TERIDIAN 73S1215F

73S1215F
80515 System-on-Chip with USB,
ISO 7816 / EMV, PINpad and More
Simplifying System Integration™
DATA SHEET
December 2008
GENERAL DESCRIPTION
The 73S1215F is a versatile and economical
CMOS System-on-Chip device intended for smart
card reader applications. The circuit features an
ISO 7816 / EMV interface, an USB 2.0 interface
(full-speed 12Mbps device) and a 5x6 PINpad
interface. Maximum design flexibility is supported
with additional features such as 9 user I/Os,
multiple interrupt options, up to 4 programmable
current outputs (to drive external LEDs), and 1
analog voltage input (suitable for DC voltage
monitoring such as battery level detection). Other
built-in hardware interfaces include an
2
asynchronous serial UART and an I C interface.
The System-on-Chip is built around an 80515 high
performance core. Its feature and instruction set is
compatible with the industry standard 8051, while
offering one clock-cycle per instruction processing
power (most instructions)With a CPU clock running
up to 24MHz, it results in up to 20 MIPS available
that meets the requirements of various encryption
needs such as AES, DES / 3-DES and even RSA
(for PIN encryption for instance). The circuit
requires a single crystal, which frequency can be
between 6MHz and 12MHz. In addition, a 32768
Hz sub-system oscillator (optional) with an
independent real-time-clock counter enables standalone applications to access an RTC value. The
respective 73S1215F embedded memories are;
64KB Flash program memory, 2KB user XRAM
memory, and 256B IRAM memory. In addition to
these memories are independent FIFOs dedicated
to the ISO7816 UART and to the USB interface.
Overall, the 73S1215F offers a cost effective
solution to implement hand-held PINpad smart card
readers - USB connected, serial connected,
standalone or combo – as well as turnkey smart
®
card reader modules, USB or ExpressCard type.
Embedded Flash memory is in-system
programmable and lockable by means of on-silicon
fuses. This makes the Teridian 73S1215F suitable
for both development and production phases.
Rev. 1.4
Teridian Semiconductor Corporation offers with
its 73S1215F a very comprehensive set of
software libraries, including the smart card and
USB protocol layers that are pre-approved
against USB, Microsoft WHQL and EMV, as
well as a CCID reference design. Refer to the
73S12xxF Software User’s Guide for a
complete description of the Application
Programming Interface (API Libraries) and
related software modules.
A complete array of development and
programming tools, libraries and demonstration
boards enable rapid development and
certification of smart card readers that meet
most demanding smart card standards.
APPLICATIONS
• Hand-held PINpad smart card readers:
o Connected through USB, serial or
un-connected
o CCID-compliant
• E-banking (MasterCard CAP, etc)
• Smart card reader modules for PC laptops
and desktops: ExpressCard® , USB
• Digital Identification (Secure Login, Gov’t ID, ...)
• General purpose smart card readers
ADVANTAGES
• The ideal balance of cost and features for
high volume, USB-connected PINpad type
of applications:
o Larger built-in Flash / RAM than its
competitors
o Higher performance CPU core
o Powerful In-Circuit- Emulation and
Programming
o A complete set of ready-to-use EMV4.1 /
USB / CCID libraries
© 2008 Teridian Semiconductor Corporation
1
73S1215F Data Sheet
DS_1215F_003
FEATURES
80515 Core:
Communication Interfaces:
•
•
•
•
•
•
• Single low-cost 6MHz to 12MHz crystal
• Full-duplex serial interface (1200 to
115kbps UART)
• USB 2.0 Full Speed 12Mbps Interface,
PC/SC compliant with 4 Endpoints:
• Control (16B FIFO)
• Interrupt IN (32B FIFO)
• Bulk IN (128B FIFO)
• Bulk OUT (128B FIFO)
• I2C Master Interface (400kbps)
• Optional 32768 Hz crystal (with internal RTC)
Man-Machine Interface and I/Os:
• An Internal PLL provides all the necessary
clocks to each block of the system
1 clock cycle per instruction (most instructions)
CPU clocked up to 24MHz
64kB Flash memory with security
2kB XRAM (User Data Memory)
256 byte IRAM
Hardware watchdog timer
Oscillators:
•
Standard 80C515 4-priority level structure
• 5x6 Keyboard (hardware scanning,
debouncing and scrambling)
• Nine User I/Os
• Up to 4 programmable current outputs
(LED)
•
Nine different sources of interrupt to the core
Voltage Detection:
Interrupts:
Power Down Modes:
•
• 2 standard 80C515 Power Down and IDLE
modes
Operating Voltage:
• Extensive device power down mode
Timers:
• Two standard 80C52 timers T0 and T1
• One 16-bit timer that can generate RTC
interrupts from the 32kHz clock
Built-in ISO-7816 Card Interface:
•
•
Analog Input (detection range: 1.0V to 1.5V)
2.7V to 3.6V (3V to 3.6V when USB is in use)
4.75 to 5.5V for smart card supply
Operating Temperature:
•
-40°C to 85°C
Packages:
•
•
68-pin QFN
44-pin QFN
Software:
• LDO regulator produces VCC for the card
(1.8V, 3V or 5V)
• Two-level Application Programming Interface
• Full compliance with EMV 4.1
• USB, T=0/T=1 and EMV-compliant smart card
• Activation/Deactivation sequencers
• Auxiliary I/O lines (C4-C8 signals)
(ANSI C-language libraries)
protocol layers
• CCID reference design and Windows® driver
• 6kV ESD protection on all interface pins
Communication with Smart Cards:
• ISO 7816 UART for protocols T=0, T=1
• (2) 2-Byte FIFOs for transmit and receive
• Configured to drive multiple external Teridian
73S8010x interfaces (for multi-SAM
architectures)
2
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Table of Contents
1 Hardware Description ......................................................................................................................... 8 1.1 Pin Description .............................................................................................................................. 8 1.2 Hardware Overview .................................................................................................................... 11 1.3 80515 MPU Core ........................................................................................................................ 11 1.3.1 80515 Overview ............................................................................................................. 11 1.3.2 Memory Organization .................................................................................................... 11 1.4 Program Security ........................................................................................................................ 16 1.5 Special Function Registers (SFRs) ............................................................................................ 18 1.5.1 Internal Data Special Function Registers (SFRs).......................................................... 18 1.5.2 IRAM Special Function Registers (Generic 80515 SFRs) ............................................ 19 1.5.3 External Data Special Function Registers (SFRs) ........................................................ 20 1.6 Instruction Set ............................................................................................................................. 23 1.7 Peripheral Descriptions............................................................................................................... 23 1.7.1 Oscillator and Clock Generation .................................................................................... 23 1.7.2 Power Control Modes .................................................................................................... 27 1.7.3 Interrupts ........................................................................................................................ 33 1.7.4 UART ............................................................................................................................. 40 1.7.5 Timers and Counters ..................................................................................................... 45 1.7.6 WD Timer (Software Watchdog Timer) ......................................................................... 47 1.7.7 User (USR) Ports ........................................................................................................... 50 1.7.8 Real-Time Clock with Hardware Watchdog (RTC) ........................................................ 52 1.7.9 Analog Voltage Comparator .......................................................................................... 55 1.7.10 LED Drivers ................................................................................................................... 57 1.7.11 I2C Master Interface ....................................................................................................... 58 1.7.12 Keypad Interface ............................................................................................................ 65 1.7.13 Emulator Port ................................................................................................................. 72 1.7.14 USB Interface ................................................................................................................ 72 1.7.15 Smart Card Interface Function ...................................................................................... 76 1.7.16 VDD Fault Detect Function .......................................................................................... 110 2 Typical Application Schematic ...................................................................................................... 111 3 Electrical Specification................................................................................................................... 112 3.1 Absolute Maximum Ratings ...................................................................................................... 112 3.2 Recommended Operating Conditions ...................................................................................... 112 3.3 Digital IO Characteristics .......................................................................................................... 113 3.4 Oscillator Interface Requirements ............................................................................................ 114 3.5 DC Characteristics: Analog Input ............................................................................................. 114 3.6 USB Interface Requirements .................................................................................................... 115 3.7 Smart Card Interface Requirements ......................................................................................... 117 3.7.1 DC Characteristics ....................................................................................................... 119 3.8 Voltage / Temperature Fault Detection Circuits ....................................................................... 119 4 Equivalent Circuits ......................................................................................................................... 120 5 Package Pin Designation ............................................................................................................... 129 5.1 68-pin QFN Pinout .................................................................................................................... 129 5.2 44-pin QFN Pinout .................................................................................................................... 130 6 Packaging Information ................................................................................................................... 131 6.1 68-Pin QFN Package Outline ................................................................................................... 131 6.2 44-Pin QFN Package Outline ................................................................................................... 132 7 Ordering Information ...................................................................................................................... 133 8 Related Documentation .................................................................................................................. 133 9 Contact Information ........................................................................................................................ 133 Revision History ...................................................................................................................................... 134 Rev. 1.4
3
73S1215F Data Sheet
DS_1215F_003
Figures
Figure 1: IC Functional Block Diagram ......................................................................................................... 7
Figure 2: Memory Map ................................................................................................................................ 15
Figure 3: Clock Generation and Control Circuits ........................................................................................ 24
Figure 4: Oscillator Circuit ........................................................................................................................... 26
Figure 5: Power Down Control .................................................................................................................... 27
Figure 6: Detail of Power Down Interrupt Logic .......................................................................................... 28
Figure 7: Power Down Sequencing ............................................................................................................ 28
Figure 8: External Interrupt Configuration ................................................................................................... 33
Figure 9: Real Time Clock Block Diagram .................................................................................................. 52
Figure 10: I2C Write Mode Operation .......................................................................................................... 59
Figure 11: I2C Read Operation .................................................................................................................... 60
Figure 12: Simplified Keypad Block Diagram.............................................................................................. 65
Figure 13: Keypad Interface Flow Chart .................................................................................................... 67
Figure 14: USB Block Diagram ................................................................................................................... 72
Figure 15: Smart Card Interface Block Diagram ......................................................................................... 76
Figure 16: Smart Card Interface Block Diagram ......................................................................................... 77
Figure 17: Asynchronous Activation Sequence Timing .............................................................................. 79
Figure 18: Deactivation Sequence .............................................................................................................. 80
Figure 19: Smart Card CLK and ETU Generation ...................................................................................... 81
Figure 20: Guard, Block, Wait and ATR Time Definitions ........................................................................... 82
Figure 21: Synchronous Activation ............................................................................................................. 84
Figure 22: Example of Sync Mode Operation: Generating/Reading ATR Signals ..................................... 84
Figure 23: Creation of Synchronous Clock Start/Stop Mode Start Bit in Sync Mode ................................. 85
Figure 24: Creation of Synchronous Clock Start/Stop Mode Stop Bit in Sync Mode ................................. 85
Figure 25: Operation of 9-bit Mode in Sync Mode ...................................................................................... 86
Figure 26: 73S1215F Typical Application Schematic ............................................................................... 111
Figure 27: 12 MHz Oscillator Circuit ......................................................................................................... 120
Figure 28: 32kHz Oscillator Circuit ........................................................................................................... 120
Figure 29: Digital I/O Circuit ...................................................................................................................... 121
Figure 30: Digital Output Circuit ................................................................................................................ 121
Figure 31: Digital I/O with Pull Up Circuit .................................................................................................. 122
Figure 32: Digital I/O with Pull-Down Circuit ............................................................................................. 122
Figure 33: Digital Input Circuit ................................................................................................................... 123
Figure 34: Keypad Row Circuit ................................................................................................................. 123
Figure 35: Keypad Column Circuit ............................................................................................................ 124
Figure 36: LED Circuit ............................................................................................................................... 125
Figure 37: Test and Security Pin Circuit ................................................................................................... 125
Figure 38: Analog Input Circuit.................................................................................................................. 126
Figure 39: Smart Card Output Circuit ....................................................................................................... 126
Figure 40: Smart Card I/O Circuit.............................................................................................................. 127
Figure 41: PRES Input Circuit ................................................................................................................... 127
Figure 42: PRES Input Circuit ................................................................................................................... 128
Figure 43: USB Circuit .............................................................................................................................. 128
Figure 44: 73S1215F 68 QFN Pinout ....................................................................................................... 129
Figure 45: 73S1215F 44 QFN Pinout ....................................................................................................... 130
Figure 46: 73S1215F 68 QFN Package Drawing ..................................................................................... 131
Figure 47: 73S1215F 44 QFN Package Drawing ..................................................................................... 132
4
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Tables
Table 1: 73S1215F Pinout Description ......................................................................................................... 8
Table 2: MPU Data Memory Map................................................................................................................ 11
Table 3: Flash Special Function Registers ................................................................................................. 13
Table 4: Internal Data Memory Map ........................................................................................................... 14
Table 5: Program Security Registers .......................................................................................................... 17
Table 6: IRAM Special Function Registers Locations ................................................................................. 18
Table 7: IRAM Special Function Registers Reset Values........................................................................... 19
Table 8: XRAM Special Function Registers Reset Values ......................................................................... 20
Table 9: PSW Register Flags ...................................................................................................................... 22
Table 10: PSW Bit Functions ...................................................................................................................... 22
Table 11: Port Registers ............................................................................................................................. 23
Table 12: Frequencies and Mcount Values for MCLK = 96MHz ................................................................ 25
Table 13: The MCLKCtl Register ................................................................................................................ 25
Table 15: The MPUCKCtl Register ............................................................................................................. 26
Table 17: The INT5Ctl Register .................................................................................................................. 29
Table 19: The MISCtl0 Register .................................................................................................................. 29
Table 21: The MISCtl1 Register .................................................................................................................. 30
Table 23: The MCLKCtl Register ................................................................................................................ 31
Table 25: The PCON Register .................................................................................................................... 32
Table 27: The IEN0 Register....................................................................................................................... 34
Table 29: The IEN1 Register....................................................................................................................... 35
Table 31: The IEN2 Register....................................................................................................................... 35
Table 33: The TCON Register .................................................................................................................... 36
Table 35: The T2CON Register .................................................................................................................. 36
Table 37: The IRCON Register ................................................................................................................... 37
Table 39: External MPU Interrupts .............................................................................................................. 37
Table 40: Control Bits for External Interrupts .............................................................................................. 38
Table 41: Priority Level Groups................................................................................................................... 38
Table 42: The IP0 Register ......................................................................................................................... 38
Table 43: The IP1 Register ......................................................................................................................... 39
Table 44: Priority Levels .............................................................................................................................. 39
Table 45: Interrupt Polling Sequence .......................................................................................................... 39
Table 46: Interrupt Vectors.......................................................................................................................... 39
Table 47: UART Modes ............................................................................................................................... 40
Table 48: Baud Rate Generation ................................................................................................................ 40
Table 49: The PCON Register .................................................................................................................... 41
Table 51: The BRCON Register ................................................................................................................. 41
Table 53: The MISCtl0 Register .................................................................................................................. 42
Table 55: The S0CON Register .................................................................................................................. 43
Table 57: The S1CON Register .................................................................................................................. 44
Table 59: The TMOD Register .................................................................................................................... 45
Table 61: Timers/Counters Mode Description ............................................................................................ 46
Table 62: The TCON Register .................................................................................................................... 47
Table 64: The IEN0 Register....................................................................................................................... 48
Table 66: The IEN1 Register....................................................................................................................... 48
Table 68: The IP0 Register ......................................................................................................................... 49
Table 70: The WDTREL Register ............................................................................................................... 49
Table 72: Direction Registers and Internal Resources for DIO Pin Groups ............................................... 50
Table 73: UDIR Control Bit.......................................................................................................................... 50
Table 74: Selectable Controls Using the UxIS Bits ..................................................................................... 50
Table 75: The USRIntCtl1 Register ............................................................................................................ 51
Table 76: The USRIntCtl2 Register ............................................................................................................ 51
Table 77: The USRIntCtl3 Register ............................................................................................................ 51
Table 78: The USRIntCtl4 Register ............................................................................................................ 51
Table 79: The RTCCtl Register ................................................................................................................... 53
Table 81: The 32-bit RTC Counter .............................................................................................................. 54
Table 82: The 24-bit RTC Accumulator ...................................................................................................... 54
Rev. 1.4
5
73S1215F Data Sheet
DS_1215F_003
Table 83: The 24-bit RTC Trim (sign magnitude value) .............................................................................. 54
Table 84: The INT5Ctl Register .................................................................................................................. 54
Table 86: The ACOMP Register ................................................................................................................. 55
Table 88: The INT6Ctl Register .................................................................................................................. 56
Table 90: The LEDCtl Register ................................................................................................................... 57
Table 92: The DAR Register ....................................................................................................................... 61
Table 94: The WDR Register ...................................................................................................................... 61
Table 96: The SWDR Register.................................................................................................................... 62
Table 98: The RDR Register ....................................................................................................................... 62
Table 100: The SRDR Register .................................................................................................................. 63
Table 102: The CSR Register ..................................................................................................................... 63
Table 104: The INT6Ctl Register ................................................................................................................ 64
Table 106: The KCOL Register ................................................................................................................... 68
Table 108: The KROW Register ................................................................................................................. 68
Table 110: The KSCAN Register ................................................................................................................ 69
Table 112: The KSTAT Register ................................................................................................................. 69
Table 114: The KSIZE Register .................................................................................................................. 70
Table 116: The KORDERL Register ........................................................................................................... 70
Table 117: The KORDERH Register .......................................................................................................... 71
Table 120: The INT5Ctl Register ................................................................................................................ 71
Table 122: The MISCtl1 Register ................................................................................................................ 74
Table 124: The CKCON Register ............................................................................................................... 75
Table 126: The SCSel Register .................................................................................................................. 87
Table 127: The SCSel Bit Functions ........................................................................................................... 87
Table 128: The SCInt Register.................................................................................................................... 88
Table 130: The SCIE Register .................................................................................................................... 89
Table 132: The VccCtl Register .................................................................................................................. 90
Table 134: The VccTmr Register ................................................................................................................ 91
Table 138: The STXCtl Register ................................................................................................................. 93
Table 140: The STXData Register .............................................................................................................. 94
Table 142: The SRXCtl Register ................................................................................................................. 94
Table 144: The SRXData Register ............................................................................................................. 95
Table 146: The SCCtl Register ................................................................................................................... 96
Table 148: The SCECtl Register ................................................................................................................. 97
Table 150: The SCDIR Register ................................................................................................................. 98
Table 152: The SPrtcol Register ................................................................................................................. 99
Table 154: The SCCLK Register .............................................................................................................. 100
Table 156: The SCECLK Register ............................................................................................................ 100
Table 158: The SParCtl Register .............................................................................................................. 101
Table 160: The SByteCtl Register............................................................................................................. 102
Table 161: The SByteCtl Bit Functions ..................................................................................................... 102
Table 162: The FDReg Register ............................................................................................................... 103
Table 163: Divider Ratios Provided by the ETU Counter ......................................................................... 103
Table 164: Divider Values for the ETU Clock ........................................................................................... 104
Table 165: The FDReg Bit Functions ........................................................................................................ 104
Table 166: The CRCMsB Register ........................................................................................................... 105
Table 167: The CRCLsB Register ............................................................................................................ 105
Table 168: The BGT Register ................................................................................................................... 106
Table 170: The EGT Register ................................................................................................................... 106
Table 172: The BWTB0 Register .............................................................................................................. 107
Table 173: The BWTB1 Register .............................................................................................................. 107
Table 174: The BWTB2 Register .............................................................................................................. 107
Table 175: The BWTB3 Register .............................................................................................................. 107
Table 176: The CWTB0 Register .............................................................................................................. 107
Table 177: The CWTB1 Register .............................................................................................................. 107
Table 178: The ATRLsB Register ............................................................................................................. 108
Table 179: The ATRMsB Register ............................................................................................................ 108
Table 180: The STSTO Register............................................................................................................... 108
6
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
VPC
TBUS0
TBUS1
TBUS2
RXTX
TBUS3
ERST
ISBR
TCLK
VDD
ANA_IN
SEC
RESET
TEST
GND
Table 181: The RLength Register ............................................................................................................. 108
Table 182: Smart Card SFR Table ........................................................................................................... 109
Table 183: The VDDFCtl Register ............................................................................................................ 110
Table 185: Order Numbers and Packaging Marks ................................................................................... 133
ICE INTERFACE
X12IN
X12OUT
X32IN
X32OUT
12MHz
OSCILLATOR
FLASH/ROM
PROGRAM
MEMORY
64KB
USB I/O
and
LOGIC
FLASH
INTERFACE
MEMORY_
CONTROL
CONTROL
UNIT
RAM_
SFR_
CONTROL
TIMER_0_
1
SCRATCH
IRAM
256B
CORE
SMART
CARD
ISO
INTERFACE
PRESB
EXTERNAL
SMART
CARD
INTERFACE
ISR
INT3
SERIAL
2
IC
MASTER
INT.
SCL
SDA
PERIPHERAL
INTERFACE
and SFR LOGIC
USR(8:0)
DRIVERS
LED2
LED1
LED0
Pins only avaiable on 68 pin package.
TXD
Pins avaiable on both 68 and 44 pin packages.
RXD
LED
DRIVERS
GND
USR0
USR1
USR2
USR3
USR4
USR5
USR6
USR7
USR8
SIO
INT2
PORTS
KEYPAD
INTERFACE
SCLK
WATCHDOG
TIMER
PMU
DATA
XRAM
2KB
AUX1
PRES
ALU
ROW0
ROW1
ROW2
ROW3
I/O
AUX2
GND
ROW4
ROW5
COL0
COL1
COL2
COL3
COL4
GND
CLK
OCDSI
VDD
D+
VCC
RST
32kHz
OSCILLATOR
RTC
D-
VCC
CONTROL
LOGIC
VOLTAGE REFERENCE
AND FUSE TRIM
CIRCUITRY
VPD REGULATOR
LED3
CPUCLK
PLL
and
TIMEBASES
SMART CARD LOGIC
ISO UART and CLOCK GENERATOR
VDD
Figure 1: IC Functional Block Diagram
Rev. 1.4
7
73S1215F Data Sheet
DS_1215F_003
1 Hardware Description
1.1 Pin Description
Pin (68 Qfn)
Pin (44 Qfn)
Type
Equivalent
Circuit*
Table 1: 73S1215F Pinout Description
X12IN
10
8
I
Figure 27
X12OUT
X32IN
11
8
9
O
I
Figure 27
Figure 28
X32OUT
CPUCLK
7
39
O
O
Figure 28
Figure 30
DP
DM
ROW(5:0)
0
1
2
3
4
5
COL(4:0)
0
1
2
3
4
USR(8:0)
0
1
2
3
4
5
6
7
8
SCL
26
27
IO
IO
I
Figure 43
Figure 43
Figure 34
MPU/USB clock crystal oscillator input pin. A 12MHz
crystal is required for USB operation. A 1MΩ resistor
is required between pins X12IN and X12OUT.
