kHz (greater than the 39.0625 kHz maximum allowed).
Care must be taken in the software to minimize the amount of time spent in this state where the FLL is
operating in this condition.
The following code sequence describes how to move from FEI mode to PEE mode until the 8 MHz crystal
reference frequency is set to achieve a bus frequency of 8 MHz. Because the MCG is in FEI mode out of
reset, this example also shows how to initialize the MCG for PEE mode out of reset. First, the code
sequence will be described. Then a flowchart will be included which illustrates the sequence.
1. First, FEI must transition to FBE mode:
a) MCGC2 = 0x36 (%00110110)
– BDIV (bits 7 and 6) set to %00, or divide-by-1
– RANGE (bit 5) set to 1 because the frequency of 8 MHz is within the high frequency range
– HGO (bit 4) set to 1 to configure external oscillator for high gain operation
– EREFS (bit 2) set to 1, because a crystal is being used
– ERCLKEN (bit 1) set to 1 to ensure the external reference clock is active
b) Loop until OSCINIT (bit 1) in MCGSC is 1, indicating the crystal selected by the EREFS bit
has been initialized.
c) Block Interrupts (If applicable by setting the interrupt bit in the CCR).
d) MCGC1 = 0xB8 (%10111000)
– CLKS (bits 7 and 6) set to %10 in order to select external reference clock as system clock
source
– RDIV (bits 5-3) set to %111, or divide-by-128.
NOTE
8 MHz / 128 = 62.5 kHz which is greater than the 31.25 kHz to 39.0625 kHz
range required by the FLL. Therefore after the transition to FBE is
complete, software must progress through to BLPE mode immediately by
setting the LP bit in MCGC2.
– IREFS (bit 2) cleared to 0, selecting the external reference clock
e) Loop until IREFST (bit 4) in MCGSC is 0, indicating the external reference is the current
source for the reference clock
f) Loop until CLKST (bits 3 and 2) in MCGSC are %10, indicating that the external reference
clock is selected to feed MCGOUT
2. Then, FBE mode transitions into BLPE mode:
a) MCGC2 = 0x3E (%00111110)
– LP (bit 3) in MCGC2 to 1 (BLPE mode entered)
NOTE
There must be no extra steps (including interrupts) between steps 1d and 2a.
b) Enable Interrupts (if applicable by clearing the interrupt bit in the CCR).
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c) MCGC1 = 0x98 (%10011000)
– RDIV (bits 5-3) set to %011, or divide-by-8 because 8 MHz / 8= 1 MHz which is in the 1
MHz to 2 MHz range required by the PLL. In BLPE mode, the configuration of the RDIV
does not matter because both the FLL and PLL are disabled. Changing them only sets up the
the dividers for PLL usage in PBE mode
d) MCGC3 = 0x44 (%01000100)
– PLLS (bit 6) set to 1, selects the PLL. In BLPE mode, changing this bit only prepares the
MCG for PLL usage in PBE mode
– VDIV (bits 3-0) set to %0100, or multiply-by-16 because 1 MHz reference * 16 = 16 MHz.
In BLPE mode, the configuration of the VDIV bits does not matter because the PLL is
disabled. Changing them only sets up the multiply value for PLL usage in PBE mode
e) Loop until PLLST (bit 5) in MCGSC is set, indicating that the current source for the PLLS
clock is the PLL
3. Then, BLPE mode transitions into PBE mode:
a) Clear LP (bit 3) in MCGC2 to 0 here to switch to PBE mode
b) Then loop until LOCK (bit 6) in MCGSC is set, indicating that the PLL has acquired lock
4. Last, PBE mode transitions into PEE mode:
a) MCGC1 = 0x18 (%00011000)
– CLKS (bits7 and 6) in MCGSC1 set to %00 in order to select the output of the PLL as the
system clock source
b) Loop until CLKST (bits 3 and 2) in MCGSC are %11, indicating that the PLL output is selected
to feed MCGOUT in the current clock mode
– Now, With an RDIV of divide-by-8, a BDIV of divide-by-1, and a VDIV of multiply-by-16,
MCGOUT = [(8 MHz / 8) * 16] / 1 = 16 MHz, and the bus frequency is MCGOUT / 2, or 8
MHz
MC9S08DZ60 Series Data Sheet, Rev. 4
162
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
START
IN FEI MODE
MCGC2 = $36
CHECK
NO
CHECK
PLLST = 1?
NO
OSCINIT = 1 ?
YES
YES
MCGC2 = $36
(LP = 0)
MCGC1 = $B8
CHECK
NO
IREFST = 0?
CHECK
LOCK = 1?
NO
YES
YES
CHECK
CLKST = %10?
NO
MCGC1 = $18
YES
CHECK
CLKST = %11?
MCGC2 = $3E
(LP = 1)
NO
YES
MCGC1 = $98
MCGC3 = $44
CONTINUE
IN PEE MODE
Figure 8-12. Flowchart of FEI to PEE Mode Transition using a 8 MHz crystal
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
163
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
8.5.3
Calibrating the Internal Reference Clock (IRC)
The IRC is calibrated by writing to the MCGTRM register first, then using the FTRIM bit to “fine tune”
the frequency. We will refer to this total 9-bit value as the trim value, ranging from 0x000 to 0x1FF, where
the FTRIM bit is the LSB.
The trim value after a POR is always 0x100 (MCGTRM = 0x80 and FTRIM = 0). Writing a larger value
will decrease the frequency and smaller values will increase the frequency. The trim value is linear with
the period, except that slight variations in wafer fab processing produce slight non-linearities between trim
value and period. These non-linearities are why an iterative trimming approach to search for the best trim
value is recommended. In Example #5: Internal Reference Clock Trim this approach will be demonstrated.
After a trim value has been found for a device, this value can be stored in FLASH memory to save the
value. If power is removed from the device, the IRC can easily be re-trimmed by copying the saved value
from FLASH to the MCG registers. Freescale identifies recommended FLASH locations for storing the
trim value for each MCU. Consult the memory map in the data sheet for these locations. On devices that
are factory trimmed, the factory trim value will be stored in these locations.
8.5.3.1
Example #5: Internal Reference Clock Trim
For applications that require a tight frequency tolerance, a trimming procedure is provided that will allow
a very accurate internal clock source. This section outlines one example of trimming the internal oscillator.
Many other possible trimming procedures are valid and can be used.
In the example below, the MCG trim will be calibrated for the 9-bit MCGTRM and FTRIM collective
value. This value will be referred to as TRMVAL.
MC9S08DZ60 Series Data Sheet, Rev. 4
164
Freescale Semiconductor
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
Initial conditions:
1) Clock supplied from ATE has 500 μs duty period
2) MCG configured for internal reference with 8MHz bus
START TRIM PROCEDURE
TRMVAL = $100
n=1
MEASURE
INCOMING CLOCK WIDTH
(COUNT = # OF BUS CLOCKS / 8)
COUNT < EXPECTED = 500
(RUNNING TOO SLOW)
.
CASE STATEMENT
COUNT = EXPECTED = 500
COUNT > EXPECTED = 500
(RUNNING TOO FAST)
TRMVAL =
TRMVAL - 256/ (2**n)
(DECREASING TRMVAL
INCREASES THE FREQUENCY)
TRMVAL =
TRMVAL + 256/ (2**n)
(INCREASING TRMVAL
DECREASES THE FREQUENCY)
STORE MCGTRM AND
FTRIM VALUES IN
NON-VOLATILE MEMORY
CONTINUE
n = n+1
YES
IS n > 9?
NO
Figure 8-13. Trim Procedure
In this particular case, the MCU has been attached to a PCB and the entire assembly is undergoing final
test with automated test equipment. A separate signal or message is provided to the MCU operating under
user provided software control. The MCU initiates a trim procedure as outlined in Figure 8-13 while the
tester supplies a precision reference signal.
If the intended bus frequency is near the maximum allowed for the device, it is recommended to trim using
a reference divider value (RDIV setting) of twice the final value. After the trim procedure is complete, the
reference divider can be restored. This will prevent accidental overshoot of the maximum clock frequency.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
165
Chapter 8 Multi-Purpose Clock Generator (S08MCGV1)
MC9S08DZ60 Series Data Sheet, Rev. 4
166
Freescale Semiconductor
Chapter 9
Analog Comparator (S08ACMPV3)
9.1
Introduction
The analog comparator module (ACMP) provides a circuit for comparing two analog input voltages or for
comparing one analog input voltage to an internal reference voltage. The comparator circuit is designed to
operate across the full range of the supply voltage (rail-to-rail operation).
All MC9S08DZ60 Series MCUs have two full function ACMPs in a 64-pin package. MCUs in the 48-pin
package have two ACMPs, but the output of ACMP2 is not accessible. MCUs in the 32-pin package
contain one full function ACMP.
NOTE
MC9S08DZ60 Series devices operate at a higher voltage range (2.7 V to
5.5 V) and do not include stop1 mode. Please ignore references to stop1.
9.1.1
ACMP Configuration Information
When using the bandgap reference voltage for input to ACMP+, the user must enable the bandgap buffer
by setting BGBE =1 in SPMSC1 see Section 5.8.7, “System Power Management Status and Control 1
Register (SPMSC1).” For value of bandgap voltage reference see Section A.6, “DC Characteristics.”
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
167
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 9 Analog Comparator (S08ACMPV3)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 9-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
168
Freescale Semiconductor
Chapter 9 Analog Comparator (S08ACMPV3)
9.1.2
Features
The ACMP has the following features:
• Full rail to rail supply operation.
• Selectable interrupt on rising edge, falling edge, or either rising or falling edges of comparator
output.
• Option to compare to fixed internal bandgap reference voltage.
• Option to allow comparator output to be visible on a pin, ACMPxO.
9.1.3
Modes of Operation
This section defines the ACMP operation in wait, stop, and background debug modes.
9.1.3.1
ACMP in Wait Mode
The ACMP continues to run in wait mode if enabled before executing the appropriate instruction.
Therefore, the ACMP can be used to bring the MCU out of wait mode if the ACMP interrupt is enabled
(ACIE is set). For lowest possible current consumption, the ACMP should be disabled by software if not
required as an interrupt source during wait mode.
9.1.3.2
ACMP in Stop Modes
The ACMP is disabled in all stop modes, regardless of the settings before executing the stop instruction.
Therefore, the ACMP cannot be used as a wake up source from stop modes.
During stop2 mode, the ACMP module is fully powered down. Upon wake-up from stop2 mode, the
ACMP module is in the reset state.
During stop3 mode, clocks to the ACMP module are halted. No registers are affected. In addition, the
ACMP comparator circuit enters a low-power state. No compare operation occurs while in stop3.
If stop3 is exited with a reset, the ACMP is put into its reset state. If stop3 is exited with an interrupt, the
ACMP continues from the state it was in when stop3 was entered.
9.1.3.3
ACMP in Active Background Mode
When the microcontroller is in active background mode, the ACMP continues to operate normally.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
169
Chapter 9 Analog Comparator (S08ACMPV3)
9.1.4
Block Diagram
The block diagram for the analog comparator module is shown Figure 9-2.
Internal Bus
Internal
Reference
ACIE
ACBGS
ACME
Status & Control
Register
ACMPx
INTERRUPT
REQUEST
ACF
ACMPx+
+
set ACF
ACMOD
ACOPE
Interrupt
Control
Comparator
ACMPx-
ACMPxO
Figure 9-2. Analog Comparator (ACMP) Block Diagram
9.2
External Signal Description
The ACMP has two analog input pins, ACMPx+ and ACMPx− and one digital output pin ACMPxO. Each
of these pins can accept an input voltage that varies across the full operating voltage range of the MCU.
As shown in Figure 9-2, the ACMPx- pin is connected to the inverting input of the comparator, and the
ACMPx+ pin is connected to the comparator non-inverting input if ACBGS is a 0. As shown in Figure 9-2,
the ACMPxO pin can be enabled to drive an external pin.
The signal properties of ACMP are shown in Table 9-1.
Table 9-1. Signal Properties
Signal
Function
I/O
ACMPx-
Inverting analog input to the ACMP.
(Minus input)
I
ACMPx+
Non-inverting analog input to the ACMP.
(Positive input)
I
ACMPxO
Digital output of the ACMP.
O
MC9S08DZ60 Series Data Sheet, Rev. 4
170
Freescale Semiconductor
Chapter 9 Analog Comparator (S08ACMPV3)
9.3
Memory Map/Register Definition
The ACMP includes one register:
• An 8-bit status and control register
Refer to the direct-page register summary in the memory section of this document for the absolute address
assignments for the ACMP register.This section refers to register and control bits only by their names and
relative address offsets.
Some MCUs may have more than one ACMP, so register names include placeholder characters (x) to
identify which ACMP is being referenced.
Table 9-2. ACMP Register Summary
Name
7
6
5
4
ACME
ACBGS
ACF
ACIE
R
3
2
1
0
ACO
ACMPxSC
ACOPE
ACMOD
W
9.3.1
ACMPx Status and Control Register (ACMPxSC)
ACMPxSC contains the status flag and control bits used to enable and configure the ACMP.
7
6
5
4
3
ACME
ACBGS
ACF
ACIE
0
0
0
0
R
2
1
0
ACO
ACOPE
ACMOD
W
Reset:
0
0
0
0
Figure 9-3. ACMPx Status and Control Register (ACMPxSC)
Table 9-3. ACMPxSC Field Descriptions
Field
7
ACME
Description
Analog Comparator Module Enable. Enables the ACMP module.
0 ACMP not enabled
1 ACMP is enabled
6
ACBGS
Analog Comparator Bandgap Select. Selects between the bandgap reference voltage or the ACMPx+ pin as the
input to the non-inverting input of the analog comparator.
0 External pin ACMPx+ selected as non-inverting input to comparator
1 Internal reference select as non-inverting input to comparator
5
ACF
Analog Comparator Flag. ACF is set when a compare event occurs. Compare events are defined by ACMOD.
ACF is cleared by writing a one to it.
0 Compare event has not occurred
1 Compare event has occurred
4
ACIE
Analog Comparator Interrupt Enable. Enables the interrupt from the ACMP. When ACIE is set, an interrupt is
asserted when ACF is set.
0 Interrupt disabled
1 Interrupt enabled
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
171
Chapter 9 Analog Comparator (S08ACMPV3)
Table 9-3. ACMPxSC Field Descriptions (continued)
Field
3
ACO
Description
Analog Comparator Output. Reading ACO returns the current value of the analog comparator output. ACO is
reset to a 0 and reads as a 0 when the ACMP is disabled (ACME = 0).
2
ACOPE
Analog Comparator Output Pin Enable. Enables the comparator output to be placed onto the external pin,
ACMPxO.
0 Analog comparator output not available on ACMPxO
1 Analog comparator output is driven out on ACMPxO
1:0
ACMOD
Analog Comparator Mode. ACMOD selects the type of compare event which sets ACF.
00 Encoding 0 — Comparator output falling edge
01 Encoding 1 — Comparator output rising edge
10 Encoding 2 — Comparator output falling edge
11 Encoding 3 — Comparator output rising or falling edge
9.4
Functional Description
The analog comparator can compare two analog input voltages applied to ACMPx+ and ACMPx−, or it
can compare an analog input voltage applied to ACMPx− with an internal bandgap reference voltage.
ACBGS selects between the bandgap reference voltage or the ACMPx+ pin as the input to the
non-inverting input of the analog comparator. The comparator output is high when the non-inverting input
is greater than the inverting input, and is low when the non-inverting input is less than the inverting input.
ACMOD selects the condition that causes ACF to be set. ACF can be set on a rising edge of the comparator
output, a falling edge of the comparator output, or a rising or a falling edge (toggle). The comparator output
can be read directly through ACO. The comparator output can be driven onto the ACMPxO pin using
ACOPE.
MC9S08DZ60 Series Data Sheet, Rev. 4
172
Freescale Semiconductor
Chapter 10
Analog-to-Digital Converter (S08ADC12V1)
10.1
Introduction
The 12-bit analog-to-digital converter (ADC) is a successive approximation ADC designed for operation
within an integrated microcontroller system-on-chip.
NOTE
MC9S08DZ60 Series devices operate at a higher voltage range (2.7 V to
5.5 V) and do not include stop1 mode. Please ignore references to stop1.
10.1.1
Analog Power and Ground Signal Names
References to VDDAD and VSSAD in this chapter correspond to signals VDDA and VSSA, respectively.
10.1.2
Channel Assignments
NOTE
The ADC channel assignments for the MC9S08DZ60 Series devices are
shown in Table 10-1. Reserved channels convert to an unknown value.
This chapter shows bits for all S08ADC12V1 channels. MC9S08DZ60
Series MCUs do not use all of these channels. All bits corresponding to
channels that are not available on a device are reserved.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
173
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
Table 10-1. ADC Channel Assignment
ADCH
Channel
Input
ADCH
Channel
Input
00000
AD0
PTA0/ADP0/MCLK
01111
AD15
PTB7/ADP15
AD16
PTC0/ADP16
00001
AD1
PTA1/ADP1/ACMP1+
10000
00010
AD2
PTA2/ADP2/ACMP1P-
10001
AD17
PTC1/ADP17
00011
AD3
PTA3/ADP3/ACMP1O
10010
AD18
PTC2/ADP18
00100
AD4
PTA4/ADP4
10011
AD19
PTC3/ADP19
AD20
PTC4/ADP20
00101
AD5
PTA5/ADP5
10100
00110
AD6
PTA6/ADP6
10101
AD21
PTC5/ADP21
00111
AD7
PTA7/ADP7
10110
AD22
PTC6/ADP22
01000
AD8
PTB0/ADP8
10111
AD23
PTC7/ADP23
AD24 through AD25
Reserved
01001
AD9
PTB1/ADP9
11000–
01010
AD10
PTB2/ADP10
11001
01011
AD11
PTB3/ADP11
11010
AD26
Temperature Sensor1
01100
AD12
PTB4/ADP12
11011
AD27
Internal Bandgap2
01101
AD13
PTB5/ADP13
11100
Reserved
Reserved
01110
AD14
PTB6/ADP14
11101
VREFH
VREFH
11110
V
V
10.1.3
Alternate Clock
The ADC module is capable of performing conversions using the MCU bus clock, the bus clock divided
by two, the local asynchronous clock (ADACK) within the module, or the alternate clock, ALTCLK. The
alternate clock for the MC9S08DZ60 Series MCU devices is the external reference clock (MCGERCLK).
The selected clock source must run at a frequency such that the ADC conversion clock (ADCK) runs at a
frequency within its specified range (fADCK) after being divided down from the ALTCLK input as
determined by the ADIV bits.
ALTCLK is active while the MCU is in wait mode provided the conditions described above are met. This
allows ALTCLK to be used as the conversion clock source for the ADC while the MCU is in wait mode.
ALTCLK cannot be used as the ADC conversion clock source while the MCU is in either stop2 or stop3.
10.1.4
Hardware Trigger
The ADC hardware trigger, ADHWT, is the output from the real time counter (RTC). The RTC counter
can be clocked by either MCGERCLK or a nominal 1 kHz clock source.
The period of the RTC is determined by the input clock frequency, the RTCPS bits, and the RTCMOD
register. When the ADC hardware trigger is enabled, a conversion is initiated upon an RTC counter
overflow.
The RTC can be configured to cause a hardware trigger in MCU run, wait, and stop3.
MC9S08DZ60 Series Data Sheet, Rev. 4
174
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.1.5
Temperature Sensor
To use the on-chip temperature sensor, the user must perform the following:
• Configure ADC for long sample with a maximum of 1 MHz clock
• Convert the bandgap voltage reference channel (AD27)
— By converting the digital value of the bandgap voltage reference channel using the value of
VBG the user can determine VDD. For value of bandgap voltage, see Section A.6, “DC
Characteristics”.
• Convert the temperature sensor channel (AD26)
— By using the calculated value of VDD, convert the digital value of AD26 into a voltage, VTEMP
Equation 10-1 provides an approximate transfer function of the temperature sensor.
Temp = 25 - ((VTEMP -VTEMP25) ÷ m)
Eqn. 10-1
where:
— VTEMP is the voltage of the temperature sensor channel at the ambient temperature.
— VTEMP25 is the voltage of the temperature sensor channel at 25°C.
— m is the hot or cold voltage versus temperature slope in V/°C.
For temperature calculations, use the VTEMP25 and m values from the ADC Electricals table.
In application code, the user reads the temperature sensor channel, calculates VTEMP, and compares to
VTEMP25. If VTEMP is greater than VTEMP25 the cold slope value is applied in Equation 10-1. If VTEMP is
less than VTEMP25 the hot slope value is applied in Equation 10-1. To improve accuracy the user should
calibrate the bandgap voltage reference and temperature sensor.
Calibrating at 25°C will improve accuracy to ± 4.5°C.
Calibration at three points, -40°C, 25°C, and 125°C will improve accuracy to ± 2.5°C. Once calibration
has been completed, the user will need to calculate the slope for both hot and cold. In application code, the
user would then calculate the temperature using Equation 10-1 as detailed above and then determine if the
temperature is above or below 25°C. Once determined if the temperature is above or below 25°C, the user
can recalculate the temperature using the hot or cold slope value obtained during calibration.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
175
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 10-1. MC9S08DZ60 Block Diagram Emphasizing the ADC Module and Pins
MC9S08DZ60 Series Data Sheet, Rev. 4
176
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.1.6
Features
Features of the ADC module include:
• Linear successive approximation algorithm with 12-bit resolution
• Up to 28 analog inputs
• Output formatted in 12-, 10-, or 8-bit right-justified unsigned format
• Single or continuous conversion (automatic return to idle after single conversion)
• Configurable sample time and conversion speed/power
• Conversion complete flag and interrupt
• Input clock selectable from up to four sources
• Operation in wait or stop3 modes for lower noise operation
• Asynchronous clock source for lower noise operation
• Selectable asynchronous hardware conversion trigger
• Automatic compare with interrupt for less-than, or greater-than or equal-to, programmable value
• Temperature sensor
10.1.7
ADC Module Block Diagram
Figure 10-2 provides a block diagram of the ADC module.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
177
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
ADIV
ADLPC
MODE
ADLSMP
ADTRG
2
ADCO
ADCH
1
ADCCFG
complete
COCO
ADCSC1
ADICLK
Compare true
AIEN
3
Async
Clock Gen
ADACK
MCU STOP
ADCK
÷2
ALTCLK
abort
transfer
sample
initialize
•••
AD0
convert
Control Sequencer
ADHWT
Bus Clock
Clock
Divide
AIEN 1
Interrupt
COCO 2
ADVIN
SAR Converter
AD27
VREFH
Data Registers
Sum
VREFL
Compare true
3
Compare Value Registers
ACFGT
Value
Compare
Logic
ADCSC2
Figure 10-2. ADC Block Diagram
10.2
External Signal Description
The ADC module supports up to 28 separate analog inputs. It also requires four supply/reference/ground
connections.
Table 10-2. Signal Properties
Name
Function
AD27–AD0
Analog Channel inputs
VREFH
High reference voltage
VREFL
Low reference voltage
VDDAD
Analog power supply
VSSAD
Analog ground
MC9S08DZ60 Series Data Sheet, Rev. 4
178
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.2.1
Analog Power (VDDAD)
The ADC analog portion uses VDDAD as its power connection. In some packages, VDDAD is connected
internally to VDD. If externally available, connect the VDDAD pin to the same voltage potential as VDD.
External filtering may be necessary to ensure clean VDDAD for good results.
10.2.2
Analog Ground (VSSAD)
The ADC analog portion uses VSSAD as its ground connection. In some packages, VSSAD is connected
internally to VSS. If externally available, connect the VSSAD pin to the same voltage potential as VSS.
10.2.3
Voltage Reference High (VREFH)
VREFH is the high reference voltage for the converter. In some packages, VREFH is connected internally to
VDDAD. If externally available, VREFH may be connected to the same potential as VDDAD or may be driven
by an external source between the minimum VDDAD spec and the VDDAD potential (VREFH must never
exceed VDDAD).
10.2.4
Voltage Reference Low (VREFL)
VREFL is the low-reference voltage for the converter. In some packages, VREFL is connected internally to
VSSAD. If externally available, connect the VREFL pin to the same voltage potential as VSSAD.
10.2.5
Analog Channel Inputs (ADx)
The ADC module supports up to 28 separate analog inputs. An input is selected for conversion through the
ADCH channel select bits.
10.3
Register Definition
These memory-mapped registers control and monitor operation of the ADC:
•
•
•
•
•
•
Status and control register, ADCSC1
Status and control register, ADCSC2
Data result registers, ADCRH and ADCRL
Compare value registers, ADCCVH and ADCCVL
Configuration register, ADCCFG
Pin control registers, APCTL1, APCTL2, APCTL3
10.3.1
Status and Control Register 1 (ADCSC1)
This section describes the function of the ADC status and control register (ADCSC1). Writing ADCSC1
aborts the current conversion and initiates a new conversion (if the ADCH bits are equal to a value other
than all 1s).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
179
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
7
R
6
5
AIEN
ADCO
0
0
4
3
2
1
0
1
1
COCO
ADCH
W
Reset:
0
1
1
1
Figure 10-3. Status and Control Register (ADCSC1)
Table 10-3. ADCSC1 Field Descriptions
Field
Description
7
COCO
Conversion Complete Flag. The COCO flag is a read-only bit set each time a conversion is completed when the
compare function is disabled (ACFE = 0). When the compare function is enabled (ACFE = 1), the COCO flag is
set upon completion of a conversion only if the compare result is true. This bit is cleared when ADCSC1 is written
or when ADCRL is read.
0 Conversion not completed
1 Conversion completed
6
AIEN
Interrupt Enable AIEN enables conversion complete interrupts. When COCO becomes set while AIEN is high,
an interrupt is asserted.
0 Conversion complete interrupt disabled
1 Conversion complete interrupt enabled
5
ADCO
Continuous Conversion Enable. ADCO enables continuous conversions.
0 One conversion following a write to the ADCSC1 when software triggered operation is selected, or one
conversion following assertion of ADHWT when hardware triggered operation is selected.
1 Continuous conversions initiated following a write to ADCSC1 when software triggered operation is selected.
Continuous conversions are initiated by an ADHWT event when hardware triggered operation is selected.
4:0
ADCH
Input Channel Select. The ADCH bits form a 5-bit field that selects one of the input channels. The input channels
are detailed in Table 10-4.
The successive approximation converter subsystem is turned off when the channel select bits are all set. This
feature allows for explicit disabling of the ADC and isolation of the input channel from all sources. Terminating
continuous conversions this way prevents an additional, single conversion from being performed. It is not
necessary to set the channel select bits to all ones to place the ADC in a low-power state when continuous
conversions are not enabled because the module automatically enters a low-power state when a conversion
completes.
Table 10-4. Input Channel Select
ADCH
Input Select
00000–01111
AD0–15
10000–11011
AD16–27
11100
Reserved
11101
VREFH
11110
VREFL
11111
Module disabled
MC9S08DZ60 Series Data Sheet, Rev. 4
180
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.3.2
Status and Control Register 2 (ADCSC2)
The ADCSC2 register controls the compare function, conversion trigger, and conversion active of the ADC
module.
Reset:
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
Figure 10-4. Status and Control Register 2 (ADCSC2)
Table 10-5. ADCSC2 Register Field Descriptions
Field
Description
7
ADACT
Conversion Active. Indicates that a conversion is in progress. ADACT is set when a conversion is initiated and
cleared when a conversion is completed or aborted.
0 Conversion not in progress
1 Conversion in progress
6
ADTRG
Conversion Trigger Select. Selects the type of trigger used for initiating a conversion. Two types of triggers are
selectable: software trigger and hardware trigger. When software trigger is selected, a conversion is initiated
following a write to ADCSC1. When hardware trigger is selected, a conversion is initiated following the assertion
of the ADHWT input.
0 Software trigger selected
1 Hardware trigger selected
5
ACFE
4
ACFGT
10.3.3
Compare Function Enable. Enables the compare function.
0 Compare function disabled
1 Compare function enabled
Compare Function Greater Than Enable. Configures the compare function to trigger when the result of the
conversion of the input being monitored is greater than or equal to the compare value. The compare function
defaults to triggering when the result of the compare of the input being monitored is less than the compare value.
0 Compare triggers when input is less than compare value
1 Compare triggers when input is greater than or equal to compare value
Data Result High Register (ADCRH)
In 12-bit operation, ADCRH contains the upper four bits of the result of a 12-bit conversion. In 10-bit
mode, ADCRH contains the upper two bits of the result of a 10-bit conversion. When configured for 10-bit
mode, ADR[11:10] are cleared. When configured for 8-bit mode, ADR[11:8] are cleared.
In 12-bit and 10-bit mode, ADCRH is updated each time a conversion completes except when automatic
compare is enabled and the compare condition is not met. When a compare event does occur, the value is
the addition of the conversion result and the two’s complement of the compare value. In 12-bit and 10-bit
mode, reading ADCRH prevents the ADC from transferring subsequent conversion results into the result
registers until ADCRL is read. If ADCRL is not read until after the next conversion is completed, the
intermediate conversion result is lost. In 8-bit mode, there is no interlocking with ADCRL.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
181
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
If the MODE bits are changed, any data in ADCRH becomes invalid.
R
7
6
5
4
3
2
1
0
0
0
0
0
ADR11
ADR10
ADR9
ADR8
0
0
0
0
0
0
0
0
W
Reset:
Figure 10-5. Data Result High Register (ADCRH)
10.3.4
Data Result Low Register (ADCRL)
ADCRL contains the lower eight bits of the result of a 12-bit or 10-bit conversion, and all eight bits of an
8-bit conversion. This register is updated each time a conversion completes except when automatic
compare is enabled and the compare condition is not met. When a compare event does occur, the value is
the addition of the conversion result and the two’s complement of the compare value. In 12-bit and 10-bit
mode, reading ADCRH prevents the ADC from transferring subsequent conversion results into the result
registers until ADCRL is read. If ADCRL is not read until the after next conversion is completed, the
intermediate conversion results are lost. In 8-bit mode, there is no interlocking with ADCRH. If the MODE
bits are changed, any data in ADCRL becomes invalid.
R
7
6
5
4
3
2
1
0
ADR7
ADR6
ADR5
ADR4
ADR3
ADR2
ADR1
ADR0
0
0
0
0
0
0
0
0
W
Reset:
Figure 10-6. Data Result Low Register (ADCRL)
10.3.5
Compare Value High Register (ADCCVH)
In 12-bit mode, the ADCCVH register holds the upper four bits of the 12-bit compare value. When the
compare function is enabled, these bits are compared to the upper four bits of the result following a
conversion in 12-bit mode.
R
7
6
5
4
0
0
0
0
3
2
1
0
ADCV11
ADCV10
ADCV9
ADCV8
0
0
0
0
W
Reset:
0
0
0
0
Figure 10-7. Compare Value High Register (ADCCVH)
MC9S08DZ60 Series Data Sheet, Rev. 4
182
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
In 10-bit mode, the ADCCVH register holds the upper two bits of the 10-bit compare value (ADCV[9:8]).
These bits are compared to the upper two bits of the result following a conversion in 10-bit mode when the
compare function is enabled.
In 8-bit mode, ADCCVH is not used during compare.
10.3.6
Compare Value Low Register (ADCCVL)
This register holds the lower 8 bits of the 12-bit or 10-bit compare value or all 8 bits of the 8-bit compare
value. When the compare function is enabled, bits ADCV[7:0] are compared to the lower 8 bits of the
result following a conversion in 12-bit, 10-bit or 8-bit mode.
7
6
5
4
3
2
1
0
ADCV7
ADCV6
ADCV5
ADCV4
ADCV3
ADCV2
ADCV1
ADCV0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 10-8. Compare Value Low Register (ADCCVL)
10.3.7
Configuration Register (ADCCFG)
ADCCFG selects the mode of operation, clock source, clock divide, and configures for low power and
long sample time.
7
6
5
4
3
2
1
0
R
ADLPC
ADIV
ADLSMP
MODE
ADICLK
W
Reset:
0
0
0
0
0
0
0
0
Figure 10-9. Configuration Register (ADCCFG)
Table 10-6. ADCCFG Register Field Descriptions
Field
Description
7
ADLPC
Low-Power Configuration. ADLPC controls the speed and power configuration of the successive approximation
converter. This optimizes power consumption when higher sample rates are not required.
0 High speed configuration
1 Low power configuration: The power is reduced at the expense of maximum clock speed.
6:5
ADIV
4
ADLSMP
Clock Divide Select. ADIV selects the divide ratio used by the ADC to generate the internal clock ADCK.
Table 10-7 shows the available clock configurations.
Long Sample Time Configuration. ADLSMP selects between long and short sample time. This adjusts the
sample period to allow higher impedance inputs to be accurately sampled or to maximize conversion speed for
lower impedance inputs. Longer sample times can also be used to lower overall power consumption when
continuous conversions are enabled if high conversion rates are not required.
0 Short sample time
1 Long sample time
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
183
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
Table 10-6. ADCCFG Register Field Descriptions (continued)
Field
Description
3:2
MODE
Conversion Mode Selection. MODE bits are used to select between 12-, 10-, or 8-bit operation. See Table 10-8.
1:0
ADICLK
Input Clock Select. ADICLK bits select the input clock source to generate the internal clock ADCK. See
Table 10-9.
Table 10-7. Clock Divide Select
ADIV
Divide Ratio
Clock Rate
00
1
Input clock
01
2
Input clock ÷ 2
10
4
Input clock ÷ 4
11
8
Input clock ÷ 8
Table 10-8. Conversion Modes
MODE
Mode Description
00
8-bit conversion (N=8)
01
12-bit conversion (N=12)
10
10-bit conversion (N=10)
11
Reserved
Table 10-9. Input Clock Select
ADICLK
10.3.8
Selected Clock Source
00
Bus clock
01
Bus clock divided by 2
10
Alternate clock (ALTCLK)
11
Asynchronous clock (ADACK)
Pin Control 1 Register (APCTL1)
The pin control registers disable the I/O port control of MCU pins used as analog inputs. APCTL1 is
MC9S08DZ60 Series Data Sheet, Rev. 4
184
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
used to control the pins associated with channels 0–7 of the ADC module.
7
6
5
4
3
2
1
0
ADPC7
ADPC6
ADPC5
ADPC4
ADPC3
ADPC2
ADPC1
ADPC0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 10-10. Pin Control 1 Register (APCTL1)
Table 10-10. APCTL1 Register Field Descriptions
Field
Description
7
ADPC7
ADC Pin Control 7. ADPC7 controls the pin associated with channel AD7.
0 AD7 pin I/O control enabled
1 AD7 pin I/O control disabled
6
ADPC6
ADC Pin Control 6. ADPC6 controls the pin associated with channel AD6.
0 AD6 pin I/O control enabled
1 AD6 pin I/O control disabled
5
ADPC5
ADC Pin Control 5. ADPC5 controls the pin associated with channel AD5.
0 AD5 pin I/O control enabled
1 AD5 pin I/O control disabled
4
ADPC4
ADC Pin Control 4. ADPC4 controls the pin associated with channel AD4.
0 AD4 pin I/O control enabled
1 AD4 pin I/O control disabled
3
ADPC3
ADC Pin Control 3. ADPC3 controls the pin associated with channel AD3.
0 AD3 pin I/O control enabled
1 AD3 pin I/O control disabled
2
ADPC2
ADC Pin Control 2. ADPC2 controls the pin associated with channel AD2.
0 AD2 pin I/O control enabled
1 AD2 pin I/O control disabled
1
ADPC1
ADC Pin Control 1. ADPC1 controls the pin associated with channel AD1.
0 AD1 pin I/O control enabled
1 AD1 pin I/O control disabled
0
ADPC0
ADC Pin Control 0. ADPC0 controls the pin associated with channel AD0.
0 AD0 pin I/O control enabled
1 AD0 pin I/O control disabled
10.3.9
Pin Control 2 Register (APCTL2)
APCTL2 controls channels 8–15 of the ADC module.
7
6
5
4
3
2
1
0
ADPC15
ADPC14
ADPC13
ADPC12
ADPC11
ADPC10
ADPC9
ADPC8
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 10-11. Pin Control 2 Register (APCTL2)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
185
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
Table 10-11. APCTL2 Register Field Descriptions
Field
Description
7
ADPC15
ADC Pin Control 15. ADPC15 controls the pin associated with channel AD15.
0 AD15 pin I/O control enabled
1 AD15 pin I/O control disabled
6
ADPC14
ADC Pin Control 14. ADPC14 controls the pin associated with channel AD14.
0 AD14 pin I/O control enabled
1 AD14 pin I/O control disabled
5
ADPC13
ADC Pin Control 13. ADPC13 controls the pin associated with channel AD13.
0 AD13 pin I/O control enabled
1 AD13 pin I/O control disabled
4
ADPC12
ADC Pin Control 12. ADPC12 controls the pin associated with channel AD12.
0 AD12 pin I/O control enabled
1 AD12 pin I/O control disabled
3
ADPC11
ADC Pin Control 11. ADPC11 controls the pin associated with channel AD11.
0 AD11 pin I/O control enabled
1 AD11 pin I/O control disabled
2
ADPC10
ADC Pin Control 10. ADPC10 controls the pin associated with channel AD10.
0 AD10 pin I/O control enabled
1 AD10 pin I/O control disabled
1
ADPC9
ADC Pin Control 9. ADPC9 controls the pin associated with channel AD9.
0 AD9 pin I/O control enabled
1 AD9 pin I/O control disabled
0
ADPC8
ADC Pin Control 8. ADPC8 controls the pin associated with channel AD8.
0 AD8 pin I/O control enabled
1 AD8 pin I/O control disabled
10.3.10 Pin Control 3 Register (APCTL3)
APCTL3 controls channels 16–23 of the ADC module.
7
6
5
4
3
2
1
0
ADPC23
ADPC22
ADPC21
ADPC20
ADPC19
ADPC18
ADPC17
ADPC16
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 10-12. Pin Control 3 Register (APCTL3)
MC9S08DZ60 Series Data Sheet, Rev. 4
186
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
Table 10-12. APCTL3 Register Field Descriptions
Field
Description
7
ADPC23
ADC Pin Control 23. ADPC23 controls the pin associated with channel AD23.
0 AD23 pin I/O control enabled
1 AD23 pin I/O control disabled
6
ADPC22
ADC Pin Control 22. ADPC22 controls the pin associated with channel AD22.
0 AD22 pin I/O control enabled
1 AD22 pin I/O control disabled
5
ADPC21
ADC Pin Control 21. ADPC21 controls the pin associated with channel AD21.
0 AD21 pin I/O control enabled
1 AD21 pin I/O control disabled
4
ADPC20
ADC Pin Control 20. ADPC20 controls the pin associated with channel AD20.
0 AD20 pin I/O control enabled
1 AD20 pin I/O control disabled
3
ADPC19
ADC Pin Control 19. ADPC19 controls the pin associated with channel AD19.
0 AD19 pin I/O control enabled
1 AD19 pin I/O control disabled
2
ADPC18
ADC Pin Control 18. ADPC18 controls the pin associated with channel AD18.
0 AD18 pin I/O control enabled
1 AD18 pin I/O control disabled
1
ADPC17
ADC Pin Control 17. ADPC17 controls the pin associated with channel AD17.
0 AD17 pin I/O control enabled
1 AD17 pin I/O control disabled
0
ADPC16
ADC Pin Control 16. ADPC16 controls the pin associated with channel AD16.
0 AD16 pin I/O control enabled
1 AD16 pin I/O control disabled
10.4
Functional Description
The ADC module is disabled during reset or when the ADCH bits are all high. The module is idle when a
conversion has completed and another conversion has not been initiated. When idle, the module is in its
lowest power state.
The ADC can perform an analog-to-digital conversion on any of the software selectable channels. In 12-bit
and 10-bit mode, the selected channel voltage is converted by a successive approximation algorithm into
a 12-bit digital result. In 8-bit mode, the selected channel voltage is converted by a successive
approximation algorithm into a 9-bit digital result.
When the conversion is completed, the result is placed in the data registers (ADCRH and ADCRL). In
10-bit mode, the result is rounded to 10 bits and placed in the data registers (ADCRH and ADCRL). In
8-bit mode, the result is rounded to 8 bits and placed in ADCRL. The conversion complete flag (COCO)
is then set and an interrupt is generated if the conversion complete interrupt has been enabled (AIEN = 1).
The ADC module has the capability of automatically comparing the result of a conversion with the
contents of its compare registers. The compare function is enabled by setting the ACFE bit and operates
with any of the conversion modes and configurations.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
187
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.4.1
Clock Select and Divide Control
One of four clock sources can be selected as the clock source for the ADC module. This clock source is
then divided by a configurable value to generate the input clock to the converter (ADCK). The clock is
selected from one of the following sources by means of the ADICLK bits.
• The bus clock, which is equal to the frequency at which software is executed. This is the default
selection following reset.
• The bus clock divided by two. For higher bus clock rates, this allows a maximum divide by 16 of
the bus clock.
• ALTCLK, as defined for this MCU (See module section introduction).
• The asynchronous clock (ADACK). This clock is generated from a clock source within the ADC
module. When selected as the clock source, this clock remains active while the MCU is in wait or
stop3 mode and allows conversions in these modes for lower noise operation.
Whichever clock is selected, its frequency must fall within the specified frequency range for ADCK. If the
available clocks are too slow, the ADC do not perform according to specifications. If the available clocks
are too fast, the clock must be divided to the appropriate frequency. This divider is specified by the ADIV
bits and can be divide-by 1, 2, 4, or 8.
10.4.2
Input Select and Pin Control
The pin control registers (APCTL3, APCTL2, and APCTL1) disable the I/O port control of the pins used
as analog inputs.When a pin control register bit is set, the following conditions are forced for the associated
MCU pin:
• The output buffer is forced to its high impedance state.
• The input buffer is disabled. A read of the I/O port returns a zero for any pin with its input buffer
disabled.
• The pullup is disabled.
10.4.3
Hardware Trigger
The ADC module has a selectable asynchronous hardware conversion trigger, ADHWT, that is enabled
when the ADTRG bit is set. This source is not available on all MCUs. Consult the module introduction for
information on the ADHWT source specific to this MCU.
When ADHWT source is available and hardware trigger is enabled (ADTRG=1), a conversion is initiated
on the rising edge of ADHWT. If a conversion is in progress when a rising edge occurs, the rising edge is
ignored. In continuous convert configuration, only the initial rising edge to launch continuous conversions
is observed. The hardware trigger function operates in conjunction with any of the conversion modes and
configurations.
10.4.4
Conversion Control
Conversions can be performed in 12-bit mode, 10-bit mode, or 8-bit mode as determined by the MODE
bits. Conversions can be initiated by a software or hardware trigger. In addition, the ADC module can be
MC9S08DZ60 Series Data Sheet, Rev. 4
188
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
configured for low power operation, long sample time, continuous conversion, and automatic compare of
the conversion result to a software determined compare value.
10.4.4.1
Initiating Conversions
A conversion is initiated:
• Following a write to ADCSC1 (with ADCH bits not all 1s) if software triggered operation is
selected.
• Following a hardware trigger (ADHWT) event if hardware triggered operation is selected.
• Following the transfer of the result to the data registers when continuous conversion is enabled.
If continuous conversions are enabled, a new conversion is automatically initiated after the completion of
the current conversion. In software triggered operation, continuous conversions begin after ADCSC1 is
written and continue until aborted. In hardware triggered operation, continuous conversions begin after a
hardware trigger event and continue until aborted.
10.4.4.2
Completing Conversions
A conversion is completed when the result of the conversion is transferred into the data result registers,
ADCRH and ADCRL. This is indicated by the setting of COCO. An interrupt is generated if AIEN is high
at the time that COCO is set.
A blocking mechanism prevents a new result from overwriting previous data in ADCRH and ADCRL if
the previous data is in the process of being read while in 12-bit or 10-bit MODE (the ADCRH register has
been read but the ADCRL register has not). When blocking is active, the data transfer is blocked, COCO
is not set, and the new result is lost. In the case of single conversions with the compare function enabled
and the compare condition false, blocking has no effect and ADC operation is terminated. In all other cases
of operation, when a data transfer is blocked, another conversion is initiated regardless of the state of
ADCO (single or continuous conversions enabled).
If single conversions are enabled, the blocking mechanism could result in several discarded conversions
and excess power consumption. To avoid this issue, the data registers must not be read after initiating a
single conversion until the conversion completes.
10.4.4.3
Aborting Conversions
Any conversion in progress is aborted when:
•
A write to ADCSC1 occurs (the current conversion will be aborted and a new conversion will be
initiated, if ADCH are not all 1s).
•
A write to ADCSC2, ADCCFG, ADCCVH, or ADCCVL occurs. This indicates a mode of
operation change has occurred and the current conversion is therefore invalid.
•
The MCU is reset.
•
The MCU enters stop mode with ADACK not enabled.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
189
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
When a conversion is aborted, the contents of the data registers, ADCRH and ADCRL, are not altered.
However, they continue to be the values transferred after the completion of the last successful conversion.
If the conversion was aborted by a reset, ADCRH and ADCRL return to their reset states.
10.4.4.4
Power Control
The ADC module remains in its idle state until a conversion is initiated. If ADACK is selected as the
conversion clock source, the ADACK clock generator is also enabled.
Power consumption when active can be reduced by setting ADLPC. This results in a lower maximum value
for fADCK (see the electrical specifications).
10.4.4.5
Sample Time and Total Conversion Time
The total conversion time depends on the sample time (as determined by ADLSMP), the MCU bus
frequency, the conversion mode (8-bit, 10-bit or 12-bit), and the frequency of the conversion clock (fADCK).
After the module becomes active, sampling of the input begins. ADLSMP selects between short (3.5
ADCK cycles) and long (23.5 ADCK cycles) sample times.When sampling is complete, the converter is
isolated from the input channel and a successive approximation algorithm is performed to determine the
digital value of the analog signal. The result of the conversion is transferred to ADCRH and ADCRL upon
completion of the conversion algorithm.
If the bus frequency is less than the fADCK frequency, precise sample time for continuous conversions
cannot be guaranteed when short sample is enabled (ADLSMP=0). If the bus frequency is less than 1/11th
of the fADCK frequency, precise sample time for continuous conversions cannot be guaranteed when long
sample is enabled (ADLSMP=1).
The maximum total conversion time for different conditions is summarized in Table 10-13.
Table 10-13. Total Conversion Time vs. Control Conditions
Conversion Type
ADICLK
ADLSMP
Max Total Conversion Time
Single or first continuous 8-bit
0x, 10
0
20 ADCK cycles + 5 bus clock cycles
Single or first continuous 10-bit or 12-bit
0x, 10
0
23 ADCK cycles + 5 bus clock cycles
Single or first continuous 8-bit
0x, 10
1
40 ADCK cycles + 5 bus clock cycles
Single or first continuous 10-bit or 12-bit
0x, 10
1
43 ADCK cycles + 5 bus clock cycles
Single or first continuous 8-bit
11
0
5 μs + 20 ADCK + 5 bus clock cycles
Single or first continuous 10-bit or 12-bit
11
0
5 μs + 23 ADCK + 5 bus clock cycles
Single or first continuous 8-bit
11
1
5 μs + 40 ADCK + 5 bus clock cycles
Single or first continuous 10-bit or 12-bit
11
1
5 μs + 43 ADCK + 5 bus clock cycles
Subsequent continuous 8-bit;
fBUS > fADCK
xx
0
17 ADCK cycles
Subsequent continuous 10-bit or 12-bit;
fBUS > fADCK
xx
0
20 ADCK cycles
Subsequent continuous 8-bit;
fBUS > fADCK/11
xx
1
37 ADCK cycles
MC9S08DZ60 Series Data Sheet, Rev. 4
190
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
Table 10-13. Total Conversion Time vs. Control Conditions
Conversion Type
ADICLK
ADLSMP
Max Total Conversion Time
Subsequent continuous 10-bit or 12-bit;
fBUS > fADCK/11
xx
1
40 ADCK cycles
The maximum total conversion time is determined by the clock source chosen and the divide ratio selected.
The clock source is selectable by the ADICLK bits, and the divide ratio is specified by the ADIV bits. For
example, in 10-bit mode, with the bus clock selected as the input clock source, the input clock divide-by-1
ratio selected, and a bus frequency of 8 MHz, then the conversion time for a single conversion is:
Conversion time =
23 ADCK Cyc
8 MHz/1
+
5 bus Cyc
8 MHz
= 3.5 ms
Number of bus cycles = 3.5 ms x 8 MHz = 28 cycles
NOTE
The ADCK frequency must be between fADCK minimum and fADCK
maximum to meet ADC specifications.
10.4.5
Automatic Compare Function
The compare function can be configured to check for an upper or lower limit. After the input is sampled
and converted, the result is added to the two’s complement of the compare value (ADCCVH and
ADCCVL). When comparing to an upper limit (ACFGT = 1), if the result is greater-than or equal-to the
compare value, COCO is set. When comparing to a lower limit (ACFGT = 0), if the result is less than the
compare value, COCO is set. The value generated by the addition of the conversion result and the two’s
complement of the compare value is transferred to ADCRH and ADCRL.
Upon completion of a conversion while the compare function is enabled, if the compare condition is not
true, COCO is not set and no data is transferred to the result registers. An ADC interrupt is generated upon
the setting of COCO if the ADC interrupt is enabled (AIEN = 1).
NOTE
The compare function can monitor the voltage on a channel while the MCU
is in wait or stop3 mode. The ADC interrupt wakes the MCU when the
compare condition is met.
10.4.6
MCU Wait Mode Operation
Wait mode is a lower power-consumption standby mode from which recovery is fast because the clock
sources remain active. If a conversion is in progress when the MCU enters wait mode, it continues until
completion. Conversions can be initiated while the MCU is in wait mode by means of the hardware trigger
or if continuous conversions are enabled.
The bus clock, bus clock divided by two, and ADACK are available as conversion clock sources while in
wait mode. The use of ALTCLK as the conversion clock source in wait is dependent on the definition of
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
191
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
ALTCLK for this MCU. Consult the module introduction for information on ALTCLK specific to this
MCU.
A conversion complete event sets the COCO and generates an ADC interrupt to wake the MCU from wait
mode if the ADC interrupt is enabled (AIEN = 1).
10.4.7
MCU Stop3 Mode Operation
Stop mode is a low power-consumption standby mode during which most or all clock sources on the MCU
are disabled.
10.4.7.1
Stop3 Mode With ADACK Disabled
If the asynchronous clock, ADACK, is not selected as the conversion clock, executing a stop instruction
aborts the current conversion and places the ADC in its idle state. The contents of ADCRH and ADCRL
are unaffected by stop3 mode. After exiting from stop3 mode, a software or hardware trigger is required
to resume conversions.
10.4.7.2
Stop3 Mode With ADACK Enabled
If ADACK is selected as the conversion clock, the ADC continues operation during stop3 mode. For
guaranteed ADC operation, the MCU’s voltage regulator must remain active during stop3 mode. Consult
the module introduction for configuration information for this MCU.
If a conversion is in progress when the MCU enters stop3 mode, it continues until completion. Conversions
can be initiated while the MCU is in stop3 mode by means of the hardware trigger or if continuous
conversions are enabled.
A conversion complete event sets the COCO and generates an ADC interrupt to wake the MCU from stop3
mode if the ADC interrupt is enabled (AIEN = 1).
NOTE
The ADC module can wake the system from low-power stop and cause the
MCU to begin consuming run-level currents without generating a system
level interrupt. To prevent this scenario, software should ensure the data
transfer blocking mechanism (discussed in Section 10.4.4.2, “Completing
Conversions) is cleared when entering stop3 and continuing ADC
conversions.
10.4.8
MCU Stop2 Mode Operation
The ADC module is automatically disabled when the MCU enters stop2 mode. All module registers
contain their reset values following exit from stop2. Therefore, the module must be re-enabled and
re-configured following exit from stop2.
MC9S08DZ60 Series Data Sheet, Rev. 4
192
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.5
Initialization Information
This section gives an example that provides some basic direction on how to initialize and configure the
ADC module. You can configure the module for 8-, 10-, or 12-bit resolution, single or continuous
conversion, and a polled or interrupt approach, among many other options. Refer to Table 10-7,
Table 10-8, and Table 10-9 for information used in this example.
NOTE
Hexadecimal values designated by a preceding 0x, binary values designated
by a preceding %, and decimal values have no preceding character.
10.5.1
ADC Module Initialization Example
10.5.1.1
Initialization Sequence
Before the ADC module can be used to complete conversions, an initialization procedure must be
performed. A typical sequence is as follows:
1. Update the configuration register (ADCCFG) to select the input clock source and the divide ratio
used to generate the internal clock, ADCK. This register is also used for selecting sample time and
low-power configuration.
2. Update status and control register 2 (ADCSC2) to select the conversion trigger (hardware or
software) and compare function options, if enabled.
3. Update status and control register 1 (ADCSC1) to select whether conversions will be continuous
or completed only once, and to enable or disable conversion complete interrupts. The input channel
on which conversions will be performed is also selected here.
10.5.1.2
Pseudo-Code Example
In this example, the ADC module is set up with interrupts enabled to perform a single 10-bit conversion
at low power with a long sample time on input channel 1, where the internal ADCK clock is derived from
the bus clock divided by 1.
ADCCFG = 0x98 (%10011000)
Bit
Bit
Bit
Bit
Bit
7
6:5
4
3:2
1:0
ADLPC
ADIV
ADLSMP
MODE
ADICLK
1
00
1
10
00
Configures for low power (lowers maximum clock speed)
Sets the ADCK to the input clock ÷ 1
Configures for long sample time
Sets mode at 10-bit conversions
Selects bus clock as input clock source
ADCSC2 = 0x00 (%00000000)
Bit
Bit
Bit
Bit
Bit
Bit
7
6
5
4
3:2
1:0
ADACT
ADTRG
ACFE
ACFGT
0
0
0
0
00
00
Flag indicates if a conversion is in progress
Software trigger selected
Compare function disabled
Not used in this example
Reserved, always reads zero
Reserved for Freescale’s internal use; always write zero
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
193
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
ADCSC1 = 0x41 (%01000001)
Bit
Bit
Bit
Bit
7
6
5
4:0
COCO
AIEN
ADCO
ADCH
0
1
0
00001
Read-only flag which is set when a conversion completes
Conversion complete interrupt enabled
One conversion only (continuous conversions disabled)
Input channel 1 selected as ADC input channel
ADCRH/L = 0xxx
Holds results of conversion. Read high byte (ADCRH) before low byte (ADCRL) so that
conversion data cannot be overwritten with data from the next conversion.
ADCCVH/L = 0xxx
Holds compare value when compare function enabled
APCTL1=0x02
AD1 pin I/O control disabled. All other AD pins remain general purpose I/O pins
APCTL2=0x00
All other AD pins remain general purpose I/O pins
Reset
Initialize ADC
ADCCFG = 0x98
ADCSC2 = 0x00
ADCSC1 = 0x41
Check
COCO=1?
No
Yes
Read ADCRH
Then ADCRL To
Clear COCO Bit
Continue
Figure 10-13. Initialization Flowchart for Example
MC9S08DZ60 Series Data Sheet, Rev. 4
194
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.6
Application Information
This section contains information for using the ADC module in applications. The ADC has been designed
to be integrated into a microcontroller for use in embedded control applications requiring an A/D
converter.
10.6.1
External Pins and Routing
The following sections discuss the external pins associated with the ADC module and how they should be
used for best results.
10.6.1.1
Analog Supply Pins
The ADC module has analog power and ground supplies (VDDAD and VSSAD) available as separate pins
on some devices. VSSAD is shared on the same pin as the MCU digital VSS on some devices. On other
devices, VSSAD and VDDAD are shared with the MCU digital supply pins. In these cases, there are separate
pads for the analog supplies bonded to the same pin as the corresponding digital supply so that some degree
of isolation between the supplies is maintained.
When available on a separate pin, both VDDAD and VSSAD must be connected to the same voltage potential
as their corresponding MCU digital supply (VDD and VSS) and must be routed carefully for maximum
noise immunity and bypass capacitors placed as near as possible to the package.
If separate power supplies are used for analog and digital power, the ground connection between these
supplies must be at the VSSAD pin. This should be the only ground connection between these supplies if
possible. The VSSAD pin makes a good single point ground location.
10.6.1.2
Analog Reference Pins
In addition to the analog supplies, the ADC module has connections for two reference voltage inputs. The
high reference is VREFH, which may be shared on the same pin as VDDAD on some devices. The low
reference is VREFL, which may be shared on the same pin as VSSAD on some devices.
When available on a separate pin, VREFH may be connected to the same potential as VDDAD, or may be
driven by an external source between the minimum VDDAD spec and the VDDAD potential (VREFH must
never exceed VDDAD). When available on a separate pin, VREFL must be connected to the same voltage
potential as VSSAD. VREFH and VREFL must be routed carefully for maximum noise immunity and bypass
capacitors placed as near as possible to the package.
AC current in the form of current spikes required to supply charge to the capacitor array at each successive
approximation step is drawn through the VREFH and VREFL loop. The best external component to meet this
current demand is a 0.1 μF capacitor with good high frequency characteristics. This capacitor is connected
between VREFH and VREFL and must be placed as near as possible to the package pins. Resistance in the
path is not recommended because the current causes a voltage drop that could result in conversion errors.
Inductance in this path must be minimum (parasitic only).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
195
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.6.1.3
Analog Input Pins
The external analog inputs are typically shared with digital I/O pins on MCU devices. The pin I/O control
is disabled by setting the appropriate control bit in one of the pin control registers. Conversions can be
performed on inputs without the associated pin control register bit set. It is recommended that the pin
control register bit always be set when using a pin as an analog input. This avoids problems with contention
because the output buffer is in its high impedance state and the pullup is disabled. Also, the input buffer
draws DC current when its input is not at VDD or VSS. Setting the pin control register bits for all pins used
as analog inputs should be done to achieve lowest operating current.
Empirical data shows that capacitors on the analog inputs improve performance in the presence of noise
or when the source impedance is high. Use of 0.01 μF capacitors with good high-frequency characteristics
is sufficient. These capacitors are not necessary in all cases, but when used they must be placed as near as
possible to the package pins and be referenced to VSSA.
For proper conversion, the input voltage must fall between VREFH and VREFL. If the input is equal to or
exceeds VREFH, the converter circuit converts the signal to 0xFFF (full scale 12-bit representation), 0x3FF
(full scale 10-bit representation) or 0xFF (full scale 8-bit representation). If the input is equal to or less
than VREFL, the converter circuit converts it to 0x000. Input voltages between VREFH and VREFL are
straight-line linear conversions. There is a brief current associated with VREFL when the sampling
capacitor is charging. The input is sampled for 3.5 cycles of the ADCK source when ADLSMP is low, or
23.5 cycles when ADLSMP is high.
For minimal loss of accuracy due to current injection, pins adjacent to the analog input pins should not be
transitioning during conversions.
10.6.2
Sources of Error
Several sources of error exist for A/D conversions. These are discussed in the following sections.
10.6.2.1
Sampling Error
For proper conversions, the input must be sampled long enough to achieve the proper accuracy. Given the
maximum input resistance of approximately 7kΩ and input capacitance of approximately 5.5 pF, sampling
to within 1/4LSB (at 12-bit resolution) can be achieved within the minimum sample window (3.5 cycles @
8 MHz maximum ADCK frequency) provided the resistance of the external analog source (RAS) is kept
below 2 kΩ.
Higher source resistances or higher-accuracy sampling is possible by setting ADLSMP (to increase the
sample window to 23.5 cycles) or decreasing ADCK frequency to increase sample time.
10.6.2.2
Pin Leakage Error
Leakage on the I/O pins can cause conversion error if the external analog source resistance (RAS) is high.
If this error cannot be tolerated by the application, keep RAS lower than VDDAD / (2N*ILEAK) for less than
1/4LSB leakage error (N = 8 in 8-bit, 10 in 10-bit or 12 in 12-bit mode).
MC9S08DZ60 Series Data Sheet, Rev. 4
196
Freescale Semiconductor
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
10.6.2.3
Noise-Induced Errors
System noise that occurs during the sample or conversion process can affect the accuracy of the
conversion. The ADC accuracy numbers are guaranteed as specified only if the following conditions are
met:
• There is a 0.1 μF low-ESR capacitor from VREFH to VREFL.
• There is a 0.1 μF low-ESR capacitor from VDDAD to VSSAD.
• If inductive isolation is used from the primary supply, an additional 1 μF capacitor is placed from
VDDAD to VSSAD.
• VSSAD (and VREFL, if connected) is connected to VSS at a quiet point in the ground plane.
• Operate the MCU in wait or stop3 mode before initiating (hardware triggered conversions) or
immediately after initiating (hardware or software triggered conversions) the ADC conversion.
— For software triggered conversions, immediately follow the write to ADCSC1 with a wait
instruction or stop instruction.
— For stop3 mode operation, select ADACK as the clock source. Operation in stop3 reduces VDD
noise but increases effective conversion time due to stop recovery.
• There is no I/O switching, input or output, on the MCU during the conversion.
There are some situations where external system activity causes radiated or conducted noise emissions or
excessive VDD noise is coupled into the ADC. In these situations, or when the MCU cannot be placed in
wait or stop3 or I/O activity cannot be halted, these recommended actions may reduce the effect of noise
on the accuracy:
• Place a 0.01 μF capacitor (CAS) on the selected input channel to VREFL or VSSAD (this improves
noise issues, but affects the sample rate based on the external analog source resistance).
• Average the result by converting the analog input many times in succession and dividing the sum
of the results. Four samples are required to eliminate the effect of a 1LSB, one-time error.
• Reduce the effect of synchronous noise by operating off the asynchronous clock (ADACK) and
averaging. Noise that is synchronous to ADCK cannot be averaged out.
10.6.2.4
Code Width and Quantization Error
The ADC quantizes the ideal straight-line transfer function into 4096 steps (in 12-bit mode). Each step
ideally has the same height (1 code) and width. The width is defined as the delta between the transition
points to one code and the next. The ideal code width for an N bit converter (in this case N can be 8, 10 or
12), defined as 1LSB, is:
1 lsb = (VREFH - VREFL) / 2N
Eqn. 10-2
There is an inherent quantization error due to the digitization of the result. For 8-bit or 10-bit conversions
the code transitions when the voltage is at the midpoint between the points where the straight line transfer
function is exactly represented by the actual transfer function. Therefore, the quantization error will be ±
1/2 lsb in 8- or 10-bit mode. As a consequence, however, the code width of the first (0x000) conversion is
only 1/2 lsb and the code width of the last (0xFF or 0x3FF) is 1.5 lsb.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
197
Chapter 10 Analog-to-Digital Converter (S08ADC12V1)
For 12-bit conversions the code transitions only after the full code width is present, so the quantization
error is −1 lsb to 0 lsb and the code width of each step is 1 lsb.
10.6.2.5
Linearity Errors
The ADC may also exhibit non-linearity of several forms. Every effort has been made to reduce these
errors but the system should be aware of them because they affect overall accuracy. These errors are:
• Zero-scale error (EZS) (sometimes called offset) — This error is defined as the difference between
the actual code width of the first conversion and the ideal code width (1/2 lsb in 8-bit or 10-bit
modes and 1 lsb in 12-bit mode). If the first conversion is 0x001, the difference between the actual
0x001 code width and its ideal (1 lsb) is used.
• Full-scale error (EFS) — This error is defined as the difference between the actual code width of
the last conversion and the ideal code width (1.5 lsb in 8-bit or 10-bit modes and 1LSB in 12-bit
mode). If the last conversion is 0x3FE, the difference between the actual 0x3FE code width and its
ideal (1LSB) is used.
• Differential non-linearity (DNL) — This error is defined as the worst-case difference between the
actual code width and the ideal code width for all conversions.
• Integral non-linearity (INL) — This error is defined as the highest-value the (absolute value of the)
running sum of DNL achieves. More simply, this is the worst-case difference of the actual
transition voltage to a given code and its corresponding ideal transition voltage, for all codes.
• Total unadjusted error (TUE) — This error is defined as the difference between the actual transfer
function and the ideal straight-line transfer function and includes all forms of error.
10.6.2.6
Code Jitter, Non-Monotonicity, and Missing Codes
Analog-to-digital converters are susceptible to three special forms of error. These are code jitter,
non-monotonicity, and missing codes.
Code jitter is when, at certain points, a given input voltage converts to one of two values when sampled
repeatedly. Ideally, when the input voltage is infinitesimally smaller than the transition voltage, the
converter yields the lower code (and vice-versa). However, even small amounts of system noise can cause
the converter to be indeterminate (between two codes) for a range of input voltages around the transition
voltage. This range is normally around 1/2lsb in 8-bit or 10-bit mode, or around 2 lsb in 12-bit mode, and
increases with noise.
This error may be reduced by repeatedly sampling the input and averaging the result. Additionally the
techniques discussed in Section 10.6.2.3 reduces this error.
Non-monotonicity is defined as when, except for code jitter, the converter converts to a lower code for a
higher input voltage. Missing codes are those values never converted for any input value.
In 8-bit or 10-bit mode, the ADC is guaranteed to be monotonic and have no missing codes.
MC9S08DZ60 Series Data Sheet, Rev. 4
198
Freescale Semiconductor
Chapter 11
Inter-Integrated Circuit (S08IICV2)
11.1
Introduction
The inter-integrated circuit (IIC) provides a method of communication between a number of devices. The
interface is designed to operate up to 100 kbps with maximum bus loading and timing. The device is
capable of operating at higher baud rates, up to a maximum of clock/20, with reduced bus loading. The
maximum communication length and the number of devices that can be connected are limited by a
maximum bus capacitance of 400 pF.
All MC9S08DZ60 Series MCUs feature the IIC, as shown in the following block diagram.
NOTE
Drive strength must be disabled (DSE=0) for the IIC pins when using the
IIC module for correct operation.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
199
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 11 Inter-Integrated Circuit (S08IICV2)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 11-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
200
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.1.1
Features
The IIC includes these distinctive features:
• Compatible with IIC bus standard
• Multi-master operation
• Software programmable for one of 64 different serial clock frequencies
• Software selectable acknowledge bit
• Interrupt driven byte-by-byte data transfer
• Arbitration lost interrupt with automatic mode switching from master to slave
• Calling address identification interrupt
• Start and stop signal generation/detection
• Repeated start signal generation
• Acknowledge bit generation/detection
• Bus busy detection
• General call recognition
• 10-bit address extension
11.1.2
Modes of Operation
A brief description of the IIC in the various MCU modes is given here.
• Run mode — This is the basic mode of operation. To conserve power in this mode, disable the
module.
• Wait mode — The module continues to operate while the MCU is in wait mode and can provide
a wake-up interrupt.
• Stop mode — The IIC is inactive in stop3 mode for reduced power consumption. The stop
instruction does not affect IIC register states. Stop2 resets the register contents.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
201
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.1.3
Block Diagram
Figure 11-2 is a block diagram of the IIC.
Address
Data Bus
Interrupt
ADDR_DECODE
CTRL_REG
DATA_MUX
FREQ_REG
ADDR_REG
STATUS_REG
DATA_REG
Input
Sync
Start
Stop
Arbitration
Control
Clock
Control
In/Out
Data
Shift
Register
Address
Compare
SCL
SDA
Figure 11-2. IIC Functional Block Diagram
11.2
External Signal Description
This section describes each user-accessible pin signal.
11.2.1
SCL — Serial Clock Line
The bidirectional SCL is the serial clock line of the IIC system.
11.2.2
SDA — Serial Data Line
The bidirectional SDA is the serial data line of the IIC system.
11.3
Register Definition
This section consists of the IIC register descriptions in address order.
MC9S08DZ60 Series Data Sheet, Rev. 4
202
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
Refer to the direct-page register summary in the memory chapter of this document for the absolute address
assignments for all IIC registers. This section refers to registers and control bits only by their names. A
Freescale-provided equate or header file is used to translate these names into the appropriate absolute
addresses.
11.3.1
IIC Address Register (IICA)
7
6
5
4
3
2
1
AD7
AD6
AD5
AD4
AD3
AD2
AD1
0
0
0
0
0
0
0
R
0
0
W
Reset
0
= Unimplemented or Reserved
Figure 11-3. IIC Address Register (IICA)
Table 11-1. IICA Field Descriptions
Field
Description
7–1
AD[7:1]
Slave Address. The AD[7:1] field contains the slave address to be used by the IIC module. This field is used on
the 7-bit address scheme and the lower seven bits of the 10-bit address scheme.
11.3.2
IIC Frequency Divider Register (IICF)
7
6
5
4
3
2
1
0
0
0
0
R
MULT
ICR
W
Reset
0
0
0
0
0
Figure 11-4. IIC Frequency Divider Register (IICF)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
203
Chapter 11 Inter-Integrated Circuit (S08IICV2)
Table 11-2. IICF Field Descriptions
Field
7–6
MULT
5–0
ICR
Description
IIC Multiplier Factor. The MULT bits define the multiplier factor, mul. This factor, along with the SCL divider,
generates the IIC baud rate. The multiplier factor mul as defined by the MULT bits is provided below.
00 mul = 01
01 mul = 02
10 mul = 04
11 Reserved
IIC Clock Rate. The ICR bits are used to prescale the bus clock for bit rate selection. These bits and the MULT
bits determine the IIC baud rate, the SDA hold time, the SCL Start hold time, and the SCL Stop hold time.
Table 11-4 provides the SCL divider and hold values for corresponding values of the ICR.
The SCL divider multiplied by multiplier factor mul generates IIC baud rate.
bus speed (Hz)
IIC baud rate = --------------------------------------------mul × SCLdivider
Eqn. 11-1
SDA hold time is the delay from the falling edge of SCL (IIC clock) to the changing of SDA (IIC data).
SDA hold time = bus period (s) × mul × SDA hold value
Eqn. 11-2
SCL start hold time is the delay from the falling edge of SDA (IIC data) while SCL is high (Start condition) to the
falling edge of SCL (IIC clock).
SCL Start hold time = bus period (s) × mul × SCL Start hold value
Eqn. 11-3
SCL stop hold time is the delay from the rising edge of SCL (IIC clock) to the rising edge of SDA
SDA (IIC data) while SCL is high (Stop condition).
SCL Stop hold time = bus period (s) × mul × SCL Stop hold value
Eqn. 11-4
For example, if the bus speed is 8 MHz, the table below shows the possible hold time values with different
ICR and MULT selections to achieve an IIC baud rate of 100kbps.
Table 11-3. Hold Time Values for 8 MHz Bus Speed
Hold Times (μs)
MULT
ICR
SDA
SCL Start
SCL Stop
0x2
0x00
3.500
3.000
5.500
0x1
0x07
2.500
4.000
5.250
0x1
0x0B
2.250
4.000
5.250
0x0
0x14
2.125
4.250
5.125
0x0
0x18
1.125
4.750
5.125
MC9S08DZ60 Series Data Sheet, Rev. 4
204
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
Table 11-4. IIC Divider and Hold Values
ICR
(hex)
SCL
Divider
SDA Hold
Value
SCL Hold
(Start)
Value
SDA Hold
(Stop)
Value
ICR
(hex)
SCL
Divider
SDA Hold
Value
SCL Hold
(Start)
Value
SCL Hold
(Stop)
Value
00
20
7
6
11
20
160
17
78
81
01
22
7
7
12
21
192
17
94
97
02
24
8
8
13
22
224
33
110
113
03
26
8
9
14
23
256
33
126
129
04
28
9
10
15
24
288
49
142
145
05
30
9
11
16
25
320
49
158
161
06
34
10
13
18
26
384
65
190
193
07
40
10
16
21
27
480
65
238
241
08
28
7
10
15
28
320
33
158
161
09
32
7
12
17
29
384
33
190
193
0A
36
9
14
19
2A
448
65
222
225
0B
40
9
16
21
2B
512
65
254
257
0C
44
11
18
23
2C
576
97
286
289
0D
48
11
20
25
2D
640
97
318
321
0E
56
13
24
29
2E
768
129
382
385
0F
68
13
30
35
2F
960
129
478
481
10
48
9
18
25
30
640
65
318
321
11
56
9
22
29
31
768
65
382
385
12
64
13
26
33
32
896
129
446
449
13
72
13
30
37
33
1024
129
510
513
14
80
17
34
41
34
1152
193
574
577
15
88
17
38
45
35
1280
193
638
641
16
104
21
46
53
36
1536
257
766
769
17
128
21
58
65
37
1920
257
958
961
18
80
9
38
41
38
1280
129
638
641
19
96
9
46
49
39
1536
129
766
769
1A
112
17
54
57
3A
1792
257
894
897
1B
128
17
62
65
3B
2048
257
1022
1025
1C
144
25
70
73
3C
2304
385
1150
1153
1D
160
25
78
81
3D
2560
385
1278
1281
1E
192
33
94
97
3E
3072
513
1534
1537
1F
240
33
118
121
3F
3840
513
1918
1921
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
205
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.3.3
IIC Control Register (IICC1)
7
6
5
4
3
IICEN
IICIE
MST
TX
TXAK
R
W
Reset
2
1
0
0
0
0
0
0
RSTA
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 11-5. IIC Control Register (IICC1)
Table 11-5. IICC1 Field Descriptions
Field
Description
7
IICEN
IIC Enable. The IICEN bit determines whether the IIC module is enabled.
0 IIC is not enabled
1 IIC is enabled
6
IICIE
IIC Interrupt Enable. The IICIE bit determines whether an IIC interrupt is requested.
0 IIC interrupt request not enabled
1 IIC interrupt request enabled
5
MST
Master Mode Select. The MST bit changes from a 0 to a 1 when a start signal is generated on the bus and
master mode is selected. When this bit changes from a 1 to a 0 a stop signal is generated and the mode of
operation changes from master to slave.
0 Slave mode
1 Master mode
4
TX
Transmit Mode Select. The TX bit selects the direction of master and slave transfers. In master mode, this bit
should be set according to the type of transfer required. Therefore, for address cycles, this bit is always high.
When addressed as a slave, this bit should be set by software according to the SRW bit in the status register.
0 Receive
1 Transmit
3
TXAK
Transmit Acknowledge Enable. This bit specifies the value driven onto the SDA during data acknowledge
cycles for master and slave receivers.
0 An acknowledge signal is sent out to the bus after receiving one data byte
1 No acknowledge signal response is sent
2
RSTA
Repeat start. Writing a 1 to this bit generates a repeated start condition provided it is the current master. This
bit is always read as cleared. Attempting a repeat at the wrong time results in loss of arbitration.
MC9S08DZ60 Series Data Sheet, Rev. 4
206
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.3.4
IIC Status Register (IICS)
7
R
6
TCF
5
4
BUSY
IAAS
3
2
0
SRW
ARBL
1
0
RXAK
IICIF
W
Reset
1
0
0
0
0
0
0
0
= Unimplemented or Reserved
Figure 11-6. IIC Status Register (IICS)
Table 11-6. IICS Field Descriptions
Field
Description
7
TCF
Transfer Complete Flag. This bit is set on the completion of a byte transfer. This bit is only valid during or
immediately following a transfer to the IIC module or from the IIC module.The TCF bit is cleared by reading the
IICD register in receive mode or writing to the IICD in transmit mode.
0 Transfer in progress
1 Transfer complete
6
IAAS
Addressed as a Slave. The IAAS bit is set when the calling address matches the programmed slave address
or when the GCAEN bit is set and a general call is received. Writing the IICC register clears this bit.
0 Not addressed
1 Addressed as a slave
5
BUSY
Bus Busy. The BUSY bit indicates the status of the bus regardless of slave or master mode. The BUSY bit is
set when a start signal is detected and cleared when a stop signal is detected.
0 Bus is idle
1 Bus is busy
4
ARBL
Arbitration Lost. This bit is set by hardware when the arbitration procedure is lost. The ARBL bit must be cleared
by software by writing a 1 to it.
0 Standard bus operation
1 Loss of arbitration
2
SRW
Slave Read/Write. When addressed as a slave, the SRW bit indicates the value of the R/W command bit of the
calling address sent to the master.
0 Slave receive, master writing to slave
1 Slave transmit, master reading from slave
1
IICIF
IIC Interrupt Flag. The IICIF bit is set when an interrupt is pending. This bit must be cleared by software, by
writing a 1 to it in the interrupt routine. One of the following events can set the IICIF bit:
• One byte transfer completes
• Match of slave address to calling address
• Arbitration lost
0 No interrupt pending
1 Interrupt pending
0
RXAK
Receive Acknowledge. When the RXAK bit is low, it indicates an acknowledge signal has been received after
the completion of one byte of data transmission on the bus. If the RXAK bit is high it means that no acknowledge
signal is detected.
0 Acknowledge received
1 No acknowledge received
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
207
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.3.5
IIC Data I/O Register (IICD)
7
6
5
4
3
2
1
0
0
0
0
0
R
DATA
W
Reset
0
0
0
0
Figure 11-7. IIC Data I/O Register (IICD)
Table 11-7. IICD Field Descriptions
Field
Description
7–0
DATA
Data — In master transmit mode, when data is written to the IICD, a data transfer is initiated. The most significant
bit is sent first. In master receive mode, reading this register initiates receiving of the next byte of data.
NOTE
When transitioning out of master receive mode, the IIC mode should be
switched before reading the IICD register to prevent an inadvertent
initiation of a master receive data transfer.
In slave mode, the same functions are available after an address match has occurred.
The TX bit in IICC must correctly reflect the desired direction of transfer in master and slave modes for
the transmission to begin. For instance, if the IIC is configured for master transmit but a master receive is
desired, reading the IICD does not initiate the receive.
Reading the IICD returns the last byte received while the IIC is configured in master receive or slave
receive modes. The IICD does not reflect every byte transmitted on the IIC bus, nor can software verify
that a byte has been written to the IICD correctly by reading it back.
In master transmit mode, the first byte of data written to IICD following assertion of MST is used for the
address transfer and should comprise of the calling address (in bit 7 to bit 1) concatenated with the required
R/W bit (in position bit 0).
11.3.6
IIC Control Register 2 (IICC2)
7
6
GCAEN
ADEXT
0
0
R
5
4
3
0
0
0
2
1
0
AD10
AD9
AD8
0
0
0
W
Reset
0
0
0
= Unimplemented or Reserved
Figure 11-8. IIC Control Register (IICC2)
MC9S08DZ60 Series Data Sheet, Rev. 4
208
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
Table 11-8. IICC2 Field Descriptions
Field
Description
7
GCAEN
General Call Address Enable. The GCAEN bit enables or disables general call address.
0 General call address is disabled
1 General call address is enabled
6
ADEXT
Address Extension. The ADEXT bit controls the number of bits used for the slave address.
0 7-bit address scheme
1 10-bit address scheme
2–0
AD[10:8]
Slave Address. The AD[10:8] field contains the upper three bits of the slave address in the 10-bit address
scheme. This field is only valid when the ADEXT bit is set.
11.4
Functional Description
This section provides a complete functional description of the IIC module.
11.4.1
IIC Protocol
The IIC bus system uses a serial data line (SDA) and a serial clock line (SCL) for data transfer. All devices
connected to it must have open drain or open collector outputs. A logic AND function is exercised on both
lines with external pull-up resistors. The value of these resistors is system dependent.
Normally, a standard communication is composed of four parts:
• Start signal
• Slave address transmission
• Data transfer
• Stop signal
The stop signal should not be confused with the CPU stop instruction. The IIC bus system communication
is described briefly in the following sections and illustrated in Figure 11-9.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
209
Chapter 11 Inter-Integrated Circuit (S08IICV2)
msb
SCL
1
SDA
lsb
2
3
4
5
6
7
8
msb
9
AD7 AD6 AD5 AD4 AD3 AD2 AD1 R/W
Start
Signal
1
SDA
3
4
5
6
7
8
Calling Address
3
4
5
6
7
8
D7
D6
D5
D4
D3
D2
D1
D0
1
XX
Read/ Ack
Write Bit
Repeated
Start
Signal
9
No
Ack
Bit
msb
9
AD7 AD6 AD5 AD4 AD3 AD2 AD1 R/W
Start
Signal
2
Data Byte
lsb
2
1
Read/ Ack
Write Bit
Calling Address
msb
SCL
XXX
lsb
Stop
Signal
lsb
2
3
4
5
6
7
8
9
AD7 AD6 AD5 AD4 AD3 AD2 AD1 R/W
New Calling Address
Read/
Write
No
Ack
Bit
Stop
Signal
Figure 11-9. IIC Bus Transmission Signals
11.4.1.1
Start Signal
When the bus is free, no master device is engaging the bus (SCL and SDA lines are at logical high), a
master may initiate communication by sending a start signal. As shown in Figure 11-9, a start signal is
defined as a high-to-low transition of SDA while SCL is high. This signal denotes the beginning of a new
data transfer (each data transfer may contain several bytes of data) and brings all slaves out of their idle
states.
11.4.1.2
Slave Address Transmission
The first byte of data transferred immediately after the start signal is the slave address transmitted by the
master. This is a seven-bit calling address followed by a R/W bit. The R/W bit tells the slave the desired
direction of data transfer.
1 = Read transfer, the slave transmits data to the master.
0 = Write transfer, the master transmits data to the slave.
Only the slave with a calling address that matches the one transmitted by the master responds by sending
back an acknowledge bit. This is done by pulling the SDA low at the ninth clock (see Figure 11-9).
No two slaves in the system may have the same address. If the IIC module is the master, it must not transmit
an address equal to its own slave address. The IIC cannot be master and slave at the same time. However,
if arbitration is lost during an address cycle, the IIC reverts to slave mode and operates correctly even if it
is being addressed by another master.
MC9S08DZ60 Series Data Sheet, Rev. 4
210
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.4.1.3
Data Transfer
Before successful slave addressing is achieved, the data transfer can proceed byte-by-byte in a direction
specified by the R/W bit sent by the calling master.
All transfers that come after an address cycle are referred to as data transfers, even if they carry sub-address
information for the slave device
Each data byte is 8 bits long. Data may be changed only while SCL is low and must be held stable while
SCL is high as shown in Figure 11-9. There is one clock pulse on SCL for each data bit, the msb being
transferred first. Each data byte is followed by a 9th (acknowledge) bit, which is signalled from the
receiving device. An acknowledge is signalled by pulling the SDA low at the ninth clock. In summary, one
complete data transfer needs nine clock pulses.
If the slave receiver does not acknowledge the master in the ninth bit time, the SDA line must be left high
by the slave. The master interprets the failed acknowledge as an unsuccessful data transfer.
If the master receiver does not acknowledge the slave transmitter after a data byte transmission, the slave
interprets this as an end of data transfer and releases the SDA line.
In either case, the data transfer is aborted and the master does one of two things:
• Relinquishes the bus by generating a stop signal.
• Commences a new calling by generating a repeated start signal.
11.4.1.4
Stop Signal
The master can terminate the communication by generating a stop signal to free the bus. However, the
master may generate a start signal followed by a calling command without generating a stop signal first.
This is called repeated start. A stop signal is defined as a low-to-high transition of SDA while SCL at
logical 1 (see Figure 11-9).
The master can generate a stop even if the slave has generated an acknowledge at which point the slave
must release the bus.
11.4.1.5
Repeated Start Signal
As shown in Figure 11-9, a repeated start signal is a start signal generated without first generating a stop
signal to terminate the communication. This is used by the master to communicate with another slave or
with the same slave in different mode (transmit/receive mode) without releasing the bus.
11.4.1.6
Arbitration Procedure
The IIC bus is a true multi-master bus that allows more than one master to be connected on it. If two or
more masters try to control the bus at the same time, a clock synchronization procedure determines the bus
clock, for which the low period is equal to the longest clock low period and the high is equal to the shortest
one among the masters. The relative priority of the contending masters is determined by a data arbitration
procedure, a bus master loses arbitration if it transmits logic 1 while another master transmits logic 0. The
losing masters immediately switch over to slave receive mode and stop driving SDA output. In this case,
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
211
Chapter 11 Inter-Integrated Circuit (S08IICV2)
the transition from master to slave mode does not generate a stop condition. Meanwhile, a status bit is set
by hardware to indicate loss of arbitration.
11.4.1.7
Clock Synchronization
Because wire-AND logic is performed on the SCL line, a high-to-low transition on the SCL line affects all
the devices connected on the bus. The devices start counting their low period and after a device’s clock has
gone low, it holds the SCL line low until the clock high state is reached. However, the change of low to
high in this device clock may not change the state of the SCL line if another device clock is still within its
low period. Therefore, synchronized clock SCL is held low by the device with the longest low period.
Devices with shorter low periods enter a high wait state during this time (see Figure 11-10). When all
devices concerned have counted off their low period, the synchronized clock SCL line is released and
pulled high. There is then no difference between the device clocks and the state of the SCL line and all the
devices start counting their high periods. The first device to complete its high period pulls the SCL line
low again.
Delay
Start Counting High Period
SCL1
SCL2
SCL
Internal Counter Reset
Figure 11-10. IIC Clock Synchronization
11.4.1.8
Handshaking
The clock synchronization mechanism can be used as a handshake in data transfer. Slave devices may hold
the SCL low after completion of one byte transfer (9 bits). In such a case, it halts the bus clock and forces
the master clock into wait states until the slave releases the SCL line.
11.4.1.9
Clock Stretching
The clock synchronization mechanism can be used by slaves to slow down the bit rate of a transfer. After
the master has driven SCL low the slave can drive SCL low for the required period and then release it. If
the slave SCL low period is greater than the master SCL low period then the resulting SCL bus signal low
period is stretched.
MC9S08DZ60 Series Data Sheet, Rev. 4
212
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.4.2
10-bit Address
For 10-bit addressing, 0x11110 is used for the first 5 bits of the first address byte. Various combinations of
read/write formats are possible within a transfer that includes 10-bit addressing.
11.4.2.1
Master-Transmitter Addresses a Slave-Receiver
The transfer direction is not changed (see Table 11-9). When a 10-bit address follows a start condition,
each slave compares the first seven bits of the first byte of the slave address (11110XX) with its own
address and tests whether the eighth bit (R/W direction bit) is 0. More than one device can find a match
and generate an acknowledge (A1). Then, each slave that finds a match compares the eight bits of the
second byte of the slave address with its own address. Only one slave finds a match and generates an
acknowledge (A2). The matching slave remains addressed by the master until it receives a stop condition
(P) or a repeated start condition (Sr) followed by a different slave address.
S
Slave Address 1st 7 bits
R/W
11110 + AD10 + AD9
0
A1
Slave Address 2nd byte
AD[8:1]
A2
Data
A
...
Data
A/A
P
Table 11-9. Master-Transmitter Addresses Slave-Receiver with a 10-bit Address
After the master-transmitter has sent the first byte of the 10-bit address, the slave-receiver sees an IIC
interrupt. Software must ensure the contents of IICD are ignored and not treated as valid data for this
interrupt.
11.4.2.2
Master-Receiver Addresses a Slave-Transmitter
The transfer direction is changed after the second R/W bit (see Table 11-10). Up to and including
acknowledge bit A2, the procedure is the same as that described for a master-transmitter addressing a
slave-receiver. After the repeated start condition (Sr), a matching slave remembers that it was addressed
before. This slave then checks whether the first seven bits of the first byte of the slave address following
Sr are the same as they were after the start condition (S) and tests whether the eighth (R/W) bit is 1. If there
is a match, the slave considers that it has been addressed as a transmitter and generates acknowledge A3.
The slave-transmitter remains addressed until it receives a stop condition (P) or a repeated start condition
(Sr) followed by a different slave address.
After a repeated start condition (Sr), all other slave devices also compare the first seven bits of the first byte
of the slave address with their own addresses and test the eighth (R/W) bit. However, none of them are
addressed because R/W = 1 (for 10-bit devices) or the 11110XX slave address (for 7-bit devices) does not
match.
S
Slave Address
1st 7 bits
R/W
11110 + AD10 + AD9
0
A1
Slave Address
2nd byte
AD[8:1]
A2
Sr
Slave Address
1st 7 bits
R/W
11110 + AD10 + AD9
1
A3
Data
A
...
Data
A
P
Table 11-10. Master-Receiver Addresses a Slave-Transmitter with a 10-bit Address
After the master-receiver has sent the first byte of the 10-bit address, the slave-transmitter sees an IIC
interrupt. Software must ensure the contents of IICD are ignored and not treated as valid data for this
interrupt.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
213
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.4.3
General Call Address
General calls can be requested in 7-bit address or 10-bit address. If the GCAEN bit is set, the IIC matches
the general call address as well as its own slave address. When the IIC responds to a general call, it acts as
a slave-receiver and the IAAS bit is set after the address cycle. Software must read the IICD register after
the first byte transfer to determine whether the address matches is its own slave address or a general call.
If the value is 00, the match is a general call. If the GCAEN bit is clear, the IIC ignores any data supplied
from a general call address by not issuing an acknowledgement.
11.5
Resets
The IIC is disabled after reset. The IIC cannot cause an MCU reset.
11.6
Interrupts
The IIC generates a single interrupt.
An interrupt from the IIC is generated when any of the events in Table 11-11 occur, provided the IICIE bit
is set. The interrupt is driven by bit IICIF (of the IIC status register) and masked with bit IICIE (of the IIC
control register). The IICIF bit must be cleared by software by writing a 1 to it in the interrupt routine. You
can determine the interrupt type by reading the status register.
Table 11-11. Interrupt Summary
11.6.1
Interrupt Source
Status
Flag
Local Enable
Complete 1-byte transfer
TCF
IICIF
IICIE
Match of received calling address
IAAS
IICIF
IICIE
Arbitration Lost
ARBL
IICIF
IICIE
Byte Transfer Interrupt
The TCF (transfer complete flag) bit is set at the falling edge of the ninth clock to indicate the completion
of byte transfer.
11.6.2
Address Detect Interrupt
When the calling address matches the programmed slave address (IIC address register) or when the
GCAEN bit is set and a general call is received, the IAAS bit in the status register is set. The CPU is
interrupted, provided the IICIE is set. The CPU must check the SRW bit and set its Tx mode accordingly.
11.6.3
Arbitration Lost Interrupt
The IIC is a true multi-master bus that allows more than one master to be connected on it. If two or more
masters try to control the bus at the same time, the relative priority of the contending masters is determined
by a data arbitration procedure. The IIC module asserts this interrupt when it loses the data arbitration
process and the ARBL bit in the status register is set.
MC9S08DZ60 Series Data Sheet, Rev. 4
214
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
Arbitration is lost in the following circumstances:
• SDA sampled as a low when the master drives a high during an address or data transmit cycle.
• SDA sampled as a low when the master drives a high during the acknowledge bit of a data receive
cycle.
• A start cycle is attempted when the bus is busy.
• A repeated start cycle is requested in slave mode.
• A stop condition is detected when the master did not request it.
This bit must be cleared by software writing a 1 to it.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
215
Chapter 11 Inter-Integrated Circuit (S08IICV2)
11.7
1.
2.
3.
4.
5.
1.
2.
3.
4.
5.
6.
7.
Initialization/Application Information
Module Initialization (Slave)
Write: IICC2
— to enable or disable general call
— to select 10-bit or 7-bit addressing mode
Write: IICA
— to set the slave address
Write: IICC1
— to enable IIC and interrupts
Initialize RAM variables (IICEN = 1 and IICIE = 1) for transmit data
Initialize RAM variables used to achieve the routine shown in Figure 11-12
Module Initialization (Master)
Write: IICF
— to set the IIC baud rate (example provided in this chapter)
Write: IICC1
— to enable IIC and interrupts
Initialize RAM variables (IICEN = 1 and IICIE = 1) for transmit data
Initialize RAM variables used to achieve the routine shown in Figure 11-12
Write: IICC1
— to enable TX
Write: IICC1
— to enable MST (master mode)
Write: IICD
— with the address of the target slave. (The lsb of this byte determines whether the communication is
master receive or transmit.)
Module Use
The routine shown in Figure 11-12 can handle both master and slave IIC operations. For slave operation, an
incoming IIC message that contains the proper address begins IIC communication. For master operation,
communication must be initiated by writing to the IICD register.
Register Model
0
AD[7:1]
IICA
When addressed as a slave (in slave mode), the module responds to this address
MULT
IICF
ICR
Baud rate = BUSCLK / (2 x MULT x (SCL DIVIDER))
IICC1
IICEN
IICIE
MST
TX
TXAK
RSTA
0
0
BUSY
ARBL
0
SRW
IICIF
RXAK
AD9
AD8
Module configuration
IICS
TCF
IAAS
Module status flags
DATA
IICD
Data register; Write to transmit IIC data read to read IIC data
IICC2 GCAEN ADEXT
0
0
0
AD10
Address configuration
Figure 11-11. IIC Module Quick Start
MC9S08DZ60 Series Data Sheet, Rev. 4
216
Freescale Semiconductor
Chapter 11 Inter-Integrated Circuit (S08IICV2)
Clear
IICIF
Master
Mode
?
Y
TX
N
Y
RX
Tx/Rx
?
Arbitration
Lost
?
N
Last Byte
Transmitted
?
N
Clear ARBL
Y
RXAK=0
?
Last
Byte to Be Read
?
N
N
N
Y
Y
IAAS=1
?
Y
IAAS=1
?
Y
Address Transfer
See Note 1
Y
End of
Addr Cycle
(Master Rx)
?
Y
Y
(Read)
2nd Last
Byte to Be Read
?
N
SRW=1
?
Write Next
Byte to IICD
Set TXACK =1
Generate
Stop Signal
(MST = 0)
Switch to
Rx Mode
Generate
Stop Signal
(MST = 0)
Read Data
from IICD
and Store
ACK from
Receiver
?
N
Read Data
from IICD
and Store
Tx Next
Byte
Write Data
to IICD
Dummy Read
from IICD
TX
Y
Set TX
Mode
RX
TX/RX
?
N (Write)
N
N
Data Transfer
See Note 2
Set RX
Mode
Switch to
Rx Mode
Dummy Read
from IICD
Dummy Read
from IICD
RTI
NOTES:
1. If general call is enabled, a check must be done to determine whether the received address was a general call address (0x00). If the received address was a
general call address, then the general call must be handled by user software.
2. When 10-bit addressing is used to address a slave, the slave sees an interrupt following the first byte of the extended address. User software must ensure that for
this interrupt, the contents of IICD are ignored and not treated as a valid data transfer
Figure 11-12. Typical IIC Interrupt Routine
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
217
Chapter 11 Inter-Integrated Circuit (S08IICV2)
MC9S08DZ60 Series Data Sheet, Rev. 4
218
Freescale Semiconductor
Chapter 12
Freescale Controller Area Network (S08MSCANV1)
12.1
Introduction
The Freescale controller area network (MSCAN) is a communication controller implementing the CAN
2.0A/B protocol as defined in the Bosch specification dated September 1991. To fully understand the
MSCAN specification, it is recommended that the Bosch specification be read first to gain familiarity with
the terms and concepts contained within this document.
Though not exclusively intended for automotive applications, CAN protocol is designed to meet the
specific requirements of a vehicle serial data bus: real-time processing, reliable operation in the EMI
environment of a vehicle, cost-effectiveness, and required bandwidth.
MSCAN uses an advanced buffer arrangement resulting in predictable real-time behavior and simplified
application software.
The MSCAN module is available in all devices in the MC9S08DZ60 Series.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
219
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 12 Freescale Controller Area Network (S08MSCANV1)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 12-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
220
Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.1.1
Features
The basic features of the MSCAN are as follows:
• Implementation of the CAN protocol — Version 2.0A/B
— Standard and extended data frames
— Zero to eight bytes data length
— Programmable bit rate up to 1 Mbps1
— Support for remote frames
• Five receive buffers with FIFO storage scheme
• Three transmit buffers with internal prioritization using a “local priority” concept
• Flexible maskable identifier filter supports two full-size (32-bit) extended identifier filters, or four
16-bit filters, or eight 8-bit filters
• Programmable wakeup functionality with integrated low-pass filter
• Programmable loopback mode supports self-test operation
• Programmable listen-only mode for monitoring of CAN bus
• Programmable bus-off recovery functionality
• Separate signalling and interrupt capabilities for all CAN receiver and transmitter error states
(warning, error passive, bus-off)
• Programmable MSCAN clock source either bus clock or oscillator clock
• Internal timer for time-stamping of received and transmitted messages
• Three low-power modes: sleep, power down, and MSCAN enable
• Global initialization of configuration registers
12.1.2
Modes of Operation
The following modes of operation are specific to the MSCAN. See Section 12.5, “Functional Description,”
for details.
• Listen-Only Mode
• MSCAN Sleep Mode
• MSCAN Initialization Mode
• MSCAN Power Down Mode
• Loopback Self Test Mode
1. Depending on the actual bit timing and the clock jitter of the PLL.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
221
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.1.3
Block Diagram
MSCAN
Oscillator Clock
Bus Clock
CANCLK
MUX
Presc.
Tq Clk
Receive/
Transmit
Engine
RXCAN
TXCAN
Transmit Interrupt Req.
Receive Interrupt Req.
Message
Filtering
and
Buffering
Control
and
Status
Errors Interrupt Req.
Wake-Up Interrupt Req.
Configuration
Registers
Wake-Up
Low Pass Filter
Figure 12-2. MSCAN Block Diagram
12.2
External Signal Description
The MSCAN uses two external pins:
12.2.1
RXCAN — CAN Receiver Input Pin
RXCAN is the MSCAN receiver input pin.
12.2.2
TXCAN — CAN Transmitter Output Pin
TXCAN is the MSCAN transmitter output pin. The TXCAN output pin represents the logic level on the
CAN bus:
0 = Dominant state
1 = Recessive state
12.2.3
CAN System
A typical CAN system with MSCAN is shown in Figure 12-3. Each CAN node is connected physically to
the CAN bus lines through a transceiver device. The transceiver is capable of driving the large current
needed for the CAN bus and has current protection against defective CAN or defective nodes.
MC9S08DZ60 Series Data Sheet, Rev. 4
222
Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
CAN node 2
CAN node 1
CAN node n
MCU
CAN Controller
(MSCAN)
TXCAN
RXCAN
Transceiver
CAN_H
CAN_L
CAN Bus
Figure 12-3. CAN System
12.3
Register Definition
This section describes in detail all the registers and register bits in the MSCAN module. Each description
includes a standard register diagram with an associated figure number. Details of register bit and field
function follow the register diagrams, in bit order. All bits of all registers in this module are completely
synchronous to internal clocks during a register read.
12.3.1
MSCAN Control Register 0 (CANCTL0)
The CANCTL0 register provides various control bits of the MSCAN module as described below.
R
7
6
RXFRM
RXACT
5
4
3
2
1
0
TIME
WUPE
SLPRQ
INITRQ
0
0
0
1
SYNCH
CSWAI
W
Reset:
0
0
0
0
= Unimplemented
Figure 12-4. MSCAN Control Register 0 (CANCTL0)
NOTE
The CANCTL0 register, except WUPE, INITRQ, and SLPRQ, is held in the
reset state when the initialization mode is active (INITRQ = 1 and
INITAK = 1). This register is writable again as soon as the initialization
mode is exited (INITRQ = 0 and INITAK = 0).
Read: Anytime
Write: Anytime when out of initialization mode; exceptions are read-only RXACT and SYNCH, RXFRM
(which is set by the module only), and INITRQ (which is also writable in initialization mode).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
223
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-1. CANCTL0 Register Field Descriptions
Field
Description
7
RXFRM1
Received Frame Flag — This bit is read and clear only. It is set when a receiver has received a valid message
correctly, independently of the filter configuration. After it is set, it remains set until cleared by software or reset.
Clearing is done by writing a 1. Writing a 0 is ignored. This bit is not valid in loopback mode.
0 No valid message was received since last clearing this flag
1 A valid message was received since last clearing of this flag
6
RXACT
Receiver Active Status — This read-only flag indicates the MSCAN is receiving a message. The flag is
controlled by the receiver front end. This bit is not valid in loopback mode.
0 MSCAN is transmitting or idle2
1 MSCAN is receiving a message (including when arbitration is lost)2
5
CSWAI3
CAN Stops in Wait Mode — Enabling this bit allows for lower power consumption in wait mode by disabling all
the clocks at the CPU bus interface to the MSCAN module.
0 The module is not affected during wait mode
1 The module ceases to be clocked during wait mode
4
SYNCH
Synchronized Status — This read-only flag indicates whether the MSCAN is synchronized to the CAN bus and
able to participate in the communication process. It is set and cleared by the MSCAN.
0 MSCAN is not synchronized to the CAN bus
1 MSCAN is synchronized to the CAN bus
3
TIME
Timer Enable — This bit activates an internal 16-bit wide free running timer which is clocked by the bit clock rate.
If the timer is enabled, a 16-bit time stamp will be assigned to each transmitted/received message within the
active TX/RX buffer. As soon as a message is acknowledged on the CAN bus, the time stamp will be written to
the highest bytes (0x000E, 0x000F) in the appropriate buffer (see Section 12.4, “Programmer’s Model of
Message Storage”). The internal timer is reset (all bits set to 0) when disabled. This bit is held low in initialization
mode.
0 Disable internal MSCAN timer
1 Enable internal MSCAN timer
2
WUPE4
Wake-Up Enable — This configuration bit allows the MSCAN to restart from sleep mode when traffic on CAN is
detected (see Section 12.5.5.4, “MSCAN Sleep Mode”). This bit must be configured before sleep mode entry for
the selected function to take effect.
0 Wake-up disabled — The MSCAN ignores traffic on CAN
1 Wake-up enabled — The MSCAN is able to restart
MC9S08DZ60 Series Data Sheet, Rev. 4
224
Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-1. CANCTL0 Register Field Descriptions (continued)
Field
Description
1
SLPRQ5
Sleep Mode Request — This bit requests the MSCAN to enter sleep mode, which is an internal power saving
mode (see Section 12.5.5.4, “MSCAN Sleep Mode”). The sleep mode request is serviced when the CAN bus is
idle, i.e., the module is not receiving a message and all transmit buffers are empty. The module indicates entry
to sleep mode by setting SLPAK = 1 (see Section 12.3.2, “MSCAN Control Register 1 (CANCTL1)”). SLPRQ
cannot be set while the WUPIF flag is set (see Section 12.3.4.1, “MSCAN Receiver Flag Register (CANRFLG)”).
Sleep mode will be active until SLPRQ is cleared by the CPU or, depending on the setting of WUPE, the MSCAN
detects activity on the CAN bus and clears SLPRQ itself.
0 Running — The MSCAN functions normally
1 Sleep mode request — The MSCAN enters sleep mode when CAN bus idle
0
INITRQ6,7
Initialization Mode Request — When this bit is set by the CPU, the MSCAN skips to initialization mode (see
Section 12.5.5.5, “MSCAN Initialization Mode”). Any ongoing transmission or reception is aborted and
synchronization to the CAN bus is lost. The module indicates entry to initialization mode by setting INITAK = 1
(Section 12.3.2, “MSCAN Control Register 1 (CANCTL1)”).
The following registers enter their hard reset state and restore their default values: CANCTL08, CANRFLG9,
CANRIER10, CANTFLG, CANTIER, CANTARQ, CANTAAK, and CANTBSEL.
The registers CANCTL1, CANBTR0, CANBTR1, CANIDAC, CANIDAR0-7, and CANIDMR0-7 can only be
written by the CPU when the MSCAN is in initialization mode (INITRQ = 1 and INITAK = 1). The values of the
error counters are not affected by initialization mode.
When this bit is cleared by the CPU, the MSCAN restarts and then tries to synchronize to the CAN bus. If the
MSCAN is not in bus-off state, it synchronizes after 11 consecutive recessive bits on the CAN bus; if the MSCAN
is in bus-off state, it continues to wait for 128 occurrences of 11 consecutive recessive bits.
Writing to other bits in CANCTL0, CANRFLG, CANRIER, CANTFLG, or CANTIER must be done only after
initialization mode is exited, which is INITRQ = 0 and INITAK = 0.
0 Normal operation
1 MSCAN in initialization mode
1
The MSCAN must be in normal mode for this bit to become set.
See the Bosch CAN 2.0A/B specification for a detailed definition of transmitter and receiver states.
3 In order to protect from accidentally violating the CAN protocol, the TXCAN pin is immediately forced to a recessive state when
the CPU enters wait (CSWAI = 1) or stop mode (see Section 12.5.5.2, “Operation in Wait Mode” and Section 12.5.5.3,
“Operation in Stop Mode”).
4 The CPU has to make sure that the WUPE bit and the WUPIE wake-up interrupt enable bit (see Section 12.3.5, “MSCAN
Receiver Interrupt Enable Register (CANRIER)) is enabled, if the recovery mechanism from stop or wait is required.
5 The CPU cannot clear SLPRQ before the MSCAN has entered sleep mode (SLPRQ = 1 and SLPAK = 1).
6 The CPU cannot clear INITRQ before the MSCAN has entered initialization mode (INITRQ = 1 and INITAK = 1).
7 In order to protect from accidentally violating the CAN protocol, the TXCAN pin is immediately forced to a recessive state when
the initialization mode is requested by the CPU. Thus, the recommended procedure is to bring the MSCAN into sleep mode
(SLPRQ = 1 and SLPAK = 1) before requesting initialization mode.
8 Not including WUPE, INITRQ, and SLPRQ.
9 TSTAT1 and TSTAT0 are not affected by initialization mode.
10 RSTAT1 and RSTAT0 are not affected by initialization mode.
2
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
225
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.3.2
MSCAN Control Register 1 (CANCTL1)
The CANCTL1 register provides various control bits and handshake status information of the MSCAN
module as described below.
7
6
5
4
3
2
CANE
CLKSRC
LOOPB
LISTEN
BORM
WUPM
0
0
0
1
0
0
R
1
0
SLPAK
INITAK
0
1
W
Reset:
= Unimplemented
Figure 12-5. MSCAN Control Register 1(CANCTL1)
Read: Anytime
Write: Anytime when INITRQ = 1 and INITAK = 1, except CANE which is write once in normal and
anytime in special system operation modes when the MSCAN is in initialization mode (INITRQ = 1 and
INITAK = 1).
Table 12-2. CANCTL1 Register Field Descriptions
Field
7
CANE
Description
MSCAN Enable
0 MSCAN module is disabled
1 MSCAN module is enabled
6
CLKSRC
MSCAN Clock Source — This bit defines the clock source for the MSCAN module (only for systems with a clock
generation module; Section 12.5.3.3, “Clock System,” and Section Figure 12-42., “MSCAN Clocking Scheme,”).
0 MSCAN clock source is the oscillator clock
1 MSCAN clock source is the bus clock
5
LOOPB
Loopback Self Test Mode — When this bit is set, the MSCAN performs an internal loopback which can be used
for self test operation. The bit stream output of the transmitter is fed back to the receiver
internally.Section 12.5.4.6, “Loopback Self Test Mode.
0 Loopback self test disabled
1 Loopback self test enabled
4
LISTEN
Listen Only Mode — This bit configures the MSCAN as a CAN bus monitor. When LISTEN is set, all valid CAN
messages with matching ID are received, but no acknowledgement or error frames are sent out (see
Section 12.5.4.4, “Listen-Only Mode”). In addition, the error counters are frozen. Listen only mode supports
applications which require “hot plugging” or throughput analysis. The MSCAN is unable to transmit any
messages when listen only mode is active.
0 Normal operation
1 Listen only mode activated
3
BORM
Bus-Off Recovery Mode — This bits configures the bus-off state recovery mode of the MSCAN. Refer to
Section 12.6.2, “Bus-Off Recovery,” for details.
0 Automatic bus-off recovery (see Bosch CAN 2.0A/B protocol specification)
1 Bus-off recovery upon user request
2
WUPM
Wake-Up Mode — If WUPE in CANCTL0 is enabled, this bit defines whether the integrated low-pass filter is
applied to protect the MSCAN from spurious wake-up (see Section 12.5.5.4, “MSCAN Sleep Mode”).
0 MSCAN wakes up on any dominant level on the CAN bus
1 MSCAN wakes up only in case of a dominant pulse on the CAN bus that has a length of Twup
MC9S08DZ60 Series Data Sheet, Rev. 4
226
Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-2. CANCTL1 Register Field Descriptions (continued)
Field
Description
1
SLPAK
Sleep Mode Acknowledge — This flag indicates whether the MSCAN module has entered sleep mode (see
Section 12.5.5.4, “MSCAN Sleep Mode”). It is used as a handshake flag for the SLPRQ sleep mode request.
Sleep mode is active when SLPRQ = 1 and SLPAK = 1. Depending on the setting of WUPE, the MSCAN will
clear the flag if it detects activity on the CAN bus while in sleep mode.CPU clearing the SLPRQ bit will also reset
the SLPAK bit.
0 Running — The MSCAN operates normally
1 Sleep mode active — The MSCAN has entered sleep mode
0
INITAK
Initialization Mode Acknowledge — This flag indicates whether the MSCAN module is in initialization mode
(see Section 12.5.5.5, “MSCAN Initialization Mode”). It is used as a handshake flag for the INITRQ initialization
mode request. Initialization mode is active when INITRQ = 1 and INITAK = 1. The registers CANCTL1,
CANBTR0, CANBTR1, CANIDAC, CANIDAR0–CANIDAR7, and CANIDMR0–CANIDMR7 can be written only by
the CPU when the MSCAN is in initialization mode.
0 Running — The MSCAN operates normally
1 Initialization mode active — The MSCAN is in initialization mode
12.3.3
MSCAN Bus Timing Register 0 (CANBTR0)
The CANBTR0 register configures various CAN bus timing parameters of the MSCAN module.
7
6
5
4
3
2
1
0
SJW1
SJW0
BRP5
BRP4
BRP3
BRP2
BRP1
BRP0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 12-6. MSCAN Bus Timing Register 0 (CANBTR0)
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1)
Table 12-3. CANBTR0 Register Field Descriptions
Field
Description
7:6
SJW[1:0]
Synchronization Jump Width — The synchronization jump width defines the maximum number of time quanta
(Tq) clock cycles a bit can be shortened or lengthened to achieve resynchronization to data transitions on the
CAN bus (see Table 12-4).
5:0
BRP[5:0]
Baud Rate Prescaler — These bits determine the time quanta (Tq) clock which is used to build up the bit timing
(see Table 12-5).
Table 12-4. Synchronization Jump Width
SJW1
SJW0
Synchronization Jump Width
0
0
1 Tq clock cycle
0
1
2 Tq clock cycles
1
0
3 Tq clock cycles
1
1
4 Tq clock cycles
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-5. Baud Rate Prescaler
12.3.4
BRP5
BRP4
BRP3
BRP2
BRP1
BRP0
Prescaler value (P)
0
0
0
0
0
0
1
0
0
0
0
0
1
2
0
0
0
0
1
0
3
0
0
0
0
1
1
4
:
:
:
:
:
:
:
1
1
1
1
1
1
64
MSCAN Bus Timing Register 1 (CANBTR1)
The CANBTR1 register configures various CAN bus timing parameters of the MSCAN module.
7
6
5
4
3
2
1
0
SAMP
TSEG22
TSEG21
TSEG20
TSEG13
TSEG12
TSEG11
TSEG10
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 12-7. MSCAN Bus Timing Register 1 (CANBTR1)
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1)
Table 12-6. CANBTR1 Register Field Descriptions
Field
Description
7
SAMP
Sampling — This bit determines the number of CAN bus samples taken per bit time.
0 One sample per bit.
1 Three samples per bit1.
If SAMP = 0, the resulting bit value is equal to the value of the single bit positioned at the sample point. If
SAMP = 1, the resulting bit value is determined by using majority rule on the three total samples. For higher bit
rates, it is recommended that only one sample is taken per bit time (SAMP = 0).
6:4
Time Segment 2 — Time segments within the bit time fix the number of clock cycles per bit time and the location
TSEG2[2:0] of the sample point (see Figure 12-43). Time segment 2 (TSEG2) values are programmable as shown in
Table 12-7.
3:0
Time Segment 1 — Time segments within the bit time fix the number of clock cycles per bit time and the location
TSEG1[3:0] of the sample point (see Figure 12-43). Time segment 1 (TSEG1) values are programmable as shown in
Table 12-8.
1
In this case, PHASE_SEG1 must be at least 2 time quanta (Tq).
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-7. Time Segment 2 Values
1
TSEG22
TSEG21
TSEG20
Time Segment 2
0
0
0
1 Tq clock cycle1
0
0
1
2 Tq clock cycles
:
:
:
:
1
1
0
7 Tq clock cycles
1
1
1
8 Tq clock cycles
This setting is not valid. Please refer to Table 12-35 for valid settings.
Table 12-8. Time Segment 1 Values
1
TSEG13
TSEG12
TSEG11
TSEG10
Time segment 1
0
0
0
0
1 Tq clock cycle1
0
0
0
1
2 Tq clock cycles1
0
0
1
0
3 Tq clock cycles1
0
0
1
1
4 Tq clock cycles
:
:
:
:
:
1
1
1
0
15 Tq clock cycles
1
1
1
1
16 Tq clock cycles
This setting is not valid. Please refer to Table 12-35 for valid settings.
The bit time is determined by the oscillator frequency, the baud rate prescaler, and the number of time
quanta (Tq) clock cycles per bit (as shown in Table 12-7 and Table 12-8).