MPU/USB clock crystal oscillator output pin.
RTC clock crystal oscillator input pin. A 32768Hz
crystal is required for low-power RTC operation.
RTC clock crystal oscillator output pin.
Output signal, square wave at the frequency of the
MPU clock.
USB D+ IO pin, requires series 24Ω resistor.
USB D- IO pin, requires series 24Ω resistor.
Keypad row input sense.
O
Figure 35
Keypad column output scan pins.
36
35
33
31
30
29
23
20
32
5
24
23
22
21
20
19
14
13
IO
Figure 31
General-purpose user pins, individually configurable as
inputs or outputs or as external input interrupt ports.
5
O
Figure 30
SDA
6
6
IO
Figure 29
I2C (master mode) compatible Clock signal. Note: the
pin is configured as an open drain output. When the
I2C interface is being used, an external pull up resistor
is required. A value of 3K is recommended.
I2C (master mode) compatible data I/O. Note: this pin is
bi-directional. When the pin is configured as output, it
is an open drain output. When the I2C interface is
being used, an external pull up resistor is required. A
value of 3K is recommended.
Pin Name
8
16
17
Description
21
22
24
34
37
38
12
13
14
16
19
Rev. 1.4
1
3
2
4
17
18
51
52
50
3
4
11
12
SCLK
Equivalent
Circuit*
LED(3:0)
0
1
2
3
RXD
TXD
INT3
INT2
SIO
Type
Pin (44 Qfn)
73S1215F Data Sheet
Pin (68 Qfn)
DS_1215F_003
IO
Figure 36
Special output drivers, programmable pull-down
current to drive LEDs. May also be used as inputs.
32
31
I
O
I
I
IO
Figure 33
Figure 30
Figure 33
Figure 33
Figure 29
48
30
O
Figure 30
PRES
64
43
I
Figure 41
PRES
56
35
I
Figure 42
CLK
RST
IO
AUX1
AUX2
VCC
57
59
63
62
61
60
36
38
42
41
40
39
O
O
IO
IO
IO
PSO
Figure 39
Figure 39
Figure 40
Figure 40
Figure 40
GND
VPC
58
55
37
34
GND
PSI
IO
Serial UART Receive data pin.
Serial UART Transmit data pin.
General purpose interrupt input.
General purpose interrupt input.
IO data signal for use with external Smart Card
interface circuit such as 73S8024.
Clock signal for use with external Smart Card interface
circuit.
Smart Card presence. Active high. Note: the pin has a
very weak pull down resistor. In noisy environments,
an external pull down may be desired to insure against
a false card event.
Smart Card presence. Active low. Note: the pin has a
very weak pull up resistor. In noisy environments, an
external pull up may be desired to insure against a
false card event.
Smart card clock signal.
Smart card Reset signal.
Smart card Data IO signal.
Auxiliary Smart Card IO signal (C4).
Auxiliary Smart Card IO signal (C8).
Smart Card VCC supply voltage output. A 0.47μF
capacitor is required and should be located at the
smart card connector. The capacitor should be a
ceramic type with low ESR.
Smart Card Ground.
Smart Card LDO regulator power supply source. A
10μF and a 0.1μF capacitor are required at the VPC
input. The 10μF capacitor should be a ceramic type
with low ESR.
Trace bus signals for ICE.
IO
IO
IO
I
ICE control.
ICE control.
ICE control.
ICE control.
Pin Name
TBUS(3:0)
0
1
2
3
RXTX
ERST
ISBR
TCLK
Rev. 1.4
Description
53
49
47
43
45
40
68
41
28
25
26
9
Pin (44 Qfn)
Type
Equivalent
Circuit*
DS_1215F_003
Pin (68 Qfn)
73S1215F Data Sheet
ANA_IN
15
10
AI
Figure 38
SEC
67
2
I
Figure 37
TEST
VDD
54
28
42
65
33
18
27
44
DI
I
Figure 37
N/C
GND
46
9
25
44
29
7
15
0
GND
RESET
66
1
I
Pin Name
Figure 33
Description
Analog input pin. This signal goes to a programmable
comparator and is used to sense the value of an
external voltage.
Input pin for use in programming security fuse. It
should be connected to ground when not in use.
Test pin, should be connected to ground.
General positive power supply pins. All digital IO is
referred to this supply voltage. There is an on-chip
regulator that uses VDD to provide power for internal
circuits (VPD). A 0.1μF capacitor is recommended at
each VDD pin.
No connect.
General ground supply pins for all IO and logic circuits.
Reset input, positive assertion. Resets logic and
registers to default condition.
* See the figures in the Equivalent Circuits section.
10
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
1.2 Hardware Overview
The Teridian 73S1215F single smart card controller integrates all primary functional blocks required to
implement a smart card reader. Included on chip are an 8051-compatible microprocessor (MPU) which
executes up to one instruction per clock cycle (80515), a fully integrated IS0-7816 compliant smart card
interface, expansion smart card interface, full speed USB 2.0 compatible interface, serial interface, I2C
interface, 6 x 5 keypad interface, 4 LED drivers, RAM, FLASH memory, a real time clock (RTC), and a
variety of I/O pins. Figure 1 shows a functional block diagram of the 73S1215F.
1.3 80515 MPU Core
1.3.1
80515 Overview
The 73S1215F includes an 80515 MPU (8-bit, 8051-compatible) that performs most instructions in one
clock cycle. The 80515 architecture eliminates redundant bus states and implements parallel execution
of fetch and execution phases. Normally a machine cycle is aligned with a memory fetch, therefore, most
of the 1-byte instructions are performed in a single cycle. This leads to an 8x performance (average)
improvement (in terms of MIPS) over the Intel 8051 device running at the same clock frequency.
Actual processor clocking speed can be adjusted to the total processing demand of the application
(cryptographic calculations, key management, memory management, and I/O management) using the
XRAM special function register MPUCKCtl.
Typical smart card, USB, serial, keyboard, I2C, and RTC management functions are available for the
MPU as part of the Teridian standard library. A standard ANSI “C” 80515-application programming
interface library is available to help reduce design cycle. Refer to the 73S12xxF Software User’s Guide.
1.3.2
Memory Organization
The 80515 MPU core incorporates the Harvard architecture with separate code and data spaces.
Memory organization in the 80515 is similar to that of the industry standard 8051. There are three
memory areas: Program memory (Flash), external data memory (XRAM), and internal data memory
(IRAM). Data bus address space is allocated to on-chip memory as shown Table 2.
Table 2: MPU Data Memory Map
Address
(hex)
Memory
Technology
Memory Type
Typical Usage
Memory Size
(bytes)
0000-FFFF
Flash Memory
Non-volatile
Program and non-volatile data
64KB
0000-07FF
Static RAM
Volatile
MPU data XRAM
2KB
FC00-FFFF
External SFR
Volatile
Peripheral control
1KB
Note: The IRAM is part of the core and is addressed differently.
Program Memory: The 80515 can address up to 64KB of program memory space from 0x0000 to
0xFFFF. Program memory is read when the MPU fetches instructions or performs a MOVC operation.
After reset, the MPU starts program execution from location 0x0000. The lower part of the program
memory includes reset and interrupt vectors. The interrupt vectors are spaced at 8-byte intervals, starting
from 0x0003 (Reset is located at 0x0000).
Flash Memory: The program memory consists of flash memory. The flash memory is intended to
primarily contain MPU program code. Flash erasure is initiated by writing a specific data pattern to
specific SFR registers in the proper sequence. These special pattern/sequence requirements prevent
inadvertent erasure of the flash memory.
Rev. 1.4
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73S1215F Data Sheet
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The mass erase sequence is:
1. Write 1 to the FLSH_MEEN bit in the FLSHCTL register (SFR address 0xB2[1]).
2. Write pattern 0xAA to ERASE (SFR address 0x94).
Note: The mass erase cycle can only be initiated when the ICE port is enabled.
The page erase sequence is:
1. Write the page address to PGADDR (SFR address 0xB7[7:1]).
2. Write pattern 0x55 to ERASE (SFR address 0x94).
The PGADDR register denotes the page address for page erase. The page size is 512 (200h) bytes and
there are 128 pages within the flash memory. The PGADDR denotes the upper seven bits of the flash
memory address such that bit 7:1 of the PGADDR corresponds to bit 15:9 of the flash memory address.
Bit 0 of the PGADDR is not used and is ignored. The MPU may write to the flash memory. This is one of
the non-volatile storage options available to the user. The FLSHCTL SFR bit FLSH_PWE (flash program
write enable) differentiates 80515 data store instructions (MOVX@DPTR,A) between Flash and XRAM
writes. Before setting FLSH_PWE, all interrupts need to be disabled by setting EAL = 1. Table 3 shows
the location and description of the 73S1215F flash-specific SFRs.
Any flash modifications must set the CPUCLK to operate at 3.6923 MHz (MPUCLKCtl = 0x0C)
before any flash memory operations are executed to insure the proper timing when modifying the
flash memory.
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73S1215F Data Sheet
Table 3: Flash Special Function Registers
Register
ERASE
SFR
Address
R/W
0x94
W
Description
This register is used to initiate either the Flash Mass Erase cycle or the
Flash Page Erase cycle. Specific patterns are expected for ERASE in
order to initiate the appropriate Erase cycle (default = 0x00).
0x55 – Initiate Flash Page Erase cycle. Must be proceeded by a write to
PGADDR @ SFR 0xB7.
0xAA – Initiate Flash Mass Erase cycle. Must be proceeded by a write to
FLSH_MEEN @ SFR 0xB2 and the debug port must be enabled.
Any other pattern written to ERASE will have no effect.
PGADDR
0xB7
R/W
Flash Page Erase Address register containing the flash memory page
address (page 0 through 127) that will be erased during the Page Erase
cycle (default = 0x00). Note: the page address is shifted left by one bit
(see detailed description above).
Must be re-written for each new Page Erase cycle.
FLSHCTL
0xB2
R/W
Bit 0 (FLSH_PWE): Program Write Enable:
0 – MOVX commands refer to XRAM Space, normal operation (default).
1 – MOVX @DPTR,A moves A to Program Space (Flash) @ DPTR.
This bit is automatically reset after each byte written to flash. Writes to
this bit are inhibited when interrupts are enabled.
W
Bit 1 (FLSH_MEEN): Mass Erase Enable:
0 – Mass Erase disabled (default).
1 – Mass Erase enabled.
Must be re-written for each new Mass Erase cycle.
R/W
Bit 6 (SECURE):
Enables security provisions that prevent external reading of flash memory
and CE program RAM. This bit is reset on chip reset and may only be
set. Attempts to write zero are ignored.
Rev. 1.4
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73S1215F Data Sheet
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Internal Data Memory: The Internal data memory provides 256 bytes (0x00 to 0xFF) of data memory.
The internal data memory address is always one byte wide and can be accessed by either direct or
indirect addressing. The Special Function Registers occupy the upper 128 bytes. This SFR area is
available only by direct addressing. Indirect addressing accesses the upper 128 bytes of Internal
RAM.
The lower 128 bytes contain working registers and bit-addressable memory. The lower 32 bytes form
four banks of eight registers (R0-R7). Two bits on the program memory status word (PSW) select which
bank is in use. The next 16 bytes form a block of bit-addressable memory space at bit addresses 0x000x7F. All of the bytes in the lower 128 bytes are accessible through direct or indirect addressing. Table 4
shows the internal data memory map.
Table 4: Internal Data Memory Map
Address
0xFF
0x80
0x7F
0x30
0x2F
0x20
0x1F
0x00
Direct Addressing
Indirect Addressing
Special Function
Registers (SFRs)
RAM
Byte-addressable area
Byte or bit-addressable area
Register banks R0…R7 (x4)
External Data Memory: While the 80515 can address up to 64KB of external data memory in the space
from 0x0000 to 0xFFFF, only the memory ranges shown in Figure 2 contain physical memory. The
80515 writes into external data memory when the MPU executes a MOVX @Ri,A or MOVX @DPTR,A
instruction. The MPU reads external data memory by executing a MOVX A,@Ri or MOVX A,@DPTR
instruction.
There are two types of instructions, differing in whether they provide an eight-bit or sixteen-bit indirect
address to the external data RAM.
In the first type (MOVX A,@Ri), the contents of R0 or R1, in the current register bank, provide the eight
lower-ordered bits of address. This method allows the user access to the first 256 bytes of the 2KB of
external data RAM. In the second type of MOVX instruction (MOVX A,@DPTR), the data pointer
generates a sixteen-bit address.
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Rev. 1.4
DS_1215F_003
Address
Use
0xFFFF
73S1215F Data Sheet
Address
Use
0xFFFF
Peripheral Control
Registers (128b)
0XFF80
0xFF7F
0XFE00
0xFDFF
0XFC00
0xFBFF
0x0800
Smart Card Control
(384b)
USB Registers (512b)
–
Use
Address
0x07FF
0xFF
Flash
Program
Memory
0x80
Indirect
Access
Direct
Access
Byte RAM
SFRs
0x7F
64K
Bytes
Byte RAM
0x48
0x47
XRAM
Bit/Byte RAM
0x20
0x1F
Register bank 3
0x18
0x17
Register bank 2
0x10
0x0F
Register bank 1
0x08
0x07
0x0000
Program Memory
0x0000
Register bank 0
0x00
External Data Memory
Internal Data Memory
Figure 2: Memory Map
Dual Data Pointer: The Dual Data Pointer accelerates the block moves of data. The standard DPTR is a
16-bit register that is used to address external memory. In the 80515 core, the standard data pointer is
called DPTR, the second data pointer is called DPTR1. The data pointer select bit chooses the active
pointer. The data pointer select bit is located at the LSB of the DPS IRAM special function register
(DPS.0). DPTR is selected when DPS.0 = 0 and DPTR1 is selected when DPS.0 = 1.
The user switches between pointers by toggling the LSB of the DPS register. All DPTR-related
instructions use the currently selected DPTR for any activity.
Note: The second data pointer may not be supported by certain compilers.
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73S1215F Data Sheet
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1.4 Program Security
Two levels of program and data security are available. Each level requires a specific fuse to be blown in
order to enable or set the specific security mode. Mode 0 security is enabled by setting the SECURE bit
(bit 6 of SFR register FLSHCTL 0xB2) Mode 0 limits the ICE interface to only allow bulk erase of the
flash program memory. All other ICE operations are blocked. This guarantees the security of the user’s
MPU program code. Security (Mode 0) is enabled by MPU code that sets the SECURE bit. The MPU
code must execute the setting of the SECURE bit immediately after a reset to properly enable Mode 0.
This should be the first instruction after the reset vector jump has been executed. If the “startup.a51”
assembly file is used in an application, then it must be modified to set the SECURE bit after the reset
vector jump. If not using “startup.a51”, then this should be the first instruction in main(). Once security
Mode 0 is enabled, the only way to disable it is to perform a global erase of the flash followed by a full
circuit reset. Once the flash has been erased and the reset has been executed, security Mode 0 is
disabled and the ICE has full control of the core. The flash can be reprogrammed after the bulk erase
operation is completed. Global erase of the flash will also clear the data XRAM memory.
The security enable bit (SECURE) is reset whenever the MPU is reset. Hardware associated with the bit
only allows it to be set. As a result, the code may set the SECURE bit to enable the security Mode 0
feature but may not reset it. Once the SECURE bit is set, the code is protected and no external read of
program code in flash or data (in XRAM) is possible. In order to invoke the security Mode 0, the
SECSET0 (bit 1 of the XRAM SFR register SECReg 0xFFD7) fuse must be blown beforehand or the
security mode 0 will not be enabled. The SECSET0 and SECSET1 fuses once blown, cannot be
overridden.
Specifically, when SECURE is set:
• The ICE is limited to bulk flash erase only.
• Page zero of flash memory may not be page-erased by either MPU or ICE. Page zero may only be
erased with global flash erase. Note that global flash erase erases XRAM whether the SECURE bit is
set or not.
• Writes to page zero, whether by MPU or ICE, are inhibited.
Security mode 1 is in effect when the SECSET1 fuse has been programmed (blown open). In security
mode 1, the ICE is completely and permanently disabled. The Flash program memory and the MPU are
not available for alteration, observation, nor control. As soon as the fuse has been blown, the ICE is
disabled. The testing of the SECSET1 fuse will occur during the reset and before the start of pre-boot
and boot cycles. This mode is not reversible, nor recoverable. In order to blow the SECSET1 fuse, the
SEC pin must be held high for the fuse burning sequence to be executed properly. The firmware can
check to see if this pin is held high by reading the SECPIN bit (bit 5 of XRAM SFR register SECReg
0xFFD7). If this bit is set and the firmware desires, it can blow the SECSET1 fuse. The burning of the
SECSET0 does not require the SEC pin to be held high.
In order to blow the fuse for SECSET1 and SECSET0, a particular set of register writes in a specific order
need to be followed. There are two additional registers that need to have a specific value written to them
in order for the desired fuse to be blown. These registers are FUSECtl (0xFFD2) and TRIMPCtl
(0xFFD1). The sequence for blowing the fuse is as follows:
1.
2.
3.
4.
5.
6.
16
Write 0x54H to FUSECtl.
Write 0x81H for security mode 0.
Write 0x82H for security mode 1.
Write 0xA6 to TRIMPCtl.
Delay about 500 us.
Write 0x00 to TRIMPCtl.
Note: only program one security mode at a time.
Note: SEC pin must be high for security mode 1.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Table 5: Program Security Registers
Register
SFR
Address
R/W
Description
FLSHCTL
0xB2
R/W
Bit 0 (FLSH_PWE): Program Write Enable:
0 – MOVX commands refer to XRAM Space, normal operation (default).
1 – MOVX @DPTR,A moves A to Program Space (Flash) @ DPTR.
This bit is automatically reset after each byte written to flash. Writes to
this bit are inhibited when interrupts are enabled.
W
Bit 1 (FLSH_MEEN): Mass Erase Enable:
0 – Mass Erase disabled (default).
1 – Mass Erase enabled.
Must be re-written for each new Mass Erase cycle.
R/W
Bit 6 (SECURE):
Enables security provisions that prevent external reading of flash
memory and CE program RAM. This bit is reset on chip reset and may
only be set. Attempts to write zero are ignored.
TRIMPCtl
0xFFD1
W
0xA6 value will cause the selected fuse to be blown. All other values
will stop the burning process.
FUSECtl
0xFFD2
W
0x54 value will set up for security fuse control. All other values are
reserved and should not be used.
SECReg
0xFFD7
W
Bit 7 (PARAMSEC):
0 – Normal operation.
1 – Enable permanent programming of the security fuses.
R
Bit 5 (SECPIN):
Indicates the state of the SEC pin. The SEC pin is held low by a pulldown resistor. The user can force this pin high during boot sequence
time to indicate to firmware that sec mode 1 is desired.
R/W
Bit 1 (SECSET1):
See the Program Security section.
R/W
Bit 0 (SECSET0):
See the Program Security section.
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73S1215F Data Sheet
DS_1215F_003
1.5 Special Function Registers (SFRs)
The 73S1215F utilizes numerous SFRs to communicate with the 73S1215F s many peripherals. This
results in the need for more SFR locations outside the direct address IRAM space (0x80 to 0xFF). While
some peripherals are mapped to unused IRAM SFR locations, additional SFRs for the USB, smart card
and other peripheral functions are mapped to the top of the XRAM data space (0xFC00 to 0xFFFF).
1.5.1
Internal Data Special Function Registers (SFRs)
A map of the Special Function Registers is shown in Table 6.
Table 6: IRAM Special Function Registers Locations
Hex\
Bin
F8
F0
E8
E0
D8
D0
C8
C0
B8
B0
A8
A0
98
90
88
80
X000
X001
X010
X011
X100
X101
KCOL
KROW
KSCAN
KSTAT
KSIZE
X110
X111
B
A
BRCON
PSW
T2CON
IRCON
IEN1
IEN0
USR8
S0CON
USR70
TCON
IP1
IP0
UDIR8
S0BUF
UDIR70
TMOD
SP
KORDERL KORDERH
S0RELH S1RELH
FLSHCTL
S0RELL
IEN2
DPS
TL0
DPL
S1CON
TL1
DPH
PGADDR
S1BUF S1RELL
ERASE
TH0
TH1
DPL1
DPH1
CKCON
WDTREL
MCLKCTL
PCON
Bin/
Hex
FF
F7
EF
E7
DF
D7
CF
C7
BF
B7
AF
A7
9F
97
8F
87
Only a few addresses are used, the others are not implemented. SFRs specific to the 73S1215F are
shown in bold print (gray background). Any read access to unimplemented addresses will return
undefined data, while most write access will have no effect. However, a few locations are reserved and
not user configurable in the 73S1215F. Writes to the unused SFR locations can affect the operation
of the core and therefore must not be written to. This applies to all the SFR areas in both the
IRAM and XRAM spaces. In addition, all unused bit locations within valid SFR registers must be
left in their default (power on default) states.
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1.5.2
73S1215F Data Sheet
IRAM Special Function Registers (Generic 80515 SFRs)
Table 7 shows the location of the SFRs and the value they assume at reset or power-up.
Table 7: IRAM Special Function Registers Reset Values
Name
Location
Reset Value
Description
SP
0x81
0x07
Stack Pointer
DPL
0x82
0x00
Data Pointer Low 0
DPH
0x83
0x00
Data Pointer High 0
DPL1
0x84
0x00
Data Pointer Low 1
DPH1
0x85
0x00
Data Pointer High 1
WDTREL
0x86
0x00
Watchdog Timer Reload register
PCON
0x87
0x00
Power Control
TCON
0x88
0x00
Timer/Counter Control
TMOD
0x89
0x00
Timer Mode Control
TL0
0x8A
0x00
Timer 0, low byte
TL1
0x8B
0x00
Timer 1, high byte
TH0
0x8C
0x00
Timer 0, low byte
TH1
0x8D
0x00
Timer 1, high byte
CKCON
0x8E
0x01
Clock Control (wait state control)
MCLKCtl
0x8F
0x0A
Master Clock Control
USR70
0x90
0xFF
User Port Data (7:0)
UDIR70
0x91
0xFF
User Port Direction (7:0)
DPS
0x92
0x00
Data Pointer select Register
ERASE
0x94
0x00
Flash Erase
S0CON
0x98
0x00
Serial Port 0, Control Register
S0BUF
0x99
0x00
Serial Port 0, Data Buffer
IEN2
0x9A
0x00
Interrupt Enable Register 2
S1CON
0x9B
0x00
Serial Port 1, Control Register
S1BUF
0x9C
0x00
Serial Port 1, Data Buffer
S1RELL
0x9D
0x00
Serial Port 1, Reload Register, low byte
USR8
0xA0
0x00
User Port Data (8)
UDIR8
0xA1
0x01
User Port Direction (8)
IEN0
0xA8
0x00
Interrupt Enable Register 0
IP0
0xA9
0x00
Interrupt Priority Register 0
S0RELL
0xAA
0xD9
Serial Port 0, Reload Register, low byte
FLSHCTL
0xB2
0x00
Flash Control
PGADDR
0xB7
0x00
Flash Page Address
IEN1
0xB8
0x00
Interrupt Enable Register 1
IP1
0xB9
0x00
Interrupt Priority Register 1
S0RELH
0xBA
0x03
Serial Port 0, Reload Register, high byte
S1RELH
0xBB
0x03
Serial Port 1, Reload Register, high byte
IRCON
0xC0
0x00
Interrupt Request Control Register
T2CON
0xC8
0x00
Timer 2 Control
Rev. 1.4
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73S1215F Data Sheet
DS_1215F_003
PSW
0xD0
0x00
Program Status Word
KCOL
0XD1
0x1F
Keypad Column
KROW
0XD2
0x3F
Keypad Row
KSCAN
0XD3
0x00
Keypad Scan Time
KSTAT
0XD4
0x00
Keypad Control/Status
KSIZE
0XD5
0x00
Keypad Size
KORDERL
0XD6
0x00
Keypad Column LS Scan Order
KORDERH
0XD7
0x00
Keypad Colum MS Scan Order
BRCON
0xD8
0x00
Baud Rate Control Register (only BRCON.7 bit used)
A
0xE0
0x00
Accumulator
B
0xF0
0x00
B Register
1.5.3
External Data Special Function Registers (SFRs)
A map of the XRAM Special Function Registers is shown in Table 8. The smart card registers are listed
separately in Table 117.