Eqn. 12-1
( Prescaler value )
Bit Time = ------------------------------------------------------ • ( 1 + TimeSegment1 + TimeSegment2 )
f CANCLK
12.3.4.1
MSCAN Receiver Flag Register (CANRFLG)
A flag can be cleared only by software (writing a 1 to the corresponding bit position) when the condition
which caused the setting is no longer valid. Every flag has an associated interrupt enable bit in the
CANRIER register.
7
6
WUPIF
CSCIF
0
0
R
5
4
3
2
RSTAT1
RSTAT0
TSTAT1
TSTAT0
1
0
OVRIF
RXF
0
0
W
Reset:
0
0
0
0
= Unimplemented
Figure 12-8. MSCAN Receiver Flag Register (CANRFLG)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
NOTE
The CANRFLG register is held in the reset state1 when the initialization
mode is active (INITRQ = 1 and INITAK = 1). This register is writable again
as soon as the initialization mode is exited (INITRQ = 0 and INITAK = 0).
Read: Anytime
Write: Anytime when out of initialization mode, except RSTAT[1:0] and TSTAT[1:0] flags which are
read-only; write of 1 clears flag; write of 0 is ignored.
Table 12-9. CANRFLG Register Field Descriptions
Field
Description
7
WUPIF
Wake-Up Interrupt Flag — If the MSCAN detects CAN bus activity while in sleep mode (see Section 12.5.5.4,
“MSCAN Sleep Mode,”) and WUPE = 1 in CANTCTL0 (see Section 12.3.1, “MSCAN Control Register 0
(CANCTL0)”), the module will set WUPIF. If not masked, a wake-up interrupt is pending while this flag is set.
0
No wake-up activity observed while in sleep mode
1
MSCAN detected activity on the CAN bus and requested wake-up
6
CSCIF
CAN Status Change Interrupt Flag — This flag is set when the MSCAN changes its current CAN bus status
due to the actual value of the transmit error counter (TEC) and the receive error counter (REC). An additional
4-bit (RSTAT[1:0], TSTAT[1:0]) status register, which is split into separate sections for TEC/REC, informs the
system on the actual CAN bus status (see Section 12.3.5, “MSCAN Receiver Interrupt Enable Register
(CANRIER)”). If not masked, an error interrupt is pending while this flag is set. CSCIF provides a blocking
interrupt. That guarantees that the receiver/transmitter status bits (RSTAT/TSTAT) are only updated when no CAN
status change interrupt is pending. If the TECs/RECs change their current value after the CSCIF is asserted,
which would cause an additional state change in the RSTAT/TSTAT bits, these bits keep their status until the
current CSCIF interrupt is cleared again.
0
No change in CAN bus status occurred since last interrupt
1
MSCAN changed current CAN bus status
5:4
Receiver Status Bits — The values of the error counters control the actual CAN bus status of the MSCAN. As
RSTAT[1:0] soon as the status change interrupt flag (CSCIF) is set, these bits indicate the appropriate receiver related CAN
bus status of the MSCAN. The coding for the bits RSTAT1, RSTAT0 is:
00
RxOK: 0 ≤ receive error counter ≤ 96
01
RxWRN: 96 < receive error counter ≤ 127
10
RxERR: 127 < receive error counter
11
Bus-off1: transmit error counter > 255
3:2
Transmitter Status Bits — The values of the error counters control the actual CAN bus status of the MSCAN.
TSTAT[1:0] As soon as the status change interrupt flag (CSCIF) is set, these bits indicate the appropriate transmitter related
CAN bus status of the MSCAN. The coding for the bits TSTAT1, TSTAT0 is:
00
TxOK: 0 ≤ transmit error counter ≤ 96
01
TxWRN: 96 < transmit error counter ≤ 127
10
TxERR: 127 < transmit error counter ≤ 255
11
Bus-Off: transmit error counter > 255
1. The RSTAT[1:0], TSTAT[1:0] bits are not affected by initialization mode.
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-9. CANRFLG Register Field Descriptions (continued)
Field
Description
1
OVRIF
Overrun Interrupt Flag — This flag is set when a data overrun condition occurs. If not masked, an error interrupt
is pending while this flag is set.
0
No data overrun condition
1
A data overrun detected
0
RXF2
Receive Buffer Full Flag — RXF is set by the MSCAN when a new message is shifted in the receiver FIFO. This
flag indicates whether the shifted buffer is loaded with a correctly received message (matching identifier,
matching cyclic redundancy code (CRC) and no other errors detected). After the CPU has read that message
from the RxFG buffer in the receiver FIFO, the RXF flag must be cleared to release the buffer. A set RXF flag
prohibits the shifting of the next FIFO entry into the foreground buffer (RxFG). If not masked, a receive interrupt
is pending while this flag is set.
0
No new message available within the RxFG
1
The receiver FIFO is not empty. A new message is available in the RxFG
1
Redundant Information for the most critical CAN bus status which is “bus-off”. This only occurs if the Tx error counter exceeds
a number of 255 errors. Bus-off affects the receiver state. As soon as the transmitter leaves its bus-off state the receiver state
skips to RxOK too. Refer also to TSTAT[1:0] coding in this register.
2 To ensure data integrity, do not read the receive buffer registers while the RXF flag is cleared. For MCUs with dual CPUs,
reading the receive buffer registers while the RXF flag is cleared may result in a CPU fault condition.
12.3.5
MSCAN Receiver Interrupt Enable Register (CANRIER)
This register contains the interrupt enable bits for the interrupt flags described in the CANRFLG register.
7
6
5
4
3
2
1
0
WUPIE
CSCIE
RSTATE1
RSTATE0
TSTATE1
TSTATE0
OVRIE
RXFIE
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 12-9. MSCAN Receiver Interrupt Enable Register (CANRIER)
NOTE
The CANRIER register is held in the reset state when the initialization mode
is active (INITRQ=1 and INITAK=1). This register is writable when not in
initialization mode (INITRQ=0 and INITAK=0).
The RSTATE[1:0], TSTATE[1:0] bits are not affected by initialization
mode.
Read: Anytime
Write: Anytime when not in initialization mode
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-10. CANRIER Register Field Descriptions
Field
7
WUPIE1
6
CSCIE
Description
Wake-Up Interrupt Enable
0 No interrupt request is generated from this event.
1 A wake-up event causes a Wake-Up interrupt request.
CAN Status Change Interrupt Enable
0 No interrupt request is generated from this event.
1 A CAN Status Change event causes an error interrupt request.
5:4
Receiver Status Change Enable — These RSTAT enable bits control the sensitivity level in which receiver state
RSTATE[1:0] changes are causing CSCIF interrupts. Independent of the chosen sensitivity level the RSTAT flags continue to
indicate the actual receiver state and are only updated if no CSCIF interrupt is pending.
00 Do not generate any CSCIF interrupt caused by receiver state changes.
01 Generate CSCIF interrupt only if the receiver enters or leaves “bus-off” state. Discard other receiver state
changes for generating CSCIF interrupt.
10 Generate CSCIF interrupt only if the receiver enters or leaves “RxErr” or “bus-off”2 state. Discard other
receiver state changes for generating CSCIF interrupt.
11 Generate CSCIF interrupt on all state changes.
3:2
Transmitter Status Change Enable — These TSTAT enable bits control the sensitivity level in which transmitter
TSTATE[1:0] state changes are causing CSCIF interrupts. Independent of the chosen sensitivity level, the TSTAT flags
continue to indicate the actual transmitter state and are only updated if no CSCIF interrupt is pending.
00 Do not generate any CSCIF interrupt caused by transmitter state changes.
01 Generate CSCIF interrupt only if the transmitter enters or leaves “bus-off” state. Discard other transmitter
state changes for generating CSCIF interrupt.
10 Generate CSCIF interrupt only if the transmitter enters or leaves “TxErr” or “bus-off” state. Discard other
transmitter state changes for generating CSCIF interrupt.
11 Generate CSCIF interrupt on all state changes.
1
OVRIE
Overrun Interrupt Enable
0 No interrupt request is generated from this event.
1 An overrun event causes an error interrupt request.
0
RXFIE
Receiver Full Interrupt Enable
0 No interrupt request is generated from this event.
1 A receive buffer full (successful message reception) event causes a receiver interrupt request.
1
WUPIE and WUPE (see Section 12.3.1, “MSCAN Control Register 0 (CANCTL0)”) must both be enabled if the recovery
mechanism from stop or wait is required.
2 Bus-off state is defined by the CAN standard (see Bosch CAN 2.0A/B protocol specification: for only transmitters. Because the
only possible state change for the transmitter from bus-off to TxOK also forces the receiver to skip its current state to RxOK,
the coding of the RXSTAT[1:0] flags define an additional bus-off state for the receiver (see Section 12.3.4.1, “MSCAN Receiver
Flag Register (CANRFLG)”).
12.3.6
MSCAN Transmitter Flag Register (CANTFLG)
The transmit buffer empty flags each have an associated interrupt enable bit in the CANTIER register.
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R
7
6
5
4
3
0
0
0
0
0
2
1
0
TXE2
TXE1
TXE0
1
1
1
W
Reset:
0
0
0
0
0
= Unimplemented
Figure 12-10. MSCAN Transmitter Flag Register (CANTFLG)
NOTE
The CANTFLG register is held in the reset state when the initialization
mode is active (INITRQ = 1 and INITAK = 1). This register is writable when
not in initialization mode (INITRQ = 0 and INITAK = 0).
Read: Anytime
Write: Anytime for TXEx flags when not in initialization mode; write of 1 clears flag, write of 0 is ignored
Table 12-11. CANTFLG Register Field Descriptions
Field
Description
2:0
TXE[2:0]
Transmitter Buffer Empty — This flag indicates that the associated transmit message buffer is empty, and thus
not scheduled for transmission. The CPU must clear the flag after a message is set up in the transmit buffer and
is due for transmission. The MSCAN sets the flag after the message is sent successfully. The flag is also set by
the MSCAN when the transmission request is successfully aborted due to a pending abort request (see
Section 12.3.8, “MSCAN Transmitter Message Abort Request Register (CANTARQ)”). If not masked, a transmit
interrupt is pending while this flag is set.
Clearing a TXEx flag also clears the corresponding ABTAKx (see Section 12.3.9, “MSCAN Transmitter Message
Abort Acknowledge Register (CANTAAK)”). When a TXEx flag is set, the corresponding ABTRQx bit is cleared
(see Section 12.3.8, “MSCAN Transmitter Message Abort Request Register (CANTARQ)”).
When listen-mode is active (see Section 12.3.2, “MSCAN Control Register 1 (CANCTL1)”) the TXEx flags cannot
be cleared and no transmission is started.
Read and write accesses to the transmit buffer are blocked, if the corresponding TXEx bit is cleared (TXEx = 0)
and the buffer is scheduled for transmission.
0 The associated message buffer is full (loaded with a message due for transmission)
1 The associated message buffer is empty (not scheduled)
12.3.7
MSCAN Transmitter Interrupt Enable Register (CANTIER)
This register contains the interrupt enable bits for the transmit buffer empty interrupt flags.
R
7
6
5
4
3
0
0
0
0
0
2
1
0
TXEIE2
TXEIE1
TXEIE0
0
0
0
W
Reset:
0
0
0
0
0
= Unimplemented
Figure 12-11. MSCAN Transmitter Interrupt Enable Register (CANTIER)
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
NOTE
The CANTIER register is held in the reset state when the initialization mode
is active (INITRQ = 1 and INITAK = 1). This register is writable when not
in initialization mode (INITRQ = 0 and INITAK = 0).
Read: Anytime
Write: Anytime when not in initialization mode
Table 12-12. CANTIER Register Field Descriptions
Field
Description
2:0
TXEIE[2:0]
12.3.8
Transmitter Empty Interrupt Enable
0 No interrupt request is generated from this event.
1 A transmitter empty (transmit buffer available for transmission) event causes a transmitter empty interrupt
request. See Section 12.5.2.2, “Transmit Structures” for details.
MSCAN Transmitter Message Abort Request Register (CANTARQ)
The CANTARQ register allows abort request of messages queued for transmission.
R
7
6
5
4
3
0
0
0
0
0
2
1
0
ABTRQ2
ABTRQ1
ABTRQ0
0
0
0
W
Reset:
0
0
0
0
0
= Unimplemented
Figure 12-12. MSCAN Transmitter Message Abort Request Register (CANTARQ)
NOTE
The CANTARQ register is held in the reset state when the initialization
mode is active (INITRQ = 1 and INITAK = 1). This register is writable when
not in initialization mode (INITRQ = 0 and INITAK = 0).
Read: Anytime
Write: Anytime when not in initialization mode
Table 12-13. CANTARQ Register Field Descriptions
Field
Description
2:0
Abort Request — The CPU sets the ABTRQx bit to request that a scheduled message buffer (TXEx = 0) be
ABTRQ[2:0] aborted. The MSCAN grants the request if the message has not already started transmission, or if the
transmission is not successful (lost arbitration or error). When a message is aborted, the associated TXE (see
Section 12.3.6, “MSCAN Transmitter Flag Register (CANTFLG)”) and abort acknowledge flags (ABTAK, see
Section 12.3.9, “MSCAN Transmitter Message Abort Acknowledge Register (CANTAAK)”) are set and a transmit
interrupt occurs if enabled. The CPU cannot reset ABTRQx. ABTRQx is reset whenever the associated TXE flag
is set.
0 No abort request
1 Abort request pending
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.3.9
MSCAN Transmitter Message Abort Acknowledge Register
(CANTAAK)
The CANTAAK register indicates the successful abort of messages queued for transmission, if requested
by the appropriate bits in the CANTARQ register.
R
7
6
5
4
3
2
1
0
0
0
0
0
0
ABTAK2
ABTAK1
ABTAK0
0
0
0
0
0
0
0
0
W
Reset:
= Unimplemented
Figure 12-13. MSCAN Transmitter Message Abort Acknowledge Register (CANTAAK)
NOTE
The CANTAAK register is held in the reset state when the initialization
mode is active (INITRQ = 1 and INITAK = 1).
Read: Anytime
Write: Unimplemented for ABTAKx flags
Table 12-14. CANTAAK Register Field Descriptions
Field
Description
2:0
Abort Acknowledge — This flag acknowledges that a message was aborted due to a pending transmission
ABTAK[2:0] abort request from the CPU. After a particular message buffer is flagged empty, this flag can be used by the
application software to identify whether the message was aborted successfully or was sent anyway. The ABTAKx
flag is cleared whenever the corresponding TXE flag is cleared.
0 The message was not aborted.
1 The message was aborted.
12.3.10 MSCAN Transmit Buffer Selection Register (CANTBSEL)
The CANTBSEL selections of the actual transmit message buffer, which is accessible in the CANTXFG
register space.
R
7
6
5
4
3
0
0
0
0
0
2
1
0
TX2
TX1
TX0
0
0
0
W
Reset:
0
0
0
0
0
= Unimplemented
Figure 12-14. MSCAN Transmit Buffer Selection Register (CANTBSEL)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
NOTE
The CANTBSEL register is held in the reset state when the initialization
mode is active (INITRQ = 1 and INITAK=1). This register is writable when
not in initialization mode (INITRQ = 0 and INITAK = 0).
Read: Find the lowest ordered bit set to 1, all other bits will be read as 0
Write: Anytime when not in initialization mode
Table 12-15. CANTBSEL Register Field Descriptions
Field
Description
2:0
TX[2:0]
Transmit Buffer Select — The lowest numbered bit places the respective transmit buffer in the CANTXFG
register space (e.g., TX1 = 1 and TX0 = 1 selects transmit buffer TX0; TX1 = 1 and TX0 = 0 selects transmit
buffer TX1). Read and write accesses to the selected transmit buffer will be blocked, if the corresponding TXEx
bit is cleared and the buffer is scheduled for transmission (see Section 12.3.6, “MSCAN Transmitter Flag Register
(CANTFLG)”).
0 The associated message buffer is deselected
1 The associated message buffer is selected, if lowest numbered bit
The following gives a short programming example of the usage of the CANTBSEL register:
To get the next available transmit buffer, application software must read the CANTFLG register and write
this value back into the CANTBSEL register. In this example Tx buffers TX1 and TX2 are available. The
value read from CANTFLG is therefore 0b0000_0110. When writing this value back to CANTBSEL, the
Tx buffer TX1 is selected in the CANTXFG because the lowest numbered bit set to 1 is at bit position 1.
Reading back this value out of CANTBSEL results in 0b0000_0010, because only the lowest numbered
bit position set to 1 is presented. This mechanism eases the application software the selection of the next
available Tx buffer.
• LDD CANTFLG; value read is 0b0000_0110
• STD CANTBSEL; value written is 0b0000_0110
• LDD CANTBSEL; value read is 0b0000_0010
If all transmit message buffers are deselected, no accesses are allowed to the CANTXFG buffer register.
12.3.11 MSCAN Identifier Acceptance Control Register (CANIDAC)
The CANIDAC register is used for identifier filter acceptance control as described below.
R
7
6
0
0
5
4
IDAM1
IDAM0
0
0
3
2
1
0
0
IDHIT2
IDHIT1
IDHIT0
0
0
0
0
W
Reset:
0
0
= Unimplemented
Figure 12-15. MSCAN Identifier Acceptance Control Register (CANIDAC)
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1), except bits IDHITx, which are
read-only
Table 12-16. CANIDAC Register Field Descriptions
Field
Description
5:4
IDAM[1:0]
Identifier Acceptance Mode — The CPU sets these flags to define the identifier acceptance filter organization
(see Section 12.5.3, “Identifier Acceptance Filter”). Table 12-17 summarizes the different settings. In filter closed
mode, no message is accepted such that the foreground buffer is never reloaded.
2:0
IDHIT[2:0]
Identifier Acceptance Hit Indicator — The MSCAN sets these flags to indicate an identifier acceptance hit (see
Section 12.5.3, “Identifier Acceptance Filter”). Table 12-18 summarizes the different settings.
Table 12-17. Identifier Acceptance Mode Settings
IDAM1
IDAM0
Identifier Acceptance Mode
0
0
Two 32-bit acceptance filters
0
1
Four 16-bit acceptance filters
1
0
Eight 8-bit acceptance filters
1
1
Filter closed
Table 12-18. Identifier Acceptance Hit Indication
IDHIT2
IDHIT1
IDHIT0
Identifier Acceptance Hit
0
0
0
Filter 0 hit
0
0
1
Filter 1 hit
0
1
0
Filter 2 hit
0
1
1
Filter 3 hit
1
0
0
Filter 4 hit
1
0
1
Filter 5 hit
1
1
0
Filter 6 hit
1
1
1
Filter 7 hit
The IDHITx indicators are always related to the message in the foreground buffer (RxFG). When a
message gets shifted into the foreground buffer of the receiver FIFO the indicators are updated as well.
12.3.12 MSCAN Miscellaneous Register (CANMISC)
This register provides additional features.
MC9S08DZ60 Series Data Sheet, Rev. 4
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R
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
BOHOLD
W
Reset:
0
0
0
0
0
0
0
0
= Unimplemented
Figure 12-16. MSCAN Miscellaneous Register (CANMISC)
Read: Anytime
Write: Anytime; write of ‘1’ clears flag; write of ‘0’ ignored
Table 12-19. CANMISC Register Field Descriptions
Field
Description
0
BOHOLD
Bus-off State Hold Until User Request — If BORM is set in Section 12.3.2, “MSCAN Control Register 1
(CANCTL1), this bit indicates whether the module has entered the bus-off state. Clearing this bit requests the
recovery from bus-off. Refer to Section 12.6.2, “Bus-Off Recovery,” for details.
0 Module is not bus-off or recovery has been requested by user in bus-off state
1 Module is bus-off and holds this state until user request
12.3.13 MSCAN Receive Error Counter (CANRXERR)
This register reflects the status of the MSCAN receive error counter.
R
7
6
5
4
3
2
1
0
RXERR7
RXERR6
RXERR5
RXERR4
RXERR3
RXERR2
RXERR1
RXERR0
0
0
0
0
0
0
0
0
W
Reset:
= Unimplemented
Figure 12-17. MSCAN Receive Error Counter (CANRXERR)
Read: Only when in sleep mode (SLPRQ = 1 and SLPAK = 1) or initialization mode (INITRQ = 1 and
INITAK = 1)
Write: Unimplemented
NOTE
Reading this register when in any other mode other than sleep or
initialization mode may return an incorrect value. For MCUs with dual
CPUs, this may result in a CPU fault condition.
Writing to this register when in special modes can alter the MSCAN
functionality.
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12.3.14 MSCAN Transmit Error Counter (CANTXERR)
This register reflects the status of the MSCAN transmit error counter.
R
7
6
5
4
3
2
1
0
TXERR7
TXERR6
TXERR5
TXERR4
TXERR3
TXERR2
TXERR1
TXERR0
0
0
0
0
0
0
0
0
W
Reset:
= Unimplemented
Figure 12-18. MSCAN Transmit Error Counter (CANTXERR)
Read: Only when in sleep mode (SLPRQ = 1 and SLPAK = 1) or initialization mode (INITRQ = 1 and
INITAK = 1)
Write: Unimplemented
NOTE
Reading this register when in any other mode other than sleep or
initialization mode, may return an incorrect value. For MCUs with dual
CPUs, this may result in a CPU fault condition.
Writing to this register when in special modes can alter the MSCAN
functionality.
12.3.15 MSCAN Identifier Acceptance Registers (CANIDAR0-7)
On reception, each message is written into the background receive buffer. The CPU is only signalled to
read the message if it passes the criteria in the identifier acceptance and identifier mask registers
(accepted); otherwise, the message is overwritten by the next message (dropped).
The acceptance registers of the MSCAN are applied on the IDR0–IDR3 registers (see Section 12.4.1,
“Identifier Registers (IDR0–IDR3)”) of incoming messages in a bit by bit manner (see Section 12.5.3,
“Identifier Acceptance Filter”).
For extended identifiers, all four acceptance and mask registers are applied. For standard identifiers, only
the first two (CANIDAR0/1, CANIDMR0/1) are applied.
R
W
Reset
7
6
5
4
3
2
1
0
AC7
AC6
AC5
AC4
AC3
AC2
AC1
AC0
0
0
0
0
0
0
0
0
Figure 12-19. MSCAN Identifier Acceptance Registers (First Bank) — CANIDAR0–CANIDAR3
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-20. CANIDAR0–CANIDAR3 Register Field Descriptions
Field
Description
7:0
AC[7:0]
Acceptance Code Bits — AC[7:0] comprise a user-defined sequence of bits with which the corresponding bits
of the related identifier register (IDRn) of the receive message buffer are compared. The result of this comparison
is then masked with the corresponding identifier mask register.
R
W
Reset
7
6
5
4
3
2
1
0
AC7
AC6
AC5
AC4
AC3
AC2
AC1
AC0
0
0
0
0
0
0
0
0
Figure 12-20. MSCAN Identifier Acceptance Registers (Second Bank) — CANIDAR4–CANIDAR7
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1)
Table 12-21. CANIDAR4–CANIDAR7 Register Field Descriptions
Field
Description
7:0
AC[7:0]
Acceptance Code Bits — AC[7:0] comprise a user-defined sequence of bits with which the corresponding bits
of the related identifier register (IDRn) of the receive message buffer are compared. The result of this comparison
is then masked with the corresponding identifier mask register.
12.3.16 MSCAN Identifier Mask Registers (CANIDMR0–CANIDMR7)
The identifier mask register specifies which of the corresponding bits in the identifier acceptance register
are relevant for acceptance filtering. To receive standard identifiers in 32 bit filter mode, it is required to
program the last three bits (AM[2:0]) in the mask registers CANIDMR1 and CANIDMR5 to “don’t care.”
To receive standard identifiers in 16 bit filter mode, it is required to program the last three bits (AM[2:0])
in the mask registers CANIDMR1, CANIDMR3, CANIDMR5, and CANIDMR7 to “don’t care.”
R
W
Reset
7
6
5
4
3
2
1
0
AM7
AM6
AM5
AM4
AM3
AM2
AM1
AM0
0
0
0
0
0
0
0
0
Figure 12-21. MSCAN Identifier Mask Registers (First Bank) — CANIDMR0–CANIDMR3
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-22. CANIDMR0–CANIDMR3 Register Field Descriptions
Field
Description
7:0
AM[7:0]
Acceptance Mask Bits — If a particular bit in this register is cleared, this indicates that the corresponding bit in
the identifier acceptance register must be the same as its identifier bit before a match is detected. The message
is accepted if all such bits match. If a bit is set, it indicates that the state of the corresponding bit in the identifier
acceptance register does not affect whether or not the message is accepted.
0 Match corresponding acceptance code register and identifier bits
1 Ignore corresponding acceptance code register bit (don’t care)
R
W
Reset
7
6
5
4
3
2
1
0
AM7
AM6
AM5
AM4
AM3
AM2
AM1
AM0
0
0
0
0
0
0
0
0
Figure 12-22. MSCAN Identifier Mask Registers (Second Bank) — CANIDMR4–CANIDMR7
Read: Anytime
Write: Anytime in initialization mode (INITRQ = 1 and INITAK = 1)
Table 12-23. CANIDMR4–CANIDMR7 Register Field Descriptions
Field
Description
7:0
AM[7:0]
Acceptance Mask Bits — If a particular bit in this register is cleared, this indicates that the corresponding bit in
the identifier acceptance register must be the same as its identifier bit before a match is detected. The message
is accepted if all such bits match. If a bit is set, it indicates that the state of the corresponding bit in the identifier
acceptance register does not affect whether or not the message is accepted.
0 Match corresponding acceptance code register and identifier bits
1 Ignore corresponding acceptance code register bit (don’t care)
12.4
Programmer’s Model of Message Storage
The following section details the organization of the receive and transmit message buffers and the
associated control registers.
To simplify the programmer interface, the receive and transmit message buffers have the same outline.
Each message buffer allocates 16 bytes in the memory map containing a 13 byte data structure.
An additional transmit buffer priority register (TBPR) is defined for the transmit buffers. Within the last
two bytes of this memory map, the MSCAN stores a special 16-bit time stamp, which is sampled from an
internal timer after successful transmission or reception of a message. This feature is only available for
transmit and receiver buffers if the TIME bit is set (see Section 12.3.1, “MSCAN Control Register 0
(CANCTL0)”).
The time stamp register is written by the MSCAN. The CPU can only read these registers.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-24. Message Buffer Organization
Offset
Address
Register
0x00X0
Identifier Register 0
0x00X1
Identifier Register 1
0x00X2
Identifier Register 2
0x00X3
Identifier Register 3
0x00X4
Data Segment Register 0
0x00X5
Data Segment Register 1
0x00X6
Data Segment Register 2
0x00X7
Data Segment Register 3
0x00X8
Data Segment Register 4
0x00X9
Data Segment Register 5
0x00XA
Data Segment Register 6
0x00XB
Data Segment Register 7
0x00XC
Data Length Register
0x00XD
Transmit Buffer Priority Register1
0x00XE
Time Stamp Register (High Byte)2
0x00XF
Time Stamp Register (Low Byte)3
Access
1
Not applicable for receive buffers
Read-only for CPU
3 Read-only for CPU
2
Figure 12-23 shows the common 13-byte data structure of receive and transmit buffers for extended
identifiers. The mapping of standard identifiers into the IDR registers is shown in Figure 12-24.
All bits of the receive and transmit buffers are ‘x’ out of reset because of RAM-based implementation1.
All reserved or unused bits of the receive and transmit buffers always read ‘x’.
1. Exception: The transmit priority registers are 0 out of reset.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Register
Name
IDR0
IDR1
R
W
R
W
R
IDR2
W
IDR3
W
R
R
DSR0
W
R
DSR1
W
R
DSR2
W
DSR3
W
R
R
DSR4
W
R
DSR5
W
DSR6
W
R
R
DSR7
W
Bit 7
6
5
4
3
2
1
Bit0
ID28
ID27
ID26
ID25
ID24
ID23
ID22
ID21
ID20
ID19
ID18
SRR(1)
IDE(1)
ID17
ID16
ID15
ID14
ID13
ID12
ID11
ID10
ID9
ID8
ID7
ID6
ID5
ID4
ID3
ID2
ID1
ID0
RTR2
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
DLC3
DLC2
DLC1
DLC0
R
DLR
W
= Unused, always read ‘x’
Figure 12-23. Receive/Transmit Message Buffer — Extended Identifier Mapping
1
2
SRR and IDE are both 1s.
The position of RTR differs between extended and standard indentifier mapping.
Read: For transmit buffers, anytime when TXEx flag is set (see Section 12.3.6, “MSCAN Transmitter Flag
Register (CANTFLG)”) and the corresponding transmit buffer is selected in CANTBSEL (see
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Section 12.3.10, “MSCAN Transmit Buffer Selection Register (CANTBSEL)”). For receive buffers, only
when RXF flag is set (see Section 12.3.4.1, “MSCAN Receiver Flag Register (CANRFLG)”).
Write: For transmit buffers, anytime when TXEx flag is set (see Section 12.3.6, “MSCAN Transmitter Flag
Register (CANTFLG)”) and the corresponding transmit buffer is selected in CANTBSEL (see
Section 12.3.10, “MSCAN Transmit Buffer Selection Register (CANTBSEL)”). Unimplemented for
receive buffers.
Reset: Undefined (0x00XX) because of RAM-based implementation
Register
Name
R
IDR0
W
R
IDR1
W
Bit 7
6
5
4
3
2
1
Bit 0
ID10
ID9
ID8
ID7
ID6
ID5
ID4
ID3
ID2
ID1
ID0
RTR1
IDE2
R
IDR2
W
R
IDR3
W
= Unused, always read ‘x’
Figure 12-24. Receive/Transmit Message Buffer — Standard Identifier Mapping
1
2
The position of RTR differs between extended and standard indentifier mapping.
IDE is 0.
12.4.1
Identifier Registers (IDR0–IDR3)
The identifier registers for an extended format identifier consist of a total of 32 bits; ID[28:0], SRR, IDE,
and RTR bits. The identifier registers for a standard format identifier consist of a total of 13 bits; ID[10:0],
RTR, and IDE bits.
12.4.1.1
IDR0–IDR3 for Extended Identifier Mapping
7
6
5
4
3
2
1
0
ID28
ID27
ID26
ID25
ID24
ID23
ID22
ID21
x
x
x
x
x
x
x
x
R
W
Reset:
Figure 12-25. Identifier Register 0 (IDR0) — Extended Identifier Mapping
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-25. IDR0 Register Field Descriptions — Extended
Field
Description
7:0
ID[28:21]
Extended Format Identifier — The identifiers consist of 29 bits (ID[28:0]) for the extended format. ID28 is the
most significant bit and is transmitted first on the CAN bus during the arbitration procedure. The priority of an
identifier is defined to be highest for the smallest binary number.
7
6
5
4
3
2
1
0
ID20
ID19
ID18
SRR(1)
IDE(1)
ID17
ID16
ID15
x
x
x
x
x
x
x
x
R
W
Reset:
Figure 12-26. Identifier Register 1 (IDR1) — Extended Identifier Mapping
1
SRR and IDE are both 1s.
Table 12-26. IDR1 Register Field Descriptions — Extended
Field
Description
7:5
ID[20:18]
Extended Format Identifier — The identifiers consist of 29 bits (ID[28:0]) for the extended format. ID28 is the
most significant bit and is transmitted first on the CAN bus during the arbitration procedure. The priority of an
identifier is defined to be highest for the smallest binary number.
4
SRR
Substitute Remote Request — This fixed recessive bit is used only in extended format. It must be set to 1 by
the user for transmission buffers and is stored as received on the CAN bus for receive buffers.
3
IDE
ID Extended — This flag indicates whether the extended or standard identifier format is applied in this buffer. In
the case of a receive buffer, the flag is set as received and indicates to the CPU how to process the buffer
identifier registers. In the case of a transmit buffer, the flag indicates to the MSCAN what type of identifier to send.
0 Standard format (11 bit)
1 Extended format (29 bit)
2:0
ID[17:15]
Extended Format Identifier — The identifiers consist of 29 bits (ID[28:0]) for the extended format. ID28 is the
most significant bit and is transmitted first on the CAN bus during the arbitration procedure. The priority of an
identifier is defined to be highest for the smallest binary number.
7
6
5
4
3
2
1
0
ID14
ID13
ID12
ID11
ID10
ID9
ID8
ID7
x
x
x
x
x
x
x
x
R
W
Reset:
Figure 12-27. Identifier Register 2 (IDR2) — Extended Identifier Mapping
Table 12-27. IDR2 Register Field Descriptions — Extended
Field
Description
7:0
ID[14:7]
Extended Format Identifier — The identifiers consist of 29 bits (ID[28:0]) for the extended format. ID28 is the
most significant bit and is transmitted first on the CAN bus during the arbitration procedure. The priority of an
identifier is defined to be highest for the smallest binary number.
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
7
6
5
4
3
2
1
0
ID6
ID5
ID4
ID3
ID2
ID1
ID0
RTR
x
x
x
x
x
x
x
x
R
W
Reset:
Figure 12-28. Identifier Register 3 (IDR3) — Extended Identifier Mapping
Table 12-28. IDR3 Register Field Descriptions — Extended
Field
Description
7:1
ID[6:0]
Extended Format Identifier — The identifiers consist of 29 bits (ID[28:0]) for the extended format. ID28 is the
most significant bit and is transmitted first on the CAN bus during the arbithation procedure. The priority of an
identifier is defined to be highest for the smallest binary number.
0
RTR
Remote Transmission Request — This flag reflects the status of the remote transmission request bit in the
CAN frame. In the case of a receive buffer, it indicates the status of the received frame and supports the
transmission of an answering frame in software. In the case of a transmit buffer, this flag defines the setting of
the RTR bit to be sent.
0 Data frame
1 Remote frame
12.4.2
IDR0–IDR3 for Standard Identifier Mapping
7
6
5
4
3
2
1
0
ID10
ID9
ID8
ID7
ID6
ID5
ID4
ID3
x
x
x
x
x
x
x
x
R
W
Reset:
Figure 12-29. Identifier Register 0 — Standard Mapping
Table 12-29. IDR0 Register Field Descriptions — Standard
Field
Description
7:0
ID[10:3]
Standard Format Identifier — The identifiers consist of 11 bits (ID[10:0]) for the standard format. ID10 is the
most significant bit and is transmitted first on the CAN bus during the arbitration procedure. The priority of an
identifier is defined to be highest for the smallest binary number. See also ID bits in Table 12-30.
7
6
5
4
3
ID2
ID1
ID0
RTR
IDE(1)
x
x
x
x
x
R
2
1
0
x
x
x
W
Reset:
= Unused; always read ‘x’
Figure 12-30. Identifier Register 1 — Standard Mapping
1
IDE is 0.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-30. IDR1 Register Field Descriptions
Field
Description
7:5
ID[2:0]
Standard Format Identifier — The identifiers consist of 11 bits (ID[10:0]) for the standard format. ID10 is the
most significant bit and is transmitted first on the CAN bus during the arbitration procedure. The priority of an
identifier is defined to be highest for the smallest binary number. See also ID bits in Table 12-29.
4
RTR
Remote Transmission Request — This flag reflects the status of the Remote Transmission Request bit in the
CAN frame. In the case of a receive buffer, it indicates the status of the received frame and supports the
transmission of an answering frame in software. In the case of a transmit buffer, this flag defines the setting of
the RTR bit to be sent.
0 Data frame
1 Remote frame
3
IDE
ID Extended — This flag indicates whether the extended or standard identifier format is applied in this buffer. In
the case of a receive buffer, the flag is set as received and indicates to the CPU how to process the buffer
identifier registers. In the case of a transmit buffer, the flag indicates to the MSCAN what type of identifier to send.
0 Standard format (11 bit)
1 Extended format (29 bit)
7
6
5
4
3
2
1
0
x
x
x
x
x
x
x
x
R
W
Reset:
= Unused; always read ‘x’
Figure 12-31. Identifier Register 2 — Standard Mapping
7
6
5
4
3
2
1
0
x
x
x
x
x
x
x
x
R
W
Reset:
= Unused; always read ‘x’
Figure 12-32. Identifier Register 3 — Standard Mapping
12.4.3
Data Segment Registers (DSR0-7)
The eight data segment registers, each with bits DB[7:0], contain the data to be transmitted or received.
The number of bytes to be transmitted or received is determined by the data length code in the
corresponding DLR register.
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
7
6
5
4
3
2
1
0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
x
x
x
x
x
x
x
x
R
W
Reset:
Figure 12-33. Data Segment Registers (DSR0–DSR7) — Extended Identifier Mapping
Table 12-31. DSR0–DSR7 Register Field Descriptions
Field
Description
7:0
DB[7:0]
Data bits 7:0
12.4.4
Data Length Register (DLR)
This register keeps the data length field of the CAN frame.
7
6
5
4
3
2
1
0
DLC3
DLC2
DLC1
DLC0
x
x
x
x
R
W
Reset:
x
x
x
x
= Unused; always read “x”
Figure 12-34. Data Length Register (DLR) — Extended Identifier Mapping
Table 12-32. DLR Register Field Descriptions
Field
Description
3:0
DLC[3:0]
Data Length Code Bits — The data length code contains the number of bytes (data byte count) of the respective
message. During the transmission of a remote frame, the data length code is transmitted as programmed while
the number of transmitted data bytes is always 0. The data byte count ranges from 0 to 8 for a data frame.
Table 12-33 shows the effect of setting the DLC bits.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Table 12-33. Data Length Codes
Data Length Code
12.4.5
DLC3
DLC2
DLC1
DLC0
Data Byte
Count
0
0
0
0
0
0
0
0
1
1
0
0
1
0
2
0
0
1
1
3
0
1
0
0
4
0
1
0
1
5
0
1
1
0
6
0
1
1
1
7
1
0
0
0
8
Transmit Buffer Priority Register (TBPR)
This register defines the local priority of the associated message transmit buffer. The local priority is used
for the internal prioritization process of the MSCAN and is defined to be highest for the smallest binary
number. The MSCAN implements the following internal prioritization mechanisms:
• All transmission buffers with a cleared TXEx flag participate in the prioritization immediately
before the SOF (start of frame) is sent.
• The transmission buffer with the lowest local priority field wins the prioritization.
In cases of more than one buffer having the same lowest priority, the message buffer with the lower index
number wins.
7
6
5
4
3
2
1
0
PRIO7
PRIO6
PRIO5
PRIO4
PRIO3
PRIO2
PRIO1
PRIO0
0
0
0
0
0
0
0
0
R
W
Reset:
Figure 12-35. Transmit Buffer Priority Register (TBPR)
Read: Anytime when TXEx flag is set (see Section 12.3.6, “MSCAN Transmitter Flag Register
(CANTFLG)”) and the corresponding transmit buffer is selected in CANTBSEL (see Section 12.3.10,
“MSCAN Transmit Buffer Selection Register (CANTBSEL)”).
Write: Anytime when TXEx flag is set (see Section 12.3.6, “MSCAN Transmitter Flag Register
(CANTFLG)”) and the corresponding transmit buffer is selected in CANTBSEL (see Section 12.3.10,
“MSCAN Transmit Buffer Selection Register (CANTBSEL)”).
12.4.6
Time Stamp Register (TSRH–TSRL)
If the TIME bit is enabled, the MSCAN will write a time stamp to the respective registers in the active
transmit or receive buffer as soon as a message has been acknowledged on the CAN bus (see
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Section 12.3.1, “MSCAN Control Register 0 (CANCTL0)”). In case of a transmission, the CPU can only
read the time stamp after the respective transmit buffer has been flagged empty.
The timer value, which is used for stamping, is taken from a free running internal CAN bit clock. A timer
overrun is not indicated by the MSCAN. The timer is reset (all bits set to 0) during initialization mode. The
CPU can only read the time stamp registers.
R
7
6
5
4
3
2
1
0
TSR15
TSR14
TSR13
TSR12
TSR11
TSR10
TSR9
TSR8
x
x
x
x
x
x
x
x
W
Reset:
Figure 12-36. Time Stamp Register — High Byte (TSRH)
R
7
6
5
4
3
2
1
0
TSR7
TSR6
TSR5
TSR4
TSR3
TSR2
TSR1
TSR0
x
x
x
x
x
x
x
x
W
Reset:
Figure 12-37. Time Stamp Register — Low Byte (TSRL)
Read: Anytime when TXEx flag is set (see Section 12.3.6, “MSCAN Transmitter Flag Register
(CANTFLG)”) and the corresponding transmit buffer is selected in CANTBSEL (see Section 12.3.10,
“MSCAN Transmit Buffer Selection Register (CANTBSEL)”).
Write: Unimplemented
12.5
12.5.1
Functional Description
General
This section provides a complete functional description of the MSCAN. It describes each of the features
and modes listed in the introduction.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.5.2
Message Storage
CAN
Receive / Transmit
Engine
CPU12
Memory Mapped
I/O
Rx0
RXF
CPU bus
RxFG
RxBG
MSCAN
Rx1
Rx2
Rx3
Rx4
Receiver
TxBG
Tx0
MSCAN
TxFG
Tx1
Transmitter
TxBG
Tx2
TXE0
PRIO
TXE1
CPU bus
PRIO
TXE2
PRIO
Figure 12-38. User Model for Message Buffer Organization
MSCAN facilitates a sophisticated message storage system which addresses the requirements of a broad
range of network applications.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.5.2.1
Message Transmit Background
Modern application layer software is built upon two fundamental assumptions:
• Any CAN node is able to send out a stream of scheduled messages without releasing the CAN bus
between the two messages. Such nodes arbitrate for the CAN bus immediately after sending the
previous message and only release the CAN bus in case of lost arbitration.
• The internal message queue within any CAN node is organized such that the highest priority
message is sent out first, if more than one message is ready to be sent.
The behavior described in the bullets above cannot be achieved with a single transmit buffer. That buffer
must be reloaded immediately after the previous message is sent. This loading process lasts a finite amount
of time and must be completed within the inter-frame sequence (IFS) to be able to send an uninterrupted
stream of messages. Even if this is feasible for limited CAN bus speeds, it requires that the CPU reacts
with short latencies to the transmit interrupt.
A double buffer scheme de-couples the reloading of the transmit buffer from the actual message sending
and, therefore, reduces the reactiveness requirements of the CPU. Problems can arise if the sending of a
message is finished while the CPU re-loads the second buffer. No buffer would then be ready for
transmission, and the CAN bus would be released.
At least three transmit buffers are required to meet the first of the above requirements under all
circumstances. The MSCAN has three transmit buffers.
The second requirement calls for some sort of internal prioritization which the MSCAN implements with
the “local priority” concept described in Section 12.5.2.2, “Transmit Structures.”
12.5.2.2
Transmit Structures
The MSCAN triple transmit buffer scheme optimizes real-time performance by allowing multiple
messages to be set up in advance. The three buffers are arranged as shown in Figure 12-38.
All three buffers have a 13-byte data structure similar to the outline of the receive buffers (see Section 12.4,
“Programmer’s Model of Message Storage”). An additional Section 12.4.5, “Transmit Buffer Priority
Register (TBPR) contains an 8-bit local priority field (PRIO) (see Section 12.4.5, “Transmit Buffer
Priority Register (TBPR)”). The remaining two bytes are used for time stamping of a message, if required
(see Section 12.4.6, “Time Stamp Register (TSRH–TSRL)”).
To transmit a message, the CPU must identify an available transmit buffer, which is indicated by a set
transmitter buffer empty (TXEx) flag (see Section 12.3.6, “MSCAN Transmitter Flag Register
(CANTFLG)”). If a transmit buffer is available, the CPU must set a pointer to this buffer by writing to the
CANTBSEL register (see Section 12.3.10, “MSCAN Transmit Buffer Selection Register
(CANTBSEL)”). This makes the respective buffer accessible within the CANTXFG address space (see
Section 12.4, “Programmer’s Model of Message Storage”). The algorithmic feature associated with the
CANTBSEL register simplifies the transmit buffer selection. In addition, this scheme makes the handler
software simpler because only one address area is applicable for the transmit process, and the required
address space is minimized.
The CPU then stores the identifier, the control bits, and the data content into one of the transmit buffers.
Finally, the buffer is flagged as ready for transmission by clearing the associated TXE flag.
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The MSCAN then schedules the message for transmission and signals the successful transmission of the
buffer by setting the associated TXE flag. A transmit interrupt (see Section 12.5.7.2, “Transmit Interrupt”)
is generated1 when TXEx is set and can be used to drive the application software to re-load the buffer.
If more than one buffer is scheduled for transmission when the CAN bus becomes available for arbitration,
the MSCAN uses the local priority setting of the three buffers to determine the prioritization. For this
purpose, every transmit buffer has an 8-bit local priority field (PRIO). The application software programs
this field when the message is set up. The local priority reflects the priority of this particular message
relative to the set of messages being transmitted from this node. The lowest binary value of the PRIO field
is defined to be the highest priority. The internal scheduling process takes place whenever the MSCAN
arbitrates for the CAN bus. This is also the case after the occurrence of a transmission error.
When a high priority message is scheduled by the application software, it may become necessary to abort
a lower priority message in one of the three transmit buffers. Because messages that are already in
transmission cannot be aborted, the user must request the abort by setting the corresponding abort request
bit (ABTRQ) (see Section 12.3.8, “MSCAN Transmitter Message Abort Request Register
(CANTARQ)”.) The MSCAN then grants the request, if possible, by:
1. Setting the corresponding abort acknowledge flag (ABTAK) in the CANTAAK register.
2. Setting the associated TXE flag to release the buffer.
3. Generating a transmit interrupt. The transmit interrupt handler software can determine from the
setting of the ABTAK flag whether the message was aborted (ABTAK = 1) or sent (ABTAK = 0).
12.5.2.3
Receive Structures
The received messages are stored in a five stage input FIFO. The five message buffers are alternately
mapped into a single memory area (see Figure 12-38). The background receive buffer (RxBG) is
exclusively associated with the MSCAN, but the foreground receive buffer (RxFG) is addressable by the
CPU (see Figure 12-38). This scheme simplifies the handler software because only one address area is
applicable for the receive process.
All receive buffers have a size of 15 bytes to store the CAN control bits, the identifier (standard or
extended), the data contents, and a time stamp, if enabled (see Section 12.4, “Programmer’s Model of
Message Storage”).
The receiver full flag (RXF) (see Section 12.3.4.1, “MSCAN Receiver Flag Register (CANRFLG)”)
signals the status of the foreground receive buffer. When the buffer contains a correctly received message
with a matching identifier, this flag is set.
On reception, each message is checked to see whether it passes the filter (see Section 12.5.3, “Identifier
Acceptance Filter”) and simultaneously is written into the active RxBG. After successful reception of a
valid message, the MSCAN shifts the content of RxBG into the receiver FIFO2, sets the RXF flag, and
generates a receive interrupt (see Section 12.5.7.3, “Receive Interrupt”) to the CPU3. The user’s receive
handler must read the received message from the RxFG and then reset the RXF flag to acknowledge the
interrupt and to release the foreground buffer. A new message, which can follow immediately after the IFS
1. The transmit interrupt occurs only if not masked. A polling scheme can be applied on TXEx also.
2. Only if the RXF flag is not set.
3. The receive interrupt occurs only if not masked. A polling scheme can be applied on RXF also.
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field of the CAN frame, is received into the next available RxBG. If the MSCAN receives an invalid
message in its RxBG (wrong identifier, transmission errors, etc.) the actual contents of the buffer will be
over-written by the next message. The buffer will then not be shifted into the FIFO.
When the MSCAN module is transmitting, the MSCAN receives its own transmitted messages into the
background receive buffer, RxBG, but does not shift it into the receiver FIFO, generate a receive interrupt,
or acknowledge its own messages on the CAN bus. The exception to this rule is in loopback mode (see
Section 12.3.2, “MSCAN Control Register 1 (CANCTL1)”) where the MSCAN treats its own messages
exactly like all other incoming messages. The MSCAN receives its own transmitted messages in the event
that it loses arbitration. If arbitration is lost, the MSCAN must be prepared to become a receiver.
An overrun condition occurs when all receive message buffers in the FIFO are filled with correctly
received messages with accepted identifiers and another message is correctly received from the CAN bus
with an accepted identifier. The latter message is discarded and an error interrupt with overrun indication
is generated if enabled (see Section 12.5.7.5, “Error Interrupt”). The MSCAN remains able to transmit
messages while the receiver FIFO is full, but all incoming messages are discarded. As soon as a receive
buffer in the FIFO is available again, new valid messages will be accepted.
12.5.3
Identifier Acceptance Filter
The MSCAN identifier acceptance registers (see Section 12.3.11, “MSCAN Identifier Acceptance Control
Register (CANIDAC)”) define the acceptable patterns of the standard or extended identifier (ID[10:0] or
ID[28:0]). Any of these bits can be marked ‘don’t care’ in the MSCAN identifier mask registers (see
Section 12.3.16, “MSCAN Identifier Mask Registers (CANIDMR0–CANIDMR7)”).
A filter hit is indicated to the application software by a set receive buffer full flag (RXF = 1) and three bits
in the CANIDAC register (see Section 12.3.11, “MSCAN Identifier Acceptance Control Register
(CANIDAC)”). These identifier hit flags (IDHIT[2:0]) clearly identify the filter section that caused the
acceptance. They simplify the application software’s task to identify the cause of the receiver interrupt. If
more than one hit occurs (two or more filters match), the lower hit has priority.
A very flexible programmable generic identifier acceptance filter has been introduced to reduce the CPU
interrupt loading. The filter is programmable to operate in four different modes (see Bosch CAN 2.0A/B
protocol specification):
• Two identifier acceptance filters, each to be applied to:
— The full 29 bits of the extended identifier and to the following bits of the CAN 2.0B frame:
– Remote transmission request (RTR)
– Identifier extension (IDE)
– Substitute remote request (SRR)
— The 11 bits of the standard identifier plus the RTR and IDE bits of the CAN 2.0A/B messages1.
This mode implements two filters for a full length CAN 2.0B compliant extended identifier.
Figure 12-39 shows how the first 32-bit filter bank (CANIDAR0–CANIDAR3,
CANIDMR0–CANIDMR3) produces a filter 0 hit. Similarly, the second filter bank
(CANIDAR4–CANIDAR7, CANIDMR4–CANIDMR7) produces a filter 1 hit.
1.Although this mode can be used for standard identifiers, it is recommended to use the four or eight identifier acceptance
filters for standard identifiers
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•
•
•
Four identifier acceptance filters, each to be applied to
— a) the 14 most significant bits of the extended identifier plus the SRR and IDE bits of CAN 2.0B
messages or
— b) the 11 bits of the standard identifier, the RTR and IDE bits of CAN 2.0A/B messages.
Figure 12-40 shows how the first 32-bit filter bank (CANIDAR0–CANIDA3,
CANIDMR0–3CANIDMR) produces filter 0 and 1 hits. Similarly, the second filter bank
(CANIDAR4–CANIDAR7, CANIDMR4–CANIDMR7) produces filter 2 and 3 hits.
Eight identifier acceptance filters, each to be applied to the first 8 bits of the identifier. This mode
implements eight independent filters for the first 8 bits of a CAN 2.0A/B compliant standard
identifier or a CAN 2.0B compliant extended identifier. Figure 12-41 shows how the first 32-bit
filter bank (CANIDAR0–CANIDAR3, CANIDMR0–CANIDMR3) produces filter 0 to 3 hits.
Similarly, the second filter bank (CANIDAR4–CANIDAR7, CANIDMR4–CANIDMR7)
produces filter 4 to 7 hits.
Closed filter. No CAN message is copied into the foreground buffer RxFG, and the RXF flag is
never set.
CAN 2.0B
Extended Identifier ID28
IDR0
ID21
ID20
IDR1
CAN 2.0A/B
Standard Identifier ID10
IDR0
ID3
ID2
IDR1
ID15
IDE
ID14
IDR2
ID7
ID6
IDR3
RTR
ID10
IDR2
ID3
ID10
IDR3
ID3
AM7
CANIDMR0
AM0
AM7
CANIDMR1
AM0
AM7
CANIDMR2
AM0
AM7
CANIDMR3
AM0
AC7
CANIDAR0
AC0
AC7
CANIDAR1
AC0
AC7
CANIDAR2
AC0
AC7
CANIDAR3
AC0
ID Accepted (Filter 0 Hit)
Figure 12-39. 32-bit Maskable Identifier Acceptance Filter
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CAN 2.0B
Extended Identifier
ID28
IDR0
ID21
ID20
IDR1
CAN 2.0A/B
Standard Identifier
ID10
IDR0
ID3
ID2
IDR1
AM7
CANIDMR0
AM0
AM7
CANIDMR1
AM0
AC7
CANIDAR0
AC0
AC7
CANIDAR1
AC0
ID15
IDE
ID14
IDR2
ID7
ID6
IDR3
RTR
ID10
IDR2
ID3
ID10
IDR3
ID3
ID Accepted (Filter 0 Hit)
AM7
CANIDMR2
AM0
AM7
CANIDMR3
AM0
AC7
CANIDAR2
AC0
AC7
CANIDAR3
AC0
ID Accepted (Filter 1 Hit)
Figure 12-40. 16-bit Maskable Identifier Acceptance Filters
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CAN 2.0B
Extended Identifier ID28
IDR0
ID21
ID20
IDR1
CAN 2.0A/B
Standard Identifier ID10
IDR0
ID3
ID2
IDR1
AM7
CIDMR0
AM0
AC7
CIDAR0
AC0
ID15
IDE
ID14
IDR2
ID7
ID6
IDR3
RTR
ID10
IDR2
ID3
ID10
IDR3
ID3
ID Accepted (Filter 0 Hit)
AM7
CIDMR1
AM0
AC7
CIDAR1
AC0
ID Accepted (Filter 1 Hit)
AM7
CIDMR2
AM0
AC7
CIDAR2
AC0
ID Accepted (Filter 2 Hit)
AM7
CIDMR3
AM0
AC7
CIDAR3
AC0
ID Accepted (Filter 3 Hit)
Figure 12-41. 8-bit Maskable Identifier Acceptance Filters
MSCAN filter uses three sets of registers to provide the filter configuration. Firstly, the CANIDAC register
determines the configuration of the banks into filter sizes and number of filters. Secondly, registers
CANIDMR0/1/2/3 determine those bits on which the filter will operate by placing a ‘0’ at the appropriate
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bit position in the filter register. Finally, registers CANIDAR0/1/2/3 determine the value of those bits
determined by CANIDMR0/1/2/3.
For instance in the case of the filter value of:
0001x1001x0
The CANIDMR0/1/2/3 register would be configured as:
00001000010
and so all message identifier bits except bit 1 and bit 6 would be compared against the CANIDAR0/1/2/3
registers. These would be configured as:
00010100100
In this case bits 1 and 6 are set to ‘0’, but since they are ignored it is equally valid to set them to ‘1’.
12.5.3.1
Identifier Acceptance Filters example
As described above, filters work by comparisons to individual bits in the CAN message identifier field. The
filter will check each one of the eleven bits of a standard CAN message identifier. Suppose a filter value of
0001x1001x0. In this simple example, there are only three possible CAN messages.
Filter value: 0001x1001x0
Message 1: 00011100110
Message 2: 00110100110
Message 3: 00010100100
Message 2 will be rejected since its third most significant bit is not ‘0’ - 001. The filter is simply a
convenient way of defining the set of messages that the CPU must receive. For full 29-bits of an extended
CAN message identifier, the filter identifies two sets of messages: one set that it receives and one set that
it rejects. Alternatively, the filter may be split into two. This allows the MSCAN to examine only the first
16 bits of a message identifier, but allows two separate filters to perform the checking. See the example
below:
Filter value A: 0001x1001x0
Filter value B: 00x101x01x0
Message 1: 00011100110
Message 2: 00110100110
Message 3: 00010100100
MSCAN will accept all three messages. Filter A will accept messages 1 and 3 as before and filter B will
accept message 2. In practice, it is unimportant which filter accepts the message - messages accepted by
either will be placed in the input buffer. A message may be accepted by more than one filter.
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12.5.3.2
Protocol Violation Protection
The MSCAN protects the user from accidentally violating the CAN protocol through programming errors.
The protection logic implements the following features:
• The receive and transmit error counters cannot be written or otherwise manipulated.
• All registers which control the configuration of the MSCAN cannot be modified while the MSCAN
is on-line. The MSCAN has to be in Initialization Mode. The corresponding INITRQ/INITAK
handshake bits in the CANCTL0/CANCTL1 registers (see Section 12.3.1, “MSCAN Control
Register 0 (CANCTL0)”) serve as a lock to protect the following registers:
— MSCAN control 1 register (CANCTL1)
— MSCAN bus timing registers 0 and 1 (CANBTR0, CANBTR1)
— MSCAN identifier acceptance control register (CANIDAC)
— MSCAN identifier acceptance registers (CANIDAR0–CANIDAR7)
— MSCAN identifier mask registers (CANIDMR0–CANIDMR7)
• The TXCAN pin is immediately forced to a recessive state when the MSCAN goes into the power
down mode or initialization mode (see Section 12.5.5.6, “MSCAN Power Down Mode,” and
Section 12.5.5.5, “MSCAN Initialization Mode”).
• The MSCAN enable bit (CANE) is writable only once in normal system operation modes, which
provides further protection against inadvertently disabling the MSCAN.
12.5.3.3
Clock System
Figure 12-42 shows the structure of the MSCAN clock generation circuitry.
MSCAN
Bus Clock
CANCLK
CLKSRC
Prescaler
(1 .. 64)
Time quanta clock (Tq)
CLKSRC
Oscillator Clock
Figure 12-42. MSCAN Clocking Scheme
The clock source bit (CLKSRC) in the CANCTL1 register (12.3.2/-226) defines whether the internal
CANCLK is connected to the output of a crystal oscillator (oscillator clock) or to the bus clock.
The clock source has to be chosen such that the tight oscillator tolerance requirements (up to 0.4%) of the
CAN protocol are met. Additionally, for high CAN bus rates (1 Mbps), a 45% to 55% duty cycle of the
clock is required.
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If the bus clock is generated from a PLL, it is recommended to select the oscillator clock rather than the
bus clock due to jitter considerations, especially at the faster CAN bus rates. PLL lock may also be too
wide to ensure adequate clock tolerance.
For microcontrollers without a clock and reset generator (CRG), CANCLK is driven from the crystal
oscillator (oscillator clock).
A programmable prescaler generates the time quanta (Tq) clock from CANCLK. A time quantum is the
atomic unit of time handled by the MSCAN.
Eqn. 12-2
f CANCLK
=
----------------------------------------------------Tq ( Prescaler value -)
A bit time is subdivided into three segments as described in the Bosch CAN specification. (see
Figure 12-43):
• SYNC_SEG: This segment has a fixed length of one time quantum. Signal edges are expected to
happen within this section.
• Time Segment 1: This segment includes the PROP_SEG and the PHASE_SEG1 of the CAN
standard. It can be programmed by setting the parameter TSEG1 to consist of 4 to 16 time quanta.
• Time Segment 2: This segment represents the PHASE_SEG2 of the CAN standard. It can be
programmed by setting the TSEG2 parameter to be 2 to 8 time quanta long.
Eqn. 12-3
f Tq
Bit Rate = --------------------------------------------------------------------------------( number of Time Quanta )
NRZ Signal
SYNC_SEG
Time Segment 1
(PROP_SEG + PHASE_SEG1)
Time Segment 2
(PHASE_SEG2)
1
4 ... 16
2 ... 8
8 ... 25 Time Quanta
= 1 Bit Time
Transmit Point
Sample Point
(single or triple sampling)
Figure 12-43. Segments within the Bit Time
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Table 12-34. Time Segment Syntax
Syntax
Description
System expects transitions to occur on the CAN bus during this
period.
SYNC_SEG
Transmit Point
A node in transmit mode transfers a new value to the CAN bus at
this point.
Sample Point
A node in receive mode samples the CAN bus at this point. If the
three samples per bit option is selected, then this point marks the
position of the third sample.
The synchronization jump width (see the Bosch CAN specification for details) can be programmed in a
range of 1 to 4 time quanta by setting the SJW parameter.
The SYNC_SEG, TSEG1, TSEG2, and SJW parameters are set by programming the MSCAN bus timing
registers (CANBTR0, CANBTR1) (see Section 12.3.3, “MSCAN Bus Timing Register 0 (CANBTR0)”
and Section 12.3.4, “MSCAN Bus Timing Register 1 (CANBTR1)”).
Table 12-35 gives an overview of the CAN compliant segment settings and the related parameter values.
NOTE
It is the user’s responsibility to ensure the bit time settings are in compliance
with the CAN standard.
Table 12-35. CAN Standard Compliant Bit Time Segment Settings
Synchronization
Jump Width
Time Segment 1
TSEG1
Time Segment 2
TSEG2
5 .. 10
4 .. 9
2
1
1 .. 2
0 .. 1
4 .. 11
3 .. 10
3
2
1 .. 3
0 .. 2
5 .. 12
4 .. 11
4
3
1 .. 4
0 .. 3
6 .. 13
5 .. 12
5
4
1 .. 4
0 .. 3
7 .. 14
6 .. 13
6
5
1 .. 4
0 .. 3
8 .. 15
7 .. 14
7
6
1 .. 4
0 .. 3
9 .. 16
8 .. 15
8
7
1 .. 4
0 .. 3
12.5.4
12.5.4.1
SJW
Modes of Operation
Normal Modes
The MSCAN module behaves as described within this specification in all normal system operation modes.
12.5.4.2
Special Modes
The MSCAN module behaves as described within this specification in all special system operation modes.
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12.5.4.3
Emulation Modes
In all emulation modes, the MSCAN module behaves just like normal system operation modes as
described within this specification.
12.5.4.4
Listen-Only Mode
In an optional CAN bus monitoring mode (listen-only), the CAN node is able to receive valid data frames
and valid remote frames, but it sends only “recessive” bits on the CAN bus. In addition, it cannot start a
transmision. If the MAC sub-layer is required to send a “dominant” bit (ACK bit, overload flag, or active
error flag), the bit is rerouted internally so that the MAC sub-layer monitors this “dominant” bit, although
the CAN bus may remain in recessive state externally.
12.5.4.5
Security Modes
The MSCAN module has no security features.
12.5.4.6
Loopback Self Test Mode
Loopback self test mode is sometimes used to check software, independent of connections in the external
system, to help isolate system problems. In this mode, the transmitter output is internally connected to the
receiver input. The RXCAN input pin is ignored and the TXCAN output goes to the recessive state (logic
1). The MSCAN behaves as it does normally when transmitting and treats its own transmitted message as
a message received from a remote node. In this state, the MSCAN ignores the bit sent during the ACK slot
in the CAN frame acknowledge field to ensure proper reception of its own message. Both transmit and
receive interrupts are generated.
12.5.5
Low-Power Options
If the MSCAN is disabled (CANE = 0), the MSCAN clocks are stopped for power saving.
If the MSCAN is enabled (CANE = 1), the MSCAN has two additional modes with reduced power
consumption, compared to normal mode: sleep and power down mode. In sleep mode, power consumption
is reduced by stopping all clocks except those to access the registers from the CPU side. In power down
mode, all clocks are stopped and no power is consumed.
Table 12-36 summarizes the combinations of MSCAN and CPU modes. A particular combination of
modes is entered by the given settings on the CSWAI and SLPRQ/SLPAK bits.
For all modes, an MSCAN wake-up interrupt can occur only if the MSCAN is in sleep mode (SLPRQ = 1
and SLPAK = 1), wake-up functionality is enabled (WUPE = 1), and the wake-up interrupt is enabled
(WUPIE = 1).
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Table 12-36. CPU vs. MSCAN Operating Modes
MSCAN Mode
Reduced Power Consumption
CPU Mode
Normal
Sleep
Run
CSWAI = X
SLPRQ = 1
SLPAK = 1
Wait
CSWAI = 0
SLPRQ = 0
SLPAK = 0
CSWAI = 0
SLPRQ = 1
SLPAK = 1
CSWAI = 1
SLPRQ = X
SLPAK = X
CSWAI = X
SLPRQ = X
SLPAK = X
CSWAI = X2
SLPRQ = 1
SLPAK = 1
CSWAI = X
SLPRQ = 0
SLPAK = 0
CSWAI = X
SLPRQ = X
SLPAK = X
CSWAI = X
SLPRQ = X
SLPAK = X
CSWAI = X
SLPRQ = X
SLPAK = X
Stop1 or 2
2
Disabled
(CANE=0)
CSWAI = X1
SLPRQ = 0
SLPAK = 0
Stop3
1
Power Down
CSWAI = X
SLPRQ = X
SLPAK = X
‘X’ means don’t care.
For a safe wake up from Sleep mode, SLPRQ and SLPAK must be set to 1 before going into Stop3 mode.
12.5.5.1
Operation in Run Mode
As shown in Table 12-36, only MSCAN sleep mode is available as low power option when the CPU is in
run mode.
12.5.5.2
Operation in Wait Mode
The WAIT instruction puts the MCU in a low power consumption stand-by mode. If the CSWAI bit is set,
additional power can be saved in power down mode because the CPU clocks are stopped. After leaving
this power down mode, the MSCAN restarts its internal controllers and enters normal mode again.
While the CPU is in wait mode, the MSCAN can be operated in normal mode and generate interrupts
(registers can be accessed via background debug mode). The MSCAN can also operate in any of the
low-power modes depending on the values of the SLPRQ/SLPAK and CSWAI bits as seen in Table 12-36.
12.5.5.3
Operation in Stop Mode
The STOP instruction puts the MCU in a low power consumption stand-by mode. In stop1 or stop2 modes,
the MSCAN is set in power down mode regardless of the value of the SLPRQ/SLPAK. In stop3 mode,
power down or sleep modes are determined by the SLPRQ/SLPAK values set prior to entering stop3.
CSWAI bit has no function in any of the stop modes.Table 12-36.
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12.5.5.4
MSCAN Sleep Mode
The CPU can request the MSCAN to enter this low power mode by asserting the SLPRQ bit in the
CANCTL0 register. The time when the MSCAN enters sleep mode depends on a fixed synchronization
delay and its current activity:
• If there are one or more message buffers scheduled for transmission (TXEx = 0), the MSCAN will
continue to transmit until all transmit message buffers are empty (TXEx = 1, transmitted
successfully or aborted) and then goes into sleep mode.
• If the MSCAN is receiving, it continues to receive and goes into sleep mode as soon as the CAN
bus next becomes idle.
• If the MSCAN is neither transmitting nor receiving, it immediately goes into sleep mode.
Bus Clock Domain
CAN Clock Domain
SLPRQ
SYNC
sync.
SLPRQ
sync.
SYNC
SLPAK
CPU
Sleep Request
SLPAK
Flag
SLPAK
SLPRQ
Flag
MSCAN
in Sleep Mode
Figure 12-44. Sleep Request / Acknowledge Cycle
NOTE
The application software must avoid setting up a transmission (by clearing
one or more TXEx flag(s)) and immediately request sleep mode (by setting
SLPRQ). Whether the MSCAN starts transmitting or goes into sleep mode
directly depends on the exact sequence of operations.
If sleep mode is active, the SLPRQ and SLPAK bits are set (Figure 12-44). The application software must
use SLPAK as a handshake indication for the request (SLPRQ) to go into sleep mode.
When in sleep mode (SLPRQ = 1 and SLPAK = 1), the MSCAN stops its internal clocks. However, clocks
that allow register accesses from the CPU side continue to run.
If the MSCAN is in bus-off state, it stops counting the 128 occurrences of 11 consecutive recessive bits
due to the stopped clocks. The TXCAN pin remains in a recessive state. If RXF = 1, the message can be
read and RXF can be cleared. Shifting a new message into the foreground buffer of the receiver FIFO
(RxFG) does not take place while in sleep mode.
It is possible to access the transmit buffers and to clear the associated TXE flags. No message abort takes
place while in sleep mode.
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If the WUPE bit in CANCLT0 is not asserted, the MSCAN will mask any activity it detects on CAN. The
RXCAN pin is therefore held internally in a recessive state. This locks the MSCAN in sleep mode
(Figure 12-45). WUPE must be set before entering sleep mode to take effect.
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The MSCAN is able to leave sleep mode (wake up) only when:
• CAN bus activity occurs and WUPE = 1
or
• the CPU clears the SLPRQ bit
NOTE
The CPU cannot clear the SLPRQ bit before sleep mode (SLPRQ = 1 and
SLPAK = 1) is active.
After wake-up, the MSCAN waits for 11 consecutive recessive bits to synchronize to the CAN bus. As a
consequence, if the MSCAN is woken-up by a CAN frame, this frame is not received.
The receive message buffers (RxFG and RxBG) contain messages if they were received before sleep mode
was entered. All pending actions will be executed upon wake-up; copying of RxBG into RxFG, message
aborts and message transmissions. If the MSCAN remains in bus-off state after sleep mode was exited, it
continues counting the 128 occurrences of 11 consecutive recessive bits.
CAN Activity
(CAN Activity & WUPE) | SLPRQ
Wait
for Idle
StartUp
CAN Activity
SLPRQ
CAN Activity &
SLPRQ
Sleep
Idle
(CAN Activity & WUPE) |
CAN Activity
CAN Activity &
SLPRQ
CAN Activity
Tx/Rx
Message
Active
CAN Activity
Figure 12-45. Simplified State Transitions for Entering/Leaving Sleep Mode
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.5.5.5
MSCAN Initialization Mode
In initialization mode, any on-going transmission or reception is immediately aborted and synchronization
to the CAN bus is lost, potentially causing CAN protocol violations. To protect the CAN bus system from
fatal consequences of violations, the MSCAN immediately drives the TXCAN pin into a recessive state.
NOTE
The user is responsible for ensuring that the MSCAN is not active when
initialization mode is entered. The recommended procedure is to bring the
MSCAN into sleep mode (SLPRQ = 1 and SLPAK = 1) before setting the
INITRQ bit in the CANCTL0 register. Otherwise, the abort of an on-going
message can cause an error condition and can impact other CAN bus
devices.
In initialization mode, the MSCAN is stopped. However, interface registers remain accessible. This mode
is used to reset the CANCTL0, CANRFLG, CANRIER, CANTFLG, CANTIER, CANTARQ,
CANTAAK, and CANTBSEL registers to their default values. In addition, the MSCAN enables the
configuration of the CANBTR0, CANBTR1 bit timing registers; CANIDAC; and the CANIDAR,
CANIDMR message filters. See Section 12.3.1, “MSCAN Control Register 0 (CANCTL0),” for a detailed
description of the initialization mode.
Bus Clock Domain
CAN Clock Domain
INITRQ
SYNC
sync.
INITRQ
sync.
SYNC
INITAK
CPU
Init Request
INITAK
Flag
INITAK
INIT
Flag
Figure 12-46. Initialization Request/Acknowledge Cycle
Due to independent clock domains within the MSCAN, INITRQ must be synchronized to all domains by
using a special handshake mechanism. This handshake causes additional synchronization delay (see
Section Figure 12-46., “Initialization Request/Acknowledge Cycle”).
If there is no message transfer ongoing on the CAN bus, the minimum delay will be two additional bus
clocks and three additional CAN clocks. When all parts of the MSCAN are in initialization mode, the
INITAK flag is set. The application software must use INITAK as a handshake indication for the request
(INITRQ) to go into initialization mode.
NOTE
The CPU cannot clear INITRQ before initialization mode (INITRQ = 1 and
INITAK = 1) is active.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.5.5.6
MSCAN Power Down Mode
The MSCAN is in power down mode (Table 12-36) when
• CPU is in stop mode
or
• CPU is in wait mode and the CSWAI bit is set
When entering the power down mode, the MSCAN immediately stops all ongoing transmissions and
receptions, potentially causing CAN protocol violations. To protect the CAN bus system from fatal
consequences of violations to the above rule, the MSCAN immediately drives the TXCAN pin into a
recessive state.
NOTE
The user is responsible for ensuring that the MSCAN is not active when
power down mode is entered. The recommended procedure is to bring the
MSCAN into Sleep mode before the STOP or WAIT instruction (if CSWAI
is set) is executed. Otherwise, the abort of an ongoing message can cause an
error condition and impact other CAN bus devices.
In power down mode, all clocks are stopped and no registers can be accessed. If the MSCAN was not in
sleep mode before power down mode became active, the module performs an internal recovery cycle after
powering up. This causes some fixed delay before the module enters normal mode again.
12.5.5.7
Programmable Wake-Up Function
The MSCAN can be programmed to wake up the MSCAN as soon as CAN bus activity is detected (see
control bit WUPE in Section 12.3.1, “MSCAN Control Register 0 (CANCTL0)”). The sensitivity to
existing CAN bus action can be modified by applying a low-pass filter function to the RXCAN input line
while in sleep mode (see control bit WUPM in Section 12.3.2, “MSCAN Control Register 1
(CANCTL1)”).
This feature can be used to protect the MSCAN from wake-up due to short glitches on the CAN bus lines.
Such glitches can result from—for example—electromagnetic interference within noisy environments.
12.5.6
Reset Initialization
The reset state of each individual bit is listed in Section 12.3, “Register Definition,” which details all the
registers and their bit-fields.
12.5.7
Interrupts
This section describes all interrupts originated by the MSCAN. It documents the enable bits and generated
flags. Each interrupt is listed and described separately.
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.5.7.1
Description of Interrupt Operation
The MSCAN supports four interrupt vectors (see Table 12-37), any of which can be individually masked
(for details see sections from Section 12.3.5, “MSCAN Receiver Interrupt Enable Register (CANRIER),”
to Section 12.3.7, “MSCAN Transmitter Interrupt Enable Register (CANTIER)”).
NOTE
The dedicated interrupt vector addresses are defined in the Resets and
Interrupts chapter.
Table 12-37. Interrupt Vectors
Interrupt Source
Wake-Up Interrupt (WUPIF)
12.5.7.2
CCR Mask
I bit
Local Enable
CANRIER (WUPIE)
Error Interrupts Interrupt (CSCIF, OVRIF)
I bit
CANRIER (CSCIE, OVRIE)
Receive Interrupt (RXF)
I bit
CANRIER (RXFIE)
Transmit Interrupts (TXE[2:0])
I bit
CANTIER (TXEIE[2:0])
Transmit Interrupt
At least one of the three transmit buffers is empty (not scheduled) and can be loaded to schedule a message
for transmission. The TXEx flag of the empty message buffer is set.
12.5.7.3
Receive Interrupt
A message is successfully received and shifted into the foreground buffer (RxFG) of the receiver FIFO.
This interrupt is generated immediately after receiving the EOF symbol. The RXF flag is set. If there are
multiple messages in the receiver FIFO, the RXF flag is set as soon as the next message is shifted to the
foreground buffer.
12.5.7.4
Wake-Up Interrupt
A wake-up interrupt is generated if activity on the CAN bus occurs during MSCAN internal sleep mode.
WUPE (see Section 12.3.1, “MSCAN Control Register 0 (CANCTL0)”) must be enabled.
12.5.7.5
Error Interrupt
An error interrupt is generated if an overrun of the receiver FIFO, error, warning, or bus-off condition
occurrs. Section 12.3.4.1, “MSCAN Receiver Flag Register (CANRFLG) indicates one of the following
conditions:
• Overrun — An overrun condition of the receiver FIFO as described in Section 12.5.2.3, “Receive
Structures,” occurred.
• CAN Status Change — The actual value of the transmit and receive error counters control the
CAN bus state of the MSCAN. As soon as the error counters skip into a critical range
(Tx/Rx-warning, Tx/Rx-error, bus-off) the MSCAN flags an error condition. The status change,
which caused the error condition, is indicated by the TSTAT and RSTAT flags (see
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
269
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
Section 12.3.4.1, “MSCAN Receiver Flag Register (CANRFLG)” and Section 12.3.5, “MSCAN
Receiver Interrupt Enable Register (CANRIER)”).
12.5.7.6
Interrupt Acknowledge
Interrupts are directly associated with one or more status flags in either the Section 12.3.4.1, “MSCAN
Receiver Flag Register (CANRFLG)” or the Section 12.3.6, “MSCAN Transmitter Flag Register
(CANTFLG).” Interrupts are pending as long as one of the corresponding flags is set. The flags in
CANRFLG and CANTFLG must be reset within the interrupt handler to handshake the interrupt. The flags
are reset by writing a 1 to the corresponding bit position. A flag cannot be cleared if the respective
condition prevails.
NOTE
It must be guaranteed that the CPU clears only the bit causing the current
interrupt. For this reason, bit manipulation instructions (BSET) must not be
used to clear interrupt flags. These instructions may cause accidental
clearing of interrupt flags which are set after entering the current interrupt
service routine.
12.5.7.7
Recovery from Stop or Wait
The MSCAN can recover from stop or wait via the wake-up interrupt. This interrupt can only occur if the
MSCAN was in sleep mode (SLPRQ = 1 and SLPAK = 1) before entering power down mode, the wake-up
option is enabled (WUPE = 1), and the wake-up interrupt is enabled (WUPIE = 1).
12.6
12.6.1
Initialization/Application Information
MSCAN initialization
The procedure to initially start up the MSCAN module out of reset is as follows:
1. Assert CANE
2. Write to the configuration registers in initialization mode
3. Clear INITRQ to leave initialization mode and enter normal mode
If the configuration of registers which are writable in initialization mode needs to be changed only when
the MSCAN module is in normal mode:
1. Bring the module into sleep mode by setting SLPRQ and awaiting SLPAK to assert after the CAN
bus becomes idle.
2. Enter initialization mode: assert INITRQ and await INITAK
3. Write to the configuration registers in initialization mode
4. Clear INITRQ to leave initialization mode and continue in normal mode
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
12.6.2
Bus-Off Recovery
The bus-off recovery is user configurable. The bus-off state can either be exited automatically or on user
request.
For reasons of backwards compatibility, the MSCAN defaults to automatic recovery after reset. In this
case, the MSCAN will become error active again after counting 128 occurrences of 11 consecutive
recessive bits on the CAN bus (See the Bosch CAN specification for details).
If the MSCAN is configured for user request (BORM set in Section 12.3.2, “MSCAN Control Register 1
(CANCTL1)”), the recovery from bus-off starts after both independent events have become true:
• 128 occurrences of 11 consecutive recessive bits on the CAN bus have been monitored
• BOHOLD in Section 12.3.12, “MSCAN Miscellaneous Register (CANMISC) has been cleared by
the user
These two events may occur in any order.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 12 Freescale’s Controller Area Network (S08MSCANV1)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 13
Serial Peripheral Interface (S08SPIV3)
13.1
Introduction
The serial peripheral interface (SPI) module provides for full-duplex, synchronous, serial communication
between the MCU and peripheral devices. These peripheral devices can include other microcontrollers,
analog-to-digital converters, shift registers, sensors, memories, etc.
The SPI runs at a baud rate up to the bus clock divided by two in master mode and bus clock divided by
four in slave mode.
All devices in the MC9S08DZ60 Series MCUs contain one SPI module, as shown in the following block
diagram.
NOTE
Ensure that the SPI should not be disabled (SPE=0) at the same time as a bit
change to the CPHA bit. These changes should be performed as separate
operations or unexpected behavior may occur.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
273
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 13 Serial Peripheral Interface (S08SPIV3)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 13-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 13 Serial Peripheral Interface (S08SPIV3)
13.1.1
Features
Features of the SPI module include:
• Master or slave mode operation
• Full-duplex or single-wire bidirectional option
• Programmable transmit bit rate
• Double-buffered transmit and receive
• Serial clock phase and polarity options
• Slave select output
• Selectable MSB-first or LSB-first shifting
13.1.2
Block Diagrams
This section includes block diagrams showing SPI system connections, the internal organization of the SPI
module, and the SPI clock dividers that control the master mode bit rate.
13.1.2.1
SPI System Block Diagram
Figure 13-2 shows the SPI modules of two MCUs connected in a master-slave arrangement. The master
device initiates all SPI data transfers. During a transfer, the master shifts data out (on the MOSI pin) to the
slave while simultaneously shifting data in (on the MISO pin) from the slave. The transfer effectively
exchanges the data that was in the SPI shift registers of the two SPI systems. The SPSCK signal is a clock
output from the master and an input to the slave. The slave device must be selected by a low level on the
slave select input (SS pin). In this system, the master device has configured its SS pin as an optional slave
select output.
SLAVE
MASTER
MOSI
MOSI
SPI SHIFTER
7
6
5
4
3
2
SPI SHIFTER
1
0
MISO
SPSCK
CLOCK
GENERATOR
SS
MISO
7
6
5
4
3
2
1
0
SPSCK
SS
Figure 13-2. SPI System Connections
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
275
Chapter 13 Serial Peripheral Interface (S08SPIV3)
The most common uses of the SPI system include connecting simple shift registers for adding input or
output ports or connecting small peripheral devices such as serial A/D or D/A converters. Although
Figure 13-2 shows a system where data is exchanged between two MCUs, many practical systems involve
simpler connections where data is unidirectionally transferred from the master MCU to a slave or from a
slave to the master MCU.
13.1.2.2
SPI Module Block Diagram
Figure 13-3 is a block diagram of the SPI module. The central element of the SPI is the SPI shift register.
Data is written to the double-buffered transmitter (write to SPID) and gets transferred to the SPI shift
register at the start of a data transfer. After shifting in a byte of data, the data is transferred into the
double-buffered receiver where it can be read (read from SPID). Pin multiplexing logic controls
connections between MCU pins and the SPI module.
When the SPI is configured as a master, the clock output is routed to the SPSCK pin, the shifter output is
routed to MOSI, and the shifter input is routed from the MISO pin.
When the SPI is configured as a slave, the SPSCK pin is routed to the clock input of the SPI, the shifter
output is routed to MISO, and the shifter input is routed from the MOSI pin.
In the external SPI system, simply connect all SPSCK pins to each other, all MISO pins together, and all
MOSI pins together. Peripheral devices often use slightly different names for these pins.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 13 Serial Peripheral Interface (S08SPIV3)
PIN CONTROL
M
SPE
MOSI
(MOMI)
S
Tx BUFFER (WRITE SPID)
ENABLE
SPI SYSTEM
M
SHIFT
OUT
SPI SHIFT REGISTER
SHIFT
IN
MISO
(SISO)
S
SPC0
Rx BUFFER (READ SPID)
BIDIROE
SHIFT
DIRECTION
LSBFE
SHIFT
CLOCK
Rx BUFFER
FULL
Tx BUFFER
EMPTY
MASTER CLOCK
BUS RATE
CLOCK
SPIBR
CLOCK GENERATOR
MSTR
CLOCK
LOGIC
SLAVE CLOCK
MASTER/SLAVE
M
SPSCK
S
MASTER/
SLAVE
MODE SELECT
MODFEN
SSOE
MODE FAULT
DETECTION
SS
SPRF
SPTEF
SPTIE
MODF
SPIE
SPI
INTERRUPT
REQUEST
Figure 13-3. SPI Module Block Diagram
13.1.3
SPI Baud Rate Generation
As shown in Figure 13-4, the clock source for the SPI baud rate generator is the bus clock. The three
prescale bits (SPPR2:SPPR1:SPPR0) choose a prescale divisor of 1, 2, 3, 4, 5, 6, 7, or 8. The three rate
select bits (SPR2:SPR1:SPR0) divide the output of the prescaler stage by 2, 4, 8, 16, 32, 64, 128, or 256
to get the internal SPI master mode bit-rate clock.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
277
Chapter 13 Serial Peripheral Interface (S08SPIV3)
BUS CLOCK
PRESCALER
CLOCK RATE DIVIDER
DIVIDE BY
1, 2, 3, 4, 5, 6, 7, or 8
DIVIDE BY
2, 4, 8, 16, 32, 64, 128, or 256
SPPR2:SPPR1:SPPR0
SPR2:SPR1:SPR0
MASTER
SPI
BIT RATE
Figure 13-4. SPI Baud Rate Generation
13.2
External Signal Description
The SPI optionally shares four port pins. The function of these pins depends on the settings of SPI control
bits. When the SPI is disabled (SPE = 0), these four pins revert to being general-purpose port I/O pins that
are not controlled by the SPI.
13.2.1
SPSCK — SPI Serial Clock
When the SPI is enabled as a slave, this pin is the serial clock input. When the SPI is enabled as a master,
this pin is the serial clock output.
13.2.2
MOSI — Master Data Out, Slave Data In
When the SPI is enabled as a master and SPI pin control zero (SPC0) is 0 (not bidirectional mode), this
pin is the serial data output. When the SPI is enabled as a slave and SPC0 = 0, this pin is the serial data
input. If SPC0 = 1 to select single-wire bidirectional mode, and master mode is selected, this pin becomes
the bidirectional data I/O pin (MOMI). Also, the bidirectional mode output enable bit determines whether
the pin acts as an input (BIDIROE = 0) or an output (BIDIROE = 1). If SPC0 = 1 and slave mode is
selected, this pin is not used by the SPI and reverts to being a general-purpose port I/O pin.
13.2.3
MISO — Master Data In, Slave Data Out
When the SPI is enabled as a master and SPI pin control zero (SPC0) is 0 (not bidirectional mode), this
pin is the serial data input. When the SPI is enabled as a slave and SPC0 = 0, this pin is the serial data
output. If SPC0 = 1 to select single-wire bidirectional mode, and slave mode is selected, this pin becomes
the bidirectional data I/O pin (SISO) and the bidirectional mode output enable bit determines whether the
pin acts as an input (BIDIROE = 0) or an output (BIDIROE = 1). If SPC0 = 1 and master mode is selected,
this pin is not used by the SPI and reverts to being a general-purpose port I/O pin.
13.2.4
SS — Slave Select
When the SPI is enabled as a slave, this pin is the low-true slave select input. When the SPI is enabled as
a master and mode fault enable is off (MODFEN = 0), this pin is not used by the SPI and reverts to being
a general-purpose port I/O pin. When the SPI is enabled as a master and MODFEN = 1, the slave select
output enable bit determines whether this pin acts as the mode fault input (SSOE = 0) or as the slave select
output (SSOE = 1).
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 13 Serial Peripheral Interface (S08SPIV3)
13.3
Modes of Operation
13.3.1
SPI in Stop Modes
The SPI is disabled in all stop modes, regardless of the settings before executing the STOP instruction.
During either stop1 or stop2 mode, the SPI module will be fully powered down. Upon wake-up from stop1
or stop2 mode, the SPI module will be in the reset state. During stop3 mode, clocks to the SPI module are
halted. No registers are affected. If stop3 is exited with a reset, the SPI will be put into its reset state. If
stop3 is exited with an interrupt, the SPI continues from the state it was in when stop3 was entered.
13.4
Register Definition
The SPI has five 8-bit registers to select SPI options, control baud rate, report SPI status, and for
transmit/receive data.
Refer to the direct-page register summary in the Memory chapter of this data sheet for the absolute address
assignments for all SPI registers. This section refers to registers and control bits only by their names, and
a Freescale-provided equate or header file is used to translate these names into the appropriate absolute
addresses.
13.4.1
SPI Control Register 1 (SPIC1)
This read/write register includes the SPI enable control, interrupt enables, and configuration options.
7
6
5
4
3
2
1
0
SPIE
SPE
SPTIE
MSTR
CPOL
CPHA
SSOE
LSBFE
0
0
0
0
0
1
0
0
R
W
Reset
Figure 13-5. SPI Control Register 1 (SPIC1)
Table 13-1. SPIC1 Field Descriptions
Field
Description
7
SPIE
SPI Interrupt Enable (for SPRF and MODF) — This is the interrupt enable for SPI receive buffer full (SPRF)
and mode fault (MODF) events.
0 Interrupts from SPRF and MODF inhibited (use polling)
1 When SPRF or MODF is 1, request a hardware interrupt
6
SPE
SPI System Enable — Disabling the SPI halts any transfer that is in progress, clears data buffers, and initializes
internal state machines. SPRF is cleared and SPTEF is set to indicate the SPI transmit data buffer is empty.
0 SPI system inactive
1 SPI system enabled
5
SPTIE
SPI Transmit Interrupt Enable — This is the interrupt enable bit for SPI transmit buffer empty (SPTEF).
0 Interrupts from SPTEF inhibited (use polling)
1 When SPTEF is 1, hardware interrupt requested
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 13 Serial Peripheral Interface (S08SPIV3)
Table 13-1. SPIC1 Field Descriptions (continued)
Field
Description
4
MSTR
Master/Slave Mode Select
0 SPI module configured as a slave SPI device
1 SPI module configured as a master SPI device
3
CPOL
Clock Polarity — This bit effectively places an inverter in series with the clock signal from a master SPI or to a
slave SPI device. Refer to Section 13.5.1, “SPI Clock Formats” for more details.
0 Active-high SPI clock (idles low)
1 Active-low SPI clock (idles high)
2
CPHA
Clock Phase — This bit selects one of two clock formats for different kinds of synchronous serial peripheral
devices. Refer to Section 13.5.1, “SPI Clock Formats” for more details.
0 First edge on SPSCK occurs at the middle of the first cycle of an 8-cycle data transfer
1 First edge on SPSCK occurs at the start of the first cycle of an 8-cycle data transfer
1
SSOE
Slave Select Output Enable — This bit is used in combination with the mode fault enable (MODFEN) bit in
SPCR2 and the master/slave (MSTR) control bit to determine the function of the SS pin as shown in Table 13-2.
0
LSBFE
LSB First (Shifter Direction)
0 SPI serial data transfers start with most significant bit
1 SPI serial data transfers start with least significant bit
Table 13-2. SS Pin Function
MODFEN
SSOE
Master Mode
Slave Mode
0
0
General-purpose I/O (not SPI)
Slave select input
0
1
General-purpose I/O (not SPI)
Slave select input
1
0
SS input for mode fault
Slave select input
1
1
Automatic SS output
Slave select input
NOTE
Ensure that the SPI should not be disabled (SPE=0) at the same time as a bit change to the CPHA bit. These
changes should be performed as separate operations or unexpected behavior may occur.
13.4.2
SPI Control Register 2 (SPIC2)
This read/write register is used to control optional features of the SPI system. Bits 7, 6, 5, and 2 are not
implemented and always read 0.
R
7
6
5
0
0
0
4
3
MODFEN
BIDIROE
0
0
2
1
0
SPISWAI
SPC0
0
0
0
W
Reset
0
0
0
0
= Unimplemented or Reserved
Figure 13-6. SPI Control Register 2 (SPIC2)
MC9S08DZ60 Series Data Sheet, Rev. 4
280
Freescale Semiconductor
Chapter 13 Serial Peripheral Interface (S08SPIV3)
Table 13-3. SPIC2 Register Field Descriptions
Field
Description
4
MODFEN
Master Mode-Fault Function Enable — When the SPI is configured for slave mode, this bit has no meaning or
effect. (The SS pin is the slave select input.) In master mode, this bit determines how the SS pin is used (refer
to Table 13-2 for more details).
0 Mode fault function disabled, master SS pin reverts to general-purpose I/O not controlled by SPI
1 Mode fault function enabled, master SS pin acts as the mode fault input or the slave select output
3
BIDIROE
Bidirectional Mode Output Enable — When bidirectional mode is enabled by SPI pin control 0 (SPC0) = 1,
BIDIROE determines whether the SPI data output driver is enabled to the single bidirectional SPI I/O pin.
Depending on whether the SPI is configured as a master or a slave, it uses either the MOSI (MOMI) or MISO
(SISO) pin, respectively, as the single SPI data I/O pin. When SPC0 = 0, BIDIROE has no meaning or effect.
0 Output driver disabled so SPI data I/O pin acts as an input
1 SPI I/O pin enabled as an output
1
SPISWAI
SPI Stop in Wait Mode
0 SPI clocks continue to operate in wait mode
1 SPI clocks stop when the MCU enters wait mode
0
SPC0
13.4.3
SPI Pin Control 0 — The SPC0 bit chooses single-wire bidirectional mode. If MSTR = 0 (slave mode), the SPI
uses the MISO (SISO) pin for bidirectional SPI data transfers. If MSTR = 1 (master mode), the SPI uses the
MOSI (MOMI) pin for bidirectional SPI data transfers. When SPC0 = 1, BIDIROE is used to enable or disable the
output driver for the single bidirectional SPI I/O pin.
0 SPI uses separate pins for data input and data output
1 SPI configured for single-wire bidirectional operation
SPI Baud Rate Register (SPIBR)
This register is used to set the prescaler and bit rate divisor for an SPI master. This register may be read or
written at any time.
7
R
6
5
4
3
SPPR2
SPPR1
SPPR0
0
0
0
0
2
1
0
SPR2
SPR1
SPR0
0
0
0
0
W
Reset
0
0
= Unimplemented or Reserved
Figure 13-7. SPI Baud Rate Register (SPIBR)
Table 13-4. SPIBR Register Field Descriptions
Field
Description
6:4
SPPR[2:0]
SPI Baud Rate Prescale Divisor — This 3-bit field selects one of eight divisors for the SPI baud rate prescaler
as shown in Table 13-5. The input to this prescaler is the bus rate clock (BUSCLK). The output of this prescaler
drives the input of the SPI baud rate divider (see Figure 13-4).
2:0
SPR[2:0]
SPI Baud Rate Divisor — This 3-bit field selects one of eight divisors for the SPI baud rate divider as shown in
Table 13-6. The input to this divider comes from the SPI baud rate prescaler (see Figure 13-4). The output of this
divider is the SPI bit rate clock for master mode.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
281
Chapter 13 Serial Peripheral Interface (S08SPIV3)
Table 13-5. SPI Baud Rate Prescaler Divisor
SPPR2:SPPR1:SPPR0
Prescaler Divisor
0:0:0
1
0:0:1
2
0:1:0
3
0:1:1
4
1:0:0
5
1:0:1
6
1:1:0
7
1:1:1
8
Table 13-6. SPI Baud Rate Divisor
13.4.4
SPR2:SPR1:SPR0
Rate Divisor
0:0:0
2
0:0:1
4
0:1:0
8
0:1:1
16
1:0:0
32
1:0:1
64
1:1:0
128
1:1:1
256
SPI Status Register (SPIS)
This register has three read-only status bits. Bits 6, 3, 2, 1, and 0 are not implemented and always read 0.
Writes have no meaning or effect.
R
7
6
5
4
3
2
1
0
SPRF
0
SPTEF
MODF
0
0
0
0
0
0
1
0
0
0
0
0
W
Reset
= Unimplemented or Reserved
Figure 13-8. SPI Status Register (SPIS)
MC9S08DZ60 Series Data Sheet, Rev. 4
282
Freescale Semiconductor
Chapter 13 Serial Peripheral Interface (S08SPIV3)
Table 13-7. SPIS Register Field Descriptions
Field
Description
7
SPRF
SPI Read Buffer Full Flag — SPRF is set at the completion of an SPI transfer to indicate that received data may
be read from the SPI data register (SPID). SPRF is cleared by reading SPRF while it is set, then reading the SPI
data register.
0 No data available in the receive data buffer
1 Data available in the receive data buffer
5
SPTEF
SPI Transmit Buffer Empty Flag — This bit is set when there is room in the transmit data buffer. It is cleared by
reading SPIS with SPTEF set, followed by writing a data value to the transmit buffer at SPID. SPIS must be read
with SPTEF = 1 before writing data to SPID or the SPID write will be ignored. SPTEF generates an SPTEF CPU
interrupt request if the SPTIE bit in the SPIC1 is also set. SPTEF is automatically set when a data byte transfers
from the transmit buffer into the transmit shift register. For an idle SPI (no data in the transmit buffer or the shift
register and no transfer in progress), data written to SPID is transferred to the shifter almost immediately so
SPTEF is set within two bus cycles allowing a second 8-bit data value to be queued into the transmit buffer. After
completion of the transfer of the value in the shift register, the queued value from the transmit buffer will
automatically move to the shifter and SPTEF will be set to indicate there is room for new data in the transmit
buffer. If no new data is waiting in the transmit buffer, SPTEF simply remains set and no data moves from the
buffer to the shifter.
0 SPI transmit buffer not empty
1 SPI transmit buffer empty
4
MODF
Master Mode Fault Flag — MODF is set if the SPI is configured as a master and the slave select input goes
low, indicating some other SPI device is also configured as a master. The SS pin acts as a mode fault error input
only when MSTR = 1, MODFEN = 1, and SSOE = 0; otherwise, MODF will never be set. MODF is cleared by
reading MODF while it is 1, then writing to SPI control register 1 (SPIC1).
0 No mode fault error
1 Mode fault error detected
13.4.5
SPI Data Register (SPID)
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
0
0
0
0
0
0
R
W
Reset
Figure 13-9. SPI Data Register (SPID)
Reads of this register return the data read from the receive data buffer. Writes to this register write data to
the transmit data buffer. When the SPI is configured as a master, writing data to the transmit data buffer
initiates an SPI transfer.
Data should not be written to the transmit data buffer unless the SPI transmit buffer empty flag (SPTEF)
is set, indicating there is room in the transmit buffer to queue a new transmit byte.
Data may be read from SPID any time after SPRF is set and before another transfer is finished. Failure to
read the data out of the receive data buffer before a new transfer ends causes a receive overrun condition
and the data from the new transfer is lost.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
283
Chapter 13 Serial Peripheral Interface (S08SPIV3)
13.5
Functional Description
An SPI transfer is initiated by checking for the SPI transmit buffer empty flag (SPTEF = 1) and then
writing a byte of data to the SPI data register (SPID) in the master SPI device. When the SPI shift register
is available, this byte of data is moved from the transmit data buffer to the shifter, SPTEF is set to indicate
there is room in the buffer to queue another transmit character if desired, and the SPI serial transfer starts.
During the SPI transfer, data is sampled (read) on the MISO pin at one SPSCK edge and shifted, changing
the bit value on the MOSI pin, one-half SPSCK cycle later. After eight SPSCK cycles, the data that was in
the shift register of the master has been shifted out the MOSI pin to the slave while eight bits of data were
shifted in the MISO pin into the master’s shift register. At the end of this transfer, the received data byte is
moved from the shifter into the receive data buffer and SPRF is set to indicate the data can be read by
reading SPID. If another byte of data is waiting in the transmit buffer at the end of a transfer, it is moved
into the shifter, SPTEF is set, and a new transfer is started.
Normally, SPI data is transferred most significant bit (MSB) first. If the least significant bit first enable
(LSBFE) bit is set, SPI data is shifted LSB first.
When the SPI is configured as a slave, its SS pin must be driven low before a transfer starts and SS must
stay low throughout the transfer. If a clock format where CPHA = 0 is selected, SS must be driven to a
logic 1 between successive transfers. If CPHA = 1, SS may remain low between successive transfers. See
Section 13.5.1, “SPI Clock Formats” for more details.
Because the transmitter and receiver are double buffered, a second byte, in addition to the byte currently
being shifted out, can be queued into the transmit data buffer, and a previously received character can be
in the receive data buffer while a new character is being shifted in. The SPTEF flag indicates when the
transmit buffer has room for a new character. The SPRF flag indicates when a received character is
available in the receive data buffer. The received character must be read out of the receive buffer (read
SPID) before the next transfer is finished or a receive overrun error results.
In the case of a receive overrun, the new data is lost because the receive buffer still held the previous
character and was not ready to accept the new data. There is no indication for such an overrun condition
so the application system designer must ensure that previous data has been read from the receive buffer
before a new transfer is initiated.
13.5.1
SPI Clock Formats
To accommodate a wide variety of synchronous serial peripherals from different manufacturers, the SPI
system has a clock polarity (CPOL) bit and a clock phase (CPHA) control bit to select one of four clock
formats for data transfers. CPOL selectively inserts an inverter in series with the clock. CPHA chooses
between two different clock phase relationships between the clock and data.
Figure 13-10 shows the clock formats when CPHA = 1. At the top of the figure, the eight bit times are
shown for reference with bit 1 starting at the first SPSCK edge and bit 8 ending one-half SPSCK cycle after
the sixteenth SPSCK edge. The MSB first and LSB first lines show the order of SPI data bits depending
on the setting in LSBFE. Both variations of SPSCK polarity are shown, but only one of these waveforms
applies for a specific transfer, depending on the value in CPOL. The SAMPLE IN waveform applies to the
MOSI input of a slave or the MISO input of a master. The MOSI waveform applies to the MOSI output
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 13 Serial Peripheral Interface (S08SPIV3)
pin from a master and the MISO waveform applies to the MISO output from a slave. The SS OUT
waveform applies to the slave select output from a master (provided MODFEN and SSOE = 1). The master
SS output goes to active low one-half SPSCK cycle before the start of the transfer and goes back high at
the end of the eighth bit time of the transfer. The SS IN waveform applies to the slave select input of a
slave.
BIT TIME #
(REFERENCE)
1
2
...
6
7
8
BIT 7
BIT 0
BIT 6
BIT 1
...
...
BIT 2
BIT 5
BIT 1
BIT 6
BIT 0
BIT 7
SPSCK
(CPOL = 0)
SPSCK
(CPOL = 1)
SAMPLE IN
(MISO OR MOSI)
MOSI
(MASTER OUT)
MSB FIRST
LSB FIRST
MISO
(SLAVE OUT)
SS OUT
(MASTER)
SS IN
(SLAVE)
Figure 13-10. SPI Clock Formats (CPHA = 1)
When CPHA = 1, the slave begins to drive its MISO output when SS goes to active low, but the data is not
defined until the first SPSCK edge. The first SPSCK edge shifts the first bit of data from the shifter onto
the MOSI output of the master and the MISO output of the slave. The next SPSCK edge causes both the
master and the slave to sample the data bit values on their MISO and MOSI inputs, respectively. At the
third SPSCK edge, the SPI shifter shifts one bit position which shifts in the bit value that was just sampled,
and shifts the second data bit value out the other end of the shifter to the MOSI and MISO outputs of the
master and slave, respectively. When CHPA = 1, the slave’s SS input is not required to go to its inactive
high level between transfers.
Figure 13-11 shows the clock formats when CPHA = 0. At the top of the figure, the eight bit times are
shown for reference with bit 1 starting as the slave is selected (SS IN goes low), and bit 8 ends at the last
SPSCK edge. The MSB first and LSB first lines show the order of SPI data bits depending on the setting
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 13 Serial Peripheral Interface (S08SPIV3)
in LSBFE. Both variations of SPSCK polarity are shown, but only one of these waveforms applies for a
specific transfer, depending on the value in CPOL. The SAMPLE IN waveform applies to the MOSI input
of a slave or the MISO input of a master. The MOSI waveform applies to the MOSI output pin from a
master and the MISO waveform applies to the MISO output from a slave. The SS OUT waveform applies
to the slave select output from a master (provided MODFEN and SSOE = 1). The master SS output goes
to active low at the start of the first bit time of the transfer and goes back high one-half SPSCK cycle after
the end of the eighth bit time of the transfer. The SS IN waveform applies to the slave select input of a
slave.
BIT TIME #
(REFERENCE)
1
2
BIT 7
BIT 0
BIT 6
BIT 1
...
6
7
8
BIT 2
BIT 5
BIT 1
BIT 6
BIT 0
BIT 7
SPSCK
(CPOL = 0)
SPSCK
(CPOL = 1)
SAMPLE IN
(MISO OR MOSI)
MOSI
(MASTER OUT)
MSB FIRST
LSB FIRST
...
...
MISO
(SLAVE OUT)
SS OUT
(MASTER)
SS IN
(SLAVE)
Figure 13-11. SPI Clock Formats (CPHA = 0)
When CPHA = 0, the slave begins to drive its MISO output with the first data bit value (MSB or LSB
depending on LSBFE) when SS goes to active low. The first SPSCK edge causes both the master and the
slave to sample the data bit values on their MISO and MOSI inputs, respectively. At the second SPSCK
edge, the SPI shifter shifts one bit position which shifts in the bit value that was just sampled and shifts the
second data bit value out the other end of the shifter to the MOSI and MISO outputs of the master and
slave, respectively. When CPHA = 0, the slave’s SS input must go to its inactive high level between
transfers.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 13 Serial Peripheral Interface (S08SPIV3)
13.5.2
SPI Interrupts
There are three flag bits, two interrupt mask bits, and one interrupt vector associated with the SPI system.
The SPI interrupt enable mask (SPIE) enables interrupts from the SPI receiver full flag (SPRF) and mode
fault flag (MODF). The SPI transmit interrupt enable mask (SPTIE) enables interrupts from the SPI
transmit buffer empty flag (SPTEF). When one of the flag bits is set, and the associated interrupt mask bit
is set, a hardware interrupt request is sent to the CPU. If the interrupt mask bits are cleared, software can
poll the associated flag bits instead of using interrupts. The SPI interrupt service routine (ISR) should
check the flag bits to determine what event caused the interrupt. The service routine should also clear the
flag bit(s) before returning from the ISR (usually near the beginning of the ISR).
13.5.3
Mode Fault Detection
A mode fault occurs and the mode fault flag (MODF) becomes set when a master SPI device detects an
error on the SS pin (provided the SS pin is configured as the mode fault input signal). The SS pin is
configured to be the mode fault input signal when MSTR = 1, mode fault enable is set (MODFEN = 1),
and slave select output enable is clear (SSOE = 0).
The mode fault detection feature can be used in a system where more than one SPI device might become
a master at the same time. The error is detected when a master’s SS pin is low, indicating that some other
SPI device is trying to address this master as if it were a slave. This could indicate a harmful output driver
conflict, so the mode fault logic is designed to disable all SPI output drivers when such an error is detected.
When a mode fault is detected, MODF is set and MSTR is cleared to change the SPI configuration back
to slave mode. The output drivers on the SPSCK, MOSI, and MISO (if not bidirectional mode) are
disabled.
MODF is cleared by reading it while it is set, then writing to the SPI control register 1 (SPIC1). User
software should verify the error condition has been corrected before changing the SPI back to master
mode.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
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Chapter 13 Serial Peripheral Interface (S08SPIV3)
MC9S08DZ60 Series Data Sheet, Rev. 4
288
Freescale Semiconductor
Chapter 14
Serial Communications Interface (S08SCIV4)
14.1
Introduction
All MCUs in the MC9S08DZ60 Series include SCI1 and SCI2.
•
•
14.1.1
NOTE
MC9S08DZ60 Series devices operate at a higher voltage range (2.7 V to
5.5 V) and do not include stop1 mode. Please ignore references to stop1.
The RxD1 pin does not contain a clamp diode to VDD and should not be
driven above VDD. The voltage measured on the internally pulled up
RxD1 pin may be as low as VDD – 0.7 V. The internal gates connected
to this pin are pulled all the way to VDD.
SCI2 Configuration Information
The SCI2 module pins, TxD2 and RxD2 can be repositioned under software control using SCI2PS in
SOPT1 as shown in Table 14-1. SCI2PS in SOPT1 selects which general-purpose I/O ports are associated
with SCI2 operation.
Table 14-1. SCI2 Position Options
SCI2PS in SOPT1
Port Pin for TxD2
Port Pin for RxD2
0 (default)
PTF0
PTF1
1
PTE6
PTE7
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
289
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 14 Serial Communications Interface (S08SCIV4)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 14-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
290
Freescale Semiconductor
Chapter 14 Serial Communications Interface (S08SCIV4)
14.1.2
Features
Features of SCI module include:
• Full-duplex, standard non-return-to-zero (NRZ) format
• Double-buffered transmitter and receiver with separate enables
• Programmable baud rates (13-bit modulo divider)
• Interrupt-driven or polled operation:
— Transmit data register empty and transmission complete
— Receive data register full
— Receive overrun, parity error, framing error, and noise error
— Idle receiver detect
— Active edge on receive pin
— Break detect supporting LIN
• Hardware parity generation and checking
• Programmable 8-bit or 9-bit character length
• Receiver wakeup by idle-line or address-mark
• Optional 13-bit break character generation / 11-bit break character detection
• Selectable transmitter output polarity
14.1.3
Modes of Operation
See Section 14.3, “Functional Description,” For details concerning SCI operation in these modes:
• 8- and 9-bit data modes
• Stop mode operation
• Loop mode
• Single-wire mode
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
291
Chapter 14 Serial Communications Interface (S08SCIV4)
14.1.4
Block Diagram
Figure 14-2 shows the transmitter portion of the SCI.
INTERNAL BUS
(WRITE-ONLY)
LOOPS
SCID – Tx BUFFER
RSRC
LOOP
CONTROL
STOP
M
START
11-BIT TRANSMIT SHIFT REGISTER
8
7
6
5
4
3
2
1
0
TO TxD PIN
L
LSB
H
1 × BAUD
RATE CLOCK
TO RECEIVE
DATA IN
SHIFT DIRECTION
PT
BREAK (ALL 0s)
PARITY
GENERATION
PREAMBLE (ALL 1s)
PE
SHIFT ENABLE
T8
LOAD FROM SCIxD
TXINV
SCI CONTROLS TxD
TE
SBK
TRANSMIT CONTROL
TXDIR
TxD DIRECTION
TO TxD
PIN LOGIC
BRK13
TDRE
TIE
TC
Tx INTERRUPT
REQUEST
TCIE
Figure 14-2. SCI Transmitter Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 14 Serial Communications Interface (S08SCIV4)
Figure 14-3 shows the receiver portion of the SCI.
INTERNAL BUS
(READ-ONLY)
16 × BAUD
RATE CLOCK
DIVIDE
BY 16
SCID – Rx BUFFER
FROM RxD PIN
RXINV
LBKDE
H
DATA RECOVERY
WAKE
ILT
8
7
6
5
4
3
2
1
START
M
LSB
RSRC
11-BIT RECEIVE SHIFT REGISTER
MSB
SINGLE-WIRE
LOOP CONTROL
ALL 1s
LOOPS
STOP
FROM
TRANSMITTER
0
L
SHIFT DIRECTION
WAKEUP
LOGIC
RWU
RWUID
ACTIVE EDGE
DETECT
RDRF
RIE
IDLE
ILIE
LBKDIF
Rx INTERRUPT
REQUEST
LBKDIE
RXEDGIF
RXEDGIE
OR
ORIE
FE
FEIE
ERROR INTERRUPT
REQUEST
NF
NEIE
PE
PT
PARITY
CHECKING
PF
PEIE
Figure 14-3. SCI Receiver Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
293
Chapter 14 Serial Communications Interface (S08SCIV4)
14.2
Register Definition
The SCI has eight 8-bit registers to control baud rate, select SCI options, report SCI status, and for
transmit/receive data.
Refer to the direct-page register summary in the Memory chapter of this data sheet for the absolute address
assignments for all SCI registers. This section refers to registers and control bits only by their names. A
Freescale-provided equate or header file is used to translate these names into the appropriate absolute
addresses.
14.2.1
SCI Baud Rate Registers (SCIxBDH, SCIxBDL)
This pair of registers controls the prescale divisor for SCI baud rate generation. To update the 13-bit baud
rate setting [SBR12:SBR0], first write to SCIxBDH to buffer the high half of the new value and then write
to SCIxBDL. The working value in SCIxBDH does not change until SCIxBDL is written.
SCIxBDL is reset to a non-zero value, so after reset the baud rate generator remains disabled until the first
time the receiver or transmitter is enabled (RE or TE bits in SCIxC2 are written to 1).
7
6
5
LBKDIE
RXEDGIE
0
0
R
4
3
2
1
0
SBR12
SBR11
SBR10
SBR9
SBR8
0
0
0
0
0
0
W
Reset
0
= Unimplemented or Reserved
Figure 14-4. SCI Baud Rate Register (SCIxBDH)
Table 14-2. SCIxBDH Field Descriptions
Field
7
LBKDIE
Description
LIN Break Detect Interrupt Enable (for LBKDIF)
0 Hardware interrupts from LBKDIF disabled (use polling).
1 Hardware interrupt requested when LBKDIF flag is 1.
6
RXEDGIE
RxD Input Active Edge Interrupt Enable (for RXEDGIF)
0 Hardware interrupts from RXEDGIF disabled (use polling).
1 Hardware interrupt requested when RXEDGIF flag is 1.
4:0
SBR[12:8]
Baud Rate Modulo Divisor — The 13 bits in SBR[12:0] are referred to collectively as BR, and they set the
modulo divide rate for the SCI baud rate generator. When BR = 0, the SCI baud rate generator is disabled to
reduce supply current. When BR = 1 to 8191, the SCI baud rate = BUSCLK/(16×BR). See also BR bits in
Table 14-3.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 14 Serial Communications Interface (S08SCIV4)
7
6
5
4
3
2
1
0
SBR7
SBR6
SBR5
SBR4
SBR3
SBR2
SBR1
SBR0
0
0
0
0
0
1
0
0
R
W
Reset
Figure 14-5. SCI Baud Rate Register (SCIxBDL)
Table 14-3. SCIxBDL Field Descriptions
Field
7:0
SBR[7:0]
14.2.2
Description
Baud Rate Modulo Divisor — These 13 bits in SBR[12:0] are referred to collectively as BR, and they set the
modulo divide rate for the SCI baud rate generator. When BR = 0, the SCI baud rate generator is disabled to
reduce supply current. When BR = 1 to 8191, the SCI baud rate = BUSCLK/(16×BR). See also BR bits in
Table 14-2.
SCI Control Register 1 (SCIxC1)
This read/write register is used to control various optional features of the SCI system.