Table 8: XRAM Special Function Registers Reset Values
Name
Location
Reset Value
Description
DAR
0x FF80
0x00
Device Address Register (I2C)
WDR
0x FF81
0x00
Write Data Register (I2C)
SWDR
0x FF82
0x00
Secondary Write Data Register (I2C)
RDR
0x FF83
0x00
Read Data Register (I2C)
SRDR
0x FF84
0x00
Secondary Read Data Register (I2C)
CSR
0x FF85
0x00
Control and Status Register (I2C)
USRIntCtl1
0x FF90
0x00
External Interrupt Control 1
USRIntCtl2
0x FF91
0x00
External Interrupt Control 2
USRIntCtl3
0x FF92
0x00
External Interrupt Control 3
USRIntCtl4
0x FF93
0x00
External Interrupt Control 4
INT5Ctl
0x FF94
0x00
External Interrupt Control 5
INT6Ctl
0x FF95
0x00
External Interrupt Control 6
MPUCKCtl
0x FFA1
0x0C
MPU Clock Control
RTCCtl
0x FFB0
0x00
Real Time Clock Control
RTCCnt3
0x FFB1
0x00
RTC Count 3
RTCCnt2
0x FFB2
0x00
RTC Count 2
RTCCnt1
0x FFB3
0x00
RTC Count 1
RTCCnt0
0x FFB4
0x00
RTC Count 0
RTCACC2
0x FFB5
0x00
RTC Accumulator 2
RTCACC1
0x FFB6
0x00
RTC Accumulator 1
RTCACC0
0x FFB7
0x00
RTC Accumulator 0
RTCTrim2
0x FFB8
0x00
RTC TRIM 2
RTCTrim1
0x FFB9
0x00
RTC TRIM 1
RTCTrim0
0x FFBA
0x00
RTC TRIM 0
ACOMP
0x FFD0
0x00
Analog Compare Register
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DS_1215F_003
73S1215F Data Sheet
Name
Location
Reset Value
Description
TRIMPCtl
0x FFD1
0x00
TRIM Pulse Control
FUSECtl
0x FFD2
0x00
FUSE Control
VDDFCtl
0x FFD4
0x00
VDDFault Control
SECReg
0x FFD7
0x00
Security Register
MISCtl0
0x FFF1
0x00
Miscellaneous Control Register 0
MISCtl1
0x FFF2
0x10
Miscellaneous Control Register 1
LEDCtl
0x FFF3
0xFF
LED Control Register
Accumulator (ACC, A): ACC is the accumulator register. Most instructions use the accumulator to hold
the operand. The mnemonics for accumulator-specific instructions refer to accumulator as “A”, not ACC.
B Register: The B register is used during multiply and divide instructions. It can also be used as a
scratch-pad register to hold temporary data.
Rev. 1.4
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73S1215F Data Sheet
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Program Status Word (PSW):
Table 9: PSW Register Flags
MSB
LSB
CV
AC
F0
RS1
RS
OV
–
P
Table 10: PSW Bit Functions
Bit
Symbol
Function
PSW.7
CV
Carry flag.
PSW.6
AC
Auxiliary Carry flag for BCD operations.
PSW.5
F0
General purpose Flag 0 available for user.
PSW.4
RS1
Register bank select control bits. The contents of RS1 and RS0 select
the working register bank:
RS1/RS0
PSW.3
RS0
Bank Selected
Location
00
Bank 0
(0x00 – 0x07)
01
Bank 1
(0x08 – 0x0F)
10
Bank 2
(0x10 – 0x17)
11
Bank 3
(0x18 – 0x1F)
PSW.2
OV
Overflow flag.
PSW.1
F1
General purpose Flag 1 available for user.
PSW.0
P
Parity flag, affected by hardware to indicate odd / even number of “one”
bits in the Accumulator, i.e. even parity.
Stack Pointer (SP): The stack pointer is a 1-byte register initialized to 0x07 after reset. This register is
incremented before PUSH and CALL instructions, causing the stack to begin at location 0x08.
Data Pointer: The data pointer (DPTR) is 2 bytes wide. The lower part is DPL, and the highest is DPH.
It can be loaded as a 2-byte register (MOV DPTR,#data16) or as two registers (e.g. MOV DPL,#data8). It
is generally used to access external code or data space (e.g. MOVC A,@A+DPTR or MOVX A,@DPTR
respectively).
Program Counter: The program counter (PC) is 2 bytes wide initialized to 0x0000 after reset. This
register is incremented during the fetching operation code or when operating on data from program
memory. Note: The program counter is not mapped to the SFR area.
Port Registers: The I/O ports are controlled by Special Function Registers USR70, and USR8. The
contents of the SFR can be observed on corresponding pins on the chip. Writing a 1 to any of the ports
(see Table 11) causes the corresponding pin to be at high level (3.3V), and writing a 0 causes the
corresponding pin to be held at low level (GND). The data direction registers UDIR70, and UDIR8 define
individual pins as input or output pins (see the User (USR) Ports section for details).
22
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DS_1215F_003
73S1215F Data Sheet
Table 11: Port Registers
SFR
Address
R/W
USR70
0x90
R/W
Register for User port bit 7:0 read and write operations (pins USR0…
USR7).
UDIR70
0x91
R/W
Data direction register for User port bits 0:7. Setting a bit to 0 means that
the corresponding pin is an output.
USR8
0xA0
R/W
Register for User port bit 8 read and write operations (pin *USR8).
UDIR8
0xA1
R/W
Data direction register for port 1.
Register
Description
All ports on the chip are bi-directional. Each consists of a Latch (SFR USR70 to USR8), an output driver,
and an input buffer, therefore the MPU can output or read data through any of these ports if they are not
used for alternate purposes.
1.6 Instruction Set
All instructions of the generic 8051 microcontroller are supported. A complete list of the instruction set
and of the associated op-codes is contained in the 73S12xxF Software User’s Guide.
1.7 Peripheral Descriptions
1.7.1
Oscillator and Clock Generation
The 73S1215F has two oscillator circuits; one for the main CPU clock and another for the RTC. The
main oscillator circuit is designed to operate with various crystals or external clock frequencies. An
internal divider working in conjunction with a PLL and VCO needs to provide a 96MHz internal clock
within the 73S1215F. 96 MHz is the required frequency for proper operation of specific peripheral blocks
such as the USB, specific timers, ISO 7816 UART and interfaces and keypad. The clock generation and
control circuits are shown in Figure 3.
Rev. 1.4
23
73S1215F Data Sheet
DS_1215F_003
MCount(2:0)
X12IN
HOSCen
12.00MHz
USBCKenb
HIGH
XTAL
OSC
HCLK
M DIVIDER
/(2*N + 4)
12.00MHz
X32IN
32768Hz
LOW
XTAL
OSC
USBCLK
48MHz
div 2
X12OUT
DIVIDER
/2930
Phase
Freq
DET
VCO
MCLK
96MHz
LMCLK=32765Hz
X32OUT
RTCCLK
Mux
LCLK=32768Hz
DIV
32
32KOSCenb
CPU CLOCK
DIVIDER
6 bits
1.5-48MHz
1kHz
ICLK
7.386MHz
7.386MHz
MPU CLOCK - CPCLK
3.6923MHz
div 2
div 2
CPUCKDiv
KEYCLK
DIVIDE
by 120
I2CCLK
400kHz
I2C_2x
800kHz
CLK1M
DIVIDE
by 96
SCLK
CLOCK
Prescaler 6bits
div 2
div 2
SC/SCE
CLOCK
Prescaler 6bits
1MHz
SEL
SELSC
SMART CARD LOGIC
BLOCK CLOCK
SCCLK
ETU CLOCK
DIVIDER
12 bits
ETUCLK
SCECLK
See SC Clock descriptions for more accurate diagram
SCCKenb
Figure 3: Clock Generation and Control Circuits
24
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
The master clock control register enables different sections of the clock circuitry and specifies the value
of the VCO Mcount divider. The MCLK must be configured to operate at 96MHz to ensure proper
operation of some of the peripheral blocks according to the following formula:
MCLK = (Mcount * 2 + 4) * FXTAL = 96MHz
Mcount is configured in the MCLKCtl register must be bound between a value of 1 to 7. The possible
crystal or external clock frequencies for getting MCLK = 96MHz are shown in Table 12.
Table 12: Frequencies and Mcount Values for MCLK = 96MHz
FXTAL (MHz)
Mcount (N)
12.00
2
9.60
3
8.00
4
6.86
5
6.00
6
Master Clock Control Register (MCLKCtl): 0x8F Å 0x0A
Table 13: The MCLKCtl Register
MSB
LSB
HSOEN
KBEN
SCEN
USBEN 32KEN
MCT.2
MCT.1
MCT.0
Bit
Symbol
Function
MCLKCtl.7
HSOEN
High-speed oscillator disable. When set = 1, disables the high-speed crystal
oscillator and VCO/PLL system. Do not set this bit = 1.
MCLKCtl.6
KBEN
1 = Disable the keypad logic clock.
MCLKCtl.5
SCEN
1 = Disable the smart card logic clock.
MCLKCtl.4
USBEN
1 = Disable the USB logic clock.
MCLKCtl.3
32KEN
1 = Disable the 32Khz oscillator. When the 32kHz oscillator is enabled, the
RTC and other circuits such as debounce clocks are clocked using the
32kHz oscillator output. When disabled, the main oscillator provides the
32kHz clock for the RTC and other circuits. Note: This bit must be set if
there is no 32KHz crystal or the 44 pin package is used. Some internal
clocks and circuits will not run if the oscillator is enabled and no
crystal is connected.
MCLKCtl.2
MCT.2
MCLKCtl.1
MCT.1
MCLKCtl.0
MCT.0
This value determines the ratio of the VCO frequency (MCLK) to the highspeed crystal oscillator frequency such that:
MCLK = (MCount*2 + 4)* FXTAL. The default value is MCount = 2h such that
MCLK = (2*2 + 4)*12.00MHz = 96MHz.
The MPU clock that drives the CPU core defaults to 3.6923MHz after reset. The MPU clock is scalable
by configuring the MPU Clock Control register (MPUCKCtl).
Rev. 1.4
25
73S1215F Data Sheet
DS_1215F_003
MPU Clock Control Register (MPUCKCtl): 0xFFA1 Å 0x0C
Table 14: The MPUCKCtl Register
MSB
LSB
–
–
Bit
Symbol
MPUCKCtl.7
–
MPUCKCtl.6
–
MPUCKCtl.5
MDIV.5
MPUCKCtl.4
MDIV.4
MPUCKCtl.3
MDIV.3
MPUCKCtl.2
MDIV.2
MPUCKCtl.1
MDIV.1
MPUCKCtl.0
MDIV.0
MDIV.5 MDIV.4 MDIV.3 MDIV.2 MDIV.1 MDIV.0
Function
This value determines the ratio of the MPU master clock frequency to
the VCO frequency (MCLK) such that
MPUClk = MCLK/(2 * (MPUCKDiv(5:0) + 1)).
Do not use values of 0 or 1 for MPUCKDiv(n).
Default is 0Ch to set CPCLK = 3.6923MHz.
The oscillator circuits are designed to connect directly to standard parallel resonant crystal in a Pierce
oscillator configuration. Each side of the crystal should include a 22pF capacitor to ground for both
oscillator circuits and a 1MΩ resistor is required across the 12MHz crystal.
CPUCLK
X32OUT
73S1215F
X32IN
X12IN
X12OUT
The CPU clock is available as an output on pin CPUCLK (68-pin version only).
1MΩ
12MHz
22pF
32KHz
22pF
22pF
22pF
Note: The crystals should be placed as close as possible to the IC, and vias should be avoided.
Figure 4: Oscillator Circuit
26
Rev. 1.4
DS_1215F_003
1.7.2
73S1215F Data Sheet
Power Control Modes
The 73S1215F contains circuitry to disable portions of the device and place it into a lower power standby
mode. This is accomplished by either shutting off the power or disabling the clock going to the block. The
miscellaneous control registers MISCtl0, MISCtl1 and the master clock control register (MCLKCtl) provide
control over the power modes. There is also a device power down mode that will stop the core, clock
subsystem and the peripherals connected to it. The PWRDN bit in MISCtl0 will set up the 73S1215F for
power down and disable all clocks except the 32kHz oscillator. The power down mode should only be
initiated by setting the PWRDN bit in the MISCtl0 register and not by manipulating individual control bits in
various registers. Figure 5 shows how the PWRDN bit controls the various functions that comprise power
down state.
Note: the PWRDN Signal is not the direct version of the PWRDN Bit. There are delays from assertion of the
PWRDN bit to the assertion of the PWRDN Signal (32 MPU clocks) Refer to the Power Down sequence diagram.
MISCtl0 - PWRDN
PWRDN Signal
+
MISCtl1 - ANAPEN
VDDFCtl - VDDFEN
MISCtl1 - USBPEN
ACOMP - CMPEN
USB
SUSPEND
PD_ANALOG
Analog functions
(VCO, PLL,
reference and bias
circuits, etc.)
+
VDDFAULT
+
USB Transceiver
(suspend mode)
+
ANALOG
COMPARE
MCLCKCtl - 32KEN
32K OSC
MCLCKCtl - HOSEN
+
High Speed OSC
SCVCCCtl - SCPRDN
+
Smart Card Power
MISCtl1 - FRPEN
+
Flash Read Pulse
one-shot circuit
These are the registers and
the names of the control bits.
These are the
block references.
Figure 5: Power Down Control
When the PWRDN bit is set, the clock subsystem will provide a delay of 32 MPUCLK cycles to allow the
program to set the STOP bit in the PCON register. This delay will enable the program to properly halt the
core before the analog circuits shut down (high speed oscillator, VCO/PLL, voltage reference and bias
circuitry, etc.). The PDMUX bit in SFR INT5Ctl should be set prior to setting the PWRDN bit in order to
configure the wake up interrupt logic. The power down mode is awakened from interrupts connected to
external interrupts 0, 4 and 5 (external USR[0:7], smart card, USB, RTC and Keypad). These interrupt
sources are OR’ed together and routed through some delay logic into INT0 to provide this functionality.
The interrupt will turn on the power to all sections that were shut off and start the clock subsystem. After
the clock subsystem clocks start running, the MPUCLK begins to clock a 512 count delay counter. When
the counter times out, the interrupt will then be active on INT0 and the program can resume. Figure 6
shows the detailed logic for waking up the 73S1215F from a power down state using these specific interrupt
sources. Figure 7 shows the timing associated with the power down mode.
Rev. 1.4
27
73S1215F Data Sheet
DS_1215F_003
PDMUX
(FF94h:bit7)
USR0
USR1
USR2
USR3
USR4
USR5
USR6
USR7
USR[7:0] Control
MPU
0
USRxINTSrc set to
4(ext INT0 high)
or
6(ext INT0 low)
INT0
1
INT4
CE
INT5
TC
9 BIT CNTR
CLR
RESETB
D
Q
PWRDN
(FFF1h:bit7)
PWRDN_analog
CLR
TC
CE
RESETB
Notes:
1. The counters are clocked by the MPUCLK
2. TC - Terminal count (high at overflow)
3. CE - Count enable
5 BIT CNTR
CLR
RESETB
Figure 6: Detail of Power Down Interrupt Logic
text
t0
PWRDN BIT
t1
PWRDN SIG
t4
EXT. EVENT
t6
INT0 to MPU
t7
MPU STOP
ANALOG Enable
t2
t3
t5
PLL CLOCKS
t0: MPU sets PWRDN bit
t1: 32 MPU clock cycles after t0, the PWRDN SIG is asserted, turning all analog functions OFF.
t2: MPU executes STOP instruction, must be done prior to t1.
t3: Analog functions go to OFF condition. No Vref, PLL/VCO, Ibias, etc.
text: An external event (RTC, Keypad, Card event, USB) occurs.
t4: PWRDN bit and PWRDN signal are cleared by external event.
t5: High-speed oscillator/PLL/VCO operating.
t6: After 512 MPU clock cycles, INT0 to MPU is asserted.
t7: INT0 causes MPU to exit STOP condition.
Figure 7: Power Down Sequencing
28
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
External Interrupt Control Register (INT5Ctl): 0xFF94 Å 0x00
Table 15: The INT5Ctl Register
MSB
LSB
PDMUX
Bit
–
RTCIEN RTCINT
USBIEN
USBINT
KPIEN
KPINT
Symbol
Function
INT5Ctl.7
PDMUX
When set = 1, enables interrupts from USB, RTC, Keypad (normally going to
int5), Smart Card interrupts (normally going to int4), or USR(7:0) pins (int0) to
cause interrupt on int0. The assertion of the interrupt to int0 is delayed by
512 MPU clocks to allow the analog circuits, including the clock system, to
stabilize. This bit must be set prior to asserting the PWRDN bit in order to
properly configure the interrupts that will wake up the circuit. This bit is reset
= 0 when this register is read.
INT5Ctl.6
–
INT5Ctl.5
RTCIEN
RTC interrupt enable.
INT5Ctl.4
RTCINT
RTC interrupt flag.
INT5Ctl.3
USBIEN
USB interrupt enable.
INT5Ctl.2
USBINT
USB interrupt flag.
INT5Ctl.1
KPIEN
Keypad interrupt enable.
INT5Ctl.0
KPINT
Keypad interrupt flag.
Miscellaneous Control Register 0 (MISCtl0): 0xFFF1 Å 0x00
Table 16: The MISCtl0 Register
MSB
LSB
PWRDN
Bit
–
–
–
–
–
SLPBK
SSEL
Symbol
Function
MISCtl0.7
PWRDN
This bit sets the circuit into a low-power condition. All analog (high speed
oscillator and VCO/PLL) functions are disabled 32 MPU clock cycles after
this bit is set = 1. This allows time for the next instruction to set the STOP bit
in the PCON register to stop the CPU core. The RTC will stay active if it is
set to operate from the 32kHz oscillator. The MPU is not operative in this
mode. When set, this bit overrides the individual control bits that otherwise
control power consumption.
MISCtl0.6
–
MISCtl0.5
–
MISCtl0.4
–
MISCtl0.3
–
MISCtl0.2
–
MISCtl0.1
SLPBK
MISCtl0.0
SSEL
Rev. 1.4
UART loop back testing mode.
Serial port pins select.
29
73S1215F Data Sheet
DS_1215F_003
Miscellaneous Control Register 1 (MISCtl1): 0xFFF2 Å 0x10
Table 17: The MISCtl1 Register
MSB
LSB
–
–
Bit
Symbol
MISCtl1.7
–
MISCtl1.6
–
FRPEN
FLSH66
–
ANAPEN USBPEN USBCON
Function
MISCtl1.5
FRPEN
Flash Read Pulse enable (low). If FRPEN = 1, the Flash Read signal is
passed through with no change. When FRPEN = 0 a one-shot circuit that
shortens the Flash Read signal is enabled to save power. The Flash Read
pulse will shorten to 40 or 66ns (approximate based on the setting of the
FLSH66 bit) in duration, regardless of the MPU clock rate. For MPU clock
frequencies greater than 10MHz, this bit should be set high.
MISCtl1.4
FLSH66
When high, creates a 66ns Flash read pulse, otherwise creates a 40ns read
pulse when FRPEN is set.
MISCtl1.3
–
MISCtl1.2
ANAPEN*
0 = Enable the analog functions that generate VREF and bias current
functions. Setting high will turn off the VPD regulator and VCO/PLL
functions.
MISCtl1.1
USBPEN
0 = Enable the USB differential transceiver.
MISCtl1.0
USBCON
USB pull-up resistor connect enable.
*Note: The ANAPEN bit should never be set under normal circumstances. Power down control should
only be initiated via use of the PWRDN bit in MISCtl0.
30
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Master Clock Control Register (MCLKCtl): 0x8F Å 0x0A
Table 18: The MCLKCtl Register
MSB
LSB
HSOEN
KBEN
SCEN
USBEN 32KEN
MCT.2
MCT.1
MCT.0
Bit
Symbol
Function
MCLKCtl.7
HSOEN*
MCLKCtl.6
KBEN
1 = Disable the keypad logic clock. This bit is not changed in PWRDN
mode but the function is disabled.
MCLKCtl.5
SCEN
1 = Disable the smart card logic clock. This bit is not changed in PWRDN
mode but the function is disabled. Interrupt logic for card insertion/removal
remains operable even with smart card clock disabled.
MCLKCtl.4
USBEN
1 = Disable the USB logic clock. This bit is not changed in PWRDN mode
but the function is disabled.
MCLKCtl.3
32KEN
1 = Disable the 32Khz oscillator. This function is not affected by PWRDN
mode. Note: This bit must be set if there is no 32KHz crystal or the 44 pin
package is used. Some internal clocks and circuits will not run if the
oscillator is enabled and no crystal is connected.
MCLKCtl.2
MCT.2
MCLKCtl.1
MCT.1
MCLKCtl.0
MCT.0
High-speed oscillator enable. When set = 1, disables the high-speed
crystal oscillator and VCO/PLL system. This bit is not changed when the
PWRDN bit is set but the oscillator/VCO/PLL is disabled.
This value determines the ratio of the VCO frequency (MCLK) to the highspeed crystal oscillator frequency such that:
MCLK = (MCount*2 + 4)*Fxtal. The default value is MCount = 2h such that
MCLK = (2*2 + 4)*12.00MHz = 96MHz.
*Note: The HSOEN bit should never be set under normal circumstances. Power down control should
only be initiated via use of the PWRDN bit in MISCtl0.
Rev. 1.4
31
73S1215F Data Sheet
DS_1215F_003
Power Control Register 0 (PCON): 0x87 Å 0x00
The SMOD bit used for the baud rate generator is setup via this register.
Table 19: The PCON Register
MSB
LSB
SMOD
32
–
–
–
Bit
Symbol
PCON.7
SMOD
PCON.6
–
PCON.5
–
PCON.4
–
PCON.3
GF1
General purpose flag 1.
PCON.2
GF0
General purpose flag 1.
PCON.1
STOP
Sets CPU to Stop mode.
PCON.0
IDLE
Sets CPU to Idle mode.
GF1
GF0
STOP
IDLE
Function
If SM0D = 1, the baud rate is doubled.
Rev. 1.4
DS_1215F_003
1.7.3
73S1215F Data Sheet
Interrupts
The 80515 core provides 10 interrupt sources with four priority levels. Each source has its own request
flag(s) located in a special function register (TCON, IRCON, and SCON). Each interrupt requested by the
corresponding flag can be individually enabled or disabled by the enable bits in SFRs IEN0, IEN1 and
IEN2. Some of the 10 sources are multiplexed in order to expand the number of interrupt sources.
These will be described in more detail in the respective sections.
External interrupts are the interrupts external to the 80515 core, i.e. signals that originate in other parts of
the 73S1215F, for example the USB interface, USR I/O, RTC, smart card interface, analog comparators,
etc. The external interrupt configuration is shown in
Figure 8.
PDMUXCtl
Clear PWRDN bit
USR0
USR1
t0
USR2
USR3
USR
Pads
USR4
0
USR
USR
Int
USR
USR
CtlIntInt
Ctl Int
Ctl
Ctl
int0
1
t1
USR5
int1
USR6
USR7
+
Delay
int2
INT2
INT
Pads
int3
INT3
Card_Det
CRDCtl
Wait Timeout
+
+
Card Event
VCC_TMR
RxData
VCC_OK
TX_Event
VccCTL
SCInt
SCIE
int4
Tx_Sent
TX_Error
MPU
CORE
RX_Error
USB
During STOP, IDLE when
PWRDN bit is set
INT5Ctl
RTC
int5
KeyPad
I 2C
VDD_Fault
INT6Ctl
int6
Analog
Comp
Serial
Ch 0
SerChan 0 int
Serial
Ch 1
SerChan 1 int
Figure 8: External Interrupt Configuration
Rev. 1.4
33
73S1215F Data Sheet
1.7.3.1
DS_1215F_003
Interrupt Overview
When an interrupt occurs, the MPU will vector to the predetermined address as shown in Table 33. Once
the interrupt service has begun, it can only be interrupted by a higher priority interrupt. The interrupt
service is terminated by a return from the REIT instruction. When a RETI is performed, the processor will
return to the instruction that would have been next when the interrupt occurred.
When the interrupt condition occurs, the processor will also indicate this by setting a flag bit. This bit is
set regardless of whether the interrupt is enabled or disabled. Each interrupt flag is sampled once per
machine cycle, then samples are polled by the hardware. If the sample indicates a pending interrupt
when the interrupt is enabled, then the interrupt request flag is set. On the next instruction cycle, the
interrupt will be acknowledged by hardware forcing an LCALL to the appropriate vector address.
Interrupt response will require a varying amount of time depending on the state of the MPU when the
interrupt occurs. If the MPU is performing an interrupt service with equal or greater priority, the new
interrupt will not be invoked. In other cases, the response time depends on the current instruction. The
fastest possible response to an interrupt is 7 machine cycles. This includes one machine cycle for
detecting the interrupt and six cycles to perform the LCALL.
1.7.3.2
Special Function Registers for Interrupts
Interrupt Enable 0 Register (IEN0): 0xA8 Å 0x00
Table 20: The IEN0 Register
MSB
EAL
34
LSB
WDT
–
ES0
ET1
EX1
Bit
Symbol
IEN0.7
EAL
EAL = 0 – disable all interrupts.
IEN0.6
WDT
Not used for interrupt control.
IEN0.5
–
IEN0.4
ES0
ES0 = 0 – disable serial channel 0 interrupt.
IEN0.3
ET1
ET1 = 0 – disable timer 1 overflow interrupt.
IEN0.2
EX1
EX1 = 0 – disable external interrupt 1.
IEN0.1
ET0
ET0 = 0 – disable timer 0 overflow interrupt.
IEN0.0
EX0
EX0 = 0 – disable external interrupt 0.
ET0
EX0
Function
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Interrupt Enable 1 Register (IEN1): 0xB8 Å 0x00
Table 21: The IEN1 Register
MSB
–
LSB
SWDT
EX6
EX5
EX4
EX3
Bit
Symbol
IEN1.7
–
IEN1.6
SWDT
IEN1.5
EX6
EX6 = 0 – disable external interrupt 6.
IEN1.4
EX5
EX5 = 0 – disable external interrupt 5.
IEN1.3
EX4
EX4 = 0 – disable external interrupt 4.
IEN1.2
EX3
EX3 = 0 – disable external interrupt 3.
IEN1.1
EX2
EX2 = 0 – disable external interrupt 2.
IEN1.0
–
EX2
–
Function
Not used for interrupt control.
Interrupt Enable 2 Register (IEN2): 0x9A Å 0x00
Table 22: The IEN2 Register
MSB
–
Bit
Symbol
IEN2.0
ES1
Rev. 1.4
LSB
–
–
–
–
–
–
ES1
Function
ES1 = 0 – disable serial channel interrupt.
35
73S1215F Data Sheet
DS_1215F_003
Timer/Counter Control Register (TCON): 0x88 Å 0x00
Table 23: The TCON Register
MSB
TF1
LSB
TR1
TF0
TR0
IE1
IT1
IE0
IT0
Bit
Symbol
Function
TCON.7
TF1
Timer 1 overflow flag.
TCON.6
TR1
Not used for interrupt control.
TCON.5
TF0
Timer 0 overflow flag.
TCON.4
TR0
Not used for interrupt control.
TCON.3
IE1
Interrupt 1 edge flag is set by hardware when the falling edge on external
interrupt int1 is observed. Cleared when an interrupt is processed.
TCON.2
IT1
Interrupt 1 type control bit. 1 selects falling edge and 0 selects low level for
input pin to cause an interrupt.
TCON.1
IE0
Interrupt 0 edge flag is set by hardware when the falling edge on external
interrupt int0 is observed. Cleared when an interrupt is processed.
TCON.0
IT0
Interrupt 0 type control bit. 1 selects falling edge and 0 sets low level for input
pin to cause interrupt.
Timer/Interrupt 2 Control Register (T2CON): 0xC8 Å 0x00
Table 24: The T2CON Register
MSB
LSB
–
I3FR
I2FR
–
–
–
–
Bit
Symbol
T2CON.7
–
T2CON.6
I3FR
External interrupt 3 failing/rising edge flag.
I3FR = 0 external interrupt 3 negative transition active.
I3FR = 1 external interrupt 3 positive transition active.
T2CON.5
I2FR
External interrupt 3 failing/rising edge flag.
I2FR = 0 external interrupt 3 negative transition active.
I2FR = 1 external interrupt 3 positive transition active.
T2CON.4
–
T2CON.3
–
T2CON.2
–
T2CON.1
–
T2CON.0
–
36
–
Function
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Interrupt Request Register (IRCON): 0xC0 Å 0x00
Table 25: The IRCON Register
MSB
LSB
–
–
EX6
IEX5
Bit
Symbol
IRCON.7
–
IRCON.6
–
IRCON.5
IEX6
External interrupt 6 flag.
IRCON.4
IEX5
External interrupt 5 flag.
IRCON.3
IEX4
External interrupt 4 flag.
IRCON.2
IEX3
External interrupt 3 flag.
IRCON.1
IEX2
External interrupt 2 flag.
IRCON.0
–
1.7.3.3
IEX4
IEX3
IEX2
–
Function
External Interrupts
The external interrupts (external to the CPU core) are connected as shown in Table 26. Interrupts with
multiple sources are OR’ed together and individual interrupt source control is provided in XRAM SFRs to
mask the individual interrupt sources and provide the corresponding interrupt flags. Multifunction USR
[7:0] pins control Interrupts 0 and 1. Dedicated external interrupt pins INT2 and INT3 control interrupts 2
and 3. The polarity of interrupts 2 and 3 is programmable in the MPU. Interrupts 4, 5 and 6 have multiple
peripheral sources and are multiplexed to one of these three interrupts. The peripheral functions will be
described in subsequent sections. Generic 80515 MPU literature states that interrupts 4 through 6 are
defined as rising edge sensitive. Thus, the hardware signals attached to interrupts 4, 5 and 6 are
converted to rising edge level by the hardware.
SFR (special function register) enable bits must be set to permit any of these interrupts to occur.
Likewise, each interrupt has its own flag bit that is set by the interrupt hardware and is reset automatically
by the MPU interrupt handler.
Table 26: External MPU Interrupts
External
Interrupt
Connection
Polarity
Flag Reset
0
USR I/O High Priority
see USRIntCtlx
Automatic
1
USR I/O Low Priority
see USRIntCtlx
Automatic
2
External Interrupt Pin INT2
Edge selectable
Automatic
3
External Interrupt Pin INT3
Edge selectable
Automatic
4
Smart Card Interrupts
N/A
Automatic
USB, RTC and Keypad
N/A
Automatic
I C, VDD_Fault, Analog Comp
N/A
Automatic
5
6
2
Note: Interrupts 4, 5 and 6 have multiple interrupt sources and the flag bits are cleared upon reading of
the corresponding register. To prevent any interrupts from being ignored, the register containing multiple
interrupt flags should be stored temporary to allow each interrupt flag to be tested separately to see which
interrupt(s) is/are pending.
Rev. 1.4
37
73S1215F Data Sheet
DS_1215F_003
Table 27: Control Bits for External Interrupts
Enable Bit
1.7.3.4
Description
Flag Bit
Description
EX0
Enable external interrupt 0
IE0
External interrupt 0 flag
EX1
Enable external interrupt 1
IE1
External interrupt 1 flag
EX2
Enable external interrupt 2
IEX2
External interrupt 2 flag
EX3
Enable external interrupt 3
IEX3
External interrupt 3 flag
EX4
Enable external interrupt 4
IEX4
External interrupt 4 flag
EX5
Enable external interrupt 5
IEX5
External interrupt 5 flag
EX6
Enable external interrupt 6
IEX6
External interrupt 6 flag
Power Down Interrupt Logic
The 73S1215F contains special interrupt logic to allow INT0 to wake up the CPU from a power down
(CPU STOP) state. See the Power Control Modes section for details.
1.7.3.5
Interrupt Priority Level Structure
All interrupt sources are combined in groups, as shown in Table 28.
Table 28: Priority Level Groups
Group
0
External interrupt 0
Serial channel 1 interrupt
1
Timer 0 interrupt
–
External interrupt 2
2
External interrupt 1
–
External interrupt 3
3
Timer 1 interrupt
–
External interrupt 4
4
Serial channel 0 interrupt
–
External interrupt 5
5
–
–
External interrupt 6
Each group of interrupt sources can be programmed individually to one of four priority levels by setting or
clearing one bit in the special function register IP0 and one in IP1. If requests of the same priority level
are received simultaneously, an internal polling sequence as per Table 32 determines which request is
serviced first.
IEN enable bits must be set to permit any of these interrupts to occur. Likewise, each interrupt has its
own flag bit that is set by the interrupt hardware
Interrupt Priority 0 Register (IP0): 0xA9 Å 0x00
Table 29: The IP0 Register
MSB
–
LSB
WDTS
IP0.5
IP0.4
IP0.3
IP0.2
IP0.1
IP0.0
Note: WDTS is not used for interrupt controls.
38
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Interrupt Priority 1 Register (IP1): 0xB9 Å 0x00
Table 30: The IP1 Register
MSB
–
LSB
–
IP1.5
IP1.4
IP1.3
IP1.2
IP1.1
IP1.0
Table 31: Priority Levels
IP1.x
IP0.x
Priority Level
0
0
Level0 (lowest)
0
1
Level1
1
0
Level2
1
1
Level3 (highest)
Table 32: Interrupt Polling Sequence
External interrupt 0
Serial channel 1 interrupt
External interrupt 2
External interrupt 1
External interrupt 3
Timer 1 interrupt
Serial channel 0 interrupt
Polling sequence
Timer 0 interrupt
External interrupt 4
External interrupt 5
External interrupt 6
1.7.3.6
Interrupt Sources and Vectors
Table 33 shows the interrupts with their associated flags and vector addresses.
Table 33: Interrupt Vectors
Interrupt Request Flag
N/A
IE0
TF0
IE1
TF1
RI0/TI0
RI1/TI1
IEX2
IEX3
IEX4
IEX5
IEX6
Rev. 1.4
Description
Chip Reset
External interrupt 0
Timer 0 interrupt
External interrupt 1
Timer 1 interrupt
Serial channel 0 interrupt
Serial channel 1 interrupt
External interrupt 2
External interrupt 3
External interrupt 4
External interrupt 5
External interrupt 6
Interrupt Vector Address
0x0000
0x0003
0x000B
0x0013
0x001B
0x0023
0x0083
0x004B
0x0053
0x005B
0x0063
0x006B
39
73S1215F Data Sheet
1.7.4
DS_1215F_003
UART
The 80515 core of the 73S1215F includes two separate UARTs that can be programmed to communicate
with a host. The 73S1215F can only connect one UART at a time since there is only one set of TX and
Rx pins. The MISCtl0 register is used to select which UART is connected to the TX and RX pins. Each
UART has a different set of operating modes that the user can select according to their needs. The
UART is a dedicated 2-wire serial interface, which can communicate with an external host processor at
up to 115,200 bits/s. The TX and RX pins operate at the VDD supply voltage levels and should never
exceed 3.6V. The operation of each pin is as follows:
RX: Serial input data is applied at this pin. Conforming to RS-232 standard, the bytes are input LSB first.
The voltage applied at RX must not exceed 3.6V.
TX: This pin is used to output the serial data. The bytes are output LSB first.
The 73S1215F has several UART-related read/write registers. All UART transfers are programmable for
parity enable, parity select, 2 stop bits/1 stop bit and XON/XOFF options for variable communication baud
rates from 300 to 115200 bps. Table 34 shows the selectable UART operation modes and Table 35
shows how the baud rates are calculated.
Table 34: UART Modes
UART 0
UART 1
Mode 0
N/A
Start bit, 8 data bits, parity, stop bit, variable
baud rate (internal baud rate generator)
Mode 1
Start bit, 8 data bits, stop bit, variable
baud rate (internal baud rate generator
or timer 1)
Start bit, 8 data bits, stop bit, variable baud
rate (internal baud rate generator)
Mode 2
Start bit, 8 data bits, parity, stop bit,
fixed baud rate 1/32 or 1/64 of fCKMPU
N/A
Mode 3
Start bit, 8 data bits, parity, stop bit,
variable baud rate (internal baud rate
generator or timer 1)
N/A
Note: Parity of serial data is available through the P flag of the accumulator. Seven-bit serial modes with
parity, such as those used by the FLAG protocol, can be simulated by setting and reading bit 7 of 8-bit
output data. Seven-bit serial modes without parity can be simulated by setting bit 7 to a constant 1.8-bit
serial modes with parity can be simulated by setting and reading the 9th bit, using the control bits
S0CON3 and S1CON3 in the S0COn and S1CON SFRs.
Table 35: Baud Rate Generation
Using Timer 1
Serial Interface 0
Serial Interface 1
2
smod
* fCKMPU/ (384 * (256-TH1))
N/A
Using Internal Baud Rate Generator
2smod * fCKMPU/(64 * (210-S0REL))
fCKMPU/(32 * (210-S1REL))
Note: S0REL (9:0) and S1REL (9:0) are 10-bit values derived by combining bits from the respective timer
reload registers SxRELH (bits 1:0) and SxRELL (bits 7:0). TH1 is the high byte of timer 1. The SMOD bit
is located in the PCON SFR.
40
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Power Control Register 0 (PCON): 0x87 Å 0x00
The SMOD bit used for the baud rate generator is set up via this register.
Table 36: The PCON Register
MSB
LSB
SMOD
–
–
–
GF1
GF0
Bit
Symbol
Function
PCON.7
SMOD
If SM0D = 1, the baud rate is doubled.
PCON.6
–
PCON.5
–
PCON.4
–
PCON.3
GF1
General purpose flag 1.
PCON.2
GF0
General purpose flag 1.
PCON.1
STOP
Sets CPU to Stop mode.
PCON.0
IDLE
Sets CPU to Idle mode.
STOP
IDLE
Baud Rate Control Register 0 (BRCON): 0xD8 Å 0x00
The BSEL bit used to enable the baud rate generator is set up via this register.
Table 37: The BRCON Register
MSB
LSB
BSEL
–
Bit
Symbol
BRCON.7
BSEL
BRCON.6
–
BRCON.5
–
BRCON.4
–
BRCON.3
–
BRCON.2
–
BRCON.1
–
BRCON.0
–
Rev. 1.4
–
–
–
–
–
–
Function
If BSEL = 0, the baud rate is derived using timer 1. If BSEL = 1
the baud rate generator circuit is used.
.
41
73S1215F Data Sheet
DS_1215F_003
Miscellaneous Control Register 0 (MISCtl0): 0xFFF1 Å 0x00
Transmit and receive (TX and RX) pin selection and loop back test configuration are set up via this register.
Table 38: The MISCtl0 Register
MSB
LSB
PWRDN
–
Bit
Symbol
MISCtl0.7
PWRDN
MISCtl0.6
–
MISCtl0.5
–
MISCtl0.4
–
MISCtl0.3
–
MISCtl0.2
–
–
–
–
–
SLPBK
SSEL
Function
This bit places the 73S1215F into a power down state.
MISCtl0.1
SLPBK
1 = UART loop back testing mode. The pins TXD and RXD are to be
connected together externally (with SLPBK =1) and therefore:
SLPBK SSEL
Mode
0
0
normal using Serial_0
0
1
normal using Serial_1
1
0
Serial_0 TX feeds Serial_1 RX
1
1
Serial_1 TX feeds Serial_0 RX
MISCtl0.0
SSEL
Selects either Serial_1 if set =1 or Serial_0 if set = 0 to be connected
to RXD and TXD pins.
1.7.4.1
Serial Interface 0
The Serial Interface 0 can operate in four modes:
•
Mode 0
Pin RX serves as input and output. TX outputs the shift clock. 8 bits are transmitted with LSB first. The
baud rate is fixed at 1/12 of the crystal frequency. Reception is initialized in Mode 0 by setting the flags in
S0CON as follows: RI0 = 0 and REN0 = 1. In other modes, a start bit when REN0 = 1 starts receiving
serial data.
•
Mode 1
Pin RX serves as input, and TX serves as serial output. No external shift clock is used, 10 bits are
transmitted: a start bit (always 0), 8 data bits (LSB first), and a stop bit (always 1). On receive, a start bit
synchronizes the transmission, 8 data bits are available by reading S0BUF, and stop bit sets the flag
RB80 in the Special Function Register S0CON. In mode 1 either internal baud rate generator or timer 1
can be use to specify baud rate.
•
Mode 2
This mode is similar to Mode 1, with two differences. The baud rate is fixed at 1/32 or 1/64 of oscillator
frequency and 11 bits are transmitted or received: a start bit (0), 8 data bits (LSB first), a programmable
9th bit, and a stop bit (1). The 9th bit can be used to control the parity of the serial interface: at
transmission, bit TB80 in S0CON is output as the 9th bit, and at receive, the 9th bit affects RB80 in
Special Function Register S0CON.
•
Mode 3
The only difference between Mode 2 and Mode 3 is that in Mode 3 either internal baud rate generator
or timer 1 can be use to specify baud rate.
The S0BUF register is used to read/write data to/from the serial 0 interface.
42
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Serial Interface 0 Control Register (S0CON): 0x9B Å 0x00
Transmit and receive data are transferred via this register.
Table 39: The S0CON Register
MSB
LSB
SM0
SM1
SM20
REN0
TB80
RB80
TI0
RI0
Bit
Symbol
Function
S0CON.7
SM0
These two bits set the UART0 mode:
S0CON.6
SM1
Mode
Description
SM0
SM1
0
N/A
0
0
1
8-bit UART
0
1
2
9-bit UART
1
0
3
9-bit UART
1
1
S0CON.5
SM20
Enables the inter-processor communication feature.
S0CON.4
REN0
If set, enables serial reception. Cleared by software to disable reception.
S0CON.3
TB80
The 9th transmitted data bit in Modes 2 and 3. Set or cleared by the MPU,
depending on the function it performs (parity check, multiprocessor
communication etc.).
S0CON.2
RB80
In Modes 2 and 3 it is the 9th data bit received. In Mode 1, if SM20 is 0,
RB80 is the stop bit. In Mode 0 this bit is not used. Must be cleared by
software.
S0CON.1
TI0
Transmit interrupt flag, set by hardware after completion of a serial transfer.
Must be cleared by software.
S0CON.0
RI0
Receive interrupt flag, set by hardware after completion of a serial
reception. Must be cleared by software.
1.7.4.2
Serial Interface 1
The Serial Interface 1 can operate in 2 modes:
•
Mode A
This mode is similar to Mode 2 and 3 of Serial interface 0, 11 bits are transmitted or received: a start
bit (0), 8 data bits (LSB first), a programmable 9th bit, and a stop bit (1). The 9th bit can be used to
control the parity of the serial interface: at transmission, bit TB81 in S1CON is outputted as the 9th
bit, and at receive, the 9th bit affects RB81 in Special Function Register S1CON. The only difference
between Mode 3 and A is that in Mode A only the internal baud rate generator can be use to specify
baud rate.
•
Mode B
This mode is similar to Mode 1 of Serial interface 0. Pin RX serves as input, and TX serves as serial
output. No external shift clock is used, 10 bits are transmitted: a start bit (always 0), 8 data bits (LSB
first), and a stop bit (always 1). On receive, a start bit synchronizes the transmission, 8 data bits are
available by reading S1BUF, and stop bit sets the flag RB81 in the Special Function Register
S1CON. In mode 1, the internal baud rate generator is use to specify the baud rate.
The S1BUF register is used to read/write data to/from the serial 1 interface.
Rev. 1.4
43
73S1215F Data Sheet
DS_1215F_003
Serial Interface Control Register (S1CON): 0x9B Å 0x00
The function of the serial port depends on the setting of the Serial Port Control Register S1CON.