7
6
5
4
3
2
1
0
LOOPS
SCISWAI
RSRC
M
WAKE
ILT
PE
PT
0
0
0
0
0
0
0
0
R
W
Reset
Figure 14-6. SCI Control Register 1 (SCIxC1)
Table 14-4. SCIxC1 Field Descriptions
Field
7
LOOPS
6
SCISWAI
5
RSRC
4
M
Description
Loop Mode Select — Selects between loop back modes and normal 2-pin full-duplex modes. When
LOOPS = 1, the transmitter output is internally connected to the receiver input.
0 Normal operation — RxD and TxD use separate pins.
1 Loop mode or single-wire mode where transmitter outputs are internally connected to receiver input. (See
RSRC bit.) RxD pin is not used by SCI.
SCI Stops in Wait Mode
0 SCI clocks continue to run in wait mode so the SCI can be the source of an interrupt that wakes up the CPU.
1 SCI clocks freeze while CPU is in wait mode.
Receiver Source Select — This bit has no meaning or effect unless the LOOPS bit is set to 1. When
LOOPS = 1, the receiver input is internally connected to the TxD pin and RSRC determines whether this
connection is also connected to the transmitter output.
0 Provided LOOPS = 1, RSRC = 0 selects internal loop back mode and the SCI does not use the RxD pins.
1 Single-wire SCI mode where the TxD pin is connected to the transmitter output and receiver input.
9-Bit or 8-Bit Mode Select
0 Normal — start + 8 data bits (LSB first) + stop.
1 Receiver and transmitter use 9-bit data characters
start + 8 data bits (LSB first) + 9th data bit + stop.
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 14 Serial Communications Interface (S08SCIV4)
Table 14-4. SCIxC1 Field Descriptions (continued)
Field
3
WAKE
Description
Receiver Wakeup Method Select — Refer to Section 14.3.3.2, “Receiver Wakeup Operation” for more
information.
0 Idle-line wakeup.
1 Address-mark wakeup.
2
ILT
Idle Line Type Select — Setting this bit to 1 ensures that the stop bit and logic 1 bits at the end of a character
do not count toward the 10 or 11 bit times of logic high level needed by the idle line detection logic. Refer to
Section 14.3.3.2.1, “Idle-Line Wakeup” for more information.
0 Idle character bit count starts after start bit.
1 Idle character bit count starts after stop bit.
1
PE
Parity Enable — Enables hardware parity generation and checking. When parity is enabled, the most significant
bit (MSB) of the data character (eighth or ninth data bit) is treated as the parity bit.
0 No hardware parity generation or checking.
1 Parity enabled.
0
PT
Parity Type — Provided parity is enabled (PE = 1), this bit selects even or odd parity. Odd parity means the total
number of 1s in the data character, including the parity bit, is odd. Even parity means the total number of 1s in
the data character, including the parity bit, is even.
0 Even parity.
1 Odd parity.
14.2.3
SCI Control Register 2 (SCIxC2)
This register can be read or written at any time.
7
6
5
4
3
2
1
0
TIE
TCIE
RIE
ILIE
TE
RE
RWU
SBK
0
0
0
0
0
0
0
0
R
W
Reset
Figure 14-7. SCI Control Register 2 (SCIxC2)
Table 14-5. SCIxC2 Field Descriptions
Field
7
TIE
6
TCIE
Description
Transmit Interrupt Enable (for TDRE)
0 Hardware interrupts from TDRE disabled (use polling).
1 Hardware interrupt requested when TDRE flag is 1.
Transmission Complete Interrupt Enable (for TC)
0 Hardware interrupts from TC disabled (use polling).
1 Hardware interrupt requested when TC flag is 1.
5
RIE
Receiver Interrupt Enable (for RDRF)
0 Hardware interrupts from RDRF disabled (use polling).
1 Hardware interrupt requested when RDRF flag is 1.
4
ILIE
Idle Line Interrupt Enable (for IDLE)
0 Hardware interrupts from IDLE disabled (use polling).
1 Hardware interrupt requested when IDLE flag is 1.
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Chapter 14 Serial Communications Interface (S08SCIV4)
Table 14-5. SCIxC2 Field Descriptions (continued)
Field
Description
3
TE
Transmitter Enable
0 Transmitter off.
1 Transmitter on.
TE must be 1 in order to use the SCI transmitter. When TE = 1, the SCI forces the TxD pin to act as an output
for the SCI system.
When the SCI is configured for single-wire operation (LOOPS = RSRC = 1), TXDIR controls the direction of
traffic on the single SCI communication line (TxD pin).
TE also can be used to queue an idle character by writing TE = 0 then TE = 1 while a transmission is in progress.
Refer to Section 14.3.2.1, “Send Break and Queued Idle” for more details.
When TE is written to 0, the transmitter keeps control of the port TxD pin until any data, queued idle, or queued
break character finishes transmitting before allowing the pin to revert to a general-purpose I/O pin.
2
RE
Receiver Enable — When the SCI receiver is off, the RxD pin reverts to being a general-purpose port I/O pin.
If LOOPS = 1 the RxD pin reverts to being a general-purpose I/O pin even if RE = 1.
0 Receiver off.
1 Receiver on.
1
RWU
Receiver Wakeup Control — This bit can be written to 1 to place the SCI receiver in a standby state where it
waits for automatic hardware detection of a selected wakeup condition. The wakeup condition is either an idle
line between messages (WAKE = 0, idle-line wakeup), or a logic 1 in the most significant data bit in a character
(WAKE = 1, address-mark wakeup). Application software sets RWU and (normally) a selected hardware
condition automatically clears RWU. Refer to Section 14.3.3.2, “Receiver Wakeup Operation” for more details.
0 Normal SCI receiver operation.
1 SCI receiver in standby waiting for wakeup condition.
0
SBK
Send Break — Writing a 1 and then a 0 to SBK queues a break character in the transmit data stream. Additional
break characters of 10 or 11 (13 or 14 if BRK13 = 1) bit times of logic 0 are queued as long as SBK = 1.
Depending on the timing of the set and clear of SBK relative to the information currently being transmitted, a
second break character may be queued before software clears SBK. Refer to Section 14.3.2.1, “Send Break and
Queued Idle” for more details.
0 Normal transmitter operation.
1 Queue break character(s) to be sent.
14.2.4
SCI Status Register 1 (SCIxS1)
This register has eight read-only status flags. Writes have no effect. Special software sequences (which do
not involve writing to this register) are used to clear these status flags.
R
7
6
5
4
3
2
1
0
TDRE
TC
RDRF
IDLE
OR
NF
FE
PF
1
1
0
0
0
0
0
0
W
Reset
= Unimplemented or Reserved
Figure 14-8. SCI Status Register 1 (SCIxS1)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 14 Serial Communications Interface (S08SCIV4)
Table 14-6. SCIxS1 Field Descriptions
Field
Description
7
TDRE
Transmit Data Register Empty Flag — TDRE is set out of reset and when a transmit data value transfers from
the transmit data buffer to the transmit shifter, leaving room for a new character in the buffer. To clear TDRE, read
SCIxS1 with TDRE = 1 and then write to the SCI data register (SCIxD).
0 Transmit data register (buffer) full.
1 Transmit data register (buffer) empty.
6
TC
Transmission Complete Flag — TC is set out of reset and when TDRE = 1 and no data, preamble, or break
character is being transmitted.
0 Transmitter active (sending data, a preamble, or a break).
1 Transmitter idle (transmission activity complete).
TC is cleared automatically by reading SCIxS1 with TC = 1 and then doing one of the following three things:
• Write to the SCI data register (SCIxD) to transmit new data
• Queue a preamble by changing TE from 0 to 1
• Queue a break character by writing 1 to SBK in SCIxC2
5
RDRF
Receive Data Register Full Flag — RDRF becomes set when a character transfers from the receive shifter into
the receive data register (SCIxD). To clear RDRF, read SCIxS1 with RDRF = 1 and then read the SCI data
register (SCIxD).
0 Receive data register empty.
1 Receive data register full.
4
IDLE
Idle Line Flag — IDLE is set when the SCI receive line becomes idle for a full character time after a period of
activity. When ILT = 0, the receiver starts counting idle bit times after the start bit. So if the receive character is
all 1s, these bit times and the stop bit time count toward the full character time of logic high (10 or 11 bit times
depending on the M control bit) needed for the receiver to detect an idle line. When ILT = 1, the receiver doesn’t
start counting idle bit times until after the stop bit. So the stop bit and any logic high bit times at the end of the
previous character do not count toward the full character time of logic high needed for the receiver to detect an
idle line.
To clear IDLE, read SCIxS1 with IDLE = 1 and then read the SCI data register (SCIxD). After IDLE has been
cleared, it cannot become set again until after a new character has been received and RDRF has been set. IDLE
will get set only once even if the receive line remains idle for an extended period.
0 No idle line detected.
1 Idle line was detected.
3
OR
Receiver Overrun Flag — OR is set when a new serial character is ready to be transferred to the receive data
register (buffer), but the previously received character has not been read from SCIxD yet. In this case, the new
character (and all associated error information) is lost because there is no room to move it into SCIxD. To clear
OR, read SCIxS1 with OR = 1 and then read the SCI data register (SCIxD).
0 No overrun.
1 Receive overrun (new SCI data lost).
2
NF
Noise Flag — The advanced sampling technique used in the receiver takes seven samples during the start bit
and three samples in each data bit and the stop bit. If any of these samples disagrees with the rest of the samples
within any bit time in the frame, the flag NF will be set at the same time as the flag RDRF gets set for the
character. To clear NF, read SCIxS1 and then read the SCI data register (SCIxD).
0 No noise detected.
1 Noise detected in the received character in SCIxD.
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Chapter 14 Serial Communications Interface (S08SCIV4)
Table 14-6. SCIxS1 Field Descriptions (continued)
Field
Description
1
FE
Framing Error Flag — FE is set at the same time as RDRF when the receiver detects a logic 0 where the stop
bit was expected. This suggests the receiver was not properly aligned to a character frame. To clear FE, read
SCIxS1 with FE = 1 and then read the SCI data register (SCIxD).
0 No framing error detected. This does not guarantee the framing is correct.
1 Framing error.
0
PF
Parity Error Flag — PF is set at the same time as RDRF when parity is enabled (PE = 1) and the parity bit in
the received character does not agree with the expected parity value. To clear PF, read SCIxS1 and then read
the SCI data register (SCIxD).
0 No parity error.
1 Parity error.
14.2.5
SCI Status Register 2 (SCIxS2)
This register has one read-only status flag.
7
6
LBKDIF
RXEDGIF
0
0
R
5
4
3
2
1
RXINV
RWUID
BRK13
LBKDE
0
0
0
0
0
0
RAF
W
Reset
0
0
= Unimplemented or Reserved
Figure 14-9. SCI Status Register 2 (SCIxS2)
Table 14-7. SCIxS2 Field Descriptions
Field
Description
7
LBKDIF
LIN Break Detect Interrupt Flag — LBKDIF is set when the LIN break detect circuitry is enabled and a LIN break
character is detected. LBKDIF is cleared by writing a “1” to it.
0 No LIN break character has been detected.
1 LIN break character has been detected.
6
RXEDGIF
RxD Pin Active Edge Interrupt Flag — RXEDGIF is set when an active edge (falling if RXINV = 0, rising if
RXINV=1) on the RxD pin occurs. RXEDGIF is cleared by writing a “1” to it.
0 No active edge on the receive pin has occurred.
1 An active edge on the receive pin has occurred.
4
RXINV1
Receive Data Inversion — Setting this bit reverses the polarity of the received data input.
0 Receive data not inverted
1 Receive data inverted
3
RWUID
Receive Wake Up Idle Detect— RWUID controls whether the idle character that wakes up the receiver sets the
IDLE bit.
0 During receive standby state (RWU = 1), the IDLE bit does not get set upon detection of an idle character.
1 During receive standby state (RWU = 1), the IDLE bit gets set upon detection of an idle character.
2
BRK13
Break Character Generation Length — BRK13 is used to select a longer transmitted break character length.
Detection of a framing error is not affected by the state of this bit.
0 Break character is transmitted with length of 10 bit times (11 if M = 1)
1 Break character is transmitted with length of 13 bit times (14 if M = 1)
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 14 Serial Communications Interface (S08SCIV4)
Table 14-7. SCIxS2 Field Descriptions (continued)
Field
1
LBKDE
0
RAF
1
Description
LIN Break Detection Enable— LBKDE is used to select a longer break character detection length. While
LBKDE is set, framing error (FE) and receive data register full (RDRF) flags are prevented from setting.
0 Break character is detected at length of 10 bit times (11 if M = 1).
1 Break character is detected at length of 11 bit times (12 if M = 1).
Receiver Active Flag — RAF is set when the SCI receiver detects the beginning of a valid start bit, and RAF is
cleared automatically when the receiver detects an idle line. This status flag can be used to check whether an
SCI character is being received before instructing the MCU to go to stop mode.
0 SCI receiver idle waiting for a start bit.
1 SCI receiver active (RxD input not idle).
Setting RXINV inverts the RxD input for all cases: data bits, start and stop bits, break, and idle.
When using an internal oscillator in a LIN system, it is necessary to raise the break detection threshold by
one bit time. Under the worst case timing conditions allowed in LIN, it is possible that a 0x00 data
character can appear to be 10.26 bit times long at a slave which is running 14% faster than the master. This
would trigger normal break detection circuitry which is designed to detect a 10 bit break symbol. When
the LBKDE bit is set, framing errors are inhibited and the break detection threshold changes from 10 bits
to 11 bits, preventing false detection of a 0x00 data character as a LIN break symbol.
14.2.6
SCI Control Register 3 (SCIxC3)
7
R
6
5
4
3
2
1
0
T8
TXDIR
TXINV
ORIE
NEIE
FEIE
PEIE
0
0
0
0
0
0
0
R8
W
Reset
0
= Unimplemented or Reserved
Figure 14-10. SCI Control Register 3 (SCIxC3)
Table 14-8. SCIxC3 Field Descriptions
Field
Description
7
R8
Ninth Data Bit for Receiver — When the SCI is configured for 9-bit data (M = 1), R8 can be thought of as a
ninth receive data bit to the left of the MSB of the buffered data in the SCIxD register. When reading 9-bit data,
read R8 before reading SCIxD because reading SCIxD completes automatic flag clearing sequences which
could allow R8 and SCIxD to be overwritten with new data.
6
T8
Ninth Data Bit for Transmitter — When the SCI is configured for 9-bit data (M = 1), T8 may be thought of as a
ninth transmit data bit to the left of the MSB of the data in the SCIxD register. When writing 9-bit data, the entire
9-bit value is transferred to the SCI shift register after SCIxD is written so T8 should be written (if it needs to
change from its previous value) before SCIxD is written. If T8 does not need to change in the new value (such
as when it is used to generate mark or space parity), it need not be written each time SCIxD is written.
5
TXDIR
TxD Pin Direction in Single-Wire Mode — When the SCI is configured for single-wire half-duplex operation
(LOOPS = RSRC = 1), this bit determines the direction of data at the TxD pin.
0 TxD pin is an input in single-wire mode.
1 TxD pin is an output in single-wire mode.
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Chapter 14 Serial Communications Interface (S08SCIV4)
Table 14-8. SCIxC3 Field Descriptions (continued)
Field
4
TXINV1
1
Description
Transmit Data Inversion — Setting this bit reverses the polarity of the transmitted data output.
0 Transmit data not inverted
1 Transmit data inverted
3
ORIE
Overrun Interrupt Enable — This bit enables the overrun flag (OR) to generate hardware interrupt requests.
0 OR interrupts disabled (use polling).
1 Hardware interrupt requested when OR = 1.
2
NEIE
Noise Error Interrupt Enable — This bit enables the noise flag (NF) to generate hardware interrupt requests.
0 NF interrupts disabled (use polling).
1 Hardware interrupt requested when NF = 1.
1
FEIE
Framing Error Interrupt Enable — This bit enables the framing error flag (FE) to generate hardware interrupt
requests.
0 FE interrupts disabled (use polling).
1 Hardware interrupt requested when FE = 1.
0
PEIE
Parity Error Interrupt Enable — This bit enables the parity error flag (PF) to generate hardware interrupt
requests.
0 PF interrupts disabled (use polling).
1 Hardware interrupt requested when PF = 1.
Setting TXINV inverts the TxD output for all cases: data bits, start and stop bits, break, and idle.
14.2.7
SCI Data Register (SCIxD)
This register is actually two separate registers. Reads return the contents of the read-only receive data
buffer and writes go to the write-only transmit data buffer. Reads and writes of this register are also
involved in the automatic flag clearing mechanisms for the SCI status flags.
7
6
5
4
3
2
1
0
R
R7
R6
R5
R4
R3
R2
R1
R0
W
T7
T6
T5
T4
T3
T2
T1
T0
0
0
0
0
0
0
0
0
Reset
Figure 14-11. SCI Data Register (SCIxD)
14.3
Functional Description
The SCI allows full-duplex, asynchronous, NRZ serial communication among the MCU and remote
devices, including other MCUs. The SCI comprises a baud rate generator, transmitter, and receiver block.
The transmitter and receiver operate independently, although they use the same baud rate generator. During
normal operation, the MCU monitors the status of the SCI, writes the data to be transmitted, and processes
received data. The following describes each of the blocks of the SCI.
14.3.1
Baud Rate Generation
As shown in Figure 14-12, the clock source for the SCI baud rate generator is the bus-rate clock.
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Chapter 14 Serial Communications Interface (S08SCIV4)
MODULO DIVIDE BY
(1 THROUGH 8191)
BUSCLK
SBR12:SBR0
BAUD RATE GENERATOR
OFF IF [SBR12:SBR0] = 0
DIVIDE BY
16
Tx BAUD RATE
Rx SAMPLING CLOCK
(16 × BAUD RATE)
BAUD RATE =
BUSCLK
[SBR12:SBR0] × 16
Figure 14-12. SCI Baud Rate Generation
SCI communications require the transmitter and receiver (which typically derive baud rates from
independent clock sources) to use the same baud rate. Allowed tolerance on this baud frequency depends
on the details of how the receiver synchronizes to the leading edge of the start bit and how bit sampling is
performed.
The MCU resynchronizes to bit boundaries on every high-to-low transition, but in the worst case, there are
no such transitions in the full 10- or 11-bit time character frame so any mismatch in baud rate is
accumulated for the whole character time. For a Freescale Semiconductor SCI system whose bus
frequency is driven by a crystal, the allowed baud rate mismatch is about 4.5percent for 8-bit data format
and about 4 percent for 9-bit data format. Although baud rate modulo divider settings do not always
produce baud rates that exactly match standard rates, it is normally possible to get within a few percent,
which is acceptable for reliable communications.
14.3.2
Transmitter Functional Description
This section describes the overall block diagram for the SCI transmitter, as well as specialized functions
for sending break and idle characters. The transmitter block diagram is shown in Figure 14-2.
The transmitter output (TxD) idle state defaults to logic high (TXINV = 0 following reset). The transmitter
output is inverted by setting TXINV = 1. The transmitter is enabled by setting the TE bit in SCIxC2. This
queues a preamble character that is one full character frame of the idle state. The transmitter then remains
idle until data is available in the transmit data buffer. Programs store data into the transmit data buffer by
writing to the SCI data register (SCIxD).
The central element of the SCI transmitter is the transmit shift register that is either 10 or 11 bits long
depending on the setting in the M control bit. For the remainder of this section, we will assume M = 0,
selecting the normal 8-bit data mode. In 8-bit data mode, the shift register holds a start bit, eight data bits,
and a stop bit. When the transmit shift register is available for a new SCI character, the value waiting in
the transmit data register is transferred to the shift register (synchronized with the baud rate clock) and the
transmit data register empty (TDRE) status flag is set to indicate another character may be written to the
transmit data buffer at SCIxD.
If no new character is waiting in the transmit data buffer after a stop bit is shifted out the TxD pin, the
transmitter sets the transmit complete flag and enters an idle mode, with TxD high, waiting for more
characters to transmit.
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Chapter 14 Serial Communications Interface (S08SCIV4)
Writing 0 to TE does not immediately release the pin to be a general-purpose I/O pin. Any transmit activity
that is in progress must first be completed. This includes data characters in progress, queued idle
characters, and queued break characters.
14.3.2.1
Send Break and Queued Idle
The SBK control bit in SCIxC2 is used to send break characters which were originally used to gain the
attention of old teletype receivers. Break characters are a full character time of logic 0 (10 bit times
including the start and stop bits). A longer break of 13 bit times can be enabled by setting BRK13 = 1.
Normally, a program would wait for TDRE to become set to indicate the last character of a message has
moved to the transmit shifter, then write 1 and then write 0 to the SBK bit. This action queues a break
character to be sent as soon as the shifter is available. If SBK is still 1 when the queued break moves into
the shifter (synchronized to the baud rate clock), an additional break character is queued. If the receiving
device is another Freescale Semiconductor SCI, the break characters will be received as 0s in all eight data
bits and a framing error (FE = 1) occurs.
When idle-line wakeup is used, a full character time of idle (logic 1) is needed between messages to wake
up any sleeping receivers. Normally, a program would wait for TDRE to become set to indicate the last
character of a message has moved to the transmit shifter, then write 0 and then write 1 to the TE bit. This
action queues an idle character to be sent as soon as the shifter is available. As long as the character in the
shifter does not finish while TE = 0, the SCI transmitter never actually releases control of the TxD pin. If
there is a possibility of the shifter finishing while TE = 0, set the general-purpose I/O controls so the pin
that is shared with TxD is an output driving a logic 1. This ensures that the TxD line will look like a normal
idle line even if the SCI loses control of the port pin between writing 0 and then 1 to TE.
The length of the break character is affected by the BRK13 and M bits as shown below.
Table 14-9. Break Character Length
14.3.3
BRK13
M
Break Character Length
0
0
10 bit times
0
1
11 bit times
1
0
13 bit times
1
1
14 bit times
Receiver Functional Description
In this section, the receiver block diagram (Figure 14-3) is used as a guide for the overall receiver
functional description. Next, the data sampling technique used to reconstruct receiver data is described in
more detail. Finally, two variations of the receiver wakeup function are explained.
The receiver input is inverted by setting RXINV = 1. The receiver is enabled by setting the RE bit in
SCIxC2. Character frames consist of a start bit of logic 0, eight (or nine) data bits (LSB first), and a stop
bit of logic 1. For information about 9-bit data mode, refer to Section 14.3.5.1, “8- and 9-Bit Data Modes.”
For the remainder of this discussion, we assume the SCI is configured for normal 8-bit data mode.
After receiving the stop bit into the receive shifter, and provided the receive data register is not already full,
the data character is transferred to the receive data register and the receive data register full (RDRF) status
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flag is set. If RDRF was already set indicating the receive data register (buffer) was already full, the overrun
(OR) status flag is set and the new data is lost. Because the SCI receiver is double-buffered, the program
has one full character time after RDRF is set before the data in the receive data buffer must be read to avoid
a receiver overrun.
When a program detects that the receive data register is full (RDRF = 1), it gets the data from the receive
data register by reading SCIxD. The RDRF flag is cleared automatically by a 2-step sequence which is
normally satisfied in the course of the user’s program that handles receive data. Refer to Section 14.3.4,
“Interrupts and Status Flags” for more details about flag clearing.
14.3.3.1
Data Sampling Technique
The SCI receiver uses a 16× baud rate clock for sampling. The receiver starts by taking logic level samples
at 16 times the baud rate to search for a falling edge on the RxD serial data input pin. A falling edge is
defined as a logic 0 sample after three consecutive logic 1 samples. The 16× baud rate clock is used to
divide the bit time into 16 segments labeled RT1 through RT16. When a falling edge is located, three more
samples are taken at RT3, RT5, and RT7 to make sure this was a real start bit and not merely noise. If at
least two of these three samples are 0, the receiver assumes it is synchronized to a receive character.
The receiver then samples each bit time, including the start and stop bits, at RT8, RT9, and RT10 to
determine the logic level for that bit. The logic level is interpreted to be that of the majority of the samples
taken during the bit time. In the case of the start bit, the bit is assumed to be 0 if at least two of the samples
at RT3, RT5, and RT7 are 0 even if one or all of the samples taken at RT8, RT9, and RT10 are 1s. If any
sample in any bit time (including the start and stop bits) in a character frame fails to agree with the logic
level for that bit, the noise flag (NF) will be set when the received character is transferred to the receive
data buffer.
The falling edge detection logic continuously looks for falling edges, and if an edge is detected, the sample
clock is resynchronized to bit times. This improves the reliability of the receiver in the presence of noise
or mismatched baud rates. It does not improve worst case analysis because some characters do not have
any extra falling edges anywhere in the character frame.
In the case of a framing error, provided the received character was not a break character, the sampling logic
that searches for a falling edge is filled with three logic 1 samples so that a new start bit can be detected
almost immediately.
In the case of a framing error, the receiver is inhibited from receiving any new characters until the framing
error flag is cleared. The receive shift register continues to function, but a complete character cannot
transfer to the receive data buffer if FE is still set.
14.3.3.2
Receiver Wakeup Operation
Receiver wakeup is a hardware mechanism that allows an SCI receiver to ignore the characters in a
message that is intended for a different SCI receiver. In such a system, all receivers evaluate the first
character(s) of each message, and as soon as they determine the message is intended for a different
receiver, they write logic 1 to the receiver wake up (RWU) control bit in SCIxC2. When RWU bit is set,
the status flags associated with the receiver (with the exception of the idle bit, IDLE, when RWUID bit is
set) are inhibited from setting, thus eliminating the software overhead for handling the unimportant
MC9S08DZ60 Series Data Sheet, Rev. 4
304
Freescale Semiconductor
Chapter 14 Serial Communications Interface (S08SCIV4)
message characters. At the end of a message, or at the beginning of the next message, all receivers
automatically force RWU to 0 so all receivers wake up in time to look at the first character(s) of the next
message.
14.3.3.2.1
Idle-Line Wakeup
When WAKE = 0, the receiver is configured for idle-line wakeup. In this mode, RWU is cleared
automatically when the receiver detects a full character time of the idle-line level. The M control bit selects
8-bit or 9-bit data mode that determines how many bit times of idle are needed to constitute a full character
time (10 or 11 bit times because of the start and stop bits).
When RWU is one and RWUID is zero, the idle condition that wakes up the receiver does not set the IDLE
flag. The receiver wakes up and waits for the first data character of the next message which will set the
RDRF flag and generate an interrupt if enabled. When RWUID is one, any idle condition sets the IDLE
flag and generates an interrupt if enabled, regardless of whether RWU is zero or one.
The idle-line type (ILT) control bit selects one of two ways to detect an idle line. When ILT = 0, the idle
bit counter starts after the start bit so the stop bit and any logic 1s at the end of a character count toward
the full character time of idle. When ILT = 1, the idle bit counter does not start until after a stop bit time,
so the idle detection is not affected by the data in the last character of the previous message.
14.3.3.2.2
Address-Mark Wakeup
When WAKE = 1, the receiver is configured for address-mark wakeup. In this mode, RWU is cleared
automatically when the receiver detects a logic 1 in the most significant bit of a received character (eighth
bit in M = 0 mode and ninth bit in M = 1 mode).
Address-mark wakeup allows messages to contain idle characters but requires that the MSB be reserved
for use in address frames. The logic 1 MSB of an address frame clears the RWU bit before the stop bit is
received and sets the RDRF flag. In this case the character with the MSB set is received even though the
receiver was sleeping during most of this character time.
14.3.4
Interrupts and Status Flags
The SCI system has three separate interrupt vectors to reduce the amount of software needed to isolate the
cause of the interrupt. One interrupt vector is associated with the transmitter for TDRE and TC events.
Another interrupt vector is associated with the receiver for RDRF, IDLE, RXEDGIF and LBKDIF events,
and a third vector is used for OR, NF, FE, and PF error conditions. Each of these ten interrupt sources can
be separately masked by local interrupt enable masks. The flags can still be polled by software when the
local masks are cleared to disable generation of hardware interrupt requests.
The SCI transmitter has two status flags that optionally can generate hardware interrupt requests. Transmit
data register empty (TDRE) indicates when there is room in the transmit data buffer to write another
transmit character to SCIxD. If the transmit interrupt enable (TIE) bit is set, a hardware interrupt will be
requested whenever TDRE = 1. Transmit complete (TC) indicates that the transmitter is finished
transmitting all data, preamble, and break characters and is idle with TxD at the inactive level. This flag is
often used in systems with modems to determine when it is safe to turn off the modem. If the transmit
complete interrupt enable (TCIE) bit is set, a hardware interrupt will be requested whenever TC = 1.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
305
Chapter 14 Serial Communications Interface (S08SCIV4)
Instead of hardware interrupts, software polling may be used to monitor the TDRE and TC status flags if
the corresponding TIE or TCIE local interrupt masks are 0s.
When a program detects that the receive data register is full (RDRF = 1), it gets the data from the receive
data register by reading SCIxD. The RDRF flag is cleared by reading SCIxS1 while RDRF = 1 and then
reading SCIxD.
When polling is used, this sequence is naturally satisfied in the normal course of the user program. If
hardware interrupts are used, SCIxS1 must be read in the interrupt service routine (ISR). Normally, this is
done in the ISR anyway to check for receive errors, so the sequence is automatically satisfied.
The IDLE status flag includes logic that prevents it from getting set repeatedly when the RxD line remains
idle for an extended period of time. IDLE is cleared by reading SCIxS1 while IDLE = 1 and then reading
SCIxD. After IDLE has been cleared, it cannot become set again until the receiver has received at least one
new character and has set RDRF.
If the associated error was detected in the received character that caused RDRF to be set, the error flags —
noise flag (NF), framing error (FE), and parity error flag (PF) — get set at the same time as RDRF. These
flags are not set in overrun cases.
If RDRF was already set when a new character is ready to be transferred from the receive shifter to the
receive data buffer, the overrun (OR) flag gets set instead the data along with any associated NF, FE, or PF
condition is lost.
At any time, an active edge on the RxD serial data input pin causes the RXEDGIF flag to set. The
RXEDGIF flag is cleared by writing a “1” to it. This function does depend on the receiver being enabled
(RE = 1).
14.3.5
Additional SCI Functions
The following sections describe additional SCI functions.
14.3.5.1
8- and 9-Bit Data Modes
The SCI system (transmitter and receiver) can be configured to operate in 9-bit data mode by setting the
M control bit in SCIxC1. In 9-bit mode, there is a ninth data bit to the left of the MSB of the SCI data
register. For the transmit data buffer, this bit is stored in T8 in SCIxC3. For the receiver, the ninth bit is
held in R8 in SCIxC3.
For coherent writes to the transmit data buffer, write to the T8 bit before writing to SCIxD.
If the bit value to be transmitted as the ninth bit of a new character is the same as for the previous character,
it is not necessary to write to T8 again. When data is transferred from the transmit data buffer to the
transmit shifter, the value in T8 is copied at the same time data is transferred from SCIxD to the shifter.
9-bit data mode typically is used in conjunction with parity to allow eight bits of data plus the parity in the
ninth bit. Or it is used with address-mark wakeup so the ninth data bit can serve as the wakeup bit. In
custom protocols, the ninth bit can also serve as a software-controlled marker.
MC9S08DZ60 Series Data Sheet, Rev. 4
306
Freescale Semiconductor
Chapter 14 Serial Communications Interface (S08SCIV4)
14.3.5.2
Stop Mode Operation
During all stop modes, clocks to the SCI module are halted.
In stop1 and stop2 modes, all SCI register data is lost and must be re-initialized upon recovery from these
two stop modes. No SCI module registers are affected in stop3 mode.
The receive input active edge detect circuit is still active in stop3 mode, but not in stop2.. An active edge
on the receive input brings the CPU out of stop3 mode if the interrupt is not masked (RXEDGIE = 1).
Note, because the clocks are halted, the SCI module will resume operation upon exit from stop (only in
stop3 mode). Software should ensure stop mode is not entered while there is a character being transmitted
out of or received into the SCI module.
14.3.5.3
Loop Mode
When LOOPS = 1, the RSRC bit in the same register chooses between loop mode (RSRC = 0) or
single-wire mode (RSRC = 1). Loop mode is sometimes used to check software, independent of
connections in the external system, to help isolate system problems. In this mode, the transmitter output is
internally connected to the receiver input and the RxD pin is not used by the SCI, so it reverts to a
general-purpose port I/O pin.
14.3.5.4
Single-Wire Operation
When LOOPS = 1, the RSRC bit in the same register chooses between loop mode (RSRC = 0) or
single-wire mode (RSRC = 1). Single-wire mode is used to implement a half-duplex serial connection.
The receiver is internally connected to the transmitter output and to the TxD pin. The RxD pin is not used
and reverts to a general-purpose port I/O pin.
In single-wire mode, the TXDIR bit in SCIxC3 controls the direction of serial data on the TxD pin. When
TXDIR = 0, the TxD pin is an input to the SCI receiver and the transmitter is temporarily disconnected
from the TxD pin so an external device can send serial data to the receiver. When TXDIR = 1, the TxD pin
is an output driven by the transmitter. In single-wire mode, the internal loop back connection from the
transmitter to the receiver causes the receiver to receive characters that are sent out by the transmitter.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
307
Chapter 14 Serial Communications Interface (S08SCIV4)
MC9S08DZ60 Series Data Sheet, Rev. 4
308
Freescale Semiconductor
Chapter 15
Real-Time Counter (S08RTCV1)
15.1
Introduction
The RTC module consists of one 8-bit counter, one 8-bit comparator, several binary-based and
decimal-based prescaler dividers, three clock sources, and one programmable periodic interrupt. This
module can be used for time-of-day, calendar or any task scheduling functions. It can also serve as a cyclic
wake up from low power modes without the need of external components.
All devices in the MC9S08DZ60 Series feature the RTC.
15.1.1
RTC Clock Signal Names
References to ERCLK and IRCLK in this chapter correspond to signals MCGERCLK and MCGIRCLK,
respectively.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
309
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 15 Real-Time Counter (S08RTCV1)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12-BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 15-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
310
Freescale Semiconductor
Chapter 15 Real-Time Counter (S08RTCV1)
15.1.2
Features
Features of the RTC module include:
• 8-bit up-counter
— 8-bit modulo match limit
— Software controllable periodic interrupt on match
• Three software selectable clock sources for input to prescaler with selectable binary-based and
decimal-based divider values
— 1-kHz internal low-power oscillator (LPO)
— External clock (ERCLK)
— 32-kHz internal clock (IRCLK)
15.1.3
Modes of Operation
This section defines the operation in stop, wait and background debug modes.
15.1.3.1
Wait Mode
The RTC continues to run in wait mode if enabled before executing the appropriate instruction. Therefore,
the RTC can bring the MCU out of wait mode if the real-time interrupt is enabled. For lowest possible
current consumption, the RTC should be stopped by software if not needed as an interrupt source during
wait mode.
15.1.3.2
Stop Modes
The RTC continues to run in stop2 or stop3 mode if the RTC is enabled before executing the STOP
instruction. Therefore, the RTC can bring the MCU out of stop modes with no external components, if the
real-time interrupt is enabled.
The LPO clock can be used in stop2 and stop3 modes. ERCLK and IRCLK clocks are only available in
stop3 mode.
Power consumption is lower when all clock sources are disabled, but in that case, the real-time interrupt
cannot wake up the MCU from stop modes.
15.1.3.3
Active Background Mode
The RTC suspends all counting during active background mode until the microcontroller returns to normal
user operating mode. Counting resumes from the suspended value as long as the RTCMOD register is not
written and the RTCPS and RTCLKS bits are not altered.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
311
Chapter 15 Real-Time Counter (S08RTCV1)
15.1.4
Block Diagram
The block diagram for the RTC module is shown in Figure 15-2.
LPO
Clock
Source
Select
ERCLK
IRCLK
8-Bit Modulo
(RTCMOD)
RTCLKS
VDD
RTCLKS[0]
RTCPS
Prescaler
Divide-By
Q
D
Background
Mode
E
8-Bit Comparator
RTC
Clock
RTC
Interrupt
Request
RTIF
R
Write 1 to
RTIF
8-Bit Counter
(RTCCNT)
RTIE
Figure 15-2. Real-Time Counter (RTC) Block Diagram
15.2
External Signal Description
The RTC does not include any off-chip signals.
15.3
Register Definition
The RTC includes a status and control register, an 8-bit counter register, and an 8-bit modulo register.
Refer to the direct-page register summary in the memory section of this document for the absolute address
assignments for all RTC registers.This section refers to registers and control bits only by their names and
relative address offsets.
Table 15-1 is a summary of RTC registers.
Table 15-1. RTC Register Summary
Name
7
6
5
4
3
2
1
0
R
RTCSC
RTIF
RTCLKS
RTIE
RTCPS
W
R
RTCCNT
RTCCNT
W
R
RTCMOD
RTCMOD
W
MC9S08DZ60 Series Data Sheet, Rev. 4
312
Freescale Semiconductor
Chapter 15 Real-Time Counter (S08RTCV1)
15.3.1
RTC Status and Control Register (RTCSC)
RTCSC contains the real-time interrupt status flag (RTIF), the clock select bits (RTCLKS), the real-time
interrupt enable bit (RTIE), and the prescaler select bits (RTCPS).
7
6
5
4
3
2
1
0
0
0
R
RTIF
RTCLKS
RTIE
RTCPS
W
Reset:
0
0
0
0
0
0
Figure 15-3. RTC Status and Control Register (RTCSC)
Table 15-2. RTCSC Field Descriptions
Field
Description
7
RTIF
Real-Time Interrupt Flag This status bit indicates the RTC counter register reached the value in the RTC modulo
register. Writing a logic 0 has no effect. Writing a logic 1 clears the bit and the real-time interrupt request. Reset
clears RTIF.
0 RTC counter has not reached the value in the RTC modulo register.
1 RTC counter has reached the value in the RTC modulo register.
6–5
RTCLKS
Real-Time Clock Source Select. These two read/write bits select the clock source input to the RTC prescaler.
Changing the clock source clears the prescaler and RTCCNT counters. When selecting a clock source, ensure
that the clock source is properly enabled (if applicable) to ensure correct operation of the RTC. Reset clears
RTCLKS.
00 Real-time clock source is the 1-kHz low power oscillator (LPO)
01 Real-time clock source is the external clock (ERCLK)
1x Real-time clock source is the internal clock (IRCLK)
4
RTIE
Real-Time Interrupt Enable. This read/write bit enables real-time interrupts. If RTIE is set, then an interrupt is
generated when RTIF is set. Reset clears RTIE.
0 Real-time interrupt requests are disabled. Use software polling.
1 Real-time interrupt requests are enabled.
3–0
RTCPS
Real-Time Clock Prescaler Select. These four read/write bits select binary-based or decimal-based divide-by
values for the clock source. See Table 15-3. Changing the prescaler value clears the prescaler and RTCCNT
counters. Reset clears RTCPS.
Table 15-3. RTC Prescaler Divide-by values
RTCPS
RTCLKS[0]
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
0
Off
23
25
26
27
28
29
210
1
2
22
10
24
102
5x102
103
1
Off
210
211
212
213
214
215
216
103
105
2x105
2x103 5x103
104
2x104 5x104
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
313
Chapter 15 Real-Time Counter (S08RTCV1)
15.3.2
RTC Counter Register (RTCCNT)
RTCCNT is the read-only value of the current RTC count of the 8-bit counter.
7
6
5
4
R
3
2
1
0
0
0
0
0
RTCCNT
W
Reset:
0
0
0
0
Figure 15-4. RTC Counter Register (RTCCNT)
Table 15-4. RTCCNT Field Descriptions
Field
Description
7:0
RTCCNT
RTC Count. These eight read-only bits contain the current value of the 8-bit counter. Writes have no effect to this
register. Reset, writing to RTCMOD, or writing different values to RTCLKS and RTCPS clear the count to 0x00.
15.3.3
RTC Modulo Register (RTCMOD)
7
6
5
4
3
2
1
0
0
0
0
0
R
RTCMOD
W
Reset:
0
0
0
0
Figure 15-5. RTC Modulo Register (RTCMOD)
Table 15-5. RTCMOD Field Descriptions
Field
Description
7:0
RTC Modulo. These eight read/write bits contain the modulo value used to reset the count to 0x00 upon a compare
RTCMOD match and set the RTIF status bit. A value of 0x00 sets the RTIF bit on each rising edge of the prescaler output.
Writing to RTCMOD resets the prescaler and the RTCCNT counters to 0x00. Reset sets the modulo to 0x00.
15.4
Functional Description
The RTC is composed of a main 8-bit up-counter with an 8-bit modulo register, a clock source selector,
and a prescaler block with binary-based and decimal-based selectable values. The module also contains
software selectable interrupt logic.
After any MCU reset, the counter is stopped and reset to 0x00, the modulus register is set to 0x00, and the
prescaler is off. The 1-kHz internal oscillator clock is selected as the default clock source. To start the
prescaler, write any value other than zero to the prescaler select bits (RTCPS).
Three clock sources are software selectable: the low power oscillator clock (LPO), the external clock
(ERCLK), and the internal clock (IRCLK). The RTC clock select bits (RTCLKS) select the desired clock
source. If a different value is written to RTCLKS, the prescaler and RTCCNT counters are reset to 0x00.
MC9S08DZ60 Series Data Sheet, Rev. 4
314
Freescale Semiconductor
Chapter 15 Real-Time Counter (S08RTCV1)
RTCPS and the RTCLKS[0] bit select the desired divide-by value. If a different value is written to RTCPS,
the prescaler and RTCCNT counters are reset to 0x00. Table 15-6 shows different prescaler period values.
Table 15-6. Prescaler Period
RTCPS
1-kHz Internal Clock
(RTCLKS = 00)
1-MHz External Clock 32-kHz Internal Clock 32-kHz Internal Clock
(RTCLKS = 01)
(RTCLKS = 10)
(RTCLKS = 11)
0000
Off
Off
Off
Off
0001
8 ms
1.024 ms
250 μs
32 ms
0010
32 ms
2.048 ms
1 ms
64 ms
0011
64 ms
4.096 ms
2 ms
128 ms
0100
128 ms
8.192 ms
4 ms
256 ms
0101
256 ms
16.4 ms
8 ms
512 ms
0110
512 ms
32.8 ms
16 ms
1.024 s
0111
1.024 s
65.5 ms
32 ms
2.048 s
1000
1 ms
1 ms
31.25 μs
31.25 ms
1001
2 ms
2 ms
62.5 μs
62.5 ms
1010
4 ms
5 ms
125 μs
156.25 ms
1011
10 ms
10 ms
312.5 μs
312.5 ms
1100
16 ms
20 ms
0.5 ms
0.625 s
1101
0.1 s
50 ms
3.125 ms
1.5625 s
1110
0.5 s
0.1 s
15.625 ms
3.125 s
1111
1s
0.2 s
31.25 ms
6.25 s
The RTC modulo register (RTCMOD) allows the compare value to be set to any value from 0x00 to 0xFF.
When the counter is active, the counter increments at the selected rate until the count matches the modulo
value. When these values match, the counter resets to 0x00 and continues counting. The real-time interrupt
flag (RTIF) is set when a match occurs. The flag sets on the transition from the modulo value to 0x00.
Writing to RTCMOD resets the prescaler and the RTCCNT counters to 0x00.
The RTC allows for an interrupt to be generated when RTIF is set. To enable the real-time interrupt, set
the real-time interrupt enable bit (RTIE) in RTCSC. RTIF is cleared by writing a 1 to RTIF.
15.4.1
RTC Operation Example
This section shows an example of the RTC operation as the counter reaches a matching value from the
modulo register.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
315
Chapter 15 Real-Time Counter (S08RTCV1)
Internal 1-kHz
Clock Source
RTC Clock
(RTCPS = 0xA)
RTCCNT
0x52
0x53
0x54
0x55
0x00
0x01
RTIF
RTCMOD
0x55
Figure 15-6. RTC Counter Overflow Example
In the example of Figure 15-6, the selected clock source is the 1-kHz internal oscillator clock source. The
prescaler (RTCPS) is set to 0xA or divide-by-4. The modulo value in the RTCMOD register is set to 0x55.
When the counter, RTCCNT, reaches the modulo value of 0x55, the counter overflows to 0x00 and
continues counting. The real-time interrupt flag, RTIF, sets when the counter value changes from 0x55 to
0x00. A real-time interrupt is generated when RTIF is set, if RTIE is set.
15.5
Initialization/Application Information
This section provides example code to give some basic direction to a user on how to initialize and configure
the RTC module. The example software is implemented in C language.
The example below shows how to implement time of day with the RTC using the 1-kHz clock source to
achieve the lowest possible power consumption. Because the 1-kHz clock source is not as accurate as a
crystal, software can be added for any adjustments. For accuracy without adjustments at the expense of
additional power consumption, the external clock (ERCLK) or the internal clock (IRCLK) can be selected
with appropriate prescaler and modulo values.
/* Initialize the elapsed time counters */
Seconds = 0;
Minutes = 0;
Hours = 0;
Days=0;
/* Configure RTC to interrupt every 1 second from 1-kHz clock source */
RTCMOD.byte = 0x00;
RTCSC.byte = 0x1F;
/**********************************************************************
Function Name : RTC_ISR
Notes : Interrupt service routine for RTC module.
**********************************************************************/
MC9S08DZ60 Series Data Sheet, Rev. 4
316
Freescale Semiconductor
Chapter 15 Real-Time Counter (S08RTCV1)
#pragma TRAP_PROC
void RTC_ISR(void)
{
/* Clear the interrupt flag */
RTCSC.byte = RTCSC.byte | 0x80;
/* RTC interrupts every 1 Second */
Seconds++;
/* 60 seconds in a minute */
if (Seconds > 59){
Minutes++;
Seconds = 0;
}
/* 60 minutes in an hour */
if (Minutes > 59){
Hours++;
Minutes = 0;
}
/* 24 hours in a day */
if (Hours > 23){
Days ++;
Hours = 0;
}
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
317
Chapter 15 Real-Time Counter (S08RTCV1)
MC9S08DZ60 Series Data Sheet, Rev. 4
318
Freescale Semiconductor
Chapter 16
Timer Pulse-Width Modulator (S08TPMV3)
NOTE
This chapter refers to S08TPM version 3, which applies to the 0M74K and
newer mask sets of this device. 3M05C and older mask set devices use
S08TPM version 2. If your device uses mask 3M05C or older, please refer
to Appendix B, “Timer Pulse-Width Modulator (TPMV2) on page 391 for
information pertaining to that module.
16.1
Introduction
The TPM is a one-to-eight-channel timer system which supports traditional input capture, output compare,
or edge-aligned PWM on each channel. A control bit allows the TPM to be configured such that all
channels may be used for center-aligned PWM functions. Timing functions are based on a 16-bit counter
with prescaler and modulo features to control frequency and range (period between overflows) of the time
reference. This timing system is ideally suited for a wide range of control applications, and the
center-aligned PWM capability extends the field of application to motor control in small appliances.
The TPM uses one input/output (I/O) pin per channel, TPMxCHn, where x is the TPM number (for
example, 1 or 2) and n is the channel number (for example, 0–5). The TPM shares its I/O pins with
general-purpose I/O port pins (refer to the Pins and Connections chapter for more information).
MC9S08DZ60 Series MCUs have two TPM modules. In all packages, TPM2 is 2-channel. The number of
channels available on external pins in TPM1 depends on the package:
• Six channels in 64-pin and 48-pin packages
• Four channels in 32-pin packages.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
319
PORT A
PTA7/PIA7/ADP7/IRQ
PTA6/PIA6/ADP6
PTA5/PIA5/ADP5
PTA4/PIA4/ADP4
PTA3/PIA3/ADP3/ACMP1O
PTA2/PIA2/ADP2/ACMP1PTA1/PIA1/ADP1/ACMP1+
PTA0/PIA0/ADP0/MCLK
PORT B
PTB7/PIB7/ADP15
PTB6/PIB6/ADP14
PTB5/PIB5/ADP13
PTB4/PIB4/ADP12
PTB3/PIB3/ADP11
PTB2/PIB2/ADP10
PTB1/PIB1/ADP9
PTB0/PIB0/ADP8
PORT C
PTC7/ADP23
PTC6/ADP22
PTC5/ADP21
PTC4/ADP20
PTC3/ADP19
PTC2/ADP18
PTC1/ADP17
PTC0/ADP16
PORT D
PTD7/PID7/TPM1CH5
PTD6/PID6/TPM1CH4
PTD5/PID5/TPM1CH3
PTD4/PID4/TPM1CH2
PTD3/PID3/TPM1CH1
PTD2/PID2/TPM1CH0
PTD1/PID1/TPM2CH1
PTD0/PID0/TPM2CH0
PORT E
PTE7/RxD2/RXCAN
PTE6/TxD2/TXCAN
PTE5/SDA/MISO
PTE4/SCL/MOSI
PTE3/SPSCK
PTE2/SS
PTE1/RxD1
PTE0/TxD1
PORT F
PTF7
PTF6/ACMP2O
PTF5/ACMP2PTF4/ACMP2+
PTF3/TPM2CLK/SDA
PTF2/TPM1CLK/SCL
PTF1/RxD2
PTF0/TxD2
PORT G
Chapter 16 Timer Pulse-Width Modulator (S08TPMV3)
PTG5
PTG4
PTG3
PTG2
PTG1/XTAL
PTG0/EXTAL
HCS08 CORE
CPU
BKGD/MS
BDC
ANALOG COMPARATOR
(ACMP1)
BKP
ACMP1O
ACMP1ACMP1+
HCS08 SYSTEM CONTROL
RESETS AND INTERRUPTS
MODES OF OPERATION
POWER MANAGEMENT
COP
LVD
INT
IRQ
ADP7-ADP0
24-CHANNEL,12--BIT
ANALOG-TO-DIGITAL
CONVERTER (ADC)
VREFH
VREFL
VDDA
VSSA
USER FLASH
MC9S0DZ60 = 60K
MC9S0DZ48 = 48K
MC9S0DZ32 = 32K
MC9S0DZ16 = 16K
USER EEPROM
MC9S0DZ60 = 2K
TPM1CH5 TPM1CH0
6
TPM1CLK
2-CHANNEL TIMER/PWM
MODULE (TPM2)
TPM2CH1,
TPM2CH0
TPM2CLK
CONTROLLER AREA
NETWORK (MSCAN)
SERIAL PERIPHERAL
INTERFACE MODULE (SPI)
DEBUG MODULE (DBG)
SERIAL COMMUNICATIONS
INTERFACE (SCI1)
VOLTAGE
REGULATOR
ADP15-ADP8
ADP23-ADP16
6-CHANNEL TIMER/PWM
MODULE (TPM1)
USER RAM
MC9S0DZ60 = 4K
REAL-TIME COUNTER (RTC)
VDD
VDD
VSS
VSS
8
IRQ
RESET
ANALOG COMPARATOR
(ACMP2)
IIC MODULE (IIC)
SERIAL COMMUNICATIONS
INTERFACE (SCI2)
RxCAN
TxCAN
MISO
MOSI
SPSCK
SS
RxD1
TxD1
ACMP2O
ACMP2ACMP2+
SDA
SCL
RxD2
TxD2
MULTI-PURPOSE
CLOCK GENERATOR
(MCG)
XTAL
EXTAL
OSCILLATOR (XOSC)
- VREFH/VREFL internally connected to VDDA/VSSA in 48-pin and 32-pin packages
- VDD and VSS pins are each internally connected to two pads in 32-pin package
- Pin not connected in 48-pin and 32-pin packages
- Pin not connected in 32-pin package
Figure 16-1. MC9S08DZ60 Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
320
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
16.1.1
Features
The TPM includes these distinctive features:
• One to eight channels:
— Each channel may be input capture, output compare, or edge-aligned PWM
— Rising-Edge, falling-edge, or any-edge input capture trigger
— Set, clear, or toggle output compare action
— Selectable polarity on PWM outputs
• Module may be configured for buffered, center-aligned pulse-width-modulation (CPWM) on all
channels
• Timer clock source selectable as prescaled bus clock, fixed system clock, or an external clock pin
— Prescale taps for divide-by 1, 2, 4, 8, 16, 32, 64, or 128
— Fixed system clock source are synchronized to the bus clock by an on-chip synchronization
circuit
— External clock pin may be shared with any timer channel pin or a separated input pin
• 16-bit free-running or modulo up/down count operation
• Timer system enable
• One interrupt per channel plus terminal count interrupt
16.1.2
Modes of Operation
In general, TPM channels may be independently configured to operate in input capture, output compare,
or edge-aligned PWM modes. A control bit allows the whole TPM (all channels) to switch to
center-aligned PWM mode. When center-aligned PWM mode is selected, input capture, output compare,
and edge-aligned PWM functions are not available on any channels of this TPM module.
When the microcontroller is in active BDM background or BDM foreground mode, the TPM temporarily
suspends all counting until the microcontroller returns to normal user operating mode. During stop mode,
all system clocks, including the main oscillator, are stopped; therefore, the TPM is effectively disabled
until clocks resume. During wait mode, the TPM continues to operate normally. Provided the TPM does
not need to produce a real time reference or provide the interrupt source(s) needed to wake the MCU from
wait mode, the user can save power by disabling TPM functions before entering wait mode.
• Input capture mode
When a selected edge event occurs on the associated MCU pin, the current value of the 16-bit timer
counter is captured into the channel value register and an interrupt flag bit is set. Rising edges,
falling edges, any edge, or no edge (disable channel) may be selected as the active edge which
triggers the input capture.
• Output compare mode
When the value in the timer counter register matches the channel value register, an interrupt flag
bit is set, and a selected output action is forced on the associated MCU pin. The output compare
action may be selected to force the pin to zero, force the pin to one, toggle the pin, or ignore the
pin (used for software timing functions).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
321
Chapter 16 Timer/PWM Module (S08TPMV3)
•
•
Edge-aligned PWM mode
The value of a 16-bit modulo register plus 1 sets the period of the PWM output signal. The channel
value register sets the duty cycle of the PWM output signal. The user may also choose the polarity
of the PWM output signal. Interrupts are available at the end of the period and at the duty-cycle
transition point. This type of PWM signal is called edge-aligned because the leading edges of all
PWM signals are aligned with the beginning of the period, which is the same for all channels within
a TPM.
Center-aligned PWM mode
Twice the value of a 16-bit modulo register sets the period of the PWM output, and the
channel-value register sets the half-duty-cycle duration. The timer counter counts up until it
reaches the modulo value and then counts down until it reaches zero. As the count matches the
channel value register while counting down, the PWM output becomes active. When the count
matches the channel value register while counting up, the PWM output becomes inactive. This type
of PWM signal is called center-aligned because the centers of the active duty cycle periods for all
channels are aligned with a count value of zero. This type of PWM is required for types of motors
used in small appliances.
This is a high-level description only. Detailed descriptions of operating modes are in later sections.
16.1.3
Block Diagram
The TPM uses one input/output (I/O) pin per channel, TPMxCHn (timer channel n) where n is the channel
number (1-8). The TPM shares its I/O pins with general purpose I/O port pins (refer to I/O pin descriptions
in full-chip specification for the specific chip implementation).
Figure 16-2 shows the TPM structure. The central component of the TPM is the 16-bit counter that can
operate as a free-running counter or a modulo up/down counter. The TPM counter (when operating in
normal up-counting mode) provides the timing reference for the input capture, output compare, and
edge-aligned PWM functions. The timer counter modulo registers, TPMxMODH:TPMxMODL, control
the modulo value of the counter (the values 0x0000 or 0xFFFF effectively make the counter free running).
Software can read the counter value at any time without affecting the counting sequence. Any write to
either half of the TPMxCNT counter resets the counter, regardless of the data value written.
MC9S08DZ60 Series Data Sheet, Rev. 4
322
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
BUS CLOCK
FIXED SYSTEM CLOCK
SYNC
EXTERNAL CLOCK
CLOCK SOURCE
SELECT
OFF, BUS, FIXED
SYSTEM CLOCK, EXT
PRESCALE AND SELECT
1, 2, 4, 8, 16, 32, 64,
or 128
CLKSB:CLKSA
PS2:PS1:PS0
CPWMS
16-BIT COUNTER
TOF
COUNTER RESET
TOIE
INTERRUPT
LOGIC
16-BIT COMPARATOR
TPMxMODH:TPMxMODL
CHANNEL 0
ELS0B
ELS0A
PORT
LOGIC
TPMxCH0
16-BIT COMPARATOR
TPMxC0VH:TPMxC0VL
CH0F
INTERNAL BUS
16-BIT LATCH
CHANNEL 1
MS0B
MS0A
ELS1B
ELS1A
CH0IE
INTERRUPT
LOGIC
PORT
LOGIC
TPMxCH1
16-BIT COMPARATOR
TPMxC1VH:TPMxC1VL
CH1F
16-BIT LATCH
MS1B
CH1IE
MS1A
INTERRUPT
LOGIC
Up to 8 channels
CHANNEL 7
ELS7B
ELS7A
PORT
LOGIC
TPMxCH7
16-BIT COMPARATOR
TPMxC7VH:TPMxC7VL
CH7F
16-BIT LATCH
MS7B
MS7A
CH7IE
INTERRUPT
LOGIC
Figure 16-2. TPM Block Diagram
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
323
Chapter 16 Timer/PWM Module (S08TPMV3)
The TPM channels are programmable independently as input capture, output compare, or edge-aligned
PWM channels. Alternately, the TPM can be configured to produce CPWM outputs on all channels. When
the TPM is configured for CPWMs, the counter operates as an up/down counter; input capture, output
compare, and EPWM functions are not practical.