Table 40: The S1CON Register
MSB
LSB
SM
–
Bit
Symbol
S1CON.7
SM
SM21
REN1
TB81
RB81
TI1
RI1
Function
Sets the UART operation mode.
SM
Mode
Description
Baud Rate
0
A
9-bit UART
variable
1
B
8-bit UART
variable
S1CON.6
–
S1CON.5
SM21
Enables the inter-processor communication feature.
S1CON.4
REN1
If set, enables serial reception. Cleared by software to disable
reception.
S1CON.3
TB81
The 9th transmitted data bit in Mode A. Set or cleared by the MPU,
depending on the function it performs (parity check, multiprocessor
communication etc.).
S1CON.2
RB81
In Mode B, if sm21 is 0, rb81 is the stop bit. Must be cleared by
software.
S1CON.1
TI1
Transmit interrupt flag, set by hardware after completion of a serial
transfer. Must be cleared by software.
S1CON.0
RI1
Receive interrupt flag, set by hardware after completion of a serial
reception. Must be cleared by software.
Multiprocessor operation mode: The feature of receiving 9 bits in Modes 2 and 3 of Serial Interface 0
or in Mode A of Serial Interface 1 can be used for multiprocessor communication. In this case, the slave
processors have bit SM20 in S0CON or SM21 in S1CON set to 1. When the master processor outputs
slave’s address, it sets the 9th bit to 1, causing a serial port receive interrupt in all the slaves. The slave
processors compare the received byte with their network address. If there is a match, the addressed
slave will clear SM20 or SM21 and receive the rest of the message, while other slaves will leave the
SM20 or SM21 bit unaffected and ignore this message. After addressing the slave, the host will output
the rest of the message with the 9th bit set to 0, so no serial port receive interrupt will be generated in
unselected slaves.
44
Rev. 1.4
DS_1215F_003
1.7.5
73S1215F Data Sheet
Timers and Counters
The 80515 has two 16-bit timer/counter registers: Timer 0 and Timer 1. These registers can be
configured for counter or timer operations.
In timer mode, the register is incremented every machine cycle, meaning that it counts up after every 12
periods of the MPU clock signal.
In counter mode, the register is incremented when the falling edge is observed at the corresponding input
signal T0 or T1 (T0 and T1 are the timer gating inputs derived from USR[0:7] pins, see the User (USR)
Ports section). Since it takes 2 machine cycles to recognize a 1-to-0 event, the maximum input count
rate is 1/2 of the oscillator frequency. There are no restrictions on the duty cycle, however to ensure
proper recognition of 0 or 1 state, an input should be stable for at least 1 machine cycle.
Four operating modes can be selected for Timer 0 and Timer 1. Two Special Function Registers (TMOD
and TCON) are used to select the appropriate mode.
The Timer 0 load registers are designated as TL0 and TH0 and the Timer 1 load registers are designated
as TL1 and TH1.
Timer/Counter Mode Control Register (TMOD): 0x89 Å 0x00
Bits TR1 and TR0 in the TCON register start their associated timers when set.
Table 41: The TMOD Register
MSB
LSB
GATE
C/T
M1
Timer 1
M0
GATE
C/T
M1
M0
Timer 0
Bit
Symbol
TMOD.7
TMOD.3
Gate
If set, enables external gate control (USR pin(s) connected to T0 or T1
for Counter 0 or 1, respectively). When T0 or T1 is high, and TRx bit is
set (see the TCON register), a counter is incremented every falling edge
on T0 or T1 input pin. If not set, the TRx bit controls the corresponding
timer.
TMOD.6
TMOD.2
C/T
Selects Timer or Counter operation. When set to 1, the counter
operation is performed based on the falling edge of T0 or T1. When
cleared to 0, the corresponding register will function as a timer.
TMOD.5
TMOD.1
M1
Selects the mode for Timer/Counter 0 or Timer/Counter 1, as shown in
TMOD description.
TMOD.4
TMOD.0
M0
Selects the mode for Timer/Counter 0 or Timer/Counter 1, as shown in
TMOD description.
Rev. 1.4
Function
45
73S1215F Data Sheet
DS_1215F_003
Table 42: Timers/Counters Mode Description
M1
M0
Mode
Function
0
0
Mode 0
13-bit Counter/Timer.
0
1
Mode 1
16-bit Counter/Timer.
1
0
Mode 2
8-bit auto-reload Counter/Timer.
1
1
Mode 3
If Timer 1 M1 and M0 bits are set to '1', Timer 1 stops. If Timer 0 M1
and M0 bits are set to '1', Timer 0 acts as two independent 8-bit
Timer/Counters.
Mode 0
Putting either timer/counter into mode 0 configures it as an 8-bit timer/counter with a divide-by-32
prescaler. In this mode, the timer register is configured as a 13-bit register. As the count rolls over from
all 1’s to all 0’s, it sets the timer overflow flag TF0. The overflow flag TF0 then can be used to request an
interrupt. The counted input is enabled to the timer when TRx = 1 and either GATE = 0 or TX = 1 (setting
GATE = 1 allows the timer to be controlled by external input TX, to facilitate pulse width measurements).
TRx are control bits in the special function register TCON; GATE is in TMOD. The 13-bit register consists
of all 8 bits of TH1 and the lower 5 bits of TL0. The upper 3 bits of TL0 are indeterminate and should be
ignored. Setting the run flag (TRx) does not clear the registers. Mode 0 operation is the same for timer 0
as for timer 1.
Mode 1
Mode 1 is the same as mode 0, except that the timer register is run with all 16 bits.
Mode 2
Mode 2 configures the timer register as an 8-bit counter (TLx) with automatic reload. The overflow from
TLx not only sets TFx, but also reloads TLx with the contents of THx, which is preset by software. The
reload leaves THx unchanged.
Mode 3
Mode 3 has different effects on timer 0 and timer 1. Timer 1 in mode 3 simply holds its count. The effect
is the same as setting TR1 = 0. Timer 0 in mode 3 establishes TL0 and TH0 as two separate counters.
TL0 uses the timer 0 control bits: C/T, GATE, TR0, INT0, and TF0. TH0 is locked into a timer function
(counting machine cycles) and takes over the use of TR1 and TF1 from timer 1. Thus, TH0 now controls
the "timer 1" interrupt. Mode 3 is provided for applications requiring an extra 8-bit timer or counter. When
timer 0 is in mode 3, timer 1 can be turned on and off by switching it out of and into its own mode 3, or
can still be used by the serial channel as a baud rate generator, or in fact, in any application not requiring
an interrupt from timer 1 itself.
46
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Timer/Counter Control Register (TCON): 0x88 Å 0x00
Table 43: The TCON Register
MSB
LSB
TF1
TR1
TF0
TR0
IE1
IT1
IE0
IT0
Bit
Symbol
Function
TCON.7
TF1
The Timer 1 overflow flag is set by hardware when Timer 1 overflows.
This flag can be cleared by software and is automatically cleared when
an interrupt is processed.
TCON.6
TR1
Timer 1 Run control bit. If cleared, Timer 1 stops.
TCON.5
TF0
Timer 0 overflow flag set by hardware when Timer 0 overflows. This
flag can be cleared by software and is automatically cleared when an
interrupt is processed.
TCON.4
TR0
Timer 0 Run control bit. If cleared, Timer 0 stops.
TCON.3
IE1
External Interrupt 1 edge flag.
TCON.2
IT1
External interrupt 1 type control bit.
TCON.1
IE0
External Interrupt 0 edge flag.
TCON.0
IT0
External Interrupt 0 type control bit.
1.7.6
WD Timer (Software Watchdog Timer)
The software watchdog timer is a 16-bit counter that is incremented once every 24 or 384 clock cycles.
After a reset, the watchdog timer is disabled and all registers are set to zero. The watchdog consists of a
16-bit counter (WDT), a reload register (WDTREL), prescalers (by 2 and by 16), and control logic. Once
the watchdog starts, it cannot be stopped unless the internal reset signal becomes active.
Note: It is recommended to use the hardware watchdog timer instead of the software watchdog
timer (refer to the RTC description).
WD Timer Start Procedure: The WDT is started by setting the SWDT flag. When the WDT register
enters the state 0x7CFF, an asynchronous WDTS signal will become active. The signal WDTS sets bit 6
in the IP0 register and requests a reset state. WDTS is cleared either by the reset signal or by changing
the state of the WDT timer.
Refreshing the WD Timer: The watchdog timer must be refreshed regularly to prevent the reset request
signal from becoming active. This requirement imposes an obligation on the programmer to issue two
instructions. The first instruction sets WDT and the second instruction sets SWDT. The maximum delay
allowed between setting WDT and SWDT is 12 clock cycles. If this period has expired and SWDT has
not been set, WDT is automatically reset, otherwise the watchdog timer is reloaded with the content of
the WDTREL register and WDT is automatically reset.
Rev. 1.4
47
73S1215F Data Sheet
DS_1215F_003
Interrupt Enable 0 Register (IEN0): 0xA8 Å 0x00
Table 44: The IEN0 Register
MSB
LSB
EAL
WDT
ET2
ES0
ET1
Bit
Symbol
IEN0.7
EAL
EAL = 0 – disable all interrupts.
IEN0.6
WDT
Watchdog timer refresh flag.
EX1
ET0
EX0
Function
Set to initiate a refresh of the watchdog timer. Must be set directly before
SWDT is set to prevent an unintentional refresh of the watchdog timer. WDT
is reset by hardware 12 clock cycles after it has been set.
IEN0.5
–
IEN0.4
ES0
ES0 = 0 – disable serial channel 0 interrupt.
IEN0.3
ET1
ET1 = 0 – disable timer 1 overflow interrupt.
IEN0.2
EX1
EX1 = 0 – disable external interrupt 1.
IEN0.1
ET0
ET0 = 0 – disable timer 0 overflow interrupt.
IEN0.0
EX0
EX0 = 0 – disable external interrupt 0.
Interrupt Enable 1 Register (IEN1): 0xB8 Å 0x00
Table 45: The IEN1 Register
MSB
LSB
–
48
SWDT
EX6
EX5
EX4
EX3
Bit
Symbol
IEN1.7
–
IEN1.6
SWDT
IEN1.5
EX6
EX6 = 0 – disable external interrupt 6.
IEN1.4
EX5
EX5 = 0 – disable external interrupt 5.
IEN1.3
EX4
EX4 = 0 – disable external interrupt 4.
IEN1.2
EX3
EX3 = 0 – disable external interrupt 3.
IEN1.1
EX2
EX2 = 0 – disable external interrupt 2.
IEN1.0
–
EX2
Function
Watchdog timer start/refresh flag. Set to activate/refresh the watchdog
timer. When directly set after setting WDT, a watchdog timer refresh is
performed. Bit SWDT is reset by the hardware 12 clock cycles after it has
been set.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Interrupt Priority 0 Register (IP0): 0xA9 Å 0x00
Table 46: The IP0 Register
MSB
LSB
–
WDTS
IP0.5
IP0.4
IP0.3
IP0.2
IP0.1
IP0.0
Bit
Symbol
Function
IP0.6
WDTS
Watchdog timer status flag. Set when the watchdog timer has expired.
The internal reset will be generated, but this bit will not be cleared by the
reset. This allows the user program to determine if the watchdog timer
caused the reset to occur and respond accordingly. Can be read and
cleared by software.
Note: The remaining bits in the IP0 register are not used for watchdog control.
Watchdog Timer Reload Register (WDTREL): 0x86 Å 0x00
Table 47: The WDTREL Register
MSB
LSB
WDPSEL WDREL6 WDREL5 WDREL4 WDREL3 WDREL2 WDREL1 WDREL0
Bit
Symbol
WDTREL.7
WDPSEL
Prescaler select bit. When set, the watchdog is clocked through an
additional divide-by-16 prescaler.
WDTREL.6
to
WDTREL.0
WDREL6-0
Seven bit reload value for the high-byte of the watchdog timer. This
value is loaded to the WDT when a refresh is triggered by a
consecutive setting of bits WDT and SWDT.
Rev. 1.4
Function
49
73S1215F Data Sheet
1.7.7
DS_1215F_003
User (USR) Ports
The 73S1215F includes 9 pins of general purpose digital I/O (GPIO). On reset or power-up, all USR pins
are inputs until they are configured for the desired direction. The pins are configured and controlled by the
USR and UDIR SFRs. Each pin declared as USR can be configured independently as an input or output
with the bits of the UDIRn registers. Table 48 lists the direction registers and configurability associated
with each group of USR pins. USR pins 0 to 7 are multiple use pins that can be used for general purpose
I/O, external interrupts and timer control.
Table 49 shows the configuration for a USR pin through its associated bit in its UDIR register. Values
read from and written into the GPIO ports use the data registers USR70 and USR8. Note: After reset, all
USR pins are defaulted as inputs and pulled up to VDD until any write to the corresponding UDIR register
is performed. This insures all USR pins are set to a known value until set by the firmware. Unused USR
pins can be set for output if unused and unconnected to prevent them from floating. Alternatively, unused
USR pins can be set for input and tied to ground or VDD.
Table 48: Direction Registers and Internal Resources for DIO Pin Groups
Direction
Register
(SFR)
Location
Data
Register
Name
Data
Register
(SFR)
Location
USR Pin Group
Type
Direction
Register
Name
USR_0…USR_7
Multi-use
UDIR70
0x91 [7:0]
USR70
0x90 [7:0]
USR_8
GPIO only
UDIR8
0xA1 [0]
USR8
0xA0 [0]
Table 49: UDIR Control Bit
UDIR Bit
USR Pin
Function
0
1
output
input
Four XRAM SFR registers (USRIntCtl1, USRIntCtl2, USRIntCtl3, and USRIntCtl4) control the use of the
USR [7:0] pins. Each of the USR [7:0] pins can be configured as GPIO or individually be assigned an
internal resource such as an interrupt or a timer/counter control. Each of the four registers contains two
3-bit configuration words named UxIS (where x corresponds to the USR pin). The control resources
selectable for the USR pins are listed in Table 50through Table 54. If more than one input is connected
to the same resource, the resources are combined using a logical OR.
Table 50: Selectable Controls Using the UxIS Bits
UxIS Value
Resource Selected for USRx Pin
0
None
1
None
2
T0 (counter0 gate/clock)
3
T1 (counter1 gate/clock)
4
Interrupt 0 rising edge/high level on USRx
5
Interrupt 1 rising edge/high level on USRx
6
Interrupt 0 falling edge/low level on USRx
7
Interrupt 1 falling edge/low level on USRx
Note: x denotes the corresponding USR pin. Interrupt edge or level control is assigned in the IT0 and IT1
bits in the TCON register.
50
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
External Interrupt Control Register (USRIntCtl1) : 0xFF90 Å 0x00
Table 51: The USRIntCtl1 Register
MSB
–
LSB
U1IS.6
U1IS.5
U1IS.4
–
U0IS.2
U0IS.1
U0IS.0
External Interrupt Control Register (USRIntCtl2) : 0xFF91 Å 0x00
Table 52: The USRIntCtl2 Register
MSB
–
LSB
U3IS.6
U3IS.5
U3IS.4
–
U2IS.2
U2IS.1
U2IS.0
External Interrupt Control Register (USRIntCtl3) : 0xFF92 Å 0x00
Table 53: The USRIntCtl3 Register
MSB
–
LSB
U5IS.6
U5IS.5
U5IS.4
–
U4IS.2
U4IS.1
U4IS.0
External Interrupt Control Register (USRIntCtl4) : 0xFF93 Å 0x00
Table 54: The USRIntCtl4 Register
MSB
–
Rev. 1.4
LSB
U7IS.6
U7IS.5
U7IS.4
–
U6IS.2
U6IS.1
U6IS.0
51
73S1215F Data Sheet
1.7.8
DS_1215F_003
Real-Time Clock with Hardware Watchdog (RTC)
R/W BUS
Figure 9 shows the block diagram of the Real Time Clock. The RTC block uses the 32768Hz oscillator
signal and divider logic to produce 0.5-second time marks. The time marks are used to create interrupts
at intervals from 0.5 seconds to 8 seconds as selected by RTC Interval (RTCINV(2:0)). The 32768Hz
oscillator can be disabled but is intended to operate at all times and in all power consumption modes.
If a 32kHz crystal is not provided, the 32kHz oscillator should be disabled and the RTC will operate from
MCLK (96MHz) divided by 2930 (refer to the oscillator and clock generation section). The clock
generated by the high speed oscillator will not yield
d exactly 32768 Hz, but a frequency of approximately
32764.505119 Hz. This yields a negative 106.6 PPM (1 / 9375) error with respect to 32768Hz. The RTC
circuit provides hardware to compensate for this error by providing an offset circuit that will adjust the
RTC counter.
1/2 Second
1 Second
1/2
1
2
4
8
WDT_TIMEOUT
SELECT
INTERRUPT
RATE
RTC INT
1/2s TIMEOUT
2 Second
DIVIDER
START
4 Second
R/W BUS
RTCCLK
8 Second
1/2
1
2
RESET
RTC ISR
SELECT
COUNT
RATE
1.024KHz
CLOCK
SIGN
23 BIT TRIM VALUE
R/W BUS
WATCH
DOG
TIMER
ADDER
R/W BUS
24 BIT ACCUMULATOR
OVERFLOW
ADVANCE
IF K overflow* sign=0, extra count
32 BIT COUNTER
R/W BUS
IF K overflow* sign=1, skip one count
Figure 9: Real Time Clock Block Diagram
52
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
A 32-bit RTC counter is clocked by a selectable clock (1/2, 1, 2 second) to measure time. A trimming
function is provided such that a trim value is accumulated in a 24-bit accumulator at the same rate as the
RTC counter. The trim value is sign magnitude number. When the accumulator reaches overflow, it will
advance the counter one additional count if the trim value is positive, or prevent the counter from
advancing one count if the trim value is negative. This mechanism allows the RTC counter to be adjusted
to keep accurate time with a minimum 0.5 second resolution. When using the high speed oscillator, the
RTC counter wants to have an extra count added every 9375 seconds to keep the RTC counter at the
proper time. If the one second RTC counter rate is used, the RTC Trim value should be set to 0x6FD
(1789 decimal). This value is derived by taking the resolution of the 24 bit accumulator (2 ^ 24 =
16777216) and dividing this by 9375. This means the RTC accumulator will overflow every 9375 seconds
and will cause the RTC counter to advance by 2 when the accumulator overflow occurs, thus bringing the
RTC count to the proper time.
In addition to the basic software watchdog timer included in the 80515 MPU, an independent, robust,
fixed-duration, hardware watchdog timer (WDT) is included with the 73S1215F RTC. The Watch Dog
timer will give the MPU ½ second to respond to the RTC Interrupt. If the processor does not perform an
RTC Interrupt service, a full RESET will be performed. The RTC interrupt is connected to the core
interrupt “external interrupt 5” signal. The RTC interrupt must be enabled to obtain the watchdog timer
function. Note: if the power down mode doesn’t want the watchdog to wake up the MPU, the RTC
interrupt should be masked before entering the power down mode.
Real Time Clock Control Register (RTCCtl) : 0x FFB0 Å 0x00
Table 55: The RTCCtl Register
MSB
LSB
–
–
Bit
Symbol
RTCCtl.7
–
RTCCtl.6
–
RTCCtl.5
RTCLD
RTCCtl.4
CTSEL.1
RTCCtl.3
CTSEL.0
RTCCtl.2
RINT.2
RTCCtl.1
RINT.1
RTCCtl.0
RINT.0
Rev. 1.4
RTCLD
CTSEL.1 CTSEL.0 RINT.2
RINT.1
RINT.0
Function
When set, RTC parameters (RTC Count, RTC Accumulator, and RTC
Trim) are loaded at the next 32kHz clock positive edge.
Selects the time value that is counted by the real time clock:
0x – 1 second (default)
10 – ½ second
11 – 2 seconds
RTC interrupt internal selection bits: (listed as bits 2,1,0)
100 – 0.5 second
0xx – 1 second (default)
101 – 2 seconds
110 – 4 seconds
111 – 8 seconds
53
73S1215F Data Sheet
DS_1215F_003
There are 3 sets of registers to load the RTC 24-bit accumulator, 32-bit counter and 23-bit trim registers.
The registers are loaded when the RTCLD bit is set in RTCCtl.
Table 56: The 32-bit RTC Counter
Register
RTCCnt3
RTCCnt2
RTCCnt1
RTCCnt0
RTCCnt[31:24]
RTCCnt[23:16]
RTCCnt[15:8]
RTCCnt[7:0]
Table 57: The 24-bit RTC Accumulator
Register
RTCACC2
RTCACC1
RTCACC0
RTCACC [23:16]
RTCACC [15:8]
RTCACC [7:0]
Table 58: The 24-bit RTC Trim (sign magnitude value)
Register
RTCTrim2
RTCTrim1
RTCTrim0
RTCTrim [23:16]
RTCTrim [15:8]
RTCTrim [7:0]
External Interrupt Control Register (INT5Ctl): 0xFF94 Å 0x00
Table 59: The INT5Ctl Register
MSB
LSB
PDMUX
–
RTCIEN
RTCINT
USBIEN USBINT
KPIEN
KPINT
Bit
Symbol
INT5Ctl.7
PDMUX
INT5Ctl.6
–
INT5Ctl.5
RTCIEN
When set =1, enables RTC interrupt. Note: The RTC based watchdog will
be enabled when set.
INT5Ctl.4
RTCINT
When set =1, indicates interrupt from Real Time Clock function. Cleared
on read of register.
INT5Ctl.3
USBIEN
USB interrupt enable.
INT5Ctl.2
USBINT
USB interrupt flag.
INT5Ctl.1
KPIEN
Keypad interrupt enable.
INT5Ctl.0
KPINT
Keypad interrupt flag.
54
Function
Power down multiplexer control.
Rev. 1.4
DS_1215F_003
1.7.9
73S1215F Data Sheet
Analog Voltage Comparator
The 73S1215F includes a programmable comparator that is connected to the ANA_IN pin. The
comparator can be configured to trigger an interrupt if the input voltage rises above or falls below a
selectable threshold voltage. The comparator control register should not be modified when the analog
interrupt (ANAIEN bit in the INT6Ctl register) is enabled to guard against any false interrupt that might be
generated when modifying the threshold. The comparator has a built-in hysteresis to prevent the
comparator from repeatedly responding to low-amplitude noise. This hysteresis is approximately 20mV.
The maximum voltage on the ANA_IN pad should be less than 3 volts. An external resistor divider is
required for detecting voltages greater than 3.0 volts. Interrupt control is handled in the INT6Ctl register.
Analog Compare Control Register (ACOMP): 0xFFD0 Å 0x00
Table 60: The ACOMP Register
MSB
LSB
ANALVL
–
ONCHG
CPOL
CMPEN
0
TSEL.1 TSEL.0
Bit
Symbol
ACOMP.7
ANALVL
ACOMP.6
–
ACOMP.5
ONCHG
If set, the Ana_interrupt is invoked on any change above or below the
threshold, bit 4 is ignored.
ACOMP.4
CPOL
If set = 1, Ana_interrupt is invoked when signal rises above selected
threshold. If set = 0, Ana_interrupt is invoked when signal goes below
selected threshold (default).
ACOMP.3
CMPEN
ACOMP.2
0
ACOMP.1
TSEL.1
ACOMP.0
TSEL.0
Rev. 1.4
Function
When read, indicates whether the input level is above or below the
threshold. This is a real time value and is not latched, so it may change
from the time of the interrupt trigger until read.
Enables power to the analog comparator. 1= Enabled. 0 = Disabled
(default).
This value must be fixed at 0.
Sets the voltage threshold for comparison to the voltage on pin ANA_IN.
Thresholds are as follows:
00 = 1.00V
01 = 1.24V
10 = 1.40V
11 = 1.50V
55
73S1215F Data Sheet
DS_1215F_003
External Interrupt Control Register (INT6Ctl): 0xFF95 Å 0x00
Table 61: The INT6Ctl Register
MSB
LSB
–
–
VFTIEN VFTINT I2CIEN
I2CINT
ANIEN
ANINT
Bit
Symbol
INT6Ctl.7
–
INT6Ctl.6
–
INT6Ctl.5
VFTIEN
VDD fault interrupt enable.
INT6Ctl.4
VFTINT
VDD fault interrupt flag.
INT6Ctl.3
I2CIEN
I2C interrupt enabled.
INT6Ctl.2
I2CINT
I2C interrupt flag.
INT6Ctl.1
ANIEN
If ANIEN = 1 Analog Compare event interrupt is enabled. When
masked (ANIEN = 0), ANINT (bit 0) may be set, but no interrupt is
generated.
INT6Ctl.0
ANINT
(Read Only) Set when the selected ANA_IN signal changes with
respect to the selected threshold if Compare_Enable is asserted.
Cleared on read of register.
56
Function
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
1.7.10 LED Drivers
The 73S1215F F provides four dedicated output pins for driving LEDs. The LED driver pins can be
configured as current sources that will pull to ground to drive LEDs that are connected to VDD without the
need for external current limiting resistors. These pins may be used as general purpose outputs with the
programmed pull-down current and a strong (CMOS) pull-up, if enabled. The analog block must be
enabled when these outputs are being used to drive the selected output current.
The pins can be used as inputs with consideration of the programmed output current and level. The
register bit when read, indicates the state of the pin.
LED Control Register (LEDCtl): 0xFFF3 Å 0xFF
Table 62: The LEDCtl Register
MSB
LSB
–
LPUEN
ISET.1
ISET.0
LEDD3
LEDD2 LEDD 1 LEDD0
Bit
Symbol
Function
LEDCtl.7
–
LEDCtl.6
LPUEN
0 = Pull-up is enabled for the LED pin.
LEDCtl.5
ISET.1
These two bits control the drive current (to ground) for all of the LED driver
pins. Current levels are:
00 = 0ma(off)
01 = 2ma
10 = 4ma
11 = 10ma
LEDCtl.4
ISET.0
LEDCtl.3
LEDD3
Write data controls output level of pin LED3. Read will report level of pin LED3.
LEDCtl.2
LEDD2
Write data controls output level of pin LED2. Read will report level of pin LED2.
LEDCtl.1
LEDD1
Write data controls output level of pin LED1. Read will report level of pin LED1.
LEDCtl.0
LEDD0
Write data controls output level of pin LED0. Read will report level of pin LED0.
Rev. 1.4
57
73S1215F Data Sheet
DS_1215F_003
1.7.11 I2C Master Interface
The 73S1215F includes a dedicated fast mode, 400kHz I2C Master interface. The I2C interface can read
or write 1 or 2 bytes of data per data transfer frame. The MPU communicates with the interface through
six dedicated SFR registers:
•
•
•
•
•
•
Device Address (DAR)
Write Data (WDR)
Secondary Write Data (SWDR)
Read Data (RDR)
Secondary Read Data (SRDR)
Control and Status (CSR)
The DAR register is used to set up the slave address and specify if the transaction is a read or write
operation. The CSR register sets up, starts the transaction and reports any errors that may occur. When
the I2C transaction is complete, the I2C interrupt is reported via external interrupt 6. The I2C interrupt is
automatically de-asserted when a subsequent I2C transaction is started. The I2C interface uses a 400kHz
clock from the time-base circuits.
1.7.11.1 I2C Write Sequence
To write data on the I2C Master Bus, the 80515 has to program the following registers according to the
following sequence:
1. Write slave device address to Device Address register (DAR). The data contains 7 bits for the slave
device address and 1 bit of op-code. The op-code bit should be written with a 0 to indicate a write
operation.
2. Write data to Write Data register (WDR). This data will be transferred to the slave device.
3. If writing 2 bytes, set bit 0 of the Control and Status register (CSR) and load the second data byte to
Secondary Write Data register (SWDR).
4. Set bit 1 of the CSR register to start I2C Master Bus.
5. Wait for I2C interrupt to be asserted. It indicates that the write on I2C Master Bus is done. Refer to
information about the INT6Ctl, IEN1 and IRCON register for masking and flag operation.
58
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Figure 10 shows the timing of the I2C write mode.
Transfer length
(CSR bit0)
Start I2C
(CSR bit1)
I2C_Interrupt
SDA
Device Address
[7:0]
MSB
SCL
Write Data [7:0
LSB
1-7
8
MSB
9
LSB
10-17
18
ACK bit
START
condition
ACK bit
STOP
condition
Transfer length
(CSR bit0)
Start I2C
(CSR bit1)
I2C_Interrupt
SDA
Device Address
[7:0]
MSB
SCL
LSB
1-7
START
condition
Secondary Write
Data [7:0]
Write Data [7:0]
8
MSB
9
ACK bit
MSB
LSB
10-17
18
ACK bit
LSB
19-26
27
ACK bit
STOP
condition
Figure 10: I2C Write Mode Operation
1.7.11.2 I2C Read Sequence
To read data on the I2C Master Bus from a slave device, the 80515 has to program the following registers
in this sequence:
1. Write slave device address to the Device Address register (DAR). The data contains 7 bits device
address and 1 bit of op-code. The op-code bit should be written with a 1.
2. Write control data to the Control and Status register (CSR). Write a 1 to bit 1 to start I2C Master Bus.
Also write a 1 to bit 0 if the Secondary Read Data (SRDR) register is to be captured from the I2C
Slave device.
3. Wait for I2C interrupt to be asserted. It indicates that the read operation on the I2C bus is done.
Refer to information about the INT6Ctl, IEN1 and IRCON registers for masking and flag operation.
4. Read data from the Read Data register (RDR).
5. Read data from Secondary Read Data register (SRDR) if bit 0 of Control and Status register (CSR) is
written with a 1.
Rev. 1.4
59
73S1215F Data Sheet
DS_1215F_003
Figure 11 shows the timing of the I2C read mode.
Transfer length
(CSR bit0)
Start I2C
(CSR bit1)
I2c_Interrupt
SDA
Device Address
[7:0]
MSB
SCL
Read Data [7:0
LSB
1-7
8
MSB
9
LSB
10-17
18
ACK bit
START
condition
No ACK bit
STOP
condition
Transfer length
(CSR bit0)
Start I2C
(CSR bit1)
I2c_Interrupt
SDA
Device Address
[7:0]
MSB
SCL
LSB
1-7
START
condition
Secondary Read
Data[7:0]
Read Data [7:0]
8
MSB
9
ACK bit
LSB
10-17
18
ACK bit
19-26
27
No ACK bit
STOP
condition
Figure 11: I2C Read Operation
60
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Device Address Register (DAR): 0xFF80 Å 0x00
Table 63: The DAR Register
MSB
LSB
DVADR.6
Bit
DVADR.5 DVADR.4 DVADR.3 DVADR.2
Symbol
DVADR.1
DVADR.0
I2CRW
Function
DAR.7
DAR.6
DAR.5
DAR.4
DAR.3
DVADR
[0:6]
Slave device address.
I2CRW
If set = 0, the transaction is a write operation. If set = 1, read.
DAR.2
DAR.1
DAR.0
I2C Write Data Register (WDR): 0XFF81 Å 0x00
Table 64: The WDR Register
MSB
WDR.7
Bit
LSB
WDR.6
WDR.5
WDR.4
WDR.3
WDR.2
WDR.1
WDR.0
Function
WDR.7
WDR.6
WDR.5
WDR.4
WDR.3
Data to be written to the I2C slave device.
WDR.2
WDR.1
WDR.0
Rev. 1.4
61
73S1215F Data Sheet
DS_1215F_003
I2C Secondary Write Data Register (SWDR): 0XFF82 Å 0x00
Table 65: The SWDR Register
MSB
SWDR.7
LSB
SWDR.6
SWDR.5
SWDR.4
SWDR.3
Bit
SWDR.2
SWDR.1
SWDR.0
Function
SWDR.7
SWDR.6
SWDR.5
SWDR.4
SWDR.3
Second Data byte to be written to the I2C slave device if bit 0 (I2CLEN) of the Control
and Status register (CSR) is set = 1.
SWDR.2
SWDR.1
SWDR.0
I2C Read Data Register (RDR): 0XFF83 Å 0x00
Table 66: The RDR Register
MSB
RDR.7
LSB
RDR.6
RDR.5
RDR.4
Bit
RDR.3
RDR.2
RDR.1
RDR.0
Function
RDR.7
RDR.6
RDR.5
RDR.4
RDR.3
Data read from the I2C slave device.
RDR.2
RDR.1
RDR.0
62
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
I2C Secondary Read Data Register (SRDR): 0XFF84 Å 0x00
Table 67: The SRDR Register
MSB
LSB
SRDR.7
SRDR.6
SRDR.5
SRDR.4
Bit
SRDR.3
SRDR.2
SRDR.1
SRDR.0
Function
SRDR.7
SRDR.6
SRDR.5
SRDR.4
Second Data byte to be read from the I2C slave device if bit 0 (I2CLEN) of the Control
and Status register (CSR) is set = 1.
SRDR.3
SRDR.2
SRDR.1
SRDR.0
I2C Control and Status Register (CSR): 0xFF85 Å 0x00
Table 68: The CSR Register
MSB
LSB
–
–
–
–
–
AKERR
I2CST
I2CLEN
Bit
Symbol
CSR.7
–
CSR.6
–
CSR.5
–
CSR.4
–
CSR.3
–
CSR.2
AKERR
Set to 1 if acknowledge bit from Slave Device is not 0. Automatically reset
when the new bus transaction is started.
CSR.1
I2CST
Write a 1 to start I2C transaction. Automatically reset to 0 when the bus
transaction is done. This bit should be treated as a “busy” indicator on
reading. If it is high, the serial read/write operations are not completed and
no new address or data should be written.
CSR.0
I2CLEN
Set to 1 for 2-byte read or write operations. Set to 0 for 1-byte operations.
Rev. 1.4
Function
63
73S1215F Data Sheet
DS_1215F_003
External Interrupt Control Register (INT6Ctl): 0xFF95 Å 0x00
Table 69: The INT6Ctl Register
MSB
LSB
–
–
VFTIEN VFTINT I2CIEN
I2CINT
ANIEN
ANINT
Bit
Symbol
INT6Ctl.7
–
INT6Ctl.6
–
INT6Ctl.5
VFTIEN
VDD fault interrupt enable.
INT6Ctl.4
VFTINT
VDD fault interrupt flag.
INT6Ctl.3
I2CIEN
When set = 1, the I2C interrupt is enabled.
INT6Ctl.2
I2CINT
When set =1, the I2C transaction has completed. Cleared upon the start of
a subsequent I2C transaction.
INT6Ctl.1
ANIEN
Analog compare interrupt enable.
INT6Ctl.0
ANINT
Analog compare interrupt flag.
64
Function
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
1.7.12 Keypad Interface
The 73S1215F supports a 30-button (6 row x 5 column) keypad (SPST Mechanical Contact Switches)
interface using 11 dedicated I/O pins.
Figure 12 shows a simplified block diagram of the keypad interface.
KORDERL / H Registers
7
6
6
5
5
4
4
3
3
2
2
Column
Scan Order
7
1
7
6
5
4
3
2
1
0
0
pull-up
VDD
Keypad Clock
Column Value
5
1
COL4:0
Scan
0
VDD
KSIZE Register
6
5
4
3
2
1
0
pullup
7
ROW5:0
KCOL Register(1)
Keypad Clock
Row Value
6
7
6
5
4
3
2
1
Debouncing
0
7
6
5
4
3
2
1
If smaller keypad than 6 x 5 is to be
implemented, unused row inputs
should be connected to VDD. Unused
column outputs should be left
unconnected.
Debounce Time
Key_Detect
Hardware Scan Enable
Key_Detect_Enable
KROW Register
0
6
KSTAT Register
Scan
Time
0
73S1215F
Dividers
1
2
3
4
5
6
7
KSCAN Register
1kHz (2)
(1) KCOL is normally used as Read only
register. When hardware keyscan mode
is disabled, this register is to be used by
firmware to write the column data to
handle firmware scanning.
(2) 1kHz internal clock signal can be
selected either from the PLL (= from the
12MHz main clock), or from the 32kHz
system clock.
Figure 12: Simplified Keypad Block Diagram
There are 5 drive lines (outputs) corresponding to columns and 6 sense lines (inputs) corresponding to
rows. Hysteresis and pull-ups are provided on all inputs (rows), which eliminate the need for external
resistors in the keypad. Key scanning happens by asserting one of the 5 column lines low and looking for
a low on a sense line indicating that a key is pressed (switch closed) at the intersection of the drive/sense
(col/row) line in the keypad. Key detection is performed by hardware with an incorporated debounce
timer. Debouncing time is adjustable through the KSCAN register. Internal hardware circuitry performs
column scanning at an adjustable scanning rate and column scanning order through registers KSCAN
and KORDERL / KORDERH. Key scanning is disabled at reset and must be enabled by firmware. When
a valid key is detected, an interrupt is generated and the valid value of the pressed key is automatically
written into KCOL and KROW registers. The keypad interface uses a 1kHz clock derived from either the
Rev. 1.4
65
73S1215F Data Sheet
DS_1215F_003
32768Hz crystal or the 12MHz crystal. The selection of the clock source is made external to this block,
by setting bit 3 – 32KBEN – in the MCLKCtl register (see the oscillator and clock generation section).
Disabling the 32kHz oscillator will source the 1kHz clock from the 12MHz main oscillator and divide it
down. Setting bit 6 – KBEN – in the MCLKCtl register will enable keypad scanning and debouncing. The
keypad size can be adjusted within the KSIZE register.
Normal scanning is performed by hardware when the bit SCNEN is set at 1 in the KSTAT register. Figure
13 shows the flowchart of how the hardware scanning operates. In order to minimize power, scanning
does not occur until a key-press is detected. Once hardware key scanning is enabled, the hardware
drives all column outputs low and waits for a low to be detected on one of the inputs. When a low is
detected on any row, and before key scanning starts, the hardware checks that the low level is still
detected after a debounce time. The debounce time is defined by firmware in the KSCAN register (bits
7:0, DBTIME). Debounce times from 4ms to 256ms in 4ms increments are supported. If a key is not
pressed after the debounce time, the hardware will go back to looking for any input to be low. If a key is
confirmed to be pressed, key scanning begins.
Key scanning asserts one of the 5 drive lines (COL 4:0) low and looks for a low on a sense line indicating
that a key is pressed at the intersection of the drive/sense line in the keypad. After all sense lines have
been checked without a key-press being detected, the next column line is asserted. The time between
checking each sense line is the scan time and is defined by firmware in the KSCAN register (bits 0:1 –
SCTIME). Scan times from 1ms to 4ms are supported. Scanning order does not affect the scan time.
This scanning continues until the entire keypad is scanned. If only one key is pressed, a valid key is
detected. Simultaneous key presses are not considered as valid (If two keys are pressed, no key is
reported to firmware).
Possible scrambling of the column scan order is provided by means of KORDERL and KORDERH
registers that define the order of column scanning. Values in these registers must be updated every time
a new keyboard scan order is desired. It is not possible to change the order of scanning the sense lines.
The column and row intersection for the detected valid key are stored in the KCOL and KROW registers.
When a valid key is detected, an interrupt is generated. Firmware can then read those registers to
determine which key had been pressed. After reading the KCOL and KROW registers, the firmware can
update the KORDERL / KORDERH registers if a new scan order is needed.
When the SCNEN bit is enabled in the KSTAT register, the KCOL and KROW registers are only updated
after a valid key has been identified. The hardware does not wait for the firmware to service the interrupt
in order to proceed with the key scanning process. Once the valid key (or invalid key – e.g. two keys
pressed) is detected, the hardware waits for the key to be released. Once the key is released, the
debounce timer is started. If the key is not still released after the debounce time, the debounce counter
starts again. After a key release, all columns will be driven low as before and the process will repeat
waiting for any key to be pressed.
When the SCNEN bit is disabled, all drive outputs are set to the value in the KCOL register. If firmware
clears the SCNEN bit in the middle of a key scan, the KCOL register contains the last value stored in
there which will then be reflected on the output pins.
A bypass mode is provided so that the firmware can do the key scanning manually (SCNEN bit must be
cleared). In bypass mode, the firmware writes/reads the Column and Row registers to perform the key
scanning.
66
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73S1215F Data Sheet
KSTAT Register:
Enable HW Scanning
Enable Keypad Interrupt
Keypad
Initialization
All Column
Outputs = 0
Any
Row
Input = 0 ?
No
Yes
No
Deboucing
Timer
KSCAN Register:
Debouncing Time
Any Row
Input still = 0 ?
KSIZE Register:
Keypad Size Definition
KORDERL / H Registers:
Column Scan Order
Keypad Scanning
KSCAN Register:
Scanning Rate
How Many
keys have been
detected?
More
than
1 key
0 key
1 key
Download of the key row and
column values in KROW and
KCOL registers
Keypad Interrupt
generation
KCOL Register:
Value of the valid key column
KROW Register:
Value of the valid key row
KSTAT Register:
Key Detect Interrupt
No
Deboucing
Timer
Is (are)
the key(s)
released ?
(*)
Yes
No
Is (are)
the key(s)
still released ?
(*)
Yes
KSCAN Register:
Debouncing Time
Register Used to Control the
hardware keypad interface
Register written by the
hardware keypad interface
(*) Key release is cheked by looking for a low level on any row.
Figure 13: Keypad Interface Flow Chart
Rev. 1.4
67
73S1215F Data Sheet
DS_1215F_003
Keypad Column Register (KCOL): 0xD1 Å 0x1F
This register contains the value of the column of a key detected as valid by the hardware. In bypass
mode, this register firmware writes directly this register to carry out manual scanning.
Table 70: The KCOL Register
MSB
LSB
–
–
Bit
Symbol
KCOL.7
–
KCOL.6
–
KCOL.5
–
KCOL.4
COL.4
KCOL.3
COL.3
KCOL.2
COL.2
KCOL.1
COL.1
KCOL.0
COL.0
–
COL.4
COL.3
COL.2
COL.1
COL.0
Function
Drive lines bit mapped to corresponding with pins COL(4:0). When a key
is detected, firmware reads this register to determine column. In bypass
(S/W keyscan) mode, Firmware writes this register directly. 0x1E =
COL(0) low, all others high. 0x0F = COL(4) low, all others high. 0x1F =
COL(4:0) all high.
Keypad Row Register (KROW): 0xD2 Å 0x3F
This register contains the value of the row of a key detected as valid by the hardware. In bypass mode,
this register firmware reads directly this register to carry out manual detection.
Table 71: The KROW Register
MSB
LSB
–
68
–
Bit
Symbol
KROW.7
–
KROW.6
–
KROW.5
ROW.6
KROW.4
ROW.4
KROW.3
ROW.3
KROW.2
ROW.2
KROW.1
ROW.1
KROW.0
ROW.0
ROW.5
ROW.4
ROW.3
ROW.2
ROW.1
ROW.0
Function
Sense lines bit mapped to correspond with pins ROW(5:0). When key
detected, firmware reads this register to determine row. In bypass mode,
firmware reads rows and has to determine if there was a key press or not.
0x3E = ROW(0) low, all others high. 0x1F = ROW(5) low, all others high.
0x3F = ROW(5:0) all high.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Keypad Scan Time Register (KSCAN): 0xD3 Å 0x00
This register contains the values of scanning time and debouncing time.
Table 72: The KSCAN Register
MSB
LSB
DBTIME.5
DBTIME.4
Bit
Symbol
KSCAN.7
DBTIME.5
KSCAN.6
DBTIME.4
KSCAN.5
DBTIME.3
KSCAN.4
DBTIME.2
KSCAN.3
DBTIME.1
KSCAN.2
DBTIME.0
KSCAN.1
SCTIME.1
KSCAN.0
SCTIME.0
DBTIME.3 DBTIME.2 DBTIME.1
DBTIME.0
SCTIME.1 SCTIME.0
Function
De-bounce time in 4ms increments. 1 = 4ms de-bounce time, 0x3F =
252ms, 0x00 = 256ms. Key presses and key releases are de-bounced by
this amount of time.
Scan time in ms. 01 = 1ms, 02 = 2ms, 00 = 3ms, 00 = 4ms. Time between
checking each key during keypad scanning.
Keypad Control/Status Register (KSTAT): 0xD4 Å 0x00
This register is used to control the hardware keypad scanning and detection capabilities, as well as the
keypad interrupt control and status.
Table 73: The KSTAT Register
MSB
LSB
–
–
–
–
KEYCLK HWSCEN KEYDET KYDTEN
Bit
Symbol
KSTAT.7
–
KSTAT.6
–
KSTAT.5
–
KSTAT.4
–
KSTAT.3
KEYCLK
The current state of the keyboard clock can be read from this bit.
KSTAT.2
HWSCEN
Hardware Scan Enable – When set, the hardware will perform automatic
key scanning. When cleared, the firmware must perform the key scanning
manually (bypass mode).
KSTAT.1
KEYDET
Key Detect – When HWSCEN = 1 this bit is set causing an interrupt that
indicates a valid key press was detected and the key location can be read
from the Keypad Column and Row registers. When HWSCEN = 0, this bit
is an interrupt which indicates a falling edge on any Row input if all Row
inputs had been high previously (note: multiple Key Detect interrupts may
occur in this case due to the keypad switch bouncing). In all cases, this bit
is cleared when read. When HWSCEN = 0 and the keypad interface 1kHz
clock is disabled, a key press will still set this bit and cause an interrupt.
KSTAT.0
KYDTEN
Key Detect Enable – When set, the KEYDET bit can cause an interrupt and
when cleared the KEYDET cannot cause an interrupt. KEYDET can still
get set even if the interrupt is not enabled.