If a channel is configured as input capture, an internal pullup device may be enabled for that channel. The
details of how a module interacts with pin controls depends upon the chip implementation because the I/O
pins and associated general purpose I/O controls are not part of the module. Refer to the discussion of the
I/O port logic in a full-chip specification.
Because center-aligned PWMs are usually used to drive 3-phase AC-induction motors and brushless DC
motors, they are typically used in sets of three or six channels.
16.2
Signal Description
Table 16-1 shows the user-accessible signals for the TPM. The number of channels may be varied from
one to eight. When an external clock is included, it can be shared with the same pin as any TPM channel;
however, it could be connected to a separate input pin. Refer to the I/O pin descriptions in full-chip
specification for the specific chip implementation.
Table 16-1. Signal Properties
Name
Function
EXTCLK1
2
TPMxCHn
External clock source which may be selected to drive the TPM counter.
I/O pin associated with TPM channel n
1
When preset, this signal can share any channel pin; however depending upon full-chip
implementation, this signal could be connected to a separate external pin.
2 n=channel number (1 to 8)
Refer to documentation for the full-chip for details about reset states, port connections, and whether there
is any pullup device on these pins.
TPM channel pins can be associated with general purpose I/O pins and have passive pullup devices which
can be enabled with a control bit when the TPM or general purpose I/O controls have configured the
associated pin as an input. When no TPM function is enabled to use a corresponding pin, the pin reverts
to being controlled by general purpose I/O controls, including the port-data and data-direction registers.
Immediately after reset, no TPM functions are enabled, so all associated pins revert to general purpose I/O
control.
16.2.1
Detailed Signal Descriptions
This section describes each user-accessible pin signal in detail. Although Table 16-1 grouped all channel
pins together, any TPM pin can be shared with the external clock source signal. Since I/O pin logic is not
part of the TPM, refer to full-chip documentation for a specific derivative for more details about the
interaction of TPM pin functions and general purpose I/O controls including port data, data direction, and
pullup controls.
MC9S08DZ60 Series Data Sheet, Rev. 4
324
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
16.2.1.1
EXTCLK — External Clock Source
Control bits in the timer status and control register allow the user to select nothing (timer disable), the
bus-rate clock (the normal default source), a crystal-related clock, or an external clock as the clock which
drives the TPM prescaler and subsequently the 16-bit TPM counter. The external clock source is
synchronized in the TPM. The bus clock clocks the synchronizer; the frequency of the external source must
be no more than one-fourth the frequency of the bus-rate clock, to meet Nyquist criteria and allowing for
jitter.
The external clock signal shares the same pin as a channel I/O pin, so the channel pin will not be usable
for channel I/O function when selected as the external clock source. It is the user’s responsibility to avoid
such settings. If this pin is used as an external clock source (CLKSB:CLKSA = 1:1), the channel can still
be used in output compare mode as a software timer (ELSnB:ELSnA = 0:0).
16.2.1.2
TPMxCHn — TPM Channel n I/O Pin(s)
Each TPM channel is associated with an I/O pin on the MCU. The function of this pin depends on the
channel configuration. The TPM pins share with general purpose I/O pins, where each pin has a port data
register bit, and a data direction control bit, and the port has optional passive pullups which may be enabled
whenever a port pin is acting as an input.
The TPM channel does not control the I/O pin when (ELSnB:ELSnA = 0:0) or when (CLKSB:CLKSA =
0:0) so it normally reverts to general purpose I/O control. When CPWMS = 1 (and ELSnB:ELSnA not =
0:0), all channels within the TPM are configured for center-aligned PWM and the TPMxCHn pins are all
controlled by the TPM system. When CPWMS=0, the MSnB:MSnA control bits determine whether the
channel is configured for input capture, output compare, or edge-aligned PWM.
When a channel is configured for input capture (CPWMS=0, MSnB:MSnA = 0:0 and ELSnB:ELSnA not
= 0:0), the TPMxCHn pin is forced to act as an edge-sensitive input to the TPM. ELSnB:ELSnA control
bits determine what polarity edge or edges will trigger input-capture events. A synchronizer based on the
bus clock is used to synchronize input edges to the bus clock. This implies the minimum pulse width—that
can be reliably detected—on an input capture pin is four bus clock periods (with ideal clock pulses as near
as two bus clocks can be detected). TPM uses this pin as an input capture input to override the port data
and data direction controls for the same pin.
When a channel is configured for output compare (CPWMS=0, MSnB:MSnA = 0:1 and ELSnB:ELSnA
not = 0:0), the associated data direction control is overridden, the TPMxCHn pin is considered an output
controlled by the TPM, and the ELSnB:ELSnA control bits determine how the pin is controlled. The
remaining three combinations of ELSnB:ELSnA determine whether the TPMxCHn pin is toggled, cleared,
or set each time the 16-bit channel value register matches the timer counter.
When the output compare toggle mode is initially selected, the previous value on the pin is driven out until
the next output compare event—then the pin is toggled.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
325
Chapter 16 Timer/PWM Module (S08TPMV3)
When a channel is configured for edge-aligned PWM (CPWMS=0, MSnB=1 and ELSnB:ELSnA not =
0:0), the data direction is overridden, the TPMxCHn pin is forced to be an output controlled by the TPM,
and ELSnA controls the polarity of the PWM output signal on the pin. When ELSnB:ELSnA=1:0, the
TPMxCHn pin is forced high at the start of each new period (TPMxCNT=0x0000), and the pin is forced
low when the channel value register matches the timer counter. When ELSnA=1, the TPMxCHn pin is
forced low at the start of each new period (TPMxCNT=0x0000), and the pin is forced high when the
channel value register matches the timer counter.
TPMxMODH:TPMxMODL = 0x0008
TPMxCnVH:TPMxCnVL = 0x0005
TPMxCNTH:TPMxCNTL
...
0
1
2
3
4
5
6
7
8
0
1
2
...
2
...
TPMxCHn
CHnF BIT
TOF BIT
Figure 16-3. High-True Pulse of an Edge-Aligned PWM
TPMxMODH:TPMxMODL = 0x0008
TPMxCnVH:TPMxCnVL = 0x0005
TPMxCNTH:TPMxCNTL
...
0
1
2
3
4
5
6
7
8
0
1
TPMxCHn
CHnF BIT
TOF BIT
Figure 16-4. Low-True Pulse of an Edge-Aligned PWM
MC9S08DZ60 Series Data Sheet, Rev. 4
326
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
When the TPM is configured for center-aligned PWM (and ELSnB:ELSnA not = 0:0), the data direction
for all channels in this TPM are overridden, the TPMxCHn pins are forced to be outputs controlled by the
TPM, and the ELSnA bits control the polarity of each TPMxCHn output. If ELSnB:ELSnA=1:0, the
corresponding TPMxCHn pin is cleared when the timer counter is counting up, and the channel value
register matches the timer counter; the TPMxCHn pin is set when the timer counter is counting down, and
the channel value register matches the timer counter. If ELSnA=1, the corresponding TPMxCHn pin is set
when the timer counter is counting up and the channel value register matches the timer counter; the
TPMxCHn pin is cleared when the timer counter is counting down and the channel value register matches
the timer counter.
TPMxMODH:TPMxMODL = 0x0008
TPMxCnVH:TPMxCnVL = 0x0005
TPMxCNTH:TPMxCNTL
...
7
8
7
6
5
4
3
2
1
0
1
2
3
4
5
6
7
8
7
6
5
...
7
8
7
6
5
...
TPMxCHn
CHnF BIT
TOF BIT
Figure 16-5. High-True Pulse of a Center-Aligned PWM
TPMxMODH:TPMxMODL = 0x0008
TPMxCnVH:TPMxCnVL = 0x0005
TPMxCNTH:TPMxCNTL
...
7
8
7
6
5
4
3
2
1
0
1
2
3
4
5
6
TPMxCHn
CHnF BIT
TOF BIT
Figure 16-6. Low-True Pulse of a Center-Aligned PWM
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
327
Chapter 16 Timer/PWM Module (S08TPMV3)
16.3
Register Definition
This section consists of register descriptions in address order. A typical MCU system may contain multiple
TPMs, and each TPM may have one to eight channels, so register names include placeholder characters to
identify which TPM and which channel is being referenced. For example, TPMxCnSC refers to timer
(TPM) x, channel n. TPM1C2SC would be the status and control register for channel 2 of timer 1.
16.3.1
TPM Status and Control Register (TPMxSC)
TPMxSC contains the overflow status flag and control bits used to configure the interrupt enable, TPM
configuration, clock source, and prescale factor. These controls relate to all channels within this timer
module.
7
R
TOF
W
0
Reset
0
6
5
4
3
2
1
0
TOIE
CPWMS
CLKSB
CLKSA
PS2
PS1
PS0
0
0
0
0
0
0
0
Figure 16-7. TPM Status and Control Register (TPMxSC)
Table 16-2. TPMxSC Field Descriptions
Field
Description
7
TOF
Timer overflow flag. This read/write flag is set when the TPM counter resets to 0x0000 after reaching the modulo
value programmed in the TPM counter modulo registers. Clear TOF by reading the TPM status and control
register when TOF is set and then writing a logic 0 to TOF. If another TPM overflow occurs before the clearing
sequence is complete, the sequence is reset so TOF would remain set after the clear sequence was completed
for the earlier TOF. This is done so a TOF interrupt request cannot be lost during the clearing sequence for a
previous TOF. Reset clears TOF. Writing a logic 1 to TOF has no effect.
0 TPM counter has not reached modulo value or overflow
1 TPM counter has overflowed
6
TOIE
Timer overflow interrupt enable. This read/write bit enables TPM overflow interrupts. If TOIE is set, an interrupt is
generated when TOF equals one. Reset clears TOIE.
0 TOF interrupts inhibited (use for software polling)
1 TOF interrupts enabled
5
CPWMS
Center-aligned PWM select. When present, this read/write bit selects CPWM operating mode. By default, the
TPM operates in up-counting mode for input capture, output compare, and edge-aligned PWM functions. Setting
CPWMS reconfigures the TPM to operate in up/down counting mode for CPWM functions. Reset clears CPWMS.
0 All channels operate as input capture, output compare, or edge-aligned PWM mode as selected by the
MSnB:MSnA control bits in each channel’s status and control register.
1 All channels operate in center-aligned PWM mode.
MC9S08DZ60 Series Data Sheet, Rev. 4
328
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
Table 16-2. TPMxSC Field Descriptions (continued)
Field
Description
4–3
Clock source selects. As shown in Table 16-3, this 2-bit field is used to disable the TPM system or select one of
CLKS[B:A] three clock sources to drive the counter prescaler. The fixed system clock source is only meaningful in systems
with a PLL-based or FLL-based system clock. When there is no PLL or FLL, the fixed-system clock source is the
same as the bus rate clock. The external source is synchronized to the bus clock by TPM module, and the fixed
system clock source (when a PLL or FLL is present) is synchronized to the bus clock by an on-chip
synchronization circuit. When a PLL or FLL is present but not enabled, the fixed-system clock source is the same
as the bus-rate clock.
2–0
PS[2:0]
Prescale factor select. This 3-bit field selects one of 8 division factors for the TPM clock input as shown in
Table 16-4. This prescaler is located after any clock source synchronization or clock source selection so it affects
the clock source selected to drive the TPM system. The new prescale factor will affect the clock source on the
next system clock cycle after the new value is updated into the register bits.
Table 16-3. TPM-Clock-Source Selection
CLKSB:CLKSA
TPM Clock Source to Prescaler Input
00
No clock selected (TPM counter disable)
01
Bus rate clock
10
Fixed system clock
11
External source
Table 16-4. Prescale Factor Selection
16.3.2
PS2:PS1:PS0
TPM Clock Source Divided-by
000
1
001
2
010
4
011
8
100
16
101
32
110
64
111
128
TPM-Counter Registers (TPMxCNTH:TPMxCNTL)
The two read-only TPM counter registers contain the high and low bytes of the value in the TPM counter.
Reading either byte (TPMxCNTH or TPMxCNTL) latches the contents of both bytes into a buffer where
they remain latched until the other half is read. This allows coherent 16-bit reads in either big-endian or
little-endian order which makes this more friendly to various compiler implementations. The coherency
mechanism is automatically restarted by an MCU reset or any write to the timer status/control register
(TPMxSC).
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
329
Chapter 16 Timer/PWM Module (S08TPMV3)
Reset clears the TPM counter registers. Writing any value to TPMxCNTH or TPMxCNTL also clears the
TPM counter (TPMxCNTH:TPMxCNTL) and resets the coherency mechanism, regardless of the data
involved in the write.
R
7
6
5
4
3
2
1
0
Bit 15
14
13
12
11
10
9
Bit 8
0
0
W
Reset
Any write to TPMxCNTH clears the 16-bit counter
0
0
0
0
0
0
Figure 16-8. TPM Counter Register High (TPMxCNTH)
R
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
W
Reset
Any write to TPMxCNTL clears the 16-bit counter
0
0
0
0
0
0
Figure 16-9. TPM Counter Register Low (TPMxCNTL)
When BDM is active, the timer counter is frozen (this is the value that will be read by user); the coherency
mechanism is frozen such that the buffer latches remain in the state they were in when the BDM became
active, even if one or both counter halves are read while BDM is active. This assures that if the user was
in the middle of reading a 16-bit register when BDM became active, it will read the appropriate value from
the other half of the 16-bit value after returning to normal execution.
In BDM mode, writing any value to TPMxSC, TPMxCNTH or TPMxCNTL registers resets the read
coherency mechanism of the TPMxCNTH:L registers, regardless of the data involved in the write.
16.3.3
TPM Counter Modulo Registers (TPMxMODH:TPMxMODL)
The read/write TPM modulo registers contain the modulo value for the TPM counter. After the TPM
counter reaches the modulo value, the TPM counter resumes counting from 0x0000 at the next clock, and
the overflow flag (TOF) becomes set. Writing to TPMxMODH or TPMxMODL inhibits the TOF bit and
overflow interrupts until the other byte is written. Reset sets the TPM counter modulo registers to 0x0000
which results in a free running timer counter (modulo disabled).
Writing to either byte (TPMxMODH or TPMxMODL) latches the value into a buffer and the registers are
updated with the value of their write buffer according to the value of CLKSB:CLKSA bits, so:
• If (CLKSB:CLKSA = 0:0), then the registers are updated when the second byte is written
• If (CLKSB:CLKSA not = 0:0), then the registers are updated after both bytes were written, and the
TPM counter changes from (TPMxMODH:TPMxMODL - 1) to (TPMxMODH:TPMxMODL). If
the TPM counter is a free-running counter, the update is made when the TPM counter changes from
0xFFFE to 0xFFFF
The latching mechanism may be manually reset by writing to the TPMxSC address (whether BDM is
active or not).
MC9S08DZ60 Series Data Sheet, Rev. 4
330
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
When BDM is active, the coherency mechanism is frozen (unless reset by writing to TPMxSC register)
such that the buffer latches remain in the state they were in when the BDM became active, even if one or
both halves of the modulo register are written while BDM is active. Any write to the modulo registers
bypasses the buffer latches and directly writes to the modulo register while BDM is active.
7
6
5
4
3
2
1
0
Bit 15
14
13
12
11
10
9
Bit 8
0
0
0
0
0
0
0
0
R
W
Reset
Figure 16-10. TPM Counter Modulo Register High (TPMxMODH)
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
0
0
0
0
0
0
R
W
Reset
Figure 16-11. TPM Counter Modulo Register Low (TPMxMODL)
Reset the TPM counter before writing to the TPM modulo registers to avoid confusion about when the first
counter overflow will occur.
16.3.4
TPM Channel n Status and Control Register (TPMxCnSC)
TPMxCnSC contains the channel-interrupt-status flag and control bits used to configure the interrupt
enable, channel configuration, and pin function.
7
R
6
5
4
3
2
CHnIE
MSnB
MSnA
ELSnB
ELSnA
0
0
0
0
0
CHnF
W
0
Reset
0
1
0
0
0
0
0
= Unimplemented or Reserved
Figure 16-12. TPM Channel n Status and Control Register (TPMxCnSC)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
331
Chapter 16 Timer/PWM Module (S08TPMV3)
Table 16-5. TPMxCnSC Field Descriptions
Field
Description
7
CHnF
Channel n flag. When channel n is an input-capture channel, this read/write bit is set when an active edge occurs
on the channel n pin. When channel n is an output compare or edge-aligned/center-aligned PWM channel, CHnF
is set when the value in the TPM counter registers matches the value in the TPM channel n value registers. When
channel n is an edge-aligned/center-aligned PWM channel and the duty cycle is set to 0% or 100%, CHnF will
not be set even when the value in the TPM counter registers matches the value in the TPM channel n value
registers.
A corresponding interrupt is requested when CHnF is set and interrupts are enabled (CHnIE = 1). Clear CHnF by
reading TPMxCnSC while CHnF is set and then writing a logic 0 to CHnF. If another interrupt request occurs
before the clearing sequence is complete, the sequence is reset so CHnF remains set after the clear sequence
completed for the earlier CHnF. This is done so a CHnF interrupt request cannot be lost due to clearing a previous
CHnF.
Reset clears the CHnF bit. Writing a logic 1 to CHnF has no effect.
0 No input capture or output compare event occurred on channel n
1 Input capture or output compare event on channel n
6
CHnIE
Channel n interrupt enable. This read/write bit enables interrupts from channel n. Reset clears CHnIE.
0 Channel n interrupt requests disabled (use for software polling)
1 Channel n interrupt requests enabled
5
MSnB
Mode select B for TPM channel n. When CPWMS=0, MSnB=1 configures TPM channel n for edge-aligned PWM
mode. Refer to the summary of channel mode and setup controls in Table 16-6.
4
MSnA
Mode select A for TPM channel n. When CPWMS=0 and MSnB=0, MSnA configures TPM channel n for
input-capture mode or output compare mode. Refer to Table 16-6 for a summary of channel mode and setup
controls.
Note: If the associated port pin is not stable for at least two bus clock cycles before changing to input capture
mode, it is possible to get an unexpected indication of an edge trigger.
3–2
ELSnB
ELSnA
Edge/level select bits. Depending upon the operating mode for the timer channel as set by CPWMS:MSnB:MSnA
and shown in Table 16-6, these bits select the polarity of the input edge that triggers an input capture event, select
the level that will be driven in response to an output compare match, or select the polarity of the PWM output.
Setting ELSnB:ELSnA to 0:0 configures the related timer pin as a general purpose I/O pin not related to any timer
functions. This function is typically used to temporarily disable an input capture channel or to make the timer pin
available as a general purpose I/O pin when the associated timer channel is set up as a software timer that does
not require the use of a pin.
Table 16-6. Mode, Edge, and Level Selection
CPWMS
MSnB:MSnA
ELSnB:ELSnA
X
XX
00
Mode
Configuration
Pin not used for TPM - revert to general
purpose I/O or other peripheral control
MC9S08DZ60 Series Data Sheet, Rev. 4
332
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
Table 16-6. Mode, Edge, and Level Selection
CPWMS
MSnB:MSnA
ELSnB:ELSnA
Mode
Configuration
0
00
01
Input capture
Capture on rising edge
only
01
10
Capture on falling edge
only
11
Capture on rising or
falling edge
01
1X
Output compare
10
Clear output on
compare
11
Set output on compare
10
Edge-aligned
PWM
X1
1
XX
High-true pulses (clear
output on compare)
Low-true pulses (set
output on compare)
10
Center-aligned
PWM
X1
16.3.5
Toggle output on
compare
High-true pulses (clear
output on compare-up)
Low-true pulses (set
output on compare-up)
TPM Channel Value Registers (TPMxCnVH:TPMxCnVL)
These read/write registers contain the captured TPM counter value of the input capture function or the
output compare value for the output compare or PWM functions. The channel registers are cleared by
reset.
7
6
5
4
3
2
1
0
Bit 15
14
13
12
11
10
9
Bit 8
0
0
0
0
0
0
0
0
R
W
Reset
Figure 16-13. TPM Channel Value Register High (TPMxCnVH)
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
0
0
0
0
0
0
R
W
Reset
Figure 16-14. TPM Channel Value Register Low (TPMxCnVL)
In input capture mode, reading either byte (TPMxCnVH or TPMxCnVL) latches the contents of both bytes
into a buffer where they remain latched until the other half is read. This latching mechanism also resets
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
333
Chapter 16 Timer/PWM Module (S08TPMV3)
(becomes unlatched) when the TPMxCnSC register is written (whether BDM mode is active or not). Any
write to the channel registers will be ignored during the input capture mode.
When BDM is active, the coherency mechanism is frozen (unless reset by writing to TPMxCnSC register)
such that the buffer latches remain in the state they were in when the BDM became active, even if one or
both halves of the channel register are read while BDM is active. This assures that if the user was in the
middle of reading a 16-bit register when BDM became active, it will read the appropriate value from the
other half of the 16-bit value after returning to normal execution. The value read from the TPMxCnVH
and TPMxCnVL registers in BDM mode is the value of these registers and not the value of their read
buffer.
In output compare or PWM modes, writing to either byte (TPMxCnVH or TPMxCnVL) latches the value
into a buffer. After both bytes are written, they are transferred as a coherent 16-bit value into the
timer-channel registers according to the value of CLKSB:CLKSA bits and the selected mode, so:
• If (CLKSB:CLKSA = 0:0), then the registers are updated when the second byte is written.
• If (CLKSB:CLKSA not = 0:0 and in output compare mode) then the registers are updated after the
second byte is written and on the next change of the TPM counter (end of the prescaler counting).
• If (CLKSB:CLKSA not = 0:0 and in EPWM or CPWM modes), then the registers are updated after
the both bytes were written, and the TPM counter changes from (TPMxMODH:TPMxMODL - 1)
to (TPMxMODH:TPMxMODL). If the TPM counter is a free-running counter then the update is
made when the TPM counter changes from 0xFFFE to 0xFFFF.
The latching mechanism may be manually reset by writing to the TPMxCnSC register (whether BDM
mode is active or not). This latching mechanism allows coherent 16-bit writes in either big-endian or
little-endian order which is friendly to various compiler implementations.
When BDM is active, the coherency mechanism is frozen such that the buffer latches remain in the state
they were in when the BDM became active even if one or both halves of the channel register are written
while BDM is active. Any write to the channel registers bypasses the buffer latches and directly write to
the channel register while BDM is active. The values written to the channel register while BDM is active
are used for PWM & output compare operation once normal execution resumes. Writes to the channel
registers while BDM is active do not interfere with partial completion of a coherency sequence. After the
coherency mechanism has been fully exercised, the channel registers are updated using the buffered values
written (while BDM was not active) by the user.
16.4
Functional Description
All TPM functions are associated with a central 16-bit counter which allows flexible selection of the clock
source and prescale factor. There is also a 16-bit modulo register associated with the main counter.
The CPWMS control bit chooses between center-aligned PWM operation for all channels in the TPM
(CPWMS=1) or general purpose timing functions (CPWMS=0) where each channel can independently be
configured to operate in input capture, output compare, or edge-aligned PWM mode. The CPWMS control
bit is located in the main TPM status and control register because it affects all channels within the TPM
and influences the way the main counter operates. (In CPWM mode, the counter changes to an up/down
mode rather than the up-counting mode used for general purpose timer functions.)
MC9S08DZ60 Series Data Sheet, Rev. 4
334
Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
The following sections describe the main counter and each of the timer operating modes (input capture,
output compare, edge-aligned PWM, and center-aligned PWM). Because details of pin operation and
interrupt activity depend upon the operating mode, these topics will be covered in the associated mode
explanation sections.
16.4.1
Counter
All timer functions are based on the main 16-bit counter (TPMxCNTH:TPMxCNTL). This section
discusses selection of the clock source, end-of-count overflow, up-counting vs. up/down counting, and
manual counter reset.
16.4.1.1
Counter Clock Source
The 2-bit field, CLKSB:CLKSA, in the timer status and control register (TPMxSC) selects one of three
possible clock sources or OFF (which effectively disables the TPM). See Table 16-3. After any MCU reset,
CLKSB:CLKSA=0:0 so no clock source is selected, and the TPM is in a very low power state. These
control bits may be read or written at any time and disabling the timer (writing 00 to the CLKSB:CLKSA
field) does not affect the values in the counter or other timer registers.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
335
Chapter 16 Timer/PWM Module (S08TPMV3)
Table 16-7. TPM Clock Source Selection
CLKSB:CLKSA
TPM Clock Source to Prescaler Input
00
No clock selected (TPM counter disabled)
01
Bus rate clock
10
Fixed system clock
11
External source
The bus rate clock is the main system bus clock for the MCU. This clock source requires no
synchronization because it is the clock that is used for all internal MCU activities including operation of
the CPU and buses.
In MCUs that have no PLL and FLL or the PLL and FLL are not engaged, the fixed system clock source
is the same as the bus-rate-clock source, and it does not go through a synchronizer. When a PLL or FLL
is present and engaged, a synchronizer is required between the crystal divided-by two clock source and the
timer counter so counter transitions will be properly aligned to bus-clock transitions. A synchronizer will
be used at chip level to synchronize the crystal-related source clock to the bus clock.
The external clock source may be connected to any TPM channel pin. This clock source always has to pass
through a synchronizer to assure that counter transitions are properly aligned to bus clock transitions. The
bus-rate clock drives the synchronizer; therefore, to meet Nyquist criteria even with jitter, the frequency of
the external clock source must not be faster than the bus rate divided-by four. With ideal clocks the external
clock can be as fast as bus clock divided by four.
When the external clock source shares the TPM channel pin, this pin should not be used for other channel
timing functions. For example, it would be ambiguous to configure channel 0 for input capture when the
TPM channel 0 pin was also being used as the timer external clock source. (It is the user’s responsibility
to avoid such settings.) The TPM channel could still be used in output compare mode for software timing
functions (pin controls set not to affect the TPM channel pin).
16.4.1.2
Counter Overflow and Modulo Reset
An interrupt flag and enable are associated with the 16-bit main counter. The flag (TOF) is a
software-accessible indication that the timer counter has overflowed. The enable signal selects between
software polling (TOIE=0) where no hardware interrupt is generated, or interrupt-driven operation
(TOIE=1) where a static hardware interrupt is generated whenever the TOF flag is equal to one.
The conditions causing TOF to become set depend on whether the TPM is configured for center-aligned
PWM (CPWMS=1). In the simplest mode, there is no modulus limit and the TPM is not in CPWMS=1
mode. In this case, the 16-bit timer counter counts from 0x0000 through 0xFFFF and overflows to 0x0000
on the next counting clock. TOF becomes set at the transition from 0xFFFF to 0x0000. When a modulus
limit is set, TOF becomes set at the transition from the value set in the modulus register to 0x0000. When
the TPM is in center-aligned PWM mode (CPWMS=1), the TOF flag gets set as the counter changes
direction at the end of the count value set in the modulus register (that is, at the transition from the value
set in the modulus register to the next lower count value). This corresponds to the end of a PWM period
(the 0x0000 count value corresponds to the center of a period).
MC9S08DZ60 Series Data Sheet, Rev. 4
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Freescale Semiconductor
Chapter 16 Timer/PWM Module (S08TPMV3)
16.4.1.3
Counting Modes
The main timer counter has two counting modes. When center-aligned PWM is selected (CPWMS=1), the
counter operates in up/down counting mode. Otherwise, the counter operates as a simple up counter. As
an up counter, the timer counter counts from 0x0000 through its terminal count and then continues with
0x0000. The terminal count is 0xFFFF or a modulus value in TPMxMODH:TPMxMODL.
When center-aligned PWM operation is specified, the counter counts up from 0x0000 through its terminal
count and then down to 0x0000 where it changes back to up counting. Both 0x0000 and the terminal count
value are normal length counts (one timer clock period long). In this mode, the timer overflow flag (TOF)
becomes set at the end of the terminal-count period (as the count changes to the next lower count value).
16.4.1.4
Manual Counter Reset
The main timer counter can be manually reset at any time by writing any value to either half of
TPMxCNTH or TPMxCNTL. Resetting the counter in this manner also resets the coherency mechanism
in case only half of the counter was read before resetting the count.
16.4.2
Channel Mode Selection
Provided CPWMS=0, the MSnB and MSnA control bits in the channel n status and control registers
determine the basic mode of operation for the corresponding channel. Choices include input capture,
output compare, and edge-aligned PWM.
16.4.2.1
Input Capture Mode
With the input-capture function, the TPM can capture the time at which an external event occurs. When an
active edge occurs on the pin of an input-capture channel, the TPM latches the contents of the TPM counter
into the channel-value registers (TPMxCnVH:TPMxCnVL). Rising edges, falling edges, or any edge may
be chosen as the active edge that triggers an input capture.
In input capture mode, the TPMxCnVH and TPMxCnVL registers are read only.
When either half of the 16-bit capture register is read, the other half is latched into a buffer to support
coherent 16-bit accesses in big-endian or little-endian order. The coherency sequence can be manually
reset by writing to the channel status/control register (TPMxCnSC).
An input capture event sets a flag bit (CHnF) which may optionally generate a CPU interrupt request.
While in BDM, the input capture function works as configured by the user. When an external event occurs,
the TPM latches the contents of the TPM counter (which is frozen because of the BDM mode) into the
channel value registers and sets the flag bit.
16.4.2.2
Output Compare Mode
With the output-compare function, the TPM can generate timed pulses with programmable position,
polarity, duration, and frequency. When the counter reaches the value in the channel-value registers of an
output-compare channel, the TPM can set, clear, or toggle the channel pin.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
337
Chapter 16 Timer/PWM Module (S08TPMV3)
In output compare mode, values are transferred to the corresponding timer channel registers only after both
8-bit halves of a 16-bit register have been written and according to the value of CLKSB:CLKSA bits, so:
• If (CLKSB:CLKSA = 0:0), the registers are updated when the second byte is written
• If (CLKSB:CLKSA not = 0:0), the registers are updated at the next change of the TPM counter
(end of the prescaler counting) after the second byte is written.
The coherency sequence can be manually reset by writing to the channel status/control register
(TPMxCnSC).
An output compare event sets a flag bit (CHnF) which may optionally generate a CPU-interrupt request.
16.4.2.3
Edge-Aligned PWM Mode
This type of PWM output uses the normal up-counting mode of the timer counter (CPWMS=0) and can
be used when other channels in the same TPM are configured for input capture or output compare
functions. The period of this PWM signal is determined by the value of the modulus register
(TPMxMODH:TPMxMODL) plus 1. The duty cycle is determined by the setting in the timer channel
register (TPMxCnVH:TPMxCnVL). The polarity of this PWM signal is determined by the setting in the
ELSnA control bit. 0% and 100% duty cycle cases are possible.
The output compare value in the TPM channel registers determines the pulse width (duty cycle) of the
PWM signal (Figure 16-15). The time between the modulus overflow and the output compare is the pulse
width. If ELSnA=0, the counter overflow forces the PWM signal high, and the output compare forces the
PWM signal low. If ELSnA=1, the counter overflow forces the PWM signal low, and the output compare
forces the PWM signal high.
OVERFLOW
OVERFLOW
OVERFLOW
PERIOD
PULSE
WIDTH
TPMxCHn
OUTPUT
COMPARE
OUTPUT
COMPARE
OUTPUT
COMPARE
Figure 16-15. PWM Period and Pulse Width (ELSnA=0)
When the channel value register is set to 0x0000, the duty cycle is 0%. 100% duty cycle can be achieved
by setting the timer-channel register (TPMxCnVH:TPMxCnVL) to a value greater than the modulus
setting. This implies that the modulus setting must be less than 0xFFFF in order to get 100% duty cycle.
Because the TPM may be used in an 8-bit MCU, the settings in the timer channel registers are buffered to
ensure coherent 16-bit updates and to avoid unexpected PWM pulse widths. Writes to any of the registers
TPMxCnVH and TPMxCnVL, actually write to buffer registers. In edge-aligned PWM mode, values are
transferred to the corresponding timer-channel registers according to the value of CLKSB:CLKSA bits, so:
• If (CLKSB:CLKSA = 0:0), the registers are updated when the second byte is written
• If (CLKSB:CLKSA not = 0:0), the registers are updated after the both bytes were written, and the
TPM counter changes from (TPMxMODH:TPMxMODL - 1) to (TPMxMODH:TPMxMODL). If
MC9S08DZ60 Series Data Sheet, Rev. 4
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Chapter 16 Timer/PWM Module (S08TPMV3)
the TPM counter is a free-running counter then the update is made when the TPM counter changes
from 0xFFFE to 0xFFFF.
16.4.2.4
Center-Aligned PWM Mode
This type of PWM output uses the up/down counting mode of the timer counter (CPWMS=1). The output
compare value in TPMxCnVH:TPMxCnVL determines the pulse width (duty cycle) of the PWM signal
while the period is determined by the value in TPMxMODH:TPMxMODL. TPMxMODH:TPMxMODL
should be kept in the range of 0x0001 to 0x7FFF because values outside this range can produce ambiguous
results. ELSnA will determine the polarity of the CPWM output.
pulse width = 2 x (TPMxCnVH:TPMxCnVL)
period = 2 x (TPMxMODH:TPMxMODL); TPMxMODH:TPMxMODL=0x0001-0x7FFF
If the channel-value register TPMxCnVH:TPMxCnVL is zero or negative (bit 15 set), the duty cycle will
be 0%. If TPMxCnVH:TPMxCnVL is a positive value (bit 15 clear) and is greater than the (non-zero)
modulus setting, the duty cycle will be 100% because the duty cycle compare will never occur. This
implies the usable range of periods set by the modulus register is 0x0001 through 0x7FFE (0x7FFF if you
do not need to generate 100% duty cycle). This is not a significant limitation. The resulting period would
be much longer than required for normal applications.
TPMxMODH:TPMxMODL=0x0000 is a special case that should not be used with center-aligned PWM
mode. When CPWMS=0, this case corresponds to the counter running free from 0x0000 through 0xFFFF,
but when CPWMS=1 the counter needs a valid match to the modulus register somewhere other than at
0x0000 in order to change directions from up-counting to down-counting.
The output compare value in the TPM channel registers (times 2) determines the pulse width (duty cycle)
of the CPWM signal (Figure 16-16). If ELSnA=0, a compare occurred while counting up forces the
CPWM output signal low and a compare occurred while counting down forces the output high. The
counter counts up until it reaches the modulo setting in TPMxMODH:TPMxMODL, then counts down
until it reaches zero. This sets the period equal to two times TPMxMODH:TPMxMODL.
COUNT= 0
OUTPUT
COUNT=
COMPARE
TPMxMODH:TPMxMODL (COUNT DOWN)
OUTPUT
COMPARE
(COUNT UP)
COUNT=
TPMxMODH:TPMxMODL
TPMxCHn
PULSE WIDTH
2 x TPMxCnVH:TPMxCnVL
PERIOD
2 x TPMxMODH:TPMxMODL
Figure 16-16. CPWM Period and Pulse Width (ELSnA=0)
Center-aligned PWM outputs typically produce less noise than edge-aligned PWMs because fewer I/O pin
transitions are lined up at the same system clock edge. This type of PWM is also required for some types
of motor drives.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
339
Chapter 16 Timer/PWM Module (S08TPMV3)
Input capture, output compare, and edge-aligned PWM functions do not make sense when the counter is
operating in up/down counting mode so this implies that all active channels within a TPM must be used in
CPWM mode when CPWMS=1.
The TPM may be used in an 8-bit MCU. The settings in the timer channel registers are buffered to ensure
coherent 16-bit updates and to avoid unexpected PWM pulse widths. Writes to any of the registers
TPMxMODH, TPMxMODL, TPMxCnVH, and TPMxCnVL, actually write to buffer registers.
In center-aligned PWM mode, the TPMxCnVH:L registers are updated with the value of their write buffer
according to the value of CLKSB:CLKSA bits, so:
• If (CLKSB:CLKSA = 0:0), the registers are updated when the second byte is written
• If (CLKSB:CLKSA not = 0:0), the registers are updated after the both bytes were written, and the
TPM counter changes from (TPMxMODH:TPMxMODL - 1) to (TPMxMODH:TPMxMODL). If
the TPM counter is a free-running counter, the update is made when the TPM counter changes from
0xFFFE to 0xFFFF.
When TPMxCNTH:TPMxCNTL=TPMxMODH:TPMxMODL, the TPM can optionally generate a TOF
interrupt (at the end of this count).
Writing to TPMxSC cancels any values written to TPMxMODH and/or TPMxMODL and resets the
coherency mechanism for the modulo registers. Writing to TPMxCnSC cancels any values written to the
channel value registers and resets the coherency mechanism for TPMxCnVH:TPMxCnVL.
16.5
16.5.1
Reset Overview
General
The TPM is reset whenever any MCU reset occurs.
16.5.2
Description of Reset Operation
Reset clears the TPMxSC register which disables clocks to the TPM and disables timer overflow interrupts
(TOIE=0). CPWMS, MSnB, MSnA, ELSnB, and ELSnA are all cleared which configures all TPM
channels for input-capture operation with the associated pins disconnected from I/O pin logic (so all MCU
pins related to the TPM revert to general purpose I/O pins).
16.6
16.6.1
Interrupts
General
The TPM generates an optional interrupt for the main counter overflow and an interrupt for each channel.
The meaning of channel interrupts depends on each channel’s mode of operation. If the channel is
configured for input capture, the interrupt flag is set each time the selected input capture edge is
recognized. If the channel is configured for output compare or PWM modes, the interrupt flag is set each
time the main timer counter matches the value in the 16-bit channel value register.
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Chapter 16 Timer/PWM Module (S08TPMV3)
All TPM interrupts are listed in Table 16-8 which shows the interrupt name, the name of any local enable
that can block the interrupt request from leaving the TPM and getting recognized by the separate interrupt
processing logic.
Table 16-8. Interrupt Summary
Interrupt
Local
Enable
Source
Description
TOF
TOIE
Counter overflow
Set each time the timer counter reaches its terminal
count (at transition to next count value which is
usually 0x0000)
CHnF
CHnIE
Channel event
An input capture or output compare event took
place on channel n
The TPM module will provide a high-true interrupt signal. Vectors and priorities are determined at chip
integration time in the interrupt module so refer to the user’s guide for the interrupt module or to the chip’s
complete documentation for details.
16.6.2
Description of Interrupt Operation
For each interrupt source in the TPM, a flag bit is set upon recognition of the interrupt condition such as
timer overflow, channel-input capture, or output-compare events. This flag may be read (polled) by
software to determine that the action has occurred, or an associated enable bit (TOIE or CHnIE) can be set
to enable hardware interrupt generation. While the interrupt enable bit is set, a static interrupt will generate
whenever the associated interrupt flag equals one. The user’s software must perform a sequence of steps
to clear the interrupt flag before returning from the interrupt-service routine.
TPM interrupt flags are cleared by a two-step process including a read of the flag bit while it is set (1)
followed by a write of zero (0) to the bit. If a new event is detected between these two steps, the sequence
is reset and the interrupt flag remains set after the second step to avoid the possibility of missing the new
event.
16.6.2.1
Timer Overflow Interrupt (TOF) Description
The meaning and details of operation for TOF interrupts varies slightly depending upon the mode of
operation of the TPM system (general purpose timing functions versus center-aligned PWM operation).
The flag is cleared by the two step sequence described above.
16.6.2.1.1
Normal Case
Normally TOF is set when the timer counter changes from 0xFFFF to 0x0000. When the TPM is not
configured for center-aligned PWM (CPWMS=0), TOF gets set when the timer counter changes from the
terminal count (the value in the modulo register) to 0x0000. This case corresponds to the normal meaning
of counter overflow.
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Chapter 16 Timer/PWM Module (S08TPMV3)
16.6.2.1.2
Center-Aligned PWM Case
When CPWMS=1, TOF gets set when the timer counter changes direction from up-counting to
down-counting at the end of the terminal count (the value in the modulo register). In this case the TOF
corresponds to the end of a PWM period.
16.6.2.2
Channel Event Interrupt Description
The meaning of channel interrupts depends on the channel’s current mode (input-capture, output-compare,
edge-aligned PWM, or center-aligned PWM).
16.6.2.2.1
Input Capture Events
When a channel is configured as an input capture channel, the ELSnB:ELSnA control bits select no edge
(off), rising edges, falling edges or any edge as the edge which triggers an input capture event. When the
selected edge is detected, the interrupt flag is set. The flag is cleared by the two-step sequence described
in Section 16.6.2, “Description of Interrupt Operation.”
16.6.2.2.2
Output Compare Events
When a channel is configured as an output compare channel, the interrupt flag is set each time the main
timer counter matches the 16-bit value in the channel value register. The flag is cleared by the two-step
sequence described Section 16.6.2, “Description of Interrupt Operation.”
16.6.2.2.3
PWM End-of-Duty-Cycle Events
For channels configured for PWM operation there are two possibilities. When the channel is configured
for edge-aligned PWM, the channel flag gets set when the timer counter matches the channel value register
which marks the end of the active duty cycle period. When the channel is configured for center-aligned
PWM, the timer count matches the channel value register twice during each PWM cycle. In this CPWM
case, the channel flag is set at the start and at the end of the active duty cycle period which are the times
when the timer counter matches the channel value register. The flag is cleared by the two-step sequence
described Section 16.6.2, “Description of Interrupt Operation.”
16.7
The Differences from TPM v2 to TPM v3
1. Write to TPMxCNTH:L registers (Section 16.3.2, “TPM-Counter Registers
(TPMxCNTH:TPMxCNTL)) [SE110-TPM case 7]
Any write to TPMxCNTH or TPMxCNTL registers in TPM v3 clears the TPM counter
(TPMxCNTH:L) and the prescaler counter. Instead, in the TPM v2 only the TPM counter is cleared
in this case.
2. Read of TPMxCNTH:L registers (Section 16.3.2, “TPM-Counter Registers
(TPMxCNTH:TPMxCNTL))
— In TPM v3, any read of TPMxCNTH:L registers during BDM mode returns the value of the
TPM counter that is frozen. In TPM v2, if only one byte of the TPMxCNTH:L registers was
read before the BDM mode became active, then any read of TPMxCNTH:L registers during
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Chapter 16 Timer/PWM Module (S08TPMV3)
BDM mode returns the latched value of TPMxCNTH:L from the read buffer instead of the
frozen TPM counter value.
— This read coherency mechanism is cleared in TPM v3 in BDM mode if there is a write to
TPMxSC, TPMxCNTH or TPMxCNTL. Instead, in these conditions the TPM v2 does not clear
this read coherency mechanism.
3. Read of TPMxCnVH:L registers (Section 16.3.5, “TPM Channel Value Registers
(TPMxCnVH:TPMxCnVL))
— In TPM v3, any read of TPMxCnVH:L registers during BDM mode returns the value of the
TPMxCnVH:L register. In TPM v2, if only one byte of the TPMxCnVH:L registers was read
before the BDM mode became active, then any read of TPMxCnVH:L registers during BDM
mode returns the latched value of TPMxCNTH:L from the read buffer instead of the value in
the TPMxCnVH:L registers.
— This read coherency mechanism is cleared in TPM v3 in BDM mode if there is a write to
TPMxCnSC. Instead, in this condition the TPM v2 does not clear this read coherency
mechanism.
4. Write to TPMxCnVH:L registers
— Input Capture Mode (Section 16.4.2.1, “Input Capture Mode)
In this mode the TPM v3 does not allow the writes to TPMxCnVH:L registers. Instead, the
TPM v2 allows these writes.
— Output Compare Mode (Section 16.4.2.2, “Output Compare Mode)
In this mode and if (CLKSB:CLKSA not = 0:0), the TPM v3 updates the TPMxCnVH:L
registers with the value of their write buffer at the next change of the TPM counter (end of the
prescaler counting) after the second byte is written. Instead, the TPM v2 always updates these
registers when their second byte is written.
The following procedure can be used in the TPM v3 to verify if the TPMxCnVH:L registers
were updated with the new value that was written to these registers (value in their write buffer).
...
write the new value to TPMxCnVH:L;
read TPMxCnVH and TPMxCnVL registers;
while (the read value of TPMxCnVH:L is different from the new value written to
TPMxCnVH:L)
begin
read again TPMxCnVH and TPMxCnVL;
end
...
In this point, the TPMxCnVH:L registers were updated, so the program can continue and, for
example, write to TPMxC0SC without cancelling the previous write to TPMxCnVH:L
registers.
— Edge-Aligned PWM (Section 16.4.2.3, “Edge-Aligned PWM Mode)
In this mode and if (CLKSB:CLKSA not = 00), the TPM v3 updates the TPMxCnVH:L
registers with the value of their write buffer after that the both bytes were written and when the
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Chapter 16 Timer/PWM Module (S08TPMV3)
TPM counter changes from (TPMxMODH:L - 1) to (TPMxMODH:L). If the TPM counter is
a free-running counter, then this update is made when the TPM counter changes from $FFFE
to $FFFF. Instead, the TPM v2 makes this update after that the both bytes were written and
when the TPM counter changes from TPMxMODH:L to $0000.
— Center-Aligned PWM (Section 16.4.2.4, “Center-Aligned PWM Mode)
In this mode and if (CLKSB:CLKSA not = 00), the TPM v3 updates the TPMxCnVH:L
registers with the value of their write buffer after that the both bytes were written and when the
TPM counter changes from (TPMxMODH:L - 1) to (TPMxMODH:L). If the TPM counter is
a free-running counter, then this update is made when the TPM counter changes from $FFFE
to $FFFF. Instead, the TPM v2 makes this update after that the both bytes were written and
when the TPM counter changes from TPMxMODH:L to (TPMxMODH:L - 1).
5. Center-Aligned PWM (Section 16.4.2.4, “Center-Aligned PWM Mode)
— TPMxCnVH:L = TPMxMODH:L [SE110-TPM case 1]
In this case, the TPM v3 produces 100% duty cycle. Instead, the TPM v2 produces 0% duty
cycle.
— TPMxCnVH:L = (TPMxMODH:L - 1) [SE110-TPM case 2]
In this case, the TPM v3 produces almost 100% duty cycle. Instead, the TPM v2 produces 0%
duty cycle.
— TPMxCnVH:L is changed from 0x0000 to a non-zero value [SE110-TPM case 3 and 5]
In this case, the TPM v3 waits for the start of a new PWM period to begin using the new duty
cycle setting. Instead, the TPM v2 changes the channel output at the middle of the current
PWM period (when the count reaches 0x0000).
— TPMxCnVH:L is changed from a non-zero value to 0x0000 [SE110-TPM case 4]
In this case, the TPM v3 finishes the current PWM period using the old duty cycle setting.
Instead, the TPM v2 finishes the current PWM period using the new duty cycle setting.
6. Write to TPMxMODH:L registers in BDM mode (Section 16.3.3, “TPM Counter Modulo
Registers (TPMxMODH:TPMxMODL))
In the TPM v3 a write to TPMxSC register in BDM mode clears the write coherency mechanism
of TPMxMODH:L registers. Instead, in the TPM v2 this coherency mechanism is not cleared when
there is a write to TPMxSC register.
7. Update of EPWM signal when CLKSB:CLKSA = 00
In the TPM v3 if CLKSB:CLKSA = 00, then the EPWM signal in the channel output is not update
(it is frozen while CLKSB:CLKSA = 00). Instead, in the TPM v2 the EPWM signal is updated at
the next rising edge of bus clock after a write to TPMxCnSC register.
The Figure 0-1 and Figure 0-2 show when the EPWM signals generated by TPM v2 and TPM v3
after the reset (CLKSB:CLKSA = 00) and if there is a write to TPMxCnSC register.
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Chapter 16 Timer/PWM Module (S08TPMV3)
EPWM mode
TPMxMODH:TPMxMODL = 0x0007
TPMxCnVH:TPMxCnVL = 0x0005
RESET (active low)
BUS CLOCK
TPMxCNTH:TPMxCNTL
0
1
2
3 4
5
00
CLKSB:CLKSA BITS
6
7
0 1
2 ...
01
MSnB:MSnA BITS
00
10
ELSnB:ELSnA BITS
00
10
TPMv2 TPMxCHn
TPMv3 TPMxCHn
CHnF BIT
(in TPMv2 and TPMv3)
Figure 0-1. Generation of high-true EPWM signal by TPM v2 and v3 after the reset
EPWM mode
TPMxMODH:TPMxMODL = 0x0007
TPMxCnVH:TPMxCnVL = 0x0005
RESET (active low)
BUS CLOCK
TPMxCNTH:TPMxCNTL
0
1
3 4
5
6
7
0 1
2 ...
01
00
CLKSB:CLKSA BITS
2
MSnB:MSnA BITS
00
10
ELSnB:ELSnA BITS
00
01
TPMv2 TPMxCHn
TPMv3 TPMxCHn
CHnF BIT
(in TPMv2 and TPMv3)
Figure 0-2. Generation of low-true EPWM signal by TPM v2 and v3 after the reset
The following procedure can be used in TPM v3 (when the channel pin is also a port pin) to emulate
the high-true EPWM generated by TPM v2 after the reset.
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...
configure the channel pin as output port pin and set the output pin;
configure the channel to generate the EPWM signal but keep ELSnB:ELSnA as 00;
configure the other registers (TPMxMODH, TPMxMODL, TPMxCnVH, TPMxCnVL, ...);
configure CLKSB:CLKSA bits (TPM v3 starts to generate the high-true EPWM signal, however
TPM does not control the channel pin, so the EPWM signal is not available);
wait until the TOF is set (or use the TOF interrupt);
enable the channel output by configuring ELSnB:ELSnA bits (now EPWM signal is available);
...
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Chapter 17
Development Support
17.1
Introduction
Development support systems in the HCS08 include the background debug controller (BDC) and the
on-chip debug module (DBG). The BDC provides a single-wire debug interface to the target MCU that
provides a convenient interface for programming the on-chip Flash and other nonvolatile memories. The
BDC is also the primary debug interface for development and allows non-intrusive access to memory data
and traditional debug features such as CPU register modify, breakpoints, and single instruction trace
commands.
In the HCS08 Family, address and data bus signals are not available on external pins (not even in test
modes). Debug is done through commands fed into the target MCU via the single-wire background debug
interface. The debug module provides a means to selectively trigger and capture bus information so an
external development system can reconstruct what happened inside the MCU on a cycle-by-cycle basis
without having external access to the address and data signals.
17.1.1
Forcing Active Background
The method for forcing active background mode depends on the specific HCS08 derivative. For the
MC9S08DZ60, you can force active background after a power-on reset by holding the BKGD pin low as
the device exits the reset condition. You can also force active background by driving BKGD low
immediately after a serial background command that writes a one to the BDFR bit in the SBDFR register.
If no debug pod is connected to the BKGD pin, the MCU will always reset into normal operating mode.
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17.1.2
Features
Features of the BDC module include:
• Single pin for mode selection and background communications
• BDC registers are not located in the memory map
• SYNC command to determine target communications rate
• Non-intrusive commands for memory access
• Active background mode commands for CPU register access
• GO and TRACE1 commands
• BACKGROUND command can wake CPU from stop or wait modes
• One hardware address breakpoint built into BDC
• Oscillator runs in stop mode, if BDC enabled
• COP watchdog disabled while in active background mode
Features of the ICE system include:
•
•
•
•
17.2
Two trigger comparators: Two address + read/write (R/W) or one full address + data + R/W
Flexible 8-word by 16-bit FIFO (first-in, first-out) buffer for capture information:
— Change-of-flow addresses or
— Event-only data
Two types of breakpoints:
— Tag breakpoints for instruction opcodes
— Force breakpoints for any address access
Nine trigger modes:
— Basic: A-only, A OR B
— Sequence: A then B
— Full: A AND B data, A AND NOT B data
— Event (store data): Event-only B, A then event-only B
— Range: Inside range (A ≤ address ≤ B), outside range (address < A or address > B)
Background Debug Controller (BDC)
All MCUs in the HCS08 Family contain a single-wire background debug interface that supports in-circuit
programming of on-chip nonvolatile memory and sophisticated non-intrusive debug capabilities. Unlike
debug interfaces on earlier 8-bit MCUs, this system does not interfere with normal application resources.
It does not use any user memory or locations in the memory map and does not share any on-chip
peripherals.
BDC commands are divided into two groups:
• Active background mode commands require that the target MCU is in active background mode (the
user program is not running). Active background mode commands allow the CPU registers to be
read or written, and allow the user to trace one user instruction at a time, or GO to the user program
from active background mode.
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Chapter 17 Development Support
•
Non-intrusive commands can be executed at any time even while the user’s program is running.
Non-intrusive commands allow a user to read or write MCU memory locations or access status and
control registers within the background debug controller.
Typically, a relatively simple interface pod is used to translate commands from a host computer into
commands for the custom serial interface to the single-wire background debug system. Depending on the
development tool vendor, this interface pod may use a standard RS-232 serial port, a parallel printer port,
or some other type of communications such as a universal serial bus (USB) to communicate between the
host PC and the pod. The pod typically connects to the target system with ground, the BKGD pin, RESET,
and sometimes VDD. An open-drain connection to reset allows the host to force a target system reset,
which is useful to regain control of a lost target system or to control startup of a target system before the
on-chip nonvolatile memory has been programmed. Sometimes VDD can be used to allow the pod to use
power from the target system to avoid the need for a separate power supply. However, if the pod is powered
separately, it can be connected to a running target system without forcing a target system reset or otherwise
disturbing the running application program.
BKGD 1
2 GND
NO CONNECT 3
4 RESET
NO CONNECT 5
6 VDD
Figure 17-1. BDM Tool Connector
17.2.1
BKGD Pin Description
BKGD is the single-wire background debug interface pin. The primary function of this pin is for
bidirectional serial communication of active background mode commands and data. During reset, this pin
is used to select between starting in active background mode or starting the user’s application program.
This pin is also used to request a timed sync response pulse to allow a host development tool to determine
the correct clock frequency for background debug serial communications.
BDC serial communications use a custom serial protocol first introduced on the M68HC12 Family of
microcontrollers. This protocol assumes the host knows the communication clock rate that is determined
by the target BDC clock rate. All communication is initiated and controlled by the host that drives a
high-to-low edge to signal the beginning of each bit time. Commands and data are sent most significant bit
first (MSB first). For a detailed description of the communications protocol, refer to Section 17.2.2,
“Communication Details.”
If a host is attempting to communicate with a target MCU that has an unknown BDC clock rate, a SYNC
command may be sent to the target MCU to request a timed sync response signal from which the host can
determine the correct communication speed.
BKGD is a pseudo-open-drain pin and there is an on-chip pullup so no external pullup resistor is required.
Unlike typical open-drain pins, the external RC time constant on this pin, which is influenced by external
capacitance, plays almost no role in signal rise time. The custom protocol provides for brief, actively
driven speedup pulses to force rapid rise times on this pin without risking harmful drive level conflicts.
Refer to Section 17.2.2, “Communication Details,” for more detail.
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When no debugger pod is connected to the 6-pin BDM interface connector, the internal pullup on BKGD
chooses normal operating mode. When a debug pod is connected to BKGD it is possible to force the MCU
into active background mode after reset. The specific conditions for forcing active background depend
upon the HCS08 derivative (refer to the introduction to this Development Support section). It is not
necessary to reset the target MCU to communicate with it through the background debug interface.
17.2.2
Communication Details
The BDC serial interface requires the external controller to generate a falling edge on the BKGD pin to
indicate the start of each bit time. The external controller provides this falling edge whether data is
transmitted or received.
BKGD is a pseudo-open-drain pin that can be driven either by an external controller or by the MCU. Data
is transferred MSB first at 16 BDC clock cycles per bit (nominal speed). The interface times out if
512 BDC clock cycles occur between falling edges from the host. Any BDC command that was in progress
when this timeout occurs is aborted without affecting the memory or operating mode of the target MCU
system.