Rev. 1.4
Function
69
73S1215F Data Sheet
DS_1215F_003
Keypad Scan Time Register (KSIZE): 0xD5 Å 0x00
This register is not applicable when HWSCEN is not set. Unused row inputs should be connected to
VDD.
Table 74: The KSIZE Register
MSB
LSB
–
–
ROWSIZ.2
Bit
Symbol
KSIZE.7
–
KSIZE.6
–
KSIZE.5
ROWSIZ.2
KSIZE.4
ROWSIZ.1
KSIZE.3
ROWSIZ.0
KSIZE.2
COLSIZ.2
KSIZE.1
COLSIZ.1
KSIZE.0
COLSIZ.0
ROWSIZ.1
ROWSIZ.0 COLSIZ.2 COLSIZ.1 COLSIZ.0
Function
Defines the number of rows in the keypad. Maximum number is 6 given
the number of row pins on the package. Allows for a reduced keypad size
for scanning.
Defines the number of columns in the keypad. Maximum number is 5
given the number of column pins on the package. Allows for a reduced
keypad size for scanning.
Keypad Column LS Scan Order Register (KORDERL): 0xD6 Å 0x00
In registers KORDERL and KORDERH, Column Scan Order(14:0) is grouped into 5 sets of 3 bits each.
Each set determines which column (COL(4:0) pin) to activate by loading the column number into the 3
bits. When in HW_Scan_Enable mode, the hardware will step through the sets from 1Col to 5Col (up to
the number of columns in Colsize) and scan the column defined in the 3 bits. To scan in sequential
order, set a counting pattern with 0 in set 0, and 1 in set 1,and 2 in set 2, and 3 in set 3, and 4 in set 4.
The firmware should update this as part of the interrupt service routine so that the new scan order is
loaded prior to the next key being pressed. For example, to scan COL(0) first, 1Col(2:0) should be
loaded with 000’b. To scan COL(4) fifth, 5Col(2:0) should be loaded with 100’b.
Table 75: The KORDERL Register
MSB
3COL.1
LSB
3COL.0
Bit
Symbol
KORDERL.7
3COL.1
KORDERL.6
3COL.0
KORDERL.5
2COL.2
KORDERL.4
2COL.1
KORDERL.3
2COL.0
KORDERL.2
1COL.2
KORDERL.1
1COL.1
KORDERL.0
1COL.0
70
2COL.2
2COL.1
2COL.0
1COL.2
1COL.1
1COL.0
Function
Column to scan 3rd (lsb’s).
Column to scan 2nd.
Column to scan 1st.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Keypad Column MS Scan Order Register (KORDERH): 0xD7 Å 0x00
Table 76: The KORDERH Register
MSB
LSB
–
5COL.2
Bit
Symbol
KORDERH.7
–
KORDERH.6
5COL.2
KORDERH.5
5COL.1
KORDERH.4
5COL.0
KORDERH.3
4COL.2
KORDERH.2
4COL.1
KORDERH.1
4COL.0
KORDERH.0
3COL.2
5COL.1
5COL.0
4COL.2
4COL.1
4COL.0
3COL.2
Function
Column to scan 5th.
Column to scan 4th.
Column to scan 3rd (msb).
External Interrupt Control Register (INT5Ctl): 0xFF94 Å 0x00
Table 77: The INT5Ctl Register
MSB
LSB
PDMUX
–
RTCIEN RTCINT
USBIEN USBINT
KPIEN
KPINT
Bit
Symbol
INT5Ctl.7
PDMUX
INT5Ctl.6
–
INT5Ctl.5
RTCIEN
When set =1, enables RTC interrupt.
INT5Ctl.4
RTCINT
When set =1, indicates interrupt from Real Time Clock function. Cleared
on read of register.
INT5Ctl.3
USBIEN
USB interrupt enable.
INT5Ctl.2
USBINT
USB interrupt flag.
INT5Ctl.1
KPIEN
Enables Keypad interrupt when set = 1.
INT5Ctl.0
KPINT
This bit indicates the Keypad logic has set Key_Detect bit and a key
location may be read. Cleared on read of register.
Rev. 1.4
Function
Power down multiplexer control.
71
73S1215F Data Sheet
DS_1215F_003
1.7.13 Emulator Port
The emulator port, consisting of the pins E_RST, E_TCLK and E_RXTX, provides control of the MPU
through an external in-circuit emulator. The E_TBUS[3:0] pins, together with the E_ISYNC/BRKRQ, add
trace capability to the emulator. The emulator port is compatible with the ADM51 emulators
manufactured by Signum Systems.
If code trace capability is needed on this interface, 20pF capacitors (to ground) need to be added to allow
the trace function capability to run properly. These capacitors should be attached to the TBUS0:3 and
ISBR signals.
1.7.14 USB Interface
The 73S1215F provides a single interface, full speed -12Mbps - USB device port as per the Universal
Serial Bus Specification, Revision 2.0 (backward compatible with USB 1.1). USB circuitry gathers the
transceiver, the Serial Interface Engine (SIE), and the data buffers. An internal pull-up to VDD on D+
indicates that the device is a full speed device attached to the USB bus (allows full speed recognition by
the host without adding any external components). When using the USB interface, VDD must be between
3.0V – 3.6V in order to meet the USB VOH requirement. The interface is highly configurable under
firmware control. Control (Endpoint 0), Interrupt IN, Bulk IN and Bulk OUT transfers are supported. Four
endpoints are supported and are configured by firmware:
•
•
•
•
•
•
•
•
Endpoint 0, the default (Control) endpoint as required by the Universal Serial Bus Specification, is
used to exchange control and status information between the 73S1215F and the USB host.
Bulk IN Endpoint #1
Bulk OUT Endpoint #1
Interrupt IN Endpoint #2
The USB block contains several FIFOs used for communication.
There is a 128 byte RAM FIFO for each BULK endpoint. Maximum Bulk packet size is 64 bytes.
There is a 32 byte RAM FIFO for the interrupt endpoint. Maximum Interrupt packet size is 16 bytes.
There is a 16 byte RAM FIFO for the control endpoint. Maximum Control packet size is 16 bytes.
Figure 14 shows the simplified block diagram of the USB interface.
USB Registers
VDD
MISCtl1
0
USBCon
16-Byte FIFO
D+
D-
Transceivers
USB
Full Speed
12Mbps
Serial
Interface
Engine
Control Endpoint 0
128-Byte FIFO
Bulk IN Endpoint 1
128-Byte FIFO
Bulk OUT Endpoint 1
32-Byte FIFO
USBPEN
Interrupt IN Endpoint 2
1
MISCtl1
48MHz
Clock
Figure 14: USB Block Diagram
72
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
The USB interface includes a Serial Interface Engine (SIE) that handles NRZI encoding/decoding, bit
stuffing / unstuffing, and CRC generation/checking. It also generates headers for packets to be
transmitted and decodes the headers of received packets. An analog transceiver interfaces with the
external USB bus. The USB interface hardware performs error checking and removes the USB protocol
fields from the incoming messages before passing the data to the firmware. The hardware also adds the
USB protocol fields to the outgoing messages coming from the firmware. The hardware implements
NRZI encoding/decoding, CRC checking/generation (both on data and token packets), device address
decoding, handshake packet generation, Data0/Data1 toggle synchronization, bit stuffing, bus idle
detection and other protocol generation/checking required in Chapter 8 of the Universal Serial Bus
Specification, Revision 2.0.
The firmware is responsible for servicing and building of the messages required under Chapter 9 of the
Universal Serial Bus Specification, Revision 2.0. Device configuration is stored in the firmware. Data
received from the USB port is stored in the appropriate IN FIFO that is read by the firmware and
processed. The messages to be sent back to the USB host are generated by firmware and placed back
into the appropriate OUT FIFO. Stall/NAK handshakes are generated as appropriate if the RAM is not
available for another message from the USB host. Suspend and resume modes are supported. All
register/FIFO spaces are located in Data Memory space. The FIFOs are dedicated for USB storage and
are unused in a configuration that is not using USB. All registers in the USB interface are located in
external data memory address (XRAM) space starting at address FC00’h.
Rev. 1.4
73
73S1215F Data Sheet
DS_1215F_003
1.7.14.1 USB Interface Implementation
The 73S1215F Application Programming Interface includes some dedicated software commands to
configure the USB interface, to get a status of each USB Endpoint, to stall / unstall portions of the USB,
and to send / receive data to / from each endpoint.
USB API entirely manages the USB circuitry, the USB registers and the FIFOs. Use of those commands
facilitates USB implementation, without dealing with low-level programming.
Miscellaneous Control Register 1 (MISCtl1): 0xFFF2 Å 0x10
Table 78: The MISCtl1 Register
MSB
–
LSB
–
FRPEN
FLSH66
–
ANAPEN USBPEN USBCON
Bit
Symbol
Function
MISCtl1.7
–
MISCtl1.6
–
MISCtl1.5
FRPEN
Flash Read Pulse enable.
MISCtl1.4
FLSH66
Flash Read Pulse.
MISCtl1.3
–
MISCtl1.2
ANAPEN
Analog power enable.
MISCtl1.1
USBPEN
0 = Enable the USB differential transceiver.
MISCtl1.0
USBCON
1 = Connect pull-up resistor from VDD to D+. If connected, the USB
host will recognize the attachment of a USB device and begin
enumeration.
Note: When using the USB on the 73S1215F, external 24Ω series resistors must be added to the D+ and
D- signals to provide the proper impedance matching on these pins.
The USB peripheral block is not able to support read or write operations to the USB SFR registers when
the MPU clock is running at MPU clock rates of 12MHz or greater. In order to properly communicate with
the USB SFR registers when running at these speeds, wait states must be inserted when addressing the
USB SFRs. The CKCON register allows wait states to be inserted when accessing these registers. The
proper settings for the number of wait states are shown in Error! Reference source not found..
When changing the MPU clock rate or the number of wait states, the USB connection
must be inactive. If the USB is active, then it must be inactivated before changing the
MPU clock or number of wait states. It can then be reconnected and re-enumerated.
Changing these parameters while the USB interface is active may cause communication errors on
the USB interface.
74
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Clock Control Register (CKCON): 0x8E Å 0x01
Table 79: The CKCON Register
MSB
LSB
–
–
Bit
Symbol
CKCON.7
–
CKCON.6
–
CKCON.5
–
CKCON.4
–
CKCON.3
–
CKCON.2
CKWT.2
CKCON.1
CKWT.1
CKCON.0
CKWT.0
Rev. 1.4
–
–
–
CKWT.2 CKWT.1 CKWT.0
Function
These three bits determine the number of wait states (machine cycles) to
insert when accessing the USB SFRs:
000 = 0 (not to be used).
001 = 1 wait state.
Use when MPU clock is <12MHz.
010 = 2 wait states. Use when MPU clock is between 12 and 16MHz.
011 = 3 wait states. Use when MPU clock is 24MHz.
100 = 4 wait states.
101 = 5 wait states.
110 = 6 wait states.
111 = 7 wait states.
75
73S1215F Data Sheet
DS_1215F_003
1.7.15 Smart Card Interface Function
The 73S1215F integrates one ISO-7816 (T=0, T=1) UART, one complete ICC electrical interface as well
as an external smart card interface to allow multiple
iple smart cards to be connected using the Teridian 8010
family of interface devices. Figure 15 shows the simplified block diagram of the card circuitry (UART +
interfaces), with detail of dedicated XRAM registers.
SCInt
SCIE
ICC Event
Card Interrupt
Management
ICC Pwr_event
Card
Insertion
SParCtl
Serial
UART
SByteCtl
SCCtl
UART
T=0 T=1
SCPrtcol
STXCtl
RX
Direct
Mode
SCECtl
2-Byte
Tx FIFO
Card and
Mode
Selection
SRXData
Bypass
Mode
SRXCtl
Activation /
Deactivation
Sequencer
VCC Card
Generation
VCC
STXData
2-Byte
Rx FIFO
VccCtl/
VccTMR
TX
SCSel
Buffer / Level
Shifter
I/O ICC#1
I/OExt. ICC
FDReg
I/O
Buffer / Level
Shifter
RST
Buffer / Level
Shifter
SCCLK/SCSCLK
CLK
BGT/EGT
BGT0/1/2/3/
CWT0/1
ATRMsB/LsB
PRES
Buffer / Level
Shifter
Timers
C4
STSTO
Buffer / Level
Shifter
RLength
C8
SCDir
SCCLK
CLK ICC
7.2MHz
Card Clock
Management
Internal ICC Interface
CLKExt. ICC
SIO
SCLK
XRAM Registers
SCCLK/
SCSCLK
SCSCLK
External ICC Interface
Figure 15: Smart Card Interface Block Diagram
Card interrupts are managed through two dedicated registers SCIE (Interrupt Enable to define which
interrupt is enabled) and SCInt (Interrupt status). They allow the firmware to determine the source of an
interrupt, that can be a card insertion / removal, card power fault, or a transmission (TX) or reception (RX)
event / fault. It should be noted that even when card clock is disabled, an ICC interrupt can be generated
76
Rev. 1.4
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73S1215F Data Sheet
on a card insertion / removal to allow power saving modes. Card insertion / removal is generated from
the respective card switch detection inputs (whose polarity is programmable).
The built-in ICC Interface has a low dropout regulator (VCC generator) capable of driving 1.8V, 3.0V and
5.0V smart cards in accordance with the ISO 7816-3 and EMV4.0 standards. This converter requires a
separate 5.0V input supply source designated as VPC. Auxiliary I/O lines C4 and C8 are only provided
for the built-in interface. If support for the auxiliary lines is necessary for the external interfaces, they
need to be handled manually through the USR GPIO pins. The external 8010 devices directly connect
the I/O (SIO) and clock (SCLK) signals and control is handled via the I2C interface.
Figure 16 shows how multiple 8010 devices can be connected to the 73S1215F.
VPC
VPC
PRES
PRES
VCC
RST
CLK
C4
C8
I/O
GND
SC1
SIO
SCLK
INT
73S1215F
SCL
PRES
73S8010
SC(n)
SDA
IOUC
XTALIN
SAD(0:2)
INT
SCL
SDA
PRES
73S8010
SC3
IOUC
XTALIN
SAD(0:2)
INT3
INT
SCL
PRES
73S8010
SDA
SDA
SCL
IOUC
XTALIN
SAD(0:2)
SC2
Figure 16: Smart Card Interface Block Diagram
Rev. 1.4
77
73S1215F Data Sheet
DS_1215F_003
1.7.15.1 ISO 7816 UART
An embedded ISO 7816 (hardware) UART is provided to control communications between a smart card
and the 73S1215F MPU. The UART can be shared between the one built-in ICC interface and the
external ICC interface. Selection of the desired interface is made by register SCSel. Control of the
external interface is handled by the I2C interface for any external 8010 devices. The following is a list of
features for the ISO 7816 UART:
•
•
•
•
•
•
•
•
•
•
•
•
Two-byte FIFO for temporary data storage on both TX and Rx data.
Parity checking in T=0. This feature can be enabled/disabled by firmware. Parity error reporting to
firmware and Break generation to ICC can be controlled independently.
Parity error generation for test purposes.
Retransmission of last byte if ICC indicates T=0 parity error. This feature can be enabled/disabled by
firmware.
Deletion of last byte received if ICC indicates T=0 parity error. This feature can be enabled/disabled
by firmware.
CRC/LRC generation and checking. CRC/LRC is automatically inserted into T=1 data stream by the
hardware. This feature can be enabled/disabled by firmware.
Support baud rates: 230000, 115200, 57600, 38400, 28800, 19200, 14400, 9600 under firmware
control (assuming 12MHz crystal) with various F/D settings
Firmware manages F/D. All F/D combinations are supported in which F/D is directly divisible by 31 or
32 (i.e. F/D is a multiple of either 31 or 32).
Flexible ETU clock generation and control.
Detection of convention (direct or indirect) character TS. This affects both polarity and order of bits in
byte. Convention can be overridden by firmware.
Supports WTX Timeout with an expanded Wait Time Counter (28 bits).
A Bypass Mode is provided to bypass the hardware UART in order for the software to emulate the
UART (for non-standard operating modes). In such a case, the I/O line value is reflected in SFR
SCCtl or SCECtl respectively for the built-in or external interfaces. This mode is appropriate for
some synchronous and non T=0 / T=1 cards.
The single integrated smart card UART is capable of supporting T=0 and T=1 cards in hardware
therefore offloading the bit manipulation tasks from the firmware. The embedded firmware instructs the
hardware which smart card it should communicate with at any point in time. Firmware reconfigures the
UART as required when switching between smart cards. When the 73S1215F has transmitted a
message with an expected response, the firmware should not switch the UART to another smart card
until the first smart card has responded. If the smart card responds while another smart card is selected,
that first smart card’s response will be ignored.
1.7.15.2 Answer to Reset Processing
A card insertion event generates an interrupt to the firmware, which is then responsible for the
configuration of the electrical interface, the UART and activation of the card. The activation sequencer
goes through the power up sequence as defined in the ISO 7816-3 specification. An asynchronous
activation timing diagram is shown in Figure 17. After the card RST is de-asserted, the firmware instructs
the hardware to look for a TS byte that begins the ATR response. If a response is not provided within the
pre-programmed timeout period, an interrupt is generated and the firmware can then take appropriate
action, including instructing the 73S1215F to begin a deactivation sequence. Once commanded, the
deactivation sequencer goes through the power down sequence as defined in the ISO 7816-3
specification. If an ATR response is received, the hardware looks for a TS byte that determines
direct/inverse convention. The hardware handles the indirect convention conversion such that the
embedded firmware only receives direct convention. This feature can be disabled by firmware within
SByteCtl register. Parity checking and break generation is performed on the TS byte unless disabled by
firmware. If during the card session, a card removal, over-current or other error event is detected, the
hardware will automatically perform the deactivation sequence and then generate an interrupt to the
firmware. The firmware can then perform any other error handling required for proper system operation.
78
Rev. 1.4
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73S1215F Data Sheet
Smart card RST, I/O and CLK, C4, C8 shall be low before the end of the deactivation sequence. Figure
18 shows the timing for a deactivation sequence.
SELSC
bits
VCCSEL
bits
VCC
VCCOK bit
t4
RSTCRD bit
See Note
RST
CLK
ATR starts
IO
t1
t2
t3
t4
t5
tto
t1: SELSC.1 bit set (selects internal ICC interface) and a non-zero value in VCCSEL bits (calling for a
value of Vcc of 1.8, 3.0, or 5.0 volts) will begin the activation sequence. t1 is the time for Vcc to rise to
acceptable level, declared as Vcc OK (bit VCCOK gets set). This time depends on filter capacitor
value and card Icc load.
tto: The time allowed for Vcc to rise to Vcc OK status after setting of the VCCSEL bits. This time is
generated by the VCCTMR counter. If Vcc OK is not set, (bit VCCOK) at this time, a deactivation will
be initiated. VCCSEL bits are not automatically cleared. The firmware must clear the VCCSEL bits
before starting a new activation.
t2: Time from VCCTMR timeout and VCC OK to IO reception (high), typically 2-3 CLK cycles if
RDYST = 0. If RDYST = 1, t2 starts when VCCOK = 1.
t3: Time from IO = high to CLK start, typically 2-3 CLK cycles.
t4: Time allowed for start of CLK to de-assertion of RST. Programmable by RLength register.
t5: Time allowed for ATR timeout, set by the STSTO register.
Note: If the RSTCRD bit is set, RST is asserted (low). Upon clearing RSTCRD bit, RST will be
de-asserted after t4.
Figure 17: Asynchronous Activation Sequence Timing
Rev. 1.4
79
73S1215F Data Sheet
Firmware sets
VCCSEL to 00
DS_1215F_003
t5
t5 delay or
Card Event
IO
RST
CLK
CMDVCCnB
VCC
t3
t1
t2
t4
t1: Time after either a “card event” occurs or firmware sets the VCCSela and VCCSelb bits to 0 (see
t5, VCCOff_tmr) occurs until RST is asserted low.
t2: Time after RST goes low until CLK stops.
t3: Time after CLK stops until IO goes low.
t4: Time after IO goes low until VCC is powered down.
t5: Delayed VCC off time (in ETUs per VCCOff_tmr bits). Only in effect due to firmware deactivation.
Figure 18: Deactivation Sequence
1.7.15.3 Data Reception/Transmission
When a 12Mhz crystal is used, the smart card UART will generate a 3.69Mhz (default) clock to both
smart card interfaces. This will allow approximately 9600bps (1/ETU) communication during ATR (ISO
7816 default). As part of the PPS negotiation between the smart card and the reader, the firmware may
determine that the smart card parameters F & D may be changed. After this negotiation, the firmware
may change the ETU by writing to the SFR FDReg to adjust the ETU and CLK. The firmware may also
change the smart card clock frequency by writing to the SFR SCCLK (SCECLK for external interface).
Independent clock frequency control is provided to each smart card interface. Clock stop high or Clock
stop low is supported in asynchronous mode. Figure 19 shows the ETU and CLK control circuits. The
firmware determines when clock stop is supported by the smart card and when it is appropriate to go into
that mode (and when to come out of it). The smart card UART is clocked by the same clock that is
provided to the selected smart card. The transition between smart card clocks is handled in hardware to
eliminate any glitches for the UART during switchover. The external smart card clock is not affected
when switching the UART to communicate with the internal smart card.
80
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
FDReg(3:0)
FDReg(7:4)
FI Decoder
F/D Register
Pre-Scaler
6 bits
ETUCLK
EDGE
ETU Divider
12 bits
7.38M
1/13
9926
CENTER
1/744
SCSel(3:2)
SCCLK(5:0)
MSCLK
SCSCLK(5:0)
7.38M
DIV
by
2
SYNC
3.69M
CLK
MCLK =
96MHz
PLL
Pre-Scaler
6 bits
MSCLKE
7.38M
1/13
DIV
by
2
3.69M
SCLK
Defaults
in Italics
Figure 19: Smart Card CLK and ETU Generation
There are two, two-byte FIFOs that are used to buffer transmit and receive data. During a T=0 processing,
if a parity error is detected by the 73S1215F during message reception, an error signal (BREAK) will be
generated to the smart card. The byte received will be discarded and the firmware notified of the error.
Break generation and receive byte dropping can be disabled under firmware control. During the
transmission of a byte, if an error signal (BREAK) is detected, the last byte is retransmitted again and the
firmware notified. Retransmission can be disabled by firmware. When a correct byte is received, an
interrupt is generated to the firmware, which then reads the byte from the receive FIFO. Receive overruns
are detected by the hardware and reported via an interrupt. During transmission of a message, the
firmware will write bytes into the transmit FIFO. The hardware will send them to the smart card. When the
last byte of a message has been written, the firmware will need to set the LASTTX bit in the STXCtl SFR.