The custom serial protocol requires the debug pod to know the target BDC communication clock speed.
The clock switch (CLKSW) control bit in the BDC status and control register allows the user to select the
BDC clock source. The BDC clock source can either be the bus or the alternate BDC clock source.
The BKGD pin can receive a high or low level or transmit a high or low level. The following diagrams
show timing for each of these cases. Interface timing is synchronous to clocks in the target BDC, but
asynchronous to the external host. The internal BDC clock signal is shown for reference in counting cycles.
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Figure 17-2 shows an external host transmitting a logic 1 or 0 to the BKGD pin of a target HCS08 MCU.
The host is asynchronous to the target so there is a 0-to-1 cycle delay from the host-generated falling edge
to where the target perceives the beginning of the bit time. Ten target BDC clock cycles later, the target
senses the bit level on the BKGD pin. Typically, the host actively drives the pseudo-open-drain BKGD pin
during host-to-target transmissions to speed up rising edges. Because the target does not drive the BKGD
pin during the host-to-target transmission period, there is no need to treat the line as an open-drain signal
during this period.
BDC CLOCK
(TARGET MCU)
HOST
TRANSMIT 1
HOST
TRANSMIT 0
10 CYCLES
SYNCHRONIZATION
UNCERTAINTY
EARLIEST START
OF NEXT BIT
TARGET SENSES BIT LEVEL
PERCEIVED START
OF BIT TIME
Figure 17-2. BDC Host-to-Target Serial Bit Timing
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Figure 17-3 shows the host receiving a logic 1 from the target HCS08 MCU. Because the host is
asynchronous to the target MCU, there is a 0-to-1 cycle delay from the host-generated falling edge on
BKGD to the perceived start of the bit time in the target MCU. The host holds the BKGD pin low long
enough for the target to recognize it (at least two target BDC cycles). The host must release the low drive
before the target MCU drives a brief active-high speedup pulse seven cycles after the perceived start of the
bit time. The host should sample the bit level about 10 cycles after it started the bit time.
BDC CLOCK
(TARGET MCU)
HOST DRIVE
TO BKGD PIN
HIGH-IMPEDANCE
TARGET MCU
SPEEDUP PULSE
HIGH-IMPEDANCE
HIGH-IMPEDANCE
PERCEIVED START
OF BIT TIME
R-C RISE
BKGD PIN
10 CYCLES
10 CYCLES
EARLIEST START
OF NEXT BIT
HOST SAMPLES BKGD PIN
Figure 17-3. BDC Target-to-Host Serial Bit Timing (Logic 1)
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Chapter 17 Development Support
Figure 17-4 shows the host receiving a logic 0 from the target HCS08 MCU. Because the host is
asynchronous to the target MCU, there is a 0-to-1 cycle delay from the host-generated falling edge on
BKGD to the start of the bit time as perceived by the target MCU. The host initiates the bit time but the
target HCS08 finishes it. Because the target wants the host to receive a logic 0, it drives the BKGD pin low
for 13 BDC clock cycles, then briefly drives it high to speed up the rising edge. The host samples the bit
level about 10 cycles after starting the bit time.
BDC CLOCK
(TARGET MCU)
HOST DRIVE
TO BKGD PIN
HIGH-IMPEDANCE
SPEEDUP
PULSE
TARGET MCU
DRIVE AND
SPEED-UP PULSE
PERCEIVED START
OF BIT TIME
BKGD PIN
10 CYCLES
10 CYCLES
EARLIEST START
OF NEXT BIT
HOST SAMPLES BKGD PIN
Figure 17-4. BDM Target-to-Host Serial Bit Timing (Logic 0)
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Chapter 17 Development Support
17.2.3
BDC Commands
BDC commands are sent serially from a host computer to the BKGD pin of the target HCS08 MCU. All
commands and data are sent MSB-first using a custom BDC communications protocol. Active background
mode commands require that the target MCU is currently in the active background mode while
non-intrusive commands may be issued at any time whether the target MCU is in active background mode
or running a user application program.
Table 17-1 shows all HCS08 BDC commands, a shorthand description of their coding structure, and the
meaning of each command.
Coding Structure Nomenclature
This nomenclature is used in Table 17-1 to describe the coding structure of the BDC commands.
Commands begin with an 8-bit hexadecimal command code in the host-to-target
direction (most significant bit first)
/ = separates parts of the command
d = delay 16 target BDC clock cycles
AAAA = a 16-bit address in the host-to-target direction
RD = 8 bits of read data in the target-to-host direction
WD = 8 bits of write data in the host-to-target direction
RD16 = 16 bits of read data in the target-to-host direction
WD16 = 16 bits of write data in the host-to-target direction
SS = the contents of BDCSCR in the target-to-host direction (STATUS)
CC = 8 bits of write data for BDCSCR in the host-to-target direction (CONTROL)
RBKP = 16 bits of read data in the target-to-host direction (from BDCBKPT breakpoint
register)
WBKP = 16 bits of write data in the host-to-target direction (for BDCBKPT breakpoint register)
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Chapter 17 Development Support
Table 17-1. BDC Command Summary
Command
Mnemonic
1
Active BDM/
Non-intrusive
Coding
Structure
Description
SYNC
Non-intrusive
n/a1
Request a timed reference pulse to determine
target BDC communication speed
ACK_ENABLE
Non-intrusive
D5/d
Enable acknowledge protocol. Refer to
Freescale document order no. HCS08RMv1/D.
ACK_DISABLE
Non-intrusive
D6/d
Disable acknowledge protocol. Refer to
Freescale document order no. HCS08RMv1/D.
BACKGROUND
Non-intrusive
90/d
Enter active background mode if enabled
(ignore if ENBDM bit equals 0)
READ_STATUS
Non-intrusive
E4/SS
Read BDC status from BDCSCR
WRITE_CONTROL
Non-intrusive
C4/CC
Write BDC controls in BDCSCR
READ_BYTE
Non-intrusive
E0/AAAA/d/RD
Read a byte from target memory
READ_BYTE_WS
Non-intrusive
E1/AAAA/d/SS/RD
Read a byte and report status
READ_LAST
Non-intrusive
E8/SS/RD
Re-read byte from address just read and
report status
WRITE_BYTE
Non-intrusive
C0/AAAA/WD/d
Write a byte to target memory
WRITE_BYTE_WS
Non-intrusive
C1/AAAA/WD/d/SS
Write a byte and report status
READ_BKPT
Non-intrusive
E2/RBKP
Read BDCBKPT breakpoint register
WRITE_BKPT
Non-intrusive
C2/WBKP
Write BDCBKPT breakpoint register
GO
Active BDM
08/d
Go to execute the user application program
starting at the address currently in the PC
TRACE1
Active BDM
10/d
Trace 1 user instruction at the address in the
PC, then return to active background mode
TAGGO
Active BDM
18/d
Same as GO but enable external tagging
(HCS08 devices have no external tagging pin)
READ_A
Active BDM
68/d/RD
Read accumulator (A)
READ_CCR
Active BDM
69/d/RD
Read condition code register (CCR)
READ_PC
Active BDM
6B/d/RD16
Read program counter (PC)
READ_HX
Active BDM
6C/d/RD16
Read H and X register pair (H:X)
READ_SP
Active BDM
6F/d/RD16
Read stack pointer (SP)
READ_NEXT
Active BDM
70/d/RD
Increment H:X by one then read memory byte
located at H:X
READ_NEXT_WS
Active BDM
71/d/SS/RD
Increment H:X by one then read memory byte
located at H:X. Report status and data.
WRITE_A
Active BDM
48/WD/d
Write accumulator (A)
WRITE_CCR
Active BDM
49/WD/d
Write condition code register (CCR)
WRITE_PC
Active BDM
4B/WD16/d
Write program counter (PC)
WRITE_HX
Active BDM
4C/WD16/d
Write H and X register pair (H:X)
WRITE_SP
Active BDM
4F/WD16/d
Write stack pointer (SP)
WRITE_NEXT
Active BDM
50/WD/d
Increment H:X by one, then write memory byte
located at H:X
WRITE_NEXT_WS
Active BDM
51/WD/d/SS
Increment H:X by one, then write memory byte
located at H:X. Also report status.
The SYNC command is a special operation that does not have a command code.
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The SYNC command is unlike other BDC commands because the host does not necessarily know the
correct communications speed to use for BDC communications until after it has analyzed the response to
the SYNC command.
To issue a SYNC command, the host:
• Drives the BKGD pin low for at least 128 cycles of the slowest possible BDC clock (The slowest
clock is normally the reference oscillator/64 or the self-clocked rate/64.)
• Drives BKGD high for a brief speedup pulse to get a fast rise time (This speedup pulse is typically
one cycle of the fastest clock in the system.)
• Removes all drive to the BKGD pin so it reverts to high impedance
• Monitors the BKGD pin for the sync response pulse
The target, upon detecting the SYNC request from the host (which is a much longer low time than would
ever occur during normal BDC communications):
• Waits for BKGD to return to a logic high
• Delays 16 cycles to allow the host to stop driving the high speedup pulse
• Drives BKGD low for 128 BDC clock cycles
• Drives a 1-cycle high speedup pulse to force a fast rise time on BKGD
• Removes all drive to the BKGD pin so it reverts to high impedance
The host measures the low time of this 128-cycle sync response pulse and determines the correct speed for
subsequent BDC communications. Typically, the host can determine the correct communication speed
within a few percent of the actual target speed and the communication protocol can easily tolerate speed
errors of several percent.
17.2.4
BDC Hardware Breakpoint
The BDC includes one relatively simple hardware breakpoint that compares the CPU address bus to a
16-bit match value in the BDCBKPT register. This breakpoint can generate a forced breakpoint or a tagged
breakpoint. A forced breakpoint causes the CPU to enter active background mode at the first instruction
boundary following any access to the breakpoint address. The tagged breakpoint causes the instruction
opcode at the breakpoint address to be tagged so that the CPU will enter active background mode rather
than executing that instruction if and when it reaches the end of the instruction queue. This implies that
tagged breakpoints can only be placed at the address of an instruction opcode while forced breakpoints can
be set at any address.
The breakpoint enable (BKPTEN) control bit in the BDC status and control register (BDCSCR) is used to
enable the breakpoint logic (BKPTEN = 1). When BKPTEN = 0, its default value after reset, the
breakpoint logic is disabled and no BDC breakpoints are requested regardless of the values in other BDC
breakpoint registers and control bits. The force/tag select (FTS) control bit in BDCSCR is used to select
forced (FTS = 1) or tagged (FTS = 0) type breakpoints.
The on-chip debug module (DBG) includes circuitry for two additional hardware breakpoints that are more
flexible than the simple breakpoint in the BDC module.
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17.3
On-Chip Debug System (DBG)
Because HCS08 devices do not have external address and data buses, the most important functions of an
in-circuit emulator have been built onto the chip with the MCU. The debug system consists of an 8-stage
FIFO that can store address or data bus information, and a flexible trigger system to decide when to capture
bus information and what information to capture. The system relies on the single-wire background debug
system to access debug control registers and to read results out of the eight stage FIFO.
The debug module includes control and status registers that are accessible in the user’s memory map.
These registers are located in the high register space to avoid using valuable direct page memory space.
Most of the debug module’s functions are used during development, and user programs rarely access any
of the control and status registers for the debug module. The one exception is that the debug system can
provide the means to implement a form of ROM patching. This topic is discussed in greater detail in
Section 17.3.6, “Hardware Breakpoints.”
17.3.1
Comparators A and B
Two 16-bit comparators (A and B) can optionally be qualified with the R/W signal and an opcode tracking
circuit. Separate control bits allow you to ignore R/W for each comparator. The opcode tracking circuitry
optionally allows you to specify that a trigger will occur only if the opcode at the specified address is
actually executed as opposed to only being read from memory into the instruction queue. The comparators
are also capable of magnitude comparisons to support the inside range and outside range trigger modes.
Comparators are disabled temporarily during all BDC accesses.
The A comparator is always associated with the 16-bit CPU address. The B comparator compares to the
CPU address or the 8-bit CPU data bus, depending on the trigger mode selected. Because the CPU data
bus is separated into a read data bus and a write data bus, the RWAEN and RWA control bits have an
additional purpose, in full address plus data comparisons they are used to decide which of these buses to
use in the comparator B data bus comparisons. If RWAEN = 1 (enabled) and RWA = 0 (write), the CPU’s
write data bus is used. Otherwise, the CPU’s read data bus is used.
The currently selected trigger mode determines what the debugger logic does when a comparator detects
a qualified match condition. A match can cause:
• Generation of a breakpoint to the CPU
• Storage of data bus values into the FIFO
• Starting to store change-of-flow addresses into the FIFO (begin type trace)
• Stopping the storage of change-of-flow addresses into the FIFO (end type trace)
17.3.2
Bus Capture Information and FIFO Operation
The usual way to use the FIFO is to setup the trigger mode and other control options, then arm the
debugger. When the FIFO has filled or the debugger has stopped storing data into the FIFO, you would
read the information out of it in the order it was stored into the FIFO. Status bits indicate the number of
words of valid information that are in the FIFO as data is stored into it. If a trace run is manually halted by
writing 0 to ARM before the FIFO is full (CNT = 1:0:0:0), the information is shifted by one position and
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the host must perform ((8 – CNT) – 1) dummy reads of the FIFO to advance it to the first significant entry
in the FIFO.
In most trigger modes, the information stored in the FIFO consists of 16-bit change-of-flow addresses. In
these cases, read DBGFH then DBGFL to get one coherent word of information out of the FIFO. Reading
DBGFL (the low-order byte of the FIFO data port) causes the FIFO to shift so the next word of information
is available at the FIFO data port. In the event-only trigger modes (see Section 17.3.5, “Trigger Modes”),
8-bit data information is stored into the FIFO. In these cases, the high-order half of the FIFO (DBGFH) is
not used and data is read out of the FIFO by simply reading DBGFL. Each time DBGFL is read, the FIFO
is shifted so the next data value is available through the FIFO data port at DBGFL.
In trigger modes where the FIFO is storing change-of-flow addresses, there is a delay between CPU
addresses and the input side of the FIFO. Because of this delay, if the trigger event itself is a change-of-flow
address or a change-of-flow address appears during the next two bus cycles after a trigger event starts the
FIFO, it will not be saved into the FIFO. In the case of an end-trace, if the trigger event is a change-of-flow,
it will be saved as the last change-of-flow entry for that debug run.
The FIFO can also be used to generate a profile of executed instruction addresses when the debugger is not
armed. When ARM = 0, reading DBGFL causes the address of the most-recently fetched opcode to be
saved in the FIFO. To use the profiling feature, a host debugger would read addresses out of the FIFO by
reading DBGFH then DBGFL at regular periodic intervals. The first eight values would be discarded
because they correspond to the eight DBGFL reads needed to initially fill the FIFO. Additional periodic
reads of DBGFH and DBGFL return delayed information about executed instructions so the host debugger
can develop a profile of executed instruction addresses.
17.3.3
Change-of-Flow Information
To minimize the amount of information stored in the FIFO, only information related to instructions that
cause a change to the normal sequential execution of instructions is stored. With knowledge of the source
and object code program stored in the target system, an external debugger system can reconstruct the path
of execution through many instructions from the change-of-flow information stored in the FIFO.
For conditional branch instructions where the branch is taken (branch condition was true), the source
address is stored (the address of the conditional branch opcode). Because BRA and BRN instructions are
not conditional, these events do not cause change-of-flow information to be stored in the FIFO.
Indirect JMP and JSR instructions use the current contents of the H:X index register pair to determine the
destination address, so the debug system stores the run-time destination address for any indirect JMP or
JSR. For interrupts, RTI, or RTS, the destination address is stored in the FIFO as change-of-flow
information.
17.3.4
Tag vs. Force Breakpoints and Triggers
Tagging is a term that refers to identifying an instruction opcode as it is fetched into the instruction queue,
but not taking any other action until and unless that instruction is actually executed by the CPU. This
distinction is important because any change-of-flow from a jump, branch, subroutine call, or interrupt
causes some instructions that have been fetched into the instruction queue to be thrown away without being
executed.
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A force-type breakpoint waits for the current instruction to finish and then acts upon the breakpoint
request. The usual action in response to a breakpoint is to go to active background mode rather than
continuing to the next instruction in the user application program.
The tag vs. force terminology is used in two contexts within the debug module. The first context refers to
breakpoint requests from the debug module to the CPU. The second refers to match signals from the
comparators to the debugger control logic. When a tag-type break request is sent to the CPU, a signal is
entered into the instruction queue along with the opcode so that if/when this opcode ever executes, the CPU
will effectively replace the tagged opcode with a BGND opcode so the CPU goes to active background
mode rather than executing the tagged instruction. When the TRGSEL control bit in the DBGT register is
set to select tag-type operation, the output from comparator A or B is qualified by a block of logic in the
debug module that tracks opcodes and only produces a trigger to the debugger if the opcode at the compare
address is actually executed. There is separate opcode tracking logic for each comparator so more than one
compare event can be tracked through the instruction queue at a time.
17.3.5
Trigger Modes
The trigger mode controls the overall behavior of a debug run. The 4-bit TRG field in the DBGT register
selects one of nine trigger modes. When TRGSEL = 1 in the DBGT register, the output of the comparator
must propagate through an opcode tracking circuit before triggering FIFO actions. The BEGIN bit in
DBGT chooses whether the FIFO begins storing data when the qualified trigger is detected (begin trace),
or the FIFO stores data in a circular fashion from the time it is armed until the qualified trigger is detected
(end trigger).
A debug run is started by writing a 1 to the ARM bit in the DBGC register, which sets the ARMF flag and
clears the AF and BF flags and the CNT bits in DBGS. A begin-trace debug run ends when the FIFO gets
full. An end-trace run ends when the selected trigger event occurs. Any debug run can be stopped manually
by writing a 0 to ARM or DBGEN in DBGC.
In all trigger modes except event-only modes, the FIFO stores change-of-flow addresses. In event-only
trigger modes, the FIFO stores data in the low-order eight bits of the FIFO.
The BEGIN control bit is ignored in event-only trigger modes and all such debug runs are begin type
traces. When TRGSEL = 1 to select opcode fetch triggers, it is not necessary to use R/W in comparisons
because opcode tags would only apply to opcode fetches that are always read cycles. It would also be
unusual to specify TRGSEL = 1 while using a full mode trigger because the opcode value is normally
known at a particular address.
The following trigger mode descriptions only state the primary comparator conditions that lead to a trigger.
Either comparator can usually be further qualified with R/W by setting RWAEN (RWBEN) and the
corresponding RWA (RWB) value to be matched against R/W. The signal from the comparator with
optional R/W qualification is used to request a CPU breakpoint if BRKEN = 1 and TAG determines
whether the CPU request will be a tag request or a force request.
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A-Only — Trigger when the address matches the value in comparator A
A OR B — Trigger when the address matches either the value in comparator A or the value in
comparator B
A Then B — Trigger when the address matches the value in comparator B but only after the address for
another cycle matched the value in comparator A. There can be any number of cycles after the A match
and before the B match.
A AND B Data (Full Mode) — This is called a full mode because address, data, and R/W (optionally)
must match within the same bus cycle to cause a trigger event. Comparator A checks address, the low byte
of comparator B checks data, and R/W is checked against RWA if RWAEN = 1. The high-order half of
comparator B is not used.
In full trigger modes it is not useful to specify a tag-type CPU breakpoint (BRKEN = TAG = 1), but if you
do, the comparator B data match is ignored for the purpose of issuing the tag request to the CPU and the
CPU breakpoint is issued when the comparator A address matches.
A AND NOT B Data (Full Mode) — Address must match comparator A, data must not match the low
half of comparator B, and R/W must match RWA if RWAEN = 1. All three conditions must be met within
the same bus cycle to cause a trigger.
In full trigger modes it is not useful to specify a tag-type CPU breakpoint (BRKEN = TAG = 1), but if you
do, the comparator B data match is ignored for the purpose of issuing the tag request to the CPU and the
CPU breakpoint is issued when the comparator A address matches.
Event-Only B (Store Data) — Trigger events occur each time the address matches the value in
comparator B. Trigger events cause the data to be captured into the FIFO. The debug run ends when the
FIFO becomes full.
A Then Event-Only B (Store Data) — After the address has matched the value in comparator A, a trigger
event occurs each time the address matches the value in comparator B. Trigger events cause the data to be
captured into the FIFO. The debug run ends when the FIFO becomes full.
Inside Range (A ≤ Address ≤ B) — A trigger occurs when the address is greater than or equal to the value
in comparator A and less than or equal to the value in comparator B at the same time.
Outside Range (Address < A or Address > B) — A trigger occurs when the address is either less than
the value in comparator A or greater than the value in comparator B.
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17.3.6
Hardware Breakpoints
The BRKEN control bit in the DBGC register may be set to 1 to allow any of the trigger conditions
described in Section 17.3.5, “Trigger Modes,” to be used to generate a hardware breakpoint request to the
CPU. TAG in DBGC controls whether the breakpoint request will be treated as a tag-type breakpoint or a
force-type breakpoint. A tag breakpoint causes the current opcode to be marked as it enters the instruction
queue. If a tagged opcode reaches the end of the pipe, the CPU executes a BGND instruction to go to active
background mode rather than executing the tagged opcode. A force-type breakpoint causes the CPU to
finish the current instruction and then go to active background mode.
If the background mode has not been enabled (ENBDM = 1) by a serial WRITE_CONTROL command
through the BKGD pin, the CPU will execute an SWI instruction instead of going to active background
mode.
17.4
Register Definition
This section contains the descriptions of the BDC and DBG registers and control bits.
Refer to the high-page register summary in the device overview chapter of this data sheet for the absolute
address assignments for all DBG registers. This section refers to registers and control bits only by their
names. A Freescale-provided equate or header file is used to translate these names into the appropriate
absolute addresses.
17.4.1
BDC Registers and Control Bits
The BDC has two registers:
• The BDC status and control register (BDCSCR) is an 8-bit register containing control and status
bits for the background debug controller.
• The BDC breakpoint match register (BDCBKPT) holds a 16-bit breakpoint match address.
These registers are accessed with dedicated serial BDC commands and are not located in the memory
space of the target MCU (so they do not have addresses and cannot be accessed by user programs).
Some of the bits in the BDCSCR have write limitations; otherwise, these registers may be read or written
at any time. For example, the ENBDM control bit may not be written while the MCU is in active
background mode. (This prevents the ambiguous condition of the control bit forbidding active background
mode while the MCU is already in active background mode.) Also, the four status bits (BDMACT, WS,
WSF, and DVF) are read-only status indicators and can never be written by the WRITE_CONTROL serial
BDC command. The clock switch (CLKSW) control bit may be read or written at any time.
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17.4.1.1
BDC Status and Control Register (BDCSCR)
This register can be read or written by serial BDC commands (READ_STATUS and WRITE_CONTROL)
but is not accessible to user programs because it is not located in the normal memory map of the MCU.
7
R
6
5
4
3
BKPTEN
FTS
CLKSW
BDMACT
ENBDM
2
1
0
WS
WSF
DVF
W
Normal
Reset
0
0
0
0
0
0
0
0
Reset in
Active BDM:
1
1
0
0
1
0
0
0
= Unimplemented or Reserved
Figure 17-5. BDC Status and Control Register (BDCSCR)
Table 17-2. BDCSCR Register Field Descriptions
Field
Description
7
ENBDM
Enable BDM (Permit Active Background Mode) — Typically, this bit is written to 1 by the debug host shortly
after the beginning of a debug session or whenever the debug host resets the target and remains 1 until a normal
reset clears it.
0 BDM cannot be made active (non-intrusive commands still allowed)
1 BDM can be made active to allow active background mode commands
6
BDMACT
Background Mode Active Status — This is a read-only status bit.
0 BDM not active (user application program running)
1 BDM active and waiting for serial commands
5
BKPTEN
BDC Breakpoint Enable — If this bit is clear, the BDC breakpoint is disabled and the FTS (force tag select)
control bit and BDCBKPT match register are ignored.
0 BDC breakpoint disabled
1 BDC breakpoint enabled
4
FTS
3
CLKSW
Force/Tag Select — When FTS = 1, a breakpoint is requested whenever the CPU address bus matches the
BDCBKPT match register. When FTS = 0, a match between the CPU address bus and the BDCBKPT register
causes the fetched opcode to be tagged. If this tagged opcode ever reaches the end of the instruction queue,
the CPU enters active background mode rather than executing the tagged opcode.
0 Tag opcode at breakpoint address and enter active background mode if CPU attempts to execute that
instruction
1 Breakpoint match forces active background mode at next instruction boundary (address need not be an
opcode)
Select Source for BDC Communications Clock — CLKSW defaults to 0, which selects the alternate BDC
clock source.
0 Alternate BDC clock source
1 MCU bus clock
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Table 17-2. BDCSCR Register Field Descriptions (continued)
Field
Description
2
WS
Wait or Stop Status — When the target CPU is in wait or stop mode, most BDC commands cannot function.
However, the BACKGROUND command can be used to force the target CPU out of wait or stop and into active
background mode where all BDC commands work. Whenever the host forces the target MCU into active
background mode, the host should issue a READ_STATUS command to check that BDMACT = 1 before
attempting other BDC commands.
0 Target CPU is running user application code or in active background mode (was not in wait or stop mode when
background became active)
1 Target CPU is in wait or stop mode, or a BACKGROUND command was used to change from wait or stop to
active background mode
1
WSF
Wait or Stop Failure Status — This status bit is set if a memory access command failed due to the target CPU
executing a wait or stop instruction at or about the same time. The usual recovery strategy is to issue a
BACKGROUND command to get out of wait or stop mode into active background mode, repeat the command
that failed, then return to the user program. (Typically, the host would restore CPU registers and stack values and
re-execute the wait or stop instruction.)
0 Memory access did not conflict with a wait or stop instruction
1 Memory access command failed because the CPU entered wait or stop mode
0
DVF
Data Valid Failure Status — This status bit is not used in the MC9S08DZ60 Series because it does not have
any slow access memory.
0 Memory access did not conflict with a slow memory access
1 Memory access command failed because CPU was not finished with a slow memory access
17.4.1.2
BDC Breakpoint Match Register (BDCBKPT)
This 16-bit register holds the address for the hardware breakpoint in the BDC. The BKPTEN and FTS
control bits in BDCSCR are used to enable and configure the breakpoint logic. Dedicated serial BDC
commands (READ_BKPT and WRITE_BKPT) are used to read and write the BDCBKPT register but is
not accessible to user programs because it is not located in the normal memory map of the MCU.
Breakpoints are normally set while the target MCU is in active background mode before running the user
application program. For additional information about setup and use of the hardware breakpoint logic in
the BDC, refer to Section 17.2.4, “BDC Hardware Breakpoint.”
17.4.2
System Background Debug Force Reset Register (SBDFR)
This register contains a single write-only control bit. A serial background mode command such as
WRITE_BYTE must be used to write to SBDFR. Attempts to write this register from a user program are
ignored. Reads always return 0x00.
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R
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
BDFR1
W
Reset
0
0
0
0
0
0
0
0
= Unimplemented or Reserved
1
BDFR is writable only through serial background mode debug commands, not from user programs.
Figure 17-6. System Background Debug Force Reset Register (SBDFR)
Table 17-3. SBDFR Register Field Description
Field
Description
0
BDFR
Background Debug Force Reset — A serial active background mode command such as WRITE_BYTE allows
an external debug host to force a target system reset. Writing 1 to this bit forces an MCU reset. This bit cannot
be written from a user program.
17.4.3
DBG Registers and Control Bits
The debug module includes nine bytes of register space for three 16-bit registers and three 8-bit control
and status registers. These registers are located in the high register space of the normal memory map so
they are accessible to normal application programs. These registers are rarely if ever accessed by normal
user application programs with the possible exception of a ROM patching mechanism that uses the
breakpoint logic.
17.4.3.1
Debug Comparator A High Register (DBGCAH)
This register contains compare value bits for the high-order eight bits of comparator A. This register is
forced to 0x00 at reset and can be read at any time or written at any time unless ARM = 1.
17.4.3.2
Debug Comparator A Low Register (DBGCAL)
This register contains compare value bits for the low-order eight bits of comparator A. This register is
forced to 0x00 at reset and can be read at any time or written at any time unless ARM = 1.
17.4.3.3
Debug Comparator B High Register (DBGCBH)
This register contains compare value bits for the high-order eight bits of comparator B. This register is
forced to 0x00 at reset and can be read at any time or written at any time unless ARM = 1.
17.4.3.4
Debug Comparator B Low Register (DBGCBL)
This register contains compare value bits for the low-order eight bits of comparator B. This register is
forced to 0x00 at reset and can be read at any time or written at any time unless ARM = 1.
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17.4.3.5
Debug FIFO High Register (DBGFH)
This register provides read-only access to the high-order eight bits of the FIFO. Writes to this register have
no meaning or effect. In the event-only trigger modes, the FIFO only stores data into the low-order byte of
each FIFO word, so this register is not used and will read 0x00.
Reading DBGFH does not cause the FIFO to shift to the next word. When reading 16-bit words out of the
FIFO, read DBGFH before reading DBGFL because reading DBGFL causes the FIFO to advance to the
next word of information.
17.4.3.6
Debug FIFO Low Register (DBGFL)
This register provides read-only access to the low-order eight bits of the FIFO. Writes to this register have
no meaning or effect.
Reading DBGFL causes the FIFO to shift to the next available word of information. When the debug
module is operating in event-only modes, only 8-bit data is stored into the FIFO (high-order half of each
FIFO word is unused). When reading 8-bit words out of the FIFO, simply read DBGFL repeatedly to get
successive bytes of data from the FIFO. It isn’t necessary to read DBGFH in this case.
Do not attempt to read data from the FIFO while it is still armed (after arming but before the FIFO is filled
or ARMF is cleared) because the FIFO is prevented from advancing during reads of DBGFL. This can
interfere with normal sequencing of reads from the FIFO.
Reading DBGFL while the debugger is not armed causes the address of the most-recently fetched opcode
to be stored to the last location in the FIFO. By reading DBGFH then DBGFL periodically, external host
software can develop a profile of program execution. After eight reads from the FIFO, the ninth read will
return the information that was stored as a result of the first read. To use the profiling feature, read the FIFO
eight times without using the data to prime the sequence and then begin using the data to get a delayed
picture of what addresses were being executed. The information stored into the FIFO on reads of DBGFL
(while the FIFO is not armed) is the address of the most-recently fetched opcode.
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17.4.3.7
Debug Control Register (DBGC)
This register can be read or written at any time.
7
6
5
4
3
2
1
0
DBGEN
ARM
TAG
BRKEN
RWA
RWAEN
RWB
RWBEN
0
0
0
0
0
0
0
0
R
W
Reset
Figure 17-7. Debug Control Register (DBGC)
Table 17-4. DBGC Register Field Descriptions
Field
Description
7
DBGEN
Debug Module Enable — Used to enable the debug module. DBGEN cannot be set to 1 if the MCU is secure.
0 DBG disabled
1 DBG enabled
6
ARM
Arm Control — Controls whether the debugger is comparing and storing information in the FIFO. A write is used
to set this bit (and ARMF) and completion of a debug run automatically clears it. Any debug run can be manually
stopped by writing 0 to ARM or to DBGEN.
0 Debugger not armed
1 Debugger armed
5
TAG
Tag/Force Select — Controls whether break requests to the CPU will be tag or force type requests. If
BRKEN = 0, this bit has no meaning or effect.
0 CPU breaks requested as force type requests
1 CPU breaks requested as tag type requests
4
BRKEN
Break Enable — Controls whether a trigger event will generate a break request to the CPU. Trigger events can
cause information to be stored in the FIFO without generating a break request to the CPU. For an end trace, CPU
break requests are issued to the CPU when the comparator(s) and R/W meet the trigger requirements. For a
begin trace, CPU break requests are issued when the FIFO becomes full. TRGSEL does not affect the timing of
CPU break requests.
0 CPU break requests not enabled
1 Triggers cause a break request to the CPU
3
RWA
R/W Comparison Value for Comparator A — When RWAEN = 1, this bit determines whether a read or a write
access qualifies comparator A. When RWAEN = 0, RWA and the R/W signal do not affect comparator A.
0 Comparator A can only match on a write cycle
1 Comparator A can only match on a read cycle
2
RWAEN
Enable R/W for Comparator A — Controls whether the level of R/W is considered for a comparator A match.
0 R/W is not used in comparison A
1 R/W is used in comparison A
1
RWB
R/W Comparison Value for Comparator B — When RWBEN = 1, this bit determines whether a read or a write
access qualifies comparator B. When RWBEN = 0, RWB and the R/W signal do not affect comparator B.
0 Comparator B can match only on a write cycle
1 Comparator B can match only on a read cycle
0
RWBEN
Enable R/W for Comparator B — Controls whether the level of R/W is considered for a comparator B match.
0 R/W is not used in comparison B
1 R/W is used in comparison B
MC9S08DZ60 Series Data Sheet, Rev. 4
366
Freescale Semiconductor
Chapter 17 Development Support
17.4.3.8
Debug Trigger Register (DBGT)
This register can be read any time, but may be written only if ARM = 0, except bits 4 and 5 are hard-wired
to 0s.
7
6
TRGSEL
BEGIN
0
0
R
5
4
0
0
3
2
1
0
TRG3
TRG2
TRG1
TRG0
0
0
0
0
W
Reset
0
0
= Unimplemented or Reserved
Figure 17-8. Debug Trigger Register (DBGT)
Table 17-5. DBGT Register Field Descriptions
Field
Description
7
TRGSEL
Trigger Type — Controls whether the match outputs from comparators A and B are qualified with the opcode
tracking logic in the debug module. If TRGSEL is set, a match signal from comparator A or B must propagate
through the opcode tracking logic and a trigger event is only signalled to the FIFO logic if the opcode at the match
address is actually executed.
0 Trigger on access to compare address (force)
1 Trigger if opcode at compare address is executed (tag)
6
BEGIN
Begin/End Trigger Select — Controls whether the FIFO starts filling at a trigger or fills in a circular manner until
a trigger ends the capture of information. In event-only trigger modes, this bit is ignored and all debug runs are
assumed to be begin traces.
0 Data stored in FIFO until trigger (end trace)
1 Trigger initiates data storage (begin trace)
3:0
TRG[3:0]
Select Trigger Mode — Selects one of nine triggering modes, as described below.
0000 A-only
0001 A OR B
0010 A Then B
0011 Event-only B (store data)
0100 A then event-only B (store data)
0101 A AND B data (full mode)
0110 A AND NOT B data (full mode)
0111 Inside range: A ≤ address ≤ B
1000 Outside range: address < A or address > B
1001 – 1111 (No trigger)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
367
Chapter 17 Development Support
17.4.3.9
Debug Status Register (DBGS)
This is a read-only status register.
R
7
6
5
4
3
2
1
0
AF
BF
ARMF
0
CNT3
CNT2
CNT1
CNT0
0
0
0
0
0
0
0
0
W
Reset
= Unimplemented or Reserved
Figure 17-9. Debug Status Register (DBGS)
Table 17-6. DBGS Register Field Descriptions
Field
Description
7
AF
Trigger Match A Flag — AF is cleared at the start of a debug run and indicates whether a trigger match A
condition was met since arming.
0 Comparator A has not matched
1 Comparator A match
6
BF
Trigger Match B Flag — BF is cleared at the start of a debug run and indicates whether a trigger match B
condition was met since arming.
0 Comparator B has not matched
1 Comparator B match
5
ARMF
Arm Flag — While DBGEN = 1, this status bit is a read-only image of ARM in DBGC. This bit is set by writing 1
to the ARM control bit in DBGC (while DBGEN = 1) and is automatically cleared at the end of a debug run. A
debug run is completed when the FIFO is full (begin trace) or when a trigger event is detected (end trace). A
debug run can also be ended manually by writing 0 to ARM or DBGEN in DBGC.
0 Debugger not armed
1 Debugger armed
3:0
CNT[3:0]
FIFO Valid Count — These bits are cleared at the start of a debug run and indicate the number of words of valid
data in the FIFO at the end of a debug run. The value in CNT does not decrement as data is read out of the FIFO.
The external debug host is responsible for keeping track of the count as information is read out of the FIFO.
0000 Number of valid words in FIFO = No valid data
0001 Number of valid words in FIFO = 1
0010 Number of valid words in FIFO = 2
0011 Number of valid words in FIFO = 3
0100 Number of valid words in FIFO = 4
0101 Number of valid words in FIFO = 5
0110 Number of valid words in FIFO = 6
0111 Number of valid words in FIFO = 7
1000 Number of valid words in FIFO = 8
MC9S08DZ60 Series Data Sheet, Rev. 4
368
Freescale Semiconductor
Appendix A
Electrical Characteristics
A.1
Introduction
This section contains the most accurate electrical and timing information for the MC9S08DZ60 Series of
microcontrollers available at the time of publication.
A.2
Parameter Classification
The electrical parameters shown in this supplement are guaranteed by various methods. To give the
customer a better understanding the following classification is used and the parameters are tagged
accordingly in the tables where appropriate:
Table A-1. Parameter Classifications
P
Those parameters are guaranteed during production testing on each individual device.
C
Those parameters are achieved by the design characterization by measuring a
statistically relevant sample size across process variations.
T
Those parameters are achieved by design characterization on a small sample size from
typical devices under typical conditions unless otherwise noted. All values shown in
the typical column are within this category.
D
Those parameters are derived mainly from simulations.
NOTE
The classification is shown in the column labeled “C” in the parameter
tables where appropriate.
A.3
Absolute Maximum Ratings
Absolute maximum ratings are stress ratings only, and functional operation at the maxima is not
guaranteed. Stress beyond the limits specified in Table A-2 may affect device reliability or cause
permanent damage to the device. For functional operating conditions, refer to the remaining tables in this
section.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
369
Appendix A Electrical Characteristics
This device contains circuitry protecting against damage due to high static voltage or electrical fields;
however, it is advised that normal precautions be taken to avoid application of any voltages higher than
maximum-rated voltages to this high-impedance circuit. Reliability of operation is enhanced if unused
inputs are tied to an appropriate logic voltage level (for instance, either VSS or VDD).
Table A-2. Absolute Maximum Ratings
Num
Rating
Symbol
Value
Unit
1
Supply voltage
VDD
–0.3 to + 5.8
V
2
Input voltage
VIn
– 0.3 to VDD + 0.3
V
3
Instantaneous maximum current
(applies to all port pins)1, 2, 3
ID
± 25
mA
4
Maximum current into VDD
IDD
120
mA
5
Storage temperature
Tstg
–55 to +150
°C
Single pin limit
1
Input must be current limited to the value specified. To determine the value of the required
current-limiting resistor, calculate resistance values for positive (VDD) and negative (VSS) clamp
voltages, then use the larger of the two resistance values.
2 All functional non-supply pins are internally clamped to V
SS and VDD.
3 Power supply must maintain regulation within operating V
DD range during instantaneous and operating
maximum current conditions. If positive injection current (VIn > VDD) is greater than IDD, the injection
current may flow out of VDD and could result in external power supply going out of regulation. Ensure
external VDD load will shunt current greater than maximum injection current. This will be the greatest
risk when the MCU is not consuming power. Examples are: if no system clock is present, or if the clock
rate is very low which would reduce overall power consumption.
A.4
Thermal Characteristics
This section provides information about operating temperature range, power dissipation, and package
thermal resistance. Power dissipation on I/O pins is usually small compared to the power dissipation in
on-chip logic and it is user-determined rather than being controlled by the MCU design. In order to take
PI/O into account in power calculations, determine the difference between actual pin voltage and VSS or
VDD and multiply by the pin current for each I/O pin. Except in cases of unusually high pin current (heavy
loads), the difference between pin voltage and VSS or VDD will be very small.
MC9S08DZ60 Series Data Sheet, Rev. 4
370
Freescale Semiconductor
Appendix A Electrical Characteristics
Table A-3. Thermal Characteristics
Num
C
1
D
Symbol
Value
Unit
Temp.
Code
Operating temperature range (packaged)
TA
–40 to 125
–40 to 105
–40 to 85
°C
M
V
C
TJ
135
°C
—
64-pin LQFP
θJA
69
°C/W
48-pin LQFP
θJA
75
°C/W
32-pin LQFP
θJA
80
°C/W
64-pin LQFP
θJA
51
°C/W
48-pin LQFP
θJA
51
°C/W
32-pin LQFP
θJA
52
°C/W
Rating
2
T
Maximum Junction Temperature1
3
D
Thermal resistance2
Single-layer board
Four-Layer board
1
Junction temperature is a function of die size, on-chip power dissipation, package thermal resistance, mounting site
(board) temperature, ambient temperature, air flow, power dissipation of other components on the board, and board
thermal resistance.
2 Junction to Ambient Natural Convection
The average chip-junction temperature (TJ) in °C can be obtained from:
TJ = TA + (PD × θJA)
Eqn. A-1
where:
TA = Ambient temperature, °C
θJA = Package thermal resistance, junction-to-ambient, °C/W
PD = Pint + PI/O
Pint = IDD × VDD, Watts — chip internal power
PI/O = Power dissipation on input and output pins — user determined
For most applications, PI/O << Pint and can be neglected. An approximate relationship between PD and TJ
(if PI/O is neglected) is:
PD = K ÷ (TJ + 273°C)
Eqn. A-2
Solving equations 1 and 2 for K gives:
K = PD × (TA + 273°C) + θJA × (PD)2
Eqn. A-3
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
371
Appendix A Electrical Characteristics
where K is a constant pertaining to the particular part. K can be determined from equation 3 by measuring
PD (at equilibrium) for a known TA. Using this value of K, the values of PD and TJ can be obtained by
solving equations 1 and 2 iteratively for any value of TA.
A.5
ESD Protection and Latch-Up Immunity
Although damage from electrostatic discharge (ESD) is much less common on these devices than on early
CMOS circuits, normal handling precautions should be used to avoid exposure to static discharge.
Qualification tests are performed to ensure that these devices can withstand exposure to reasonable levels
of static without suffering any permanent damage.
All ESD testing is in conformity with AEC-Q100 Stress Test Qualification for Automotive Grade
Integrated Circuits. During the device qualification ESD stresses were performed for the Human Body
Model (HBM) and the Charge Device Model (CDM).
A device is defined as a failure if after exposure to ESD pulses the device no longer meets the device
specification. Complete DC parametric and functional testing is performed per the applicable device
specification at room temperature followed by hot temperature, unless specified otherwise in the device
specification.
Table A-4. ESD and Latch-up Test Conditions
Model
Human Body
Description
Symbol
Value
Unit
Series Resistance
R1
1500
Ω
Storage Capacitance
C
100
pF
Number of Pulse per pin
–
3
Minimum input voltage limit
–2.5
V
Maximum input voltage limit
7.5
V
Latch-up
Table A-5. ESD and Latch-Up Protection Characteristics
Num
Rating
Symbol
Min
Max
Unit
1
Human Body Model (HBM)
VHBM
+/- 2000
–
V
2
Charge Device Model (CDM)
VCDM
+/- 500
–
V
3
Latch-up Current at TA = 125°C
ILAT
+/- 100
–
mA
MC9S08DZ60 Series Data Sheet, Rev. 4
372
Freescale Semiconductor
Appendix A Electrical Characteristics
A.6
DC Characteristics
This section includes information about power supply requirements, I/O pin characteristics, and power
supply current in various operating modes.
Table A-6. DC Characteristics
Num
1
C
Typ1
Max
Unit
2.7
V
—
5.5
—
—
C
3 V, ILoad = –0.6 mA
VDD – 1.5
—
—
C Output high
C voltage
5 V, ILoad = –0.4 mA
VDD – 0.8
—
—
3 V, ILoad = –0.24 mA VDD – 0.8
5 V, ILoad = –10 mA VDD – 1.5
—
—
—
—
C
3 V, ILoad = –3 mA
VDD – 1.5
—
—
C
5 V, ILoad = –2 mA
VDD – 0.8
—
—
C
3 V, ILoad = –0.4 mA
VDD – 0.8
—
—
VDD
All I/O pins, low-drive strength
VOH
All I/O pins, high-drive strength
5V
0
—
-100
3V
0
—
-60
5 V, ILoad = 2 mA
—
—
1.5
C
3 V, ILoad = 0.6 mA
—
—
1.5
C Output low
C voltage
5 V, ILoad = 0.4 mA
—
—
0.8
3 V, ILoad = 0.24 mA
—
—
0.8
C Output
high current
Max total IOH for all ports
IOHT
All I/O pins, low-drive strength
VOL
5 V, ILoad = 10 mA
—
—
1.5
C
3 V, ILoad = 3 mA
—
—
1.5
C
5 V, ILoad = 2 mA
—
—
0.8
C
3 V, ILoad = 0.4 mA
—
—
0.8
P
5
Min
VDD – 1.5
P
4
Condition
5 V, ILoad = –2 mA
P
3
Symbol
— Operating Voltage
P
2
Characteristic
All I/O pins, high-drive strength
C Output
low current
Max total IOL for all ports
IOLT
5V
0
—
100
3V
0
—
60
6
C Input high voltage; all digital inputs
VIH
5V
0.65 x VDD
—
—
7
C Input low voltage; all digital inputs
VIL
5V
—
—
0.35 x VDD
8
C Input hysteresis
Vhys
9
Input leakage
P current (Per pin)
all input only pins
10
11
P
P
Hi-Z (off-state) leakage
current (per pin)
all input/output
Pullup resistors (or Pulldown2 resistors
when enabled)
0.06 x VDD
V
mA
V
mA
V
mV
|IIn|
VIn = VDD or VSS
—
0.1
1
μA
|IOZ|
VIn = VDD or VSS
—
0.1
1
μA
RPU,
RPD
5V
20
45
65
C
kΩ
3V
20
45
65
Input Capacitance, all pins
12
T
13
D RAM retention voltage
CIn
—
—
8
pF
VRAM
—
0.6
1.0
V
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
373
Appendix A Electrical Characteristics
Table A-6. DC Characteristics (continued)
Num
14
C
Min
Typ1
Max
Unit
VPOR
0.9
1.4
2.0
V
tPOR
10
—
—
μs
3.9
4.0
4.0
4.1
4.1
4.2
V
2.48
2.54
2.56
2.62
2.64
2.70
V
4.5
4.6
4.6
4.7
4.7
4.8
V
4.2
4.3
4.3
4.4
4.4
4.5
V
2.84
2.90
2.92
2.98
3.00
3.06
V
2.66
2.72
2.74
2.80
2.82
2.88
V
5V
—
100
—
3V
—
60
—
VIN > VDD
0
—
2
VIN < VSS
0
—
–0.2
VIN > VDD
0
—
25
VIN < VSS
0
—
–5
1.19
1.20
1.21
Characteristic
Symbol
3
D POR re-arm voltage
4
15
D POR re-arm time
16
Low-voltage detection threshold —
high range
P
VDD falling
VDD rising
17
Low-voltage detection threshold —
low range
P
VDD falling
VDD rising
18
Low-voltage warning threshold —
high range 1
C
VDD falling
VDD rising
19
Low-voltage warning threshold —
high range 0
P
VDD falling
VDD rising
20
Low-voltage warning threshold
low range 1
P
VDD falling
VDD rising
21
Low-voltage warning threshold —
low range 0
C
VDD falling
VDD rising
22
Low-voltage inhibit reset/recover
T hysteresis
Condition
VLVD1
VLVD0
VLVW3
VLVW2
VLVW1
VLVW0
Vhys
mV
dc injection current 5, 6, 7, 8
Single pin limit
23
D
IIC
Total MCU limit, includes
sum of all stressed pins
24
1
2
3
4
5
6
Bandgap Voltage Reference
C Factory trimmed at
VDD = 5.0 V, Temp = 25°C
mA
VBG
V
Typical values are measured at 25°C. Characterized, not tested
When a pin interrupt is configured to detect rising edges, pulldown resistors are used in place of pullup resistors.
Maximum is highest voltage that POR is guaranteed.
Simulated, not tested
Power supply must maintain regulation within operating VDD range during instantaneous and operating maximum current
conditions. If positive injection current (VIn > VDD) is greater than IDD, the injection current may flow out of VDD and could result
in external power supply going out of regulation. Ensure external VDD load will shunt current greater than maximum injection
current. This will be the greatest risk when the MCU is not consuming power. Examples are: if no system clock is present, or
if clock rate is very low which (would reduce overall power consumption).
All functional non-supply pins are internally clamped to VSS and VDD.
MC9S08DZ60 Series Data Sheet, Rev. 4
374
Freescale Semiconductor
Appendix A Electrical Characteristics
7
Input must be current limited to the value specified. To determine the value of the required current-limiting resistor, calculate
resistance values for positive and negative clamp voltages, then use the larger of the two values.
8
PTE1 does not have a clamp diode to VDD. Do not drive PTE1 above VDD.
A.7
Supply Current Characteristics
Table A-7. Supply Current Characteristics
Num
C
C
1
C
P
2
C
P
3
C
P4
4
Run supply current3 measured at
(CPU clock = 2 MHz, fBus = 1 MHz)
Symbol
RIDD
3
Run supply current measured at
(CPU clock = 16 MHz, fBus = 8 MHz)
RIDD
Run supply current3 measured at
(CPU clock = 40 MHz, fBus = 20 MHz)
RIDD
Stop3 mode
supply
current
VDD (V)
Typical1
Max2
5
3
7.5
3
2.8
7.4
5
7.7
11.4
3
7.4
11.2
5
15
24
3
14
23
0.9
—
1.0
—
26
39
62
90
0.8
—
0.9
—
mA
mA
–40 °C (C, V, & M suffix)
25 °C (All parts)
P
105 °C (V suffix only)
P
125 °C (M suffix only)
C
–40 °C (C, V, & M suffix)
C
25 °C (All parts)
C
105 °C (V suffix only)
21
32
C
125 °C (M suffix only)
52
80
–40 °C (C, V, & M suffix)
0.8
—
0.9
—
25
37
46
70
0.7
—
0.8
—
Stop2 mode
supply
current
Unit
mA
P4
P4
5
Parameter
5
S3IDD
3
P4
25 °C (All parts)
P
105 °C (V suffix only)
P
125 °C (M suffix only)
C
–40 °C (C, V, & M suffix)
C
25 °C (All parts)
C
105 °C (V suffix only)
20
30
C
125 °C (M suffix only)
40
60
5
S2IDD
3
μA
μA
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
375
Appendix A Electrical Characteristics
Table A-7. Supply Current Characteristics (continued)
Num
C
6
C
Parameter
Symbol
VDD (V)
Typical1
Max2
Unit
5
300
—
nA
3
300
—
nA
5
110
—
μA
3
90
—
μA
5
5
—
μA
3
5
—
μA
RTC adder to stop2 or stop35, 25°C
LVD adder to stop3 (LVDE = LVDSE = 1)
7
C
8
1
2
3
4
5
6
A.8
C
Adder to stop3 for oscillator enabled6
(IRCLKEN = 1 and IREFSTEN = 1 or
ERCLKEN = 1 and EREFSTEN = 1)
Typicals are measured at 25°C, unless otherwise noted.
Maximum values in this column apply for the full operating temperature range of the device unless otherwise noted.
All modules except ADC active, MCG configured for FBE, and does not include any dc loads on port pins
Stop currents are tested in production for 25°C on all parts. Tests at other temperatures depend upon the part number
suffix and maturity of the product. Freescale may eliminate a test insertion at a particular temperature from the
production test flow once sufficient data has been collected and is approved.
Most customers are expected to find that auto-wakeup from stop2 or stop3 can be used instead of the higher current
wait mode.
Values given under the following conditions: low range operation (RANGE = 0), low power mode (HGO = 0).
Analog Comparator (ACMP) Electricals
Table A-8. Analog Comparator Electrical Specifications
Num
C
Symbol
Min
Typical
Max
Unit
1
—
Supply voltage
VDD
2.7
—
5.5
V
2
D
Supply current (active)
IDDAC
—
20
35
μA
3
D
Analog input voltage
VAIN
VSS – 0.3
—
VDD
V
4
D
Analog input offset voltage
VAIO
20
40
mV
5
D
Analog Comparator hysteresis
6
D
7
D
A.9
Rating
VH
3.0
6.0
20.0
mV
Analog input leakage current
IALKG
--
--
1.0
μA
Analog Comparator initialization delay
tAINIT
—
—
1.0
μs
ADC Characteristics
Table A-9. 12-bit ADC Operating Conditions
Characteristic
Supply voltage
Ground voltage
Symb
Min
Typ1
Max
Unit
Absolute
VDDAD
2.7
—
5.5
V
Delta to VDD (VDD-VDDAD)2
ΔVDDAD
-100
0
+100
mV
Delta to VSS (VSS-VSSAD)2
ΔVSSAD
-100
0
+100
mV
Conditions
Comment
MC9S08DZ60 Series Data Sheet, Rev. 4
376
Freescale Semiconductor
Appendix A Electrical Characteristics
Table A-9. 12-bit ADC Operating Conditions (continued)
Symb
Min
Typ1
Max
Unit
Comment
Ref Voltage
High
VREFH
2.7
VDDAD
VDDAD
V
Applicable in only
64-pin packages
{VREFH < VDDAD
characterized but
not production test}
Ref Voltage
Low
VREFL
VSSAD
VSSAD
VSSAD
V
Not Applicable in
64-pin packages
(only 32- and
48-pin packages)
Input Voltage
VADIN
VREFL
—
VREFH
V
Input
Capacitance
CADIN
—
4.5
5.5
pF
Input
Resistance
RADIN
—
3
5
kΩ
—
—
—
—
2
5
10 bit mode
fADCK > 4MHz
fADCK < 4MHz
—
—
—
—
5
10
8 bit mode (all valid fADCK)
—
—
10
0.4
—
8.0
0.4
—
4.0
Characteristic
Analog Source
Resistance
ADC
Conversion
Clock Freq.
Conditions
12 bit mode
fADCK > 4MHz
fADCK < 4MHz
kΩ
RAS
High Speed (ADLPC=0)
Low Power (ADLPC=1)
fADCK
External to MCU
MHz
1
Typical values assume VDDAD = 5.0V, Temp = 25°C, fADCK=1.0MHz unless otherwise stated. Typical values are for reference
only and are not tested in production.
2 DC potential difference.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
377
Appendix A Electrical Characteristics
SIMPLIFIED
INPUT PIN EQUIVALENT
CIRCUIT
ZADIN
SIMPLIFIED
CHANNEL SELECT
CIRCUIT
Pad
leakage
due to
input
protection
ZAS
RAS
ADC SAR
ENGINE
RADIN
+
VADIN
VAS
–
CAS
+
–
RADIN
INPUT PIN
RADIN
INPUT PIN
RADIN
INPUT PIN
CADIN
Figure A-1. ADC Input Impedance Equivalency Diagram
Table A-10. 12-bit ADC Characteristics (VREFH = VDDAD, VREFL = VSSAD)
Characteristic
Conditions
C
Symb
Min
Typ1
Max
Unit
Comment
Supply Current
ADLPC=1
ADLSMP=1
ADCO=1
T
IDD +
IDDAD
—
133
—
μA
ADC current
only
Supply Current
ADLPC=1
ADLSMP=0
ADCO=1
T
IDD +
IDDAD
—
218
—
μA
ADC current
only
Supply Current
ADLPC=0
ADLSMP=1
ADCO=1
T
IDD +
IDDAD
—
327
—
μA
ADC current
only
Supply Current
ADLPC=0
ADLSMP=0
ADCO=1
D
IDD +
IDDAD
—
0.582
1
mA
ADC current
only
Supply Current
Stop, Reset, Module Off
IDD +
IDDAD
—
0.011
1
μA
ADC current
only
ADC
Asynchronous
Clock Source
High Speed (ADLPC=0)
fADACK
2
3.3
5
MHz
1.25
2
3.3
tADACK =
1/fADACK
Low Power (ADLPC=1)
P
MC9S08DZ60 Series Data Sheet, Rev. 4
378
Freescale Semiconductor
Appendix A Electrical Characteristics
Table A-10. 12-bit ADC Characteristics (VREFH = VDDAD, VREFL = VSSAD) (continued)
Characteristic
Conditions
C
Symb
Min
Typ1
Max
Unit
Comment
Conversion
Time (Including
sample time)
Short Sample (ADLSMP=0)
D
tADC
—
20
—
—
40
—
ADCK
cycles
Sample Time
Short Sample (ADLSMP=0)
—
3.5
—
See
Table 10-13
for conversion
time variances
—
23.5
—
—
±3.0
±10
Long Sample (ADLSMP=1)
D
tADS
Long Sample (ADLSMP=1)
Total
Unadjusted
Error
Differential
Non-Linearity
Integral
Non-Linearity
Zero-Scale
Error
Full-Scale Error
Quantization
Error
Input Leakage
Error
12 bit mode
T
10 bit mode
P
—
±1
±2.5
8 bit mode
T
—
±0.5
±1.0
12 bit mode
T
—
±1.75
±4.0
10 bit mode3
P
—
±0.5
±1.0
8 bit mode3
T
—
±0.3
±0.5
12 bit mode
T
—
±1.5
±4.0
10 bit mode
T
—
±0.5
±1.0
8 bit mode
T
—
±0.3
±0.5
12 bit mode
T
—
±1.5
±6.0
10 bit mode
P
—
±0.5
±1.5
8 bit mode
T
—
±0.5
±0.5
12 bit mode
T
—
±1
±4.0
10 bit mode
T
—
±0.5
±1
8 bit mode
T
—
±0.5
±0.5
12 bit mode
D
—
-1 to 0
-1 to 0
10 bit mode
—
—
±0.5
8 bit mode
—
—
±0.5
—
±1
±10.0
10 bit mode
—
±0.2
±2.5
8 bit mode
—
±0.1
±1
—
3.266
—
—
3.638
—
—
1.396
—
12 bit mode
Temp Sensor
Slope
-40°C– 25°C
Temp Sensor
Voltage
25°C
D
D
ETUE
DNL
INL
EZS
EFS
EQ
EIL
m
25°C– 125°C
D
VTEMP25
ADCK
cycles
LSB2
Includes
quantization
LSB2
LSB2
LSB2
VADIN = VSSAD
LSB2
VADIN = VDDAD
LSB2
LSB2
Pad leakage4 *
RAS
mV/°C
V
1
Typical values assume VDDAD = 5.0V, Temp = 25°C, fADCK=1.0MHz unless otherwise stated. Typical values are for reference
only and are not tested in production.