This will cause the hardware to insert the CRC/LRC if in a T=1 protocol mode. CRC/LRC
generation/checking is only provided during T=1 processing. Firmware will need to instruct the smart
function to go into receive mode after this last transmit data byte if it expects a response from the smart
card. At the end of the smart card response, the firmware will put the interface back into transmit mode if
appropriate.
The hardware can check for the following card-related timeouts:
•
•
•
Character Waiting Time (CWT)
Block Waiting Time (BWT)
Initial Waiting Time (IWT)
The firmware will load the Wait Time registers with the appropriate value for the operating mode at the
appropriate time. Figure 20 shows the guard, block, wait and ATR time definitions. If a timeout occurs,
an interrupt will be generated and the firmware can take appropriate recovery steps. Support is provided
for adding additional guard times between characters (Extra Guard Time register) and between the last
byte received by the 73S1215F and the first byte transmitted by the 73S1215F Block Guard Time register
(BGT). Other than the protocol checks described above, the firmware is responsible for all protocol
checking and error recovery.
Rev. 1.4
81
73S1215F Data Sheet
DS_1215F_003
T = 0 Mode
> EGT
CHAR 1
CHAR 2
< WWT
WWT is set by the value in the BWT registers.
T = 1 Mode
TRANSMISSION
RECEPTION
(By seting Last_TXByte and
TX/RXB=0 during CHAR N,
RX mode will start after last
TX byte)
BLOCK1
CHAR 1
CHAR 2
CHAR N
BGT(4:0)
BLOCK2
CHAR
N+1
CHAR
N+2
CHAR
N+3
TX
> BWT
EGT
< CWT
ATR Timing Parameters
CHAR 1
CHAR 2
CHAR N
IO
TSTO(7:0)
ATRTO(15:0)
RST
IWT(15:0)
RLen(7:0)
VCC_OK
Figure 20: Guard, Block, Wait and ATR Time Definitions
1.7.15.4 Bypass Mode
It is possible to bypass the smart card UART in order for the firmware to support non-T=0/T=1 smart cards.
This is called Bypass mode. In this mode the embedded firmware will communicate directly with the
selected smart card and drive I/O during transmit and read I/O during receive in order to communicate with
the smart card. In this mode, ATR processing is under firmware control. The firmware must sequence the
interface signals as required. Firmware must perform TS processing, parity checking, break generation and
CRC/LRC calculation (if required).
1.7.15.5 Synchronous Operation Mode
The 73S1215F supports synchronous operation. When sync mode is selected for either interface, the CLK
signal is generated by the ETU counter. The values in FDReg, SCCLK, and SCECLK must be set to obtain
the desired sync CLK rate. There is only one ETU counter and therefore, in sync mode, the interface must
be selected to obtain a smart card clock signal. In sync mode, input data is sampled on the rise of CLK,
and output data is changed on the fall of CLK.
82
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Special Notes Regarding Synchronous Mode Operation
When the SCISYN or SCESNC bits (SPrtcol, bit 7, bit 5, respectively) are set, the selected smart card
interface operates in synchronous mode and there are changes in the definition and behavior of pertinent
register bits and associated circuitry. The following requirements are to be noted:
1. The source for the smart card clock (CLK or SCLK) is the ETU counter. Only the actively selected
interface can have a running synchronous clock. In contrast, an unselected interface may have a
running clock in the asynchronous mode of operation.
2. The control bits CLKLVL, SCLKLVL, CLKOFF, and SCLKOFF are functional in synchronous mode.
When the CLKOFF bit is set, it will not truncate either the logic low or logic high period when the (stop
at) level is of opposite polarity. The CLK/SCLK signal will complete a correct logic low or logic high
duty cycle before stopping at the selected level. The CLK “start” is a result of the falling edge of the
CLKOFF bit. Setting clock to run when it is stopped low will result in a half period of low before going
high. Setting clock to run when it is stopped high will result in the clock going low immediately and
then running at the selected rate with 50% duty cycle (within the limitations of the ETU divisor value).
3. The Rlen(7:0) is configured to count the falling edges of the ETU clock (CLK or SCLK) after it has
been loaded with a value from 1 to 255. A value of 0 disables the counting function and RLen
functions such as I/O source selection (I/O signal bypasses the FIFOs and is controlled by the
SCCLK/SCECLK SFRs). When the RLen counter reaches the “max” (loaded) value, it sets the
WAITTO interrupt (SEInt, bit 7)), which is maskable via WTOIEN (SCIE, bit 7). It must be reloaded in
order to start the counting/clocking process again. This allows the processor to select the number of
CLK cycles and hence, the number of bits to be read or written to/from the card.
4. The FIFO is not clocked by the first CLK (falling) edge resulting from a CLKOFF de-assertion (a clock
start event) when the CLK was stopped in the high state and RLen has been loaded but not yet
clocked.
5. The state of the pin IO or SIO is sampled on the rising edge of CLK/SCLK and stored in bit 5 of the
SCCtl/SCECtl register.
6. When Rlen = max or 0 and I2CMODE = 1 (STXCtl, b7), the IO or SIO signal is directly controlled by
the data and direction bits in the respective SCCtl and SCECtl register. The state of the data in the
TX FIFO is bypassed.
7. In the SPrtcol register, bit 6 (MODE9/8B) becomes active. When set, the RXData FIFO will read
nine-bit words with the state of the ninth bit being readable in SRXCtl, bit 7 (B9DAT). The RXDAV
interrupt will occur when the ninth bit has been clocked in (rising edge of CLK or SCLK).
8. Care must be taken to clear the RX and TX FIFOs at the start of any transaction. The user shall read
the RX FIFO until it indicates empty status. Reading the TX FIFO twice will reset the input byte
pointer and the next write to the TX FIFO will load the byte to the “first out” position. Note that the bit
pointer (serializer/deserializer) is reset to bit 0 on any change of the TX/RXD bit.
Special bits that are only active for sync mode include: SRXCTL, b7 “BIT9DAT”, SPrtcol b6 “MODE9/8B”,
STXCtl, b7 “I2CMODE”, and the definition of SCInt b7, was “WAITTO”, becomes RLenINT interrupt, and
SCIE b7, was “WTOIEN”, becomes RLenIEN.
Rev. 1.4
83
73S1215F Data Sheet
DS_1215F_003
VCCSEL
bits
VCC
VCCOK
RSTCRD
RST
t3
CLK
IO
t4
t1
t2
tto
t1: The time from setting VCCSEL bits until VCCOK = 1.
tto: The time from setting VCCSEL bits until VCCTMR times out. At t1 (if RDYST = 1) or tto (if RDYST = 0),
activation starts. It is suggested to have RDYST = 0 and use the VCCTMR interrupt to let MPU know when
sequence is starting.
t2: time from start of activation (no external indication) until IO goes into reception mode (= 1). This is
approximately 4 SCCLK (or SCECLK) clock cycles.
t3: minimum one half of ETU period.
t4: ETU period.
Note that in Sync mode, IO as input is sampled on the rising edge of CLK. IO changes on the falling edge of CLK,
either from the card or from the 73S1215F. The RST signal to the card is directly controlled by the RSTCRD bit
(non-inverted) via the MPU and is shown as an example of a possible RST pattern.
Figure 21: Synchronous Activation
IO reception on
5
2
RST
CLK
CLKOFF
1
CLKLVL
RLength Count
RLenght = 1
7
Count MAX
3
Rlength Interrupt
4
6
TX/RXB Mode bit
(TX = '1')
t1
1. Clear CLKOFF after Card is in reception mode.
2. Set RST bit.
3. Interrupt is generated when Rlength counter is MAX.
4. Read and clear Interrupt.
5. Clear RST bit.
6. Toggle TX/RXB to reset bit counter.
7. Reload RLength Counter.
t1. CLK wll start at least 1/2 ETU after CLKOFF is set low
when CLKLVL = 0
Figure 22: Example of Sync Mode Operation: Generating/Reading ATR Signals
84
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
START Bit
CLK
IO
Data from Card -end of ATR
RLength
Count MAX
RLength Count - was set for length of ATR
1
RLength Interrupt
Data from TX FIFO
6
RLen=0
5
Rlen=1
2
CLK Stop
3
CLK Stop Level
7
IO Bit
IODir Bit
6
TX/RX Mode Bit
TX = '1'
4
1. Interrupt generated when Rlength counter is MAX.
2. Read and clear Interrupt.
3. Set CLK Stop and CLK Stop level high in Interrupt routine.
4. Set TX/RX Bit to TX mode.
5. Reload Rlength Counter.
6. Set IO Bit low and IODir = Output. Since Rlen=(MAX or 0) and TX/RX =1, IO pin is controlled by IO bit.
7. Clear CLK Stop and CLK Stop level.
Note: Data in TX fifo should not be Empty here.
Synchronous Clock Start/Stop Mode style Start bit procedure. This procedure should be used to
generate the start bit insertion in Synchronous mode for Synchronous Clock Start/Stop Mode protocol.
Figure 23: Creation of Synchronous Clock Start/Stop Mode Start Bit in Sync Mode
STOP Bit
CLK
IO
I2CMode = 1: Data to/from Card
I2CMode = 0: Data from TX fifo
Min ½ ETU
RLength Count MAX
RLength Count
(Rlength = 9)
RLength Interrupt
I2CMode = 1:ACK Bit (to/from card)
I2CMode = 0: Data from TX fifo
1
6
2
CLK Stop
CLK Stop Level
7
3
4
IO Bit
IODir Bit
TX/RX Mode Bit
TX = '1'
5
1. Interrupt generated when Rlength counter is MAX.
2. Read and clear Interrupt.
3. Set CLK Stop and CLK Stop level high, set IO Bit low and IODir = Output.
4. Set IO Bit High and IODir = Output.
5. Set TX/RX Bit to RX mode.
6. Reload Rlength Counter.
7. Clear CLK Stop and CLK Stop level.
Synchronous Clock Start/Stop Mode Stop bit procedure. This procedure should be used to
generate the Stop bit in Synchronous Mode.
Figure 24: Creation of Synchronous Clock Start/Stop Mode Stop Bit in Sync Mode
Rev. 1.4
85
73S1215F Data Sheet
DS_1215F_003
CLK
IO
RLength Count
RLength = 9
Data from Card
(Bit 8)
Protection Bit
(Bit 9)
RLength Count MAX
Rlen=9
Rlen=8
Data from Card
(Bit 1)
Rlen=0
Rlen =1
RLength Interrupt
RX FIFO
(Data from Card is ready for CPU read)
RX data
Protection Bit Data
(Bit 9)
Protection Bit is ready for CPU read
TX/RX Mode Bit
TX = '1'
1._ Interrupt generated
when Rlength counter is
Max
2._ Read and clear
Interrupt
3._ Reload RLength
counter
Receive data in 9 bit mode
CLK
RLength Count
RLength = 9
RLength Count MAX
Rlen=9
Rlen=8
RLength Interrupt
CLK Stop
CLK Stop Level = 0
1._ Interrupt generated
when Rlength counter is Max
2._Stop CLK after the last
byte and protection bit
Stop CLK after receiving the last byte and protection bit.
Figure 25: Operation of 9-bit Mode in Sync Mode
Synchronous card operation is broken down into three primary types. These are commonly referred to as
2-wire, 3-wire and I2C synchronous cards. Each card type requires different control and timing and
therefore requires different algorithms to access. Teridian has created an application note to provide
detailed algorithms for each card type. Refer to the 73S12xxF Synchronous Card Design Application
Note application note.
86
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Smart Card SFRs
Smart Card Select Register (SCSel): 0xFE00 Å 0x00
Table 80: The SCSel Register
MSB
–
LSB
–
–
–
SELSC.1
SELSC.0 BYPASS
–
The smart card select register is used to determine which smart card interface is using the ISO UART.
The internal Smart Card has integrated 7816-3 compliant sequencer circuitry to drive an external smart
card interface. The external smart card interface relies on 73S8010x parts to generate the ISO 7816-3
compatible signals and sequences. Multiple 73S8010x devices can be connected to the external smart
card interface.
Table 81: The SCSel Bit Functions
Bit
Symbol
SCSel.7
–
SCSel.6
–
SCSel.5
–
SCSel.4
–
SCSel.3
SELSC.1
Select Smart Card Interface – These bits select the interface that
is using the IS0 UART. These bits do not activate the interface.
Activation is performed by the VccCtl register.
SCSel.2
SELSC.0
00 = No smart card interface selected.
01 = External Smart Card Interface selected (using SCLK, SIO).
1X = Internal Smart Card Interface selected.
SCSel.1
BYPASS
1 = Enabled, 0 = Disabled. When enabled, ISO UART is
bypassed and the I/O line is controlled via the SCCtl and SCECtl
registers.
SCSel.0
–
Rev. 1.4
Function
87
73S1215F Data Sheet
DS_1215F_003
Smart Card Interrupt Register (SCInt): 0xFE01 Å 0x00
When the smart card interrupt is asserted, the firmware can read this register to determine the actual
cause of the interrupt. The bits are cleared when this register is read. Each interrupt can be disabled by
the Smart Card Interrupt Enable register. Error processing must be handled by the firmware. This
register relates to the interface that is active – see the SCSel register.
Table 82: The SCInt Register
MSB
LSB
WAITTO CRDEVT VCCTMRI
Bit
TXEVT
TXSENT
TXERR
RXERR
Symbol
Function
WAITTO
Wait Timeout – An ATR or card wait timeout has occurred. In sync
mode, this interrupt is asserted when the RLen counter (it advances on
falling edges of CLK/ETU) reaches the loaded (max) value. This bit is
cleared when the SCInt register is read. When running in Synchronous
Clock Stop Mode, this bit becomes RLenINT interrupt (set when the Rlen
counter reaches the terminal count).
SCInt.6
CRDEVT
Card Event – A card event is signaled via pin DETCARD either when the
Card was inserted or removed (read the CRDCtl register to determine
card presence) or there was a fault condition in the interface circuitry.
This bit is functional even if the smart card logic clock is disabled and
when the PWRDN bit is set. This bit is cleared when the SCInt register is
read.
SCInt.5
VCCTMRI
VCC Timer – This bit is set when the VCCTMR times out. This bit is
cleared when the SCInt register is read.
SCInt.7
SCInt.4
RXDAV
Rx Data Available – Data was received from the smart card because the
Rx FIFO is not empty. In bypass mode, this interrupt is generated on a
falling edge of the smart card I/O line. After receiving this interrupt in
bypass mode, firmware should disable it until the firmware has received
the entire byte and is waiting for the next start delimiter. This bit is
cleared when there is no RX data available in the RX FIFO.
SCInt.3
TXEVNT
TX Event – Set whenever the TXEMTY or TXFULL bits are set in the
SRXCtl SFR. This bit is cleared when the STXCtl register is read.
TXSENT
TX Sent – Set whenever the ISO UART has successfully transmitted a
byte to the smart card. Also set when a CRC/LRC byte is sent in T=1
mode. Will not be set in T=0 when a break is detected at the end of a
byte (when break detection is enabled). This bit is cleared when the
SCInt register is read.
TXERR
TX Error – An error was detected during the transmission of data to the
smart card as indicated by either BREAKD or TXUNDR bit being set in
the STXCtl SFR. Additional information can be found in that register
description. This bit is cleared when the STXCtl register is read.
RXERR
RX Error – An error was detected during the reception of data from the
smart card. Additional information can be found in the SRXCtl register.
This interrupt will be asserted for RXOVRR, or RX Parity error events.
This bit is cleared when the SRXCtl register is read.
SCInt.2
SCInt.1
SCInt.0
88
RXDAV
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Smart Card Interrupt Enable Register (SCIE): 0xFE02 Å 0x00
When set to a 1, the respective condition can cause a smart card interrupt. When set to a 0, the
respective condition cannot cause an interrupt. When disabled, the respective bit in the Smart Card
Interrupt register can still be set, but it will not interrupt the MPU.
Table 83: The SCIE Register
MSB
LSB
WTOIEN CDEVEN
VTMREN
RXDAEN
TXEVEN
TXSNTEN
TXEREN
RXEREN
Bit
Symbol
Function
SCIE.7
WTOIEN
Wait Timeout Interrupt Enable – Enable for ATR or Wait Timeout Interrupt.
In sync mode, function is RLIEN (RLen = max.) interrupt enable.
SCIE.6
CDEVEN
Card Event Interrupt Enable.
SCIE.5
VTMREN
VCC Timer Interrupt Enable.
SCIE.4
RXDAEN
Rx Data Available Interrupt Enable.
SCIE.3
TXEVEN
TX Event Interrupt Enable.
SCIE.2
TXSNTEN
TX Sent Interrupt Enable.
SCIE.1
TXEREN
TX Error Interrupt Enable.
SCIE.0
RXEREN
RX Error Interrupt Enable.
Rev. 1.4
89
73S1215F Data Sheet
DS_1215F_003
Smart Card VCC Control/Status Register (VccCtl): 0xFE03 Å 0x00
This register is used to control the power up and power down of the integrated smart card interface. It is
used to determine whether to apply 5V, 3V, or 1.8V to the smart card. Perform the voltage selection with
one write operation, setting both VCCSEL.1 and VCCSEL.0 bits simultaneously. The VDDFLT bit (if
enabled) will provide an emergency deactivation of the internal smart card slot. See the VDD Fault
Detect Function section for more detail.
Table 84: The VccCtl Register
MSB
LSB
VCCSEL.1 VCCSEL.0
Bit
Symbol
VccCtl.7
VCCSEL.1
VccCtl.6
VCCSEL.0
VDDFLT
RDYST
VCCOK
–
–
SCPWRDN
Function
Setting non-zero value for bits 7,6 will begin activation sequence with target
Vcc as given below:
State VCCSEL.1
VCCSEL.0
VCC
1
0
0
0V
2
0
1
1.8V
3
1
0
3.0V
4
1
1
5V
A card event or VCCOK going low will initiate a deactivation sequence.
When the deactivation sequence for RST, CLK and I/O is complete, VCC will
be turned off. When this type of deactivation occurs, the bits must be reset
before initiating another activation.
VccCtl.5
VDDFLT
If this bit is set = 0, the CMDVCC3B and CMDVCC5B outputs are
immediately set = 1 to signal to the companion circuit to begin deactivation
when there is a VDD Fault event. If this bit is set = 1 and there is a VDD
Fault, the firmware should perform a deactivation sequence and then set
CMDVCC3B or CMDVCC5B = 1 to signal the companion circuit to set
VCC = 0.
VccCtl.4
RDYST
If this bit is set = 1, the activation sequence will start when bit VCCOK is
set = 1. If not set, the deactivation sequence shall start when the VCCTMR
times out.
VccCtl.3
VCCOK
(Read only). Indicates that VCC output voltage is stable.
VccCtl.2
–
VccCtl.1
–
VccCtl.0
SCPWRDN
90
This bit controls the power down mode of the 73S1215F circuit.
1 = power down, 0 = normal operation.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
VCC Stable Timer Register (VccTmr): 0xFE04 Å 0x0F
A programmable timer is provided to set the time from activation start (setting the VCCSEL.1 and
VCCSEL.0 bits to non-zero) to when VCC_OK is evaluated. VCC_OK must be true at the end of this
timers programmed interval (tto in Figure 17) in order for the activation sequence to continue. If VCC_OK
is not true and the end of the interval (tto), the Card Event interrupt will be set, and a deactivation
sequence shall begin including clearing of the VCCSEL bits.
Table 85: The VccTmr Register
MSB
LSB
OFFTMR.3 OFFTMR.2 OFFTMR.1 OFFTMR.0 VCCTMR.3 VCCTMR.2 VCCTMR.1 VCCTMR.0
Bit
Symbol
Function
VccTmr.7
OFFTMR.3
VccTmr.6
OFFTMR.2
VccTmr.5
OFFTMR.1
VccTmr.4
OFFTMR.0
VCC Off Timer – The bits set the delay (in number of ETUs) for
deactivation after the VCCSEL.1 and VCC SEL.0 have been set
to 0. The time value is a count of the 32768Hz clock and is given
by tto = OFFTMR(7:4) * 30.5μs. This delay does not affect
emergency deactivations due to VDD Fault or card events. A
value of 0000 results in no additional delay.
VccTmr.3
VCCTMR.3 VCC Timer – VCCOK must be true at the time set by the value in
VCCTMR.2 these bits in order for the activation sequence to continue. If not,
the VCCSEL bits will be cleared. The time value is a count of the
VCCTMR.1 32768Hz clock and is given by tto = VCCTMR(3:0) * 30.5μs. A
value of 0000 results in no timeout, not zero time, and activation
VCCTMR.0 requires that RDYST is set and RDY goes high.
VccTmr.2
VccTmr.1
VccTmr.0
Rev. 1.4
91
73S1215F Data Sheet
DS_1215F_003
Card Status/Control Register (CRDCtl): 0xFE05 Å 0x00
This register is used to configure the card detect pin (DETCARD) and monitor card detect status. This
register be written to properly configure Debounce, Detect_Polarity (= 0 or = 1), and the pull-up/down
enable before setting CDETEN. The card detect logic is functional even without smart card logic clock.
When the PWRDN bit is set = 1, no debounce is provided but card presence is operable.
MSB
LSB
DEBOUN CDETEN
Bit
–
DETPOL
PUENB
PDEN
CARDIN
Function
CRDCtl.7
DEBOUN
Debounce – When set = 1, this will enable hardware de-bounce
of the card detect pin. The de-bounce function shall wait for
64ms of stable card detect assertion before setting the CARDIN
bit. This counter/timer uses the keypad clock as a source of
1kHz signal. De-assertion of the CARDIN bit is immediate upon
de-assertion of the card detect pin(s).
CRDCtl.6
CDETEN
Card Detect Enable – When set = 1, activates card detection
input. Default upon power-on reset is 0.
CRDCtl.5
–
CRDCtl.4
–
CRDCtl.3
DETPOL
Detect Polarity – When set = 1, the DETCARD pin shall interpret
a logic 1 as card present.
CRDCtl.2
PUENB
Enable pull-up current on DETCARD pin (active low).
CRDCtl.1
PDEN
CRDCtl.0
92
Symbol
–
CARDIN
Enable pull-down current on DETCARD pin.
Card Inserted – (Read only). 1 = card inserted, 0 = card not
inserted. A change in the value of this bit is a “card event.” A
read of this bit indicates whether smart card is inserted or not
inserted in conjunction with the DETPOL setting.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
TX Control/Status Register (STXCtl): 0xFE06 Å 0x00
This register is used to control transmission of data to the smart card. Some control and some status bits
are in this register.
Table 86: The STXCtl Register
MSB
LSB
I2CMODE
Bit
STXCtl.7
–
Symbol
TXFULL
TXEMTY TXUNDR LASTTX
TX/RXB
BREAKD
Function
I2C Mode – When in sync mode and this bit is set, and when the RLen count
value = max or 0, the source of the smart card data for IO pin