2 1 LSB = (V
N
REFH - VREFL)/2
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
379
Appendix A Electrical Characteristics
3
4
Monotonicity and No-Missing-Codes guaranteed in 10 bit and 8 bit modes
Based on input pad leakage current. Refer to pad electricals.
A.10
External Oscillator (XOSC) Characteristics
Table A-11. Oscillator Electrical Specifications (Temperature Range = –40 to 125°C Ambient)
Num C
Rating
Symbol
Min
Typ1
Max
Unit
Oscillator crystal or resonator (EREFS = 1, ERCLKEN = 1
Low range (RANGE = 0)
C
1
flo
32
—
38.4
kHz
High range (RANGE = 1) FEE or FBE mode
2
fhi-fll
1
—
5
MHz
High range (RANGE = 1) PEE or PBE mode
3
fhi-pll
1
—
16
MHz
High range (RANGE = 1, HGO = 1) BLPE mode
fhi-hgo
1
—
16
MHz
High range (RANGE = 1, HGO = 0) BLPE mode
fhi-lp
1
—
8
MHz
2
— Load capacitors
3
—
C1
C2
See crystal or resonator
manufacturer’s recommendation.
Feedback resistor
Low range (32 kHz to 100 kHz)
RF
High range (1 MHz to 16 MHz)
—
10
—
MΩ
—
1
—
MΩ
—
0
—
Series resistor
Low range, low gain (RANGE = 0, HGO = 0)
Low range, high gain (RANGE = 0, HGO = 1)
4
—
—
100
—
—
0
—
≥ 8 MHz
—
0
0
4 MHz
—
0
10
1 MHz
—
0
20
t
CSTL-LP
—
200
—
CSTL-HGO
—
400
—
t
CSTH-LP
—
5
—
CSTH-HGO
—
15
—
0.03125
—
5
1
—
16
0
—
40
High range, low gain (RANGE = 1, HGO = 0)
High range, high gain (RANGE = 1, HGO = 1)
Crystal start-up time
RS
4
Low range, low gain (RANGE = 0, HGO = 0)
5
T
kΩ
Low range, high gain (RANGE = 0, HGO = 1)
t
High range, low gain (RANGE = 1, HGO = 0)5
High range, high gain (RANGE = 1, HGO = 1)4
t
ms
Square wave input clock frequency (EREFS = 0, ERCLKEN = 1)
6
T
FEE or FBE mode 2
3
PEE or PBE mode
fextal
BLPE mode
MHz
1
Typical data was characterized at 3.0 V, 25°C or is recommended value.
When MCG is configured for FEE or FBE mode, the input clock source must be divisible using RDIV to within the range of
31.25 kHz to 39.0625 kHz.
3
When MCG is configured for PEE or PBE mode, input clock source must be divisible using RDIV to within the range of 1 MHz
to 2 MHz.
4
This parameter is characterized and not tested on each device. Proper PC board layout procedures must be followed to
achieve specifications. This data will vary based upon the crystal manufacturer and board design. The crystal should be
characterized by the crystal manufacturer.
5 4 MHz crystal.
2
MC9S08DZ60 Series Data Sheet, Rev. 4
380
Freescale Semiconductor
Appendix A Electrical Characteristics
MCU
EXTAL
XTAL
RS
RF
C1
A.11
Crystal or Resonator
C2
MCG Specifications
Table A-12. MCG Frequency Specifications (Temperature Range = –40 to 125°C Ambient)
Num C
Rating
Symbol
Min
Typical
Max
Unit
1
P
Internal reference frequency - factory trimmed at
VDD = 5 V and temperature = 25 °C
fint_ft
—
31.25
—
kHz
2
P
Average internal reference frequency untrimmed 1
fint_ut
25
32.7
41.66
kHz
3
P
Average internal reference frequency - user
trimmed
fint_t
31.25
—
39.0625
kHz
4
D Internal reference startup time
tirefst
—
60
100
us
1
5
DCO output frequency range - untrimmed
— value provided for reference: fdco_ut = 1024 X
fint_ut
fdco_ut
25.6
33.48
42.66
MHz
6
P DCO output frequency range - trimmed
fdco_t
32
—
40
MHz
7
C
Resolution of trimmed DCO output frequency at
fixed voltage and temperature (using FTRIM)
Δfdco_res_t
—
± 0.1
± 0.2
%fdco
8
C
Resolution of trimmed DCO output frequency at
fixed voltage and temperature (not using FTRIM)
Δfdco_res_t
—
± 0.2
± 0.4
%fdco
9
P
Total deviation of trimmed DCO output frequency
over voltage and temperature
Δfdco_t
—
+ 0.5
-1.0
±2
%fdco
10
Total deviation of trimmed DCO output frequency
C over fixed voltage and temperature range of
0 - 70 °C
Δfdco_t
—
± 0.5
±1
%fdco
11
C FLL acquisition time 2
tfll_acquire
—
—
1
ms
12
D PLL acquisition time 3
tpll_acquire
—
—
1
ms
13
C
CJitter
—
0.02
0.2
%fdco
14
D VCO operating frequency
fvco
7.0
—
55.0
MHz
15
D PLL reference frequency range
fpll_ref
1.0
—
2.0
MHz
16
T
RMS frequency variation of a single clock cycle
measured 2 ms after reference edge.5
fpll_cycjit_2ms
—
0.5904
—
%fpll
17
T
Maximum frequency variation averaged over
2 ms window.
fpll_maxjit_2ms
—
0.001
—
%fpll
Long term Jitter of DCO output clock (averaged
over 2ms interval) 4
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
381
Appendix A Electrical Characteristics
Table A-12. MCG Frequency Specifications (Temperature Range = –40 to 125°C Ambient) (continued)
Num C
1
2
3
4
5
6
7
8
Rating
Symbol
Min
Typical
Max
Unit
18
T
RMS frequency variation of a single clock cycle
measured 625 ns after reference edge.6
fpll_cycjit_625ns
—
0.5664
—
%fpll
19
T
Maximum frequency variation averaged over
625 ns window.
fpll_maxjit_625ns
—
0.113
—
%fpll
20
D Lock entry frequency tolerance 7
Dlock
± 1.49
—
± 2.98
%
21
D Lock exit frequency tolerance 8
Dunl
± 4.47
—
± 5.97
%
22
D Lock time - FLL
tfll_lock
—
—
tfll_acquire+
1075(1/fint_t)
s
23
D Lock time - PLL
tpll_lock
—
—
tpll_acquire+
1075(1/fpll_ref)
s
24
Loss of external clock minimum frequency D RANGE = 0
floc_low
(3/5) x fint
—
—
kHz
25
Loss of external clock minimum frequency D RANGE = 1
floc_high
(16/5) x fint
—
—
kHz
TRIM register at default value (0x80) and FTRIM control bit at default value (0x0).
This specification applies to any time the FLL reference source or reference divider is changed, trim value changed or
changing from FLL disabled (BLPE, BLPI) to FLL enabled (FEI, FEE, FBE, FBI). If a crystal/resonator is being used as the
reference, this specification assumes it is already running.
This specification applies to any time the PLL VCO divider or reference divider is changed, or changing from PLL disabled
(BLPE, BLPI) to PLL enabled (PBE, PEE). If a crystal/resonator is being used as the reference, this specification assumes it
is already running.
Jitter is the average deviation from the programmed frequency measured over the specified interval at maximum fBUS.
Measurements are made with the device powered by filtered supplies and clocked by a stable external clock signal. Noise
injected into the FLL circuitry via VDD and VSS and variation in crystal oscillator frequency increase the CJitter percentage for
a given interval. Jitter measurements are based upon a 40MHz MCGOUT clock frequency.
In some specifications, this value is described as “long term accuracy of PLL output clock (averaged over 2 ms)” with symbol
“fpll_jitter_2ms.” The parameter is unchanged, but the description has been changed for clarification purposes.
In some specifications, this value is described as “Jitter of PLL output clock measured over 625 ns” with symbol
“fpll_jitter_625ns.” The parameter is unchanged, but the description has been changed for clarification purposes.
Below Dlock minimum, the MCG is guaranteed to enter lock. Above Dlock maximum, the MCG will not enter lock. But if the
MCG is already in lock, then the MCG may stay in lock.
Below Dunl minimum, the MCG will not exit lock if already in lock. Above Dunl maximum, the MCG is guaranteed to exit lock.
MC9S08DZ60 Series Data Sheet, Rev. 4
382
Freescale Semiconductor
Appendix A Electrical Characteristics
A.12
AC Characteristics
This section describes ac timing characteristics for each peripheral system.
A.12.1
Control Timing
Table A-13. Control Timing
Nu
m
C
1
D/
P
2
Symbol
Min
Typical1
Max
Unit
Bus frequency (tcyc = 1/fBus)
fBus
dc
—
20
MHz
T
Internal low-power oscillator period
tLPO
—
1500
—
μs
3
D
External reset pulse width2
textrst
1.5 x tcyc
—
ns
4
D
Reset low drive3
trstdrv
34 x tcyc
—
ns
5
D
Active background debug mode latch setup time
tMSSU
25
—
ns
6
D
Active background debug mode latch hold time
tMSH
25
—
ns
7
D
IRQ/PIAx/ PIBx/PIDx pulse width
Asynchronous path2
Synchronous path3
tILIH, tIHIL
100
1.5 tcyc
—
—
ns
Port rise and fall time —
Low output drive (PTxDS = 0) (load = 50 pF)4
Slew rate control disabled (PTxSE = 0)
Slew rate control enabled (PTxSE = 1)
tRise, tFall
—
—
40
75
Port rise and fall time —
High output drive (PTxDS = 1) (load = 50 pF)4
Slew rate control disabled (PTxSE = 0)
Slew rate control enabled (PTxSE = 1)
tRise, tFall
—
—
11
35
8
T
Rating
ns
ns
1
Typical data was characterized at 5.0 V, 25°C unless otherwise stated.
This is the shortest pulse that is guaranteed to be recognized as a reset pin request. Shorter pulses are not guaranteed to
override reset requests from internal sources.
3 When any reset is initiated, internal circuitry drives the RESET pin low for about 34 cycles of t . After POR reset, the bus
cyc
clock frequency changes to the untrimmed DCO frequency (freset = (fdco_ut)/4) because TRIM is reset to 0x80 and FTRIM is
reset to 0; and there is an extra divide-by-two because BDIV is reset to 0:1. After other resets, trim stays at the pre-reset value.
4 Timing is shown with respect to 20% V
DD and 80% VDD levels. Temperature range –40°C to 125°C.
2
textrst
RESET PIN
Figure A-2. Reset Timing
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
383
Appendix A Electrical Characteristics
BKGD/MS
RESET
tMSH
tMSSU
Figure A-3. Active Background Debug Mode Latch Timing
tIHIL
PIAx/PIBx/PIDx
IRQ/PIAx/PIBx/PIDx
tILIH
Figure A-4. Pin Interrupt Timing
A.12.2
Timer/PWM
Synchronizer circuits determine the shortest input pulses that can be recognized or the fastest clock that
can be used as the optional external source to the timer counter. These synchronizers operate from the
current bus rate clock.
Table A-14. TPM Input Timing
Num
C
1
—
2
Rating
Symbol
Min
Max
Unit
External clock frequency
fTCLK
dc
fBus/4
MHz
—
External clock period
tTCLK
4
—
tcyc
3
D
External clock high time
tclkh
1.5
—
tcyc
4
D
External clock low time
tclkl
1.5
—
tcyc
5
D
Input capture pulse width
tICPW
1.5
—
tcyc
MC9S08DZ60 Series Data Sheet, Rev. 4
384
Freescale Semiconductor
Appendix A Electrical Characteristics
tTCLK
tclkh
TPMxCHn
tclkl
Figure A-5. Timer External Clock
tICPW
TPMxCHn
TPMxCHn
tICPW
Figure A-6. Timer Input Capture Pulse
A.12.3
MSCAN
Table A-15. MSCAN Wake-up Pulse Characteristics
Num C
Rating
Symbol
Min
Typ
Max
Unit
1
D MSCAN Wake-up dominant pulse filtered
tWUP
—
—
2
μs
2
D MSCAN Wake-up dominant pulse pass
tWUP
5
—
—
μs
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
385
Appendix A Electrical Characteristics
A.12.4
SPI
Table A-16 and Figure A-7 through Figure A-10 describe the timing requirements for the SPI system.
Table A-16. SPI Electrical Characteristic
Num1
C
1
D
Rating2
Symbol
Min
Max
Unit
Master
Slave
tSCK
tSCK
2
4
2048
—
tcyc
tcyc
Master
Slave
tLead
tLead
—
1/2
1/2
—
tSCK
tSCK
tLag
tLag
—
1/2
1/2
—
tSCK
tSCK
Cycle time
Enable lead time
2
D
Enable lag time
3
D
Master
Slave
4
D
Clock (SPSCK) high time
Master and Slave
tSCKH
(1/2 tSCK)– 25
—
ns
5
D
Clock (SPSCK) low time
Master and Slave
tSCKL
(1/2 tSCK) – 25
—
ns
6
D
Master
Slave
tSI(M)
tSI(S)
30
30
—
—
ns
ns
7
D
Master
Slave
tHI(M)
tHI(S)
30
30
—
—
ns
ns
8
D
Access time, slave3
tA
0
40
ns
9
D
Disable time,
slave4
tdis
—
40
ns
10
D
Data setup time (outputs)
Master
Slave
tSO
tSO
25
25
—
—
ns
ns
11
D
Master
Slave
tHO
tHO
–10
–10
—
—
ns
ns
Master
Slave
fop
fop
fBus/2048
dc
5
MHz
Data setup time (inputs)
Data hold time (inputs)
Data hold time (outputs)
Operating frequency5
12
D
fBus/4
1
Refer to Figure A-7 through Figure A-10.
All timing is shown with respect to 20% VDD and 70% VDD, unless noted; 100 pF load on all SPI
pins. All timing assumes slew rate control disabled and high drive strength enabled for SPI output
pins.
3
Time to data active from high-impedance state.
4 Hold time to high-impedance state.
5 Maximum baud rate must be limited to 5 MHz due to pad input characteristics.
2
MC9S08DZ60 Series Data Sheet, Rev. 4
386
Freescale Semiconductor
Appendix A Electrical Characteristics
SS1
(OUTPUT)
1
2
SCK
(CPOL = 0)
(OUTPUT)
3
5
4
SCK
(CPOL = 1)
(OUTPUT)
5
4
6
MISO
(INPUT)
7
MSB IN2
BIT 6 . . . 1
10
MOSI
(OUTPUT)
LSB IN
10
MSB OUT2
11
BIT 6 . . . 1
LSB OUT
NOTES:
1. SS output mode (MODFEN = 1, SSOE = 1).
2. LSBF = 0. For LSBF = 1, bit order is LSB, bit 1, ..., bit 6, MSB.
Figure A-7. SPI Master Timing (CPHA = 0)
SS(1)
(OUTPUT)
1
2
SCK
(CPOL = 0)
(OUTPUT)
3
5
4
SCK
(CPOL = 1)
(OUTPUT)
5
4
6
MISO
(INPUT)
7
MSB IN(2)
10
MOSI
(OUTPUT)
BIT 6 . . . 1
LSB IN
11
MSB OUT(2)
BIT 6 . . . 1
LSB OUT
NOTES:
1. SS output mode (MODFEN = 1, SSOE = 1).
2. LSBF = 0. For LSBF = 1, bit order is LSB, bit 1, ..., bit 6, MSB.
Figure A-8. SPI Master Timing (CPHA = 1)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
387
Appendix A Electrical Characteristics
SS
(INPUT)
3
1
SCK
(CPOL = 0)
(INPUT)
5
4
2
SCK
(CPOL = 1)
(INPUT)
5
4
8
MISO
(OUTPUT)
11
10
BIT 6 . . . 1
MSB OUT
SLAVE
SEE
NOTE
SLAVE LSB OUT
7
6
MOSI
(INPUT)
9
BIT 6 . . . 1
MSB IN
LSB IN
NOTE:
1. Not defined but normally MSB of character just received
Figure A-9. SPI Slave Timing (CPHA = 0)
SS
(INPUT)
1
3
2
SCK
(CPOL = 0)
(INPUT)
5
4
SCK
(CPOL = 1)
(INPUT)
5
4
10
MISO
(OUTPUT)
SEE
NOTE
8
MOSI
(INPUT)
SLAVE
11
MSB OUT
6
BIT 6 . . . 1
9
SLAVE LSB OUT
7
MSB IN
BIT 6 . . . 1
LSB IN
NOTE:
1. Not defined but normally LSB of character just received
Figure A-10. SPI Slave Timing (CPHA = 1)
MC9S08DZ60 Series Data Sheet, Rev. 4
388
Freescale Semiconductor
Appendix A Electrical Characteristics
A.13
Flash and EEPROM
This section provides details about program/erase times and program-erase endurance for the Flash and
EEPROM memory.
Program and erase operations do not require any special power sources other than the normal VDD supply.
For more detailed information about program/erase operations, see Chapter 4, “Memory.”
Table A-17. Flash and EEPROM Characteristics
Num
C
1
—
2
Symbol
Min
Max
Unit
Supply voltage for program/erase
Vprog/erase
2.7
5.5
V
—
Supply voltage for read operation
0 < fBus < 8 MHz
0 < fBus < 20 MHz
VRead
2.7
5.5
V
3
—
Internal FCLK frequency1
fFCLK
150
200
kHz
4
—
Internal FCLK period (1/FCLK)
tFcyc
5
6.67
μs
5
—
Byte program time (random location)(2)
tprog
9
tFcyc
6
—
Byte program time (burst mode)(2)
tBurst
4
tFcyc
7
—
Page erase time2
tPage
4000
tFcyc
8
—
Mass erase time(2)
tMass
20,000
tFcyc
C
Flash Program/erase endurance3
TL to TH = –40°C to + 125°C
T = 25°C
nFLPE
10
C
EEPROM Program/erase endurance3
TL to TH = –40°C to + 0°C
TL to TH = 0°C to + 125°C
T = 25°C
11
C
Data retention4
9
Rating
10,000
—
Typical
—
100,000
—
—
cycles
nEEPE
10,000
50,000
—
—
—
100,000
—
—
—
cycles
tD_ret
15
100
—
years
1
The frequency of this clock is controlled by a software setting.
These values are hardware state machine controlled. User code does not need to count cycles. This information supplied for
calculating approximate time to program and erase.
3 Typical endurance for Flash and EEPROM is based on the intrinsic bit cell performance. For additional information on how
Freescale Semiconductor defines typical endurance, please refer to Engineering Bulletin EB619, Typical Endurance for
Nonvolatile Memory.
4 Typical data retention values are based on intrinsic capability of the technology measured at high temperature and de-rated
to 25°C using the Arrhenius equation. For additional information on how Freescale Semiconductor defines typical data
retention, please refer to Engineering Bulletin EB618, Typical Data Retention for Nonvolatile Memory.
2
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
389
Appendix A Electrical Characteristics
A.14
EMC Performance
Electromagnetic compatibility (EMC) performance is highly dependant on the environment in which the
MCU resides. Board design and layout, circuit topology choices, location and characteristics of external
components as well as MCU software operation all play a significant role in EMC performance. The
system designer should consult Freescale applications notes such as AN2321, AN1050, AN1263,
AN2764, and AN1259 for advice and guidance specifically targeted at optimizing EMC performance.
A.14.1
Radiated Emissions
Microcontroller radiated RF emissions are measured from 150 kHz to 1 GHz using the TEM/GTEM Cell
method in accordance with the IEC 61967-2 and SAE J1752/3 standards. The measurement is performed
with the microcontroller installed on a custom EMC evaluation board while running specialized EMC test
software. The radiated emissions from the microcontroller are measured in a TEM cell in two package
orientations (North and East). For more detailed information concerning the evaluation results, conditions
and setup, please refer to the EMC Evaluation Report for this device.
The maximum radiated RF emissions of the tested configuration in all orientations are less than or equal
to the reported emissions levels.
Table A-18. Radiated Emissions for 3M05C Mask Set
Parameter
Symbol
Conditions
Frequency
VRE_TEM
VDD = 5
TA = +25oC
64 LQFP
0.15 – 50 MHz
Radiated emissions,
electric field — Conditions -
1
fosc/fCPU
50 – 150 MHz
150 – 500 MHz
500 – 1000 MHz
Level1
(Max)
Unit
18
dBμV
18
16 MHz
Crystal
20 MHz Bus
13
7
IEC Level
L
—
SAE Level
2
—
Data based on qualification test results.
MC9S08DZ60 Series Data Sheet, Rev. 4
390
Freescale Semiconductor
Appendix B
Timer Pulse-Width Modulator (TPMV2)
NOTE
This chapter refers to S08TPM version 2, which applies to the 3M05C and
older mask sets of this device. )M74K and newer mask set devices use
S08TPM version 3. If your device uses mask 0M74K or newer, please refer
to Chapter 16, “Timer Pulse-Width Modulator (S08TPMV3) for
information pertaining to that module.
The TPM uses one input/output (I/O) pin per channel, TPMxCHn where x is the TPM number (for
example, 1 or 2) and n is the channel number (for example, 0–4). The TPM shares its I/O pins with
general-purpose I/O port pins (refer to the Pins and Connections chapter for more information).
B.0.1
Features
The TPM has the following features:
• Each TPM may be configured for buffered, center-aligned pulse-width modulation (CPWM) on all
channels
• Clock sources independently selectable per TPM (multiple TPMs device)
• Selectable clock sources (device dependent): bus clock, fixed system clock, external pin
• Clock prescaler taps for divide by 1, 2, 4, 8, 16, 32, 64, or 128
• 16-bit free-running or up/down (CPWM) count operation
• 16-bit modulus register to control counter range
• Timer system enable
• One interrupt per channel plus a terminal count interrupt for each TPM module (multiple TPMs
device)
• Channel features:
— Each channel may be input capture, output compare, or buffered edge-aligned PWM
— Rising-edge, falling-edge, or any-edge input capture trigger
— Set, clear, or toggle output compare action
— Selectable polarity on PWM outputs
B.0.2
Block Diagram
Figure B-1 shows the structure of a TPM. Some MCUs include more than one TPM, with various numbers
of channels.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
391
Appendix B Timer Pulse-Width Modulator (TPMV2)
BUSCLK
XCLK
TPMxCLK
SYNC
CLOCK SOURCE
SELECT
OFF, BUS, XCLK, EXT
CLKSB
PRESCALE AND SELECT
DIVIDE BY
1, 2, 4, 8, 16, 32, 64, or 128
PS2
CLKSA
PS1
PS0
CPWMS
MAIN 16-BIT COUNTER
TOF
COUNTER RESET
INTERRUPT
LOGIC
TOIE
16-BIT COMPARATOR
TPMxMODH:TPMxMODL
CHANNEL 0
ELS0B
ELS0A
PORT
LOGIC
16-BIT COMPARATOR
TPMxC0VH:TPMxC0VL
CH0F
INTERRUPT
LOGIC
16-BIT LATCH
INTERNAL BUS
CHANNEL 1
MS0B
MS0A
ELS1B
ELS1A
CH0IE
TPMxCH1
PORT
LOGIC
16-BIT COMPARATOR
CH1F
TPMxC1VH:TPMxC1VL
INTERRUPT
LOGIC
16-BIT LATCH
MS1A
ELSnB
ELSnA
...
...
MS1B
CH1IE
...
CHANNEL n
TPMxCH0
TPMxCHn
PORT
LOGIC
16-BIT COMPARATOR
TPMxCnVH:TPMxCnVL
CHnF
16-BIT LATCH
MSnB
MSnA
CHnIE
INTERRUPT
LOGIC
Figure B-1. TPM Block Diagram
The central component of the TPM is the 16-bit counter that can operate as a free-running counter, a
modulo counter, or an up-/down-counter when the TPM is configured for center-aligned PWM. The TPM
counter (when operating in normal up-counting mode) provides the timing reference for the input capture,
output compare, and edge-aligned PWM functions. The timer counter modulo registers,
TPMxMODH:TPMxMODL, control the modulo value of the counter. (The values 0x0000 or 0xFFFF
effectively make the counter free running.) Software can read the counter value at any time without
affecting the counting sequence. Any write to either byte of the TPMxCNT counter resets the counter
regardless of the data value written.
MC9S08DZ60 Series Data Sheet, Rev. 4
392
Freescale Semiconductor
Appendix B Timer Pulse-Width Modulator (TPMV2)
All TPM channels are programmable independently as input capture, output compare, or buffered
edge-aligned PWM channels.
B.1
External Signal Description
When any pin associated with the timer is configured as a timer input, a passive pullup can be enabled.
After reset, the TPM modules are disabled and all pins default to general-purpose inputs with the passive
pullups disabled.
B.1.1
External TPM Clock Sources
When control bits CLKSB:CLKSA in the timer status and control register are set to 1:1, the prescaler and
consequently the 16-bit counter for TPMx are driven by an external clock source, TPMxCLK, connected
to an I/O pin. A synchronizer is needed between the external clock and the rest of the TPM. This
synchronizer is clocked by the bus clock so the frequency of the external source must be less than one-half
the frequency of the bus rate clock. The upper frequency limit for this external clock source is specified to
be one-fourth the bus frequency to conservatively accommodate duty cycle and phase-locked loop (PLL)
or frequency-locked loop (FLL) frequency jitter effects.
On some devices the external clock input is shared with one of the TPM channels. When a TPM channel
is shared as the external clock input, the associated TPM channel cannot use the pin. (The channel can still
be used in output compare mode as a software timer.) Also, if one of the TPM channels is used as the
external clock input, the corresponding ELSnB:ELSnA control bits must be set to 0:0 so the channel is not
trying to use the same pin.
B.1.2
TPMxCHn — TPMx Channel n I/O Pins
Each TPM channel is associated with an I/O pin on the MCU. The function of this pin depends on the
configuration of the channel. In some cases, no pin function is needed so the pin reverts to being controlled
by general-purpose I/O controls. When a timer has control of a port pin, the port data and data direction
registers do not affect the related pin(s). See the Pins and Connections chapter for additional information
about shared pin functions.
B.2
Register Definition
The TPM includes:
• An 8-bit status and control register (TPMxSC)
• A 16-bit counter (TPMxCNTH:TPMxCNTL)
• A 16-bit modulo register (TPMxMODH:TPMxMODL)
Each timer channel has:
• An 8-bit status and control register (TPMxCnSC)
• A 16-bit channel value register (TPMxCnVH:TPMxCnVL)
Refer to the direct-page register summary in the Memory chapter of this data sheet for the absolute address
assignments for all TPM registers. This section refers to registers and control bits only by their names. A
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
393
Appendix B Timer Pulse-Width Modulator (TPMV2)
Freescale-provided equate or header file is used to translate these names into the appropriate absolute
addresses.
B.2.1
Timer Status and Control Register (TPMxSC)
TPMxSC contains the overflow status flag and control bits that are used to configure the interrupt enable,
TPM configuration, clock source, and prescale divisor. These controls relate to all channels within this
timer module.
7
R
6
5
4
3
2
1
0
TOIE
CPWMS
CLKSB
CLKSA
PS2
PS1
PS0
0
0
0
0
0
0
0
TOF
W
Reset
0
= Unimplemented or Reserved
Figure B-2. Timer Status and Control Register (TPMxSC)
Table B-1. TPMxSC Register Field Descriptions
Field
Description
7
TOF
Timer Overflow Flag — This flag is set when the TPM counter changes to 0x0000 after reaching the modulo
value programmed in the TPM counter modulo registers. When the TPM is configured for CPWM, TOF is set
after the counter has reached the value in the modulo register, at the transition to the next lower count value.
Clear TOF by reading the TPM status and control register when TOF is set and then writing a 0 to TOF. If another
TPM overflow occurs before the clearing sequence is complete, the sequence is reset so TOF would remain set
after the clear sequence was completed for the earlier TOF. Reset clears TOF. Writing a 1 to TOF has no effect.
0 TPM counter has not reached modulo value or overflow
1 TPM counter has overflowed
6
TOIE
Timer Overflow Interrupt Enable — This read/write bit enables TPM overflow interrupts. If TOIE is set, an
interrupt is generated when TOF equals 1. Reset clears TOIE.
0 TOF interrupts inhibited (use software polling)
1 TOF interrupts enabled
5
CPWMS
Center-Aligned PWM Select — This read/write bit selects CPWM operating mode. Reset clears this bit so the
TPM operates in up-counting mode for input capture, output compare, and edge-aligned PWM functions. Setting
CPWMS reconfigures the TPM to operate in up-/down-counting mode for CPWM functions. Reset clears
CPWMS.
0 All TPMx channels operate as input capture, output compare, or edge-aligned PWM mode as selected by the
MSnB:MSnA control bits in each channel’s status and control register
1 All TPMx channels operate in center-aligned PWM mode
4:3
CLKS[B:A]
Clock Source Select — As shown in Table B-2, this 2-bit field is used to disable the TPM system or select one
of three clock sources to drive the counter prescaler. The external source and the XCLK are synchronized to the
bus clock by an on-chip synchronization circuit.
2:0
PS[2:0]
Prescale Divisor Select — This 3-bit field selects one of eight divisors for the TPM clock input as shown in
Table B-3. This prescaler is located after any clock source synchronization or clock source selection, so it affects
whatever clock source is selected to drive the TPM system.
MC9S08DZ60 Series Data Sheet, Rev. 4
394
Freescale Semiconductor
Appendix B Timer Pulse-Width Modulator (TPMV2)
Table B-2. TPM Clock Source Selection
CLKSB:CLKSA
TPM Clock Source to Prescaler Input
0:0
No clock selected (TPMx disabled)
0:1
Bus rate clock (BUSCLK)
1:0
Fixed system clock (XCLK)
1:1
External source (TPMxCLK)1,2
1
The maximum frequency that is allowed as an external clock is one-fourth of the bus
frequency.
2
If the external clock input is shared with channel n and is selected as the TPM clock source,
the corresponding ELSnB:ELSnA control bits should be set to 0:0 so channel n does not try
to use the same pin for a conflicting function.
Table B-3. Prescale Divisor Selection
B.2.2
PS2:PS1:PS0
TPM Clock Source Divided-By
0:0:0
1
0:0:1
2
0:1:0
4
0:1:1
8
1:0:0
16
1:0:1
32
1:1:0
64
1:1:1
128
Timer Counter Registers (TPMxCNTH:TPMxCNTL)
The two read-only TPM counter registers contain the high and low bytes of the value in the TPM counter.
Reading either byte (TPMxCNTH or TPMxCNTL) latches the contents of both bytes into a buffer where
they remain latched until the other byte is read. This allows coherent 16-bit reads in either order. The
coherency mechanism is automatically restarted by an MCU reset, a write of any value to TPMxCNTH or
TPMxCNTL, or any write to the timer status/control register (TPMxSC).
Reset clears the TPM counter registers.
R
7
6
5
4
3
2
1
0
Bit 15
14
13
12
11
10
9
Bit 8
0
0
W
Reset
Any write to TPMxCNTH clears the 16-bit counter.
0
0
0
0
0
0
Figure B-3. Timer Counter Register High (TPMxCNTH)
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
395
Appendix B Timer Pulse-Width Modulator (TPMV2)
R
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
W
Reset
Any write to TPMxCNTL clears the 16-bit counter.
0
0
0
0
0
0
Figure B-4. Timer Counter Register Low (TPMxCNTL)
When background mode is active, the timer counter and the coherency mechanism are frozen such that the
buffer latches remain in the state they were in when the background mode became active even if one or
both bytes of the counter are read while background mode is active.
B.2.3
Timer Counter Modulo Registers (TPMxMODH:TPMxMODL)
The read/write TPM modulo registers contain the modulo value for the TPM counter. After the TPM
counter reaches the modulo value, the TPM counter resumes counting from 0x0000 at the next clock
(CPWMS = 0) or starts counting down (CPWMS = 1), and the overflow flag (TOF) becomes set. Writing
to TPMxMODH or TPMxMODL inhibits TOF and overflow interrupts until the other byte is written. Reset
sets the TPM counter modulo registers to 0x0000, which results in a free-running timer counter (modulo
disabled).
7
6
5
4
3
2
1
0
Bit 15
14
13
12
11
10
9
Bit 8
0
0
0
0
0
0
0
0
R
W
Reset
Figure B-5. Timer Counter Modulo Register High (TPMxMODH)
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
0
0
0
0
0
0
R
W
Reset
Figure B-6. Timer Counter Modulo Register Low (TPMxMODL)
It is good practice to wait for an overflow interrupt so both bytes of the modulo register can be written well
before a new overflow. An alternative approach is to reset the TPM counter before writing to the TPM
modulo registers to avoid confusion about when the first counter overflow will occur.
MC9S08DZ60 Series Data Sheet, Rev. 4
396
Freescale Semiconductor
Appendix B Timer Pulse-Width Modulator (TPMV2)
B.2.4
Timer Channel n Status and Control Register (TPMxCnSC)
TPMxCnSC contains the channel interrupt status flag and control bits that are used to configure the
interrupt enable, channel configuration, and pin function.
7
6
5
4
3
2
CHnF
CHnIE
MSnB
MSnA
ELSnB
ELSnA
0
0
0
0
0
0
R
1
0
0
0
0
0
W
Reset
= Unimplemented or Reserved
Figure B-7. Timer Channel n Status and Control Register (TPMxCnSC)
Table B-4. TPMxCnSC Register Field Descriptions
Field
Description
7
CHnF
Channel n Flag — When channel n is configured for input capture, this flag bit is set when an active edge occurs
on the channel n pin. When channel n is an output compare or edge-aligned PWM channel, CHnF is set when
the value in the TPM counter registers matches the value in the TPM channel n value registers. This flag is
seldom used with center-aligned PWMs because it is set every time the counter matches the channel value
register, which correspond to both edges of the active duty cycle period.
A corresponding interrupt is requested when CHnF is set and interrupts are enabled (CHnIE = 1). Clear CHnF
by reading TPMxCnSC while CHnF is set and then writing a 0 to CHnF. If another interrupt request occurs before
the clearing sequence is complete, the sequence is reset so CHnF would remain set after the clear sequence
was completed for the earlier CHnF. This is done so a CHnF interrupt request cannot be lost by clearing a
previous CHnF. Reset clears CHnF. Writing a 1 to CHnF has no effect.
0 No input capture or output compare event occurred on channel n
1 Input capture or output compare event occurred on channel n
6
CHnIE
Channel n Interrupt Enable — This read/write bit enables interrupts from channel n. Reset clears CHnIE.
0 Channel n interrupt requests disabled (use software polling)
1 Channel n interrupt requests enabled
5
MSnB
Mode Select B for TPM Channel n — When CPWMS = 0, MSnB = 1 configures TPM channel n for
edge-aligned PWM mode. For a summary of channel mode and setup controls, refer to Table B-5.
4
MSnA
Mode Select A for TPM Channel n — When CPWMS = 0 and MSnB = 0, MSnA configures TPM channel n for
input capture mode or output compare mode. Refer to Table B-5 for a summary of channel mode and setup
controls.
3:2
ELSn[B:A]
Edge/Level Select Bits — Depending on the operating mode for the timer channel as set by
CPWMS:MSnB:MSnA and shown in Table B-5, these bits select the polarity of the input edge that triggers an
input capture event, select the level that will be driven in response to an output compare match, or select the
polarity of the PWM output.
Setting ELSnB:ELSnA to 0:0 configures the related timer pin as a general-purpose I/O pin unrelated to any timer
channel functions. This function is typically used to temporarily disable an input capture channel or to make the
timer pin available as a general-purpose I/O pin when the associated timer channel is set up as a software timer
that does not require the use of a pin.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
397
Appendix B Timer Pulse-Width Modulator (TPMV2)
Table B-5. Mode, Edge, and Level Selection
CPWMS
MSnB:MSnA
ELSnB:ELSnA
X
XX
00
0
00
01
01
Input capture
Capture on falling edge only
11
Capture on rising or falling edge
Output
compare
Software compare only
Toggle output on compare
10
Clear output on compare
11
Set output on compare
10
Edge-aligned
PWM
X1
XX
Capture on rising edge only
10
01
1
Configuration
Pin not used for TPM channel; use as an external clock for the TPM or
revert to general-purpose I/O
00
1X
Mode
10
Center-aligned
PWM
X1
High-true pulses (clear output on compare)
Low-true pulses (set output on compare)
High-true pulses (clear output on compare-up)
Low-true pulses (set output on compare-up)
If the associated port pin is not stable for at least two bus clock cycles before changing to input capture
mode, it is possible to get an unexpected indication of an edge trigger. Typically, a program would clear
status flags after changing channel configuration bits and before enabling channel interrupts or using the
status flags to avoid any unexpected behavior.
B.2.5
Timer Channel Value Registers (TPMxCnVH:TPMxCnVL)
These read/write registers contain the captured TPM counter value of the input capture function or the
output compare value for the output compare or PWM functions. The channel value registers are cleared
by reset.
7
6
5
4
3
2
1
0
Bit 15
14
13
12
11
10
9
Bit 8
0
0
0
0
0
0
0
0
R
W
Reset
Figure B-8. Timer Channel Value Register High (TPMxCnVH)
7
6
5
4
3
2
1
0
Bit 7
6
5
4
3
2
1
Bit 0
0
0
0
0
0
0
0
0
R
W
Reset
Figure B-9. Timer Channel Value Register Low (TPMxCnVL)
MC9S08DZ60 Series Data Sheet, Rev. 4
398
Freescale Semiconductor
Appendix B Timer Pulse-Width Modulator (TPMV2)
In input capture mode, reading either byte (TPMxCnVH or TPMxCnVL) latches the contents of both bytes
into a buffer where they remain latched until the other byte is read. This latching mechanism also resets
(becomes unlatched) when the TPMxCnSC register is written.
In output compare or PWM modes, writing to either byte (TPMxCnVH or TPMxCnVL) latches the value
into a buffer. When both bytes have been written, they are transferred as a coherent 16-bit value into the
timer channel value registers. This latching mechanism may be manually reset by writing to the
TPMxCnSC register.
This latching mechanism allows coherent 16-bit writes in either order, which is friendly to various
compiler implementations.
B.3
Functional Description
All TPM functions are associated with a main 16-bit counter that allows flexible selection of the clock
source and prescale divisor. A 16-bit modulo register also is associated with the main 16-bit counter in the
TPM. Each TPM channel is optionally associated with an MCU pin and a maskable interrupt function.
The TPM has center-aligned PWM capabilities controlled by the CPWMS control bit in TPMxSC. When
CPWMS is set to 1, timer counter TPMxCNT changes to an up-/down-counter and all channels in the
associated TPM act as center-aligned PWM channels. When CPWMS = 0, each channel can
independently be configured to operate in input capture, output compare, or buffered edge-aligned PWM
mode.
The following sections describe the main 16-bit counter and each of the timer operating modes (input
capture, output compare, edge-aligned PWM, and center-aligned PWM). Because details of pin operation
and interrupt activity depend on the operating mode, these topics are covered in the associated mode
sections.
B.3.1
Counter
All timer functions are based on the main 16-bit counter (TPMxCNTH:TPMxCNTL). This section
discusses selection of the clock source, up-counting vs. up-/down-counting, end-of-count overflow, and
manual counter reset.
After any MCU reset, CLKSB:CLKSA = 0:0 so no clock source is selected and the TPM is inactive.
Normally, CLKSB:CLKSA would be set to 0:1 so the bus clock drives the timer counter. The clock source
for the TPM can be selected to be off, the bus clock (BUSCLK), the fixed system clock (XCLK), or an
external input. The maximum frequency allowed for the external clock option is one-fourth the bus rate.
Refer to Section B.2.1, “Timer Status and Control Register (TPMxSC)” and Table B-2 for more
information about clock source selection.
When the microcontroller is in active background mode, the TPM temporarily suspends all counting until
the microcontroller returns to normal user operating mode. During stop mode, all TPM clocks are stopped;
therefore, the TPM is effectively disabled until clocks resume. During wait mode, the TPM continues to
operate normally.
The main 16-bit counter has two counting modes. When center-aligned PWM is selected (CPWMS = 1),
the counter operates in up-/down-counting mode. Otherwise, the counter operates as a simple up-counter.
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
399
Appendix B Timer Pulse-Width Modulator (TPMV2)
As an up-counter, the main 16-bit counter counts from 0x0000 through its terminal count and then
continues with 0x0000. The terminal count is 0xFFFF or a modulus value in TPMxMODH:TPMxMODL.
When center-aligned PWM operation is specified, the counter counts upward from 0x0000 through its
terminal count and then counts downward to 0x0000 where it returns to up-counting. Both 0x0000 and the
terminal count value (value in TPMxMODH:TPMxMODL) are normal length counts (one timer clock
period long).
An interrupt flag and enable are associated with the main 16-bit counter. The timer overflow flag (TOF) is
a software-accessible indication that the timer counter has overflowed. The enable signal selects between
software polling (TOIE = 0) where no hardware interrupt is generated, or interrupt-driven operation
(TOIE = 1) where a static hardware interrupt is automatically generated whenever the TOF flag is 1.
The conditions that cause TOF to become set depend on the counting mode (up or up/down). In
up-counting mode, the main 16-bit counter counts from 0x0000 through 0xFFFF and overflows to 0x0000
on the next counting clock. TOF becomes set at the transition from 0xFFFF to 0x0000. When a modulus
limit is set, TOF becomes set at the transition from the value set in the modulus register to 0x0000. When
the main 16-bit counter is operating in up-/down-counting mode, the TOF flag gets set as the counter
changes direction at the transition from the value set in the modulus register and the next lower count value.
This corresponds to the end of a PWM period. (The 0x0000 count value corresponds to the center of a
period.)
Because the HCS08 MCU is an 8-bit architecture, a coherency mechanism is built into the timer counter
for read operations. Whenever either byte of the counter is read (TPMxCNTH or TPMxCNTL), both bytes
are captured into a buffer so when the other byte is read, the value will represent the other byte of the count
at the time the first byte was read. The counter continues to count normally, but no new value can be read
from either byte until both bytes of the old count have been read.
The main timer counter can be reset manually at any time by writing any value to either byte of the timer
count TPMxCNTH or TPMxCNTL. Resetting the counter in this manner also resets the coherency
mechanism in case only one byte of the counter was read before resetting the count.
B.3.2
Channel Mode Selection
Provided CPWMS = 0 (center-aligned PWM operation is not specified), the MSnB and MSnA control bits
in the channel n status and control registers determine the basic mode of operation for the corresponding
channel. Choices include input capture, output compare, and buffered edge-aligned PWM.
B.3.2.1
Input Capture Mode
With the input capture function, the TPM can capture the time at which an external event occurs. When an
active edge occurs on the pin of an input capture channel, the TPM latches the contents of the TPM counter
into the channel value registers (TPMxCnVH:TPMxCnVL). Rising edges, falling edges, or any edge may
be chosen as the active edge that triggers an input capture.
When either byte of the 16-bit capture register is read, both bytes are latched into a buffer to support
coherent 16-bit accesses regardless of order. The coherency sequence can be manually reset by writing to
the channel status/control register (TPMxCnSC).
MC9S08DZ60 Series Data Sheet, Rev. 4
400
Freescale Semiconductor
Appendix B Timer Pulse-Width Modulator (TPMV2)
An input capture event sets a flag bit (CHnF) that can optionally generate a CPU interrupt request.
B.3.2.2
Output Compare Mode
With the output compare function, the TPM can generate timed pulses with programmable position,
polarity, duration, and frequency. When the counter reaches the value in the channel value registers of an
output compare channel, the TPM can set, clear, or toggle the channel pin.
In output compare mode, values are transferred to the corresponding timer channel value registers only
after both 8-bit bytes of a 16-bit register have been written. This coherency sequence can be manually reset
by writing to the channel status/control register (TPMxCnSC).
An output compare event sets a flag bit (CHnF) that can optionally generate a CPU interrupt request.
B.3.2.3
Edge-Aligned PWM Mode
This type of PWM output uses the normal up-counting mode of the timer counter (CPWMS = 0) and can
be used when other channels in the same TPM are configured for input capture or output compare
functions. The period of this PWM signal is determined by the setting in the modulus register
(TPMxMODH:TPMxMODL). The duty cycle is determined by the setting in the timer channel value
register (TPMxCnVH:TPMxCnVL). The polarity of this PWM signal is determined by the setting in the
ELSnA control bit. Duty cycle cases of 0 percent and 100 percent are possible.
As Figure B-10 shows, the output compare value in the TPM channel registers determines the pulse width
(duty cycle) of the PWM signal. The time between the modulus overflow and the output compare is the
pulse width. If ELSnA = 0, the counter overflow forces the PWM signal high and the output compare
forces the PWM signal low. If ELSnA = 1, the counter overflow forces the PWM signal low and the output
compare forces the PWM signal high.
OVERFLOW
OVERFLOW
OVERFLOW
PERIOD
PULSE
WIDTH
TPMxC
OUTPUT
COMPARE
OUTPUT
COMPARE
OUTPUT
COMPARE
Figure B-10. PWM Period and Pulse Width (ELSnA = 0)
When the channel value register is set to 0x0000, the duty cycle is 0 percent. By setting the timer channel
value register (TPMxCnVH:TPMxCnVL) to a value greater than the modulus setting, 100% duty cycle
can be achieved. This implies that the modulus setting must be less than 0xFFFF to get 100% duty cycle.
Because the HCS08 is a family of 8-bit MCUs, the settings in the timer channel registers are buffered to
ensure coherent 16-bit updates and to avoid unexpected PWM pulse widths. Writes to either register,
TPMxCnVH or TPMxCnVL, write to buffer registers. In edge-PWM mode, values are transferred to the
corresponding timer channel registers only after both 8-bit bytes of a 16-bit register have been written and
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
401
Appendix B Timer Pulse-Width Modulator (TPMV2)
the value in the TPMxCNTH:TPMxCNTL counter is 0x0000. (The new duty cycle does not take effect
until the next full period.)
B.3.3
Center-Aligned PWM Mode
This type of PWM output uses the up-/down-counting mode of the timer counter (CPWMS = 1). The
output compare value in TPMxCnVH:TPMxCnVL determines the pulse width (duty cycle) of the PWM
signal and the period is determined by the value in TPMxMODH:TPMxMODL.
TPMxMODH:TPMxMODL should be kept in the range of 0x0001 to 0x7FFF because values outside this
range can produce ambiguous results. ELSnA will determine the polarity of the CPWM output.
pulse width = 2 x (TPMxCnVH:TPMxCnVL)
Eqn. 17-1
period = 2 x (TPMxMODH:TPMxMODL);
for TPMxMODH:TPMxMODL = 0x0001–0x7FFF
Eqn. 17-2
If the channel value register TPMxCnVH:TPMxCnVL is zero or negative (bit 15 set), the duty cycle will
be 0%. If TPMxCnVH:TPMxCnVL is a positive value (bit 15 clear) and is greater than the (nonzero)
modulus setting, the duty cycle will be 100% because the duty cycle compare will never occur. This
implies the usable range of periods set by the modulus register is 0x0001 through 0x7FFE (0x7FFF if
generation of 100% duty cycle is not necessary). This is not a significant limitation because the resulting
period is much longer than required for normal applications.
TPMxMODH:TPMxMODL = 0x0000 is a special case that should not be used with center-aligned PWM
mode. When CPWMS = 0, this case corresponds to the counter running free from 0x0000 through
0xFFFF, but when CPWMS = 1 the counter needs a valid match to the modulus register somewhere other
than at 0x0000 in order to change directions from up-counting to down-counting.
Figure B-11 shows the output compare value in the TPM channel registers (multiplied by 2), which
determines the pulse width (duty cycle) of the CPWM signal. If ELSnA = 0, the compare match while
counting up forces the CPWM output signal low and a compare match while counting down forces the
output high. The counter counts up until it reaches the modulo setting in TPMxMODH:TPMxMODL, then
counts down until it reaches zero. This sets the period equal to two times TPMxMODH:TPMxMODL.
COUNT = 0
COUNT =
TPMxMODH:TPMx
OUTPUT
COMPARE
(COUNT UP)
OUTPUT
COMPARE
(COUNT DOWN)
COUNT =
TPMxMODH:TPMx
TPM1C
PULSE WIDTH
2x
2x
PERIOD
Figure B-11. CPWM Period and Pulse Width (ELSnA = 0)
Center-aligned PWM outputs typically produce less noise than edge-aligned PWMs because fewer I/O pin
transitions are lined up at the same system clock edge. This type of PWM is also required for some types
of motor drives.
MC9S08DZ60 Series Data Sheet, Rev. 4
402
Freescale Semiconductor
Appendix B Timer Pulse-Width Modulator (TPMV2)
Because the HCS08 is a family of 8-bit MCUs, the settings in the timer channel registers are buffered to
ensure coherent 16-bit updates and to avoid unexpected PWM pulse widths. Writes to any of the registers,
TPMxMODH, TPMxMODL, TPMxCnVH, and TPMxCnVL, actually write to buffer registers. Values are
transferred to the corresponding timer channel registers only after both 8-bit bytes of a 16-bit register have
been written and the timer counter overflows (reverses direction from up-counting to down-counting at the
end of the terminal count in the modulus register). This TPMxCNT overflow requirement only applies to
PWM channels, not output compares.
Optionally, when TPMxCNTH:TPMxCNTL = TPMxMODH:TPMxMODL, the TPM can generate a TOF
interrupt at the end of this count. The user can choose to reload any number of the PWM buffers, and they
will all update simultaneously at the start of a new period.
Writing to TPMxSC cancels any values written to TPMxMODH and/or TPMxMODL and resets the
coherency mechanism for the modulo registers. Writing to TPMxCnSC cancels any values written to the
channel value registers and resets the coherency mechanism for TPMxCnVH:TPMxCnVL.
B.4
TPM Interrupts
The TPM generates an optional interrupt for the main counter overflow and an interrupt for each channel.
The meaning of channel interrupts depends on the mode of operation for each channel. If the channel is
configured for input capture, the interrupt flag is set each time the selected input capture edge is
recognized. If the channel is configured for output compare or PWM modes, the interrupt flag is set each
time the main timer counter matches the value in the 16-bit channel value register. See the Resets,
Interrupts, and System Configuration chapter for absolute interrupt vector addresses, priority, and local
interrupt mask control bits.
For each interrupt source in the TPM, a flag bit is set on recognition of the interrupt condition such as timer
overflow, channel input capture, or output compare events. This flag may be read (polled) by software to
verify that the action has occurred, or an associated enable bit (TOIE or CHnIE) can be set to enable
hardware interrupt generation. While the interrupt enable bit is set, a static interrupt will be generated
whenever the associated interrupt flag equals 1. It is the responsibility of user software to perform a
sequence of steps to clear the interrupt flag before returning from the interrupt service routine.
B.4.1
Clearing Timer Interrupt Flags
TPM interrupt flags are cleared by a 2-step process that includes a read of the flag bit while it is set (1)
followed by a write of 0 to the bit. If a new event is detected between these two steps, the sequence is reset
and the interrupt flag remains set after the second step to avoid the possibility of missing the new event.
B.4.2
Timer Overflow Interrupt Description
The conditions that cause TOF to become set depend on the counting mode (up or up/down). In
up-counting mode, the 16-bit timer counter counts from 0x0000 through 0xFFFF and overflows to 0x0000
on the next counting clock. TOF becomes set at the transition from 0xFFFF to 0x0000. When a modulus
limit is set, TOF becomes set at the transition from the value set in the modulus register to 0x0000. When
the counter is operating in up-/down-counting mode, the TOF flag gets set as the counter changes direction
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
403
Appendix B Timer Pulse-Width Modulator (TPMV2)
at the transition from the value set in the modulus register and the next lower count value. This corresponds
to the end of a PWM period. (The 0x0000 count value corresponds to the center of a period.)
B.4.3
Channel Event Interrupt Description
The meaning of channel interrupts depends on the current mode of the channel (input capture, output
compare, edge-aligned PWM, or center-aligned PWM).
When a channel is configured as an input capture channel, the ELSnB:ELSnA control bits select rising
edges, falling edges, any edge, or no edge (off) as the edge that triggers an input capture event. When the
selected edge is detected, the interrupt flag is set. The flag is cleared by the 2-step sequence described in
Section B.4.1, “Clearing Timer Interrupt Flags.”
When a channel is configured as an output compare channel, the interrupt flag is set each time the main
timer counter matches the 16-bit value in the channel value register. The flag is cleared by the 2-step
sequence described in Section B.4.1, “Clearing Timer Interrupt Flags.”
B.4.4
PWM End-of-Duty-Cycle Events
For channels that are configured for PWM operation, there are two possibilities:
• When the channel is configured for edge-aligned PWM, the channel flag is set when the timer
counter matches the channel value register that marks the end of the active duty cycle period.
• When the channel is configured for center-aligned PWM, the timer count matches the channel
value register twice during each PWM cycle. In this CPWM case, the channel flag is set at the start
and at the end of the active duty cycle, which are the times when the timer counter matches the
channel value register.
The flag is cleared by the 2-step sequence described in Section B.4.1, “Clearing Timer Interrupt Flags.”
MC9S08DZ60 Series Data Sheet, Rev. 4
404
Freescale Semiconductor
Appendix C
Ordering Information and Mechanical Drawings
C.1
Ordering Information
This section contains ordering information for MC9S08DZ60 Series devices.
Example of the device numbering system:
MC 9 S08 DZ
60
F1 M XX
Status
(MC = Fully Qualified)
(S = Auto Qualified)
Memory
(9 = Flash-based)
Core
Package designator (see Table C-2)
Temperature range
(C = –40°C to 85°C)
(V = –40°C to 105°C)
(M = –40°C to 125°C)
Family
Mast Set Identifier
Only appears for “Auto Qualified” part numbers
beginning with “S”
F1 = 1M74K mask set
Approximate Flash
size in KB
C.1.1
MC9S08DZ60 Series Devices
Table C-1. Devices in the MC9S08DZ60 Series
Memory
Available Packages1
Device Number
1
C.2
FLASH
RAM
EEPROM
MC9S08DZ60
60,032
4096
2048
MC9S08DZ48
49,152
3072
1536
MC9S08DZ32
33,792
2048
1024
MC9S08DZ16
16,896
1024
512
64-LQFP,
48-LQFP, 32-LQFP
48-LQFP, 32-LQFP
See Table C-2 for package information.
Mechanical Drawings
The following pages are mechanical drawings for the packages described in the following table:
MC9S08DZ60 Series Data Sheet, Rev. 4
Freescale Semiconductor
405
Appendix C Ordering Information and Mechanical Drawings
Table C-2. Package Descriptions
Pin Count
64
Type
Low Quad Flat Package
Abbreviation
Designator
Document No.
LQFP
LH
98ASS23234W
48
Low Quad Flat Package
LQFP
LF
98ASH00962A
32
Low Quad Flat Package
LQFP
LC
98ASH70029A
MC9S08DZ60 Series Data Sheet, Rev. 4
406
Freescale Semiconductor
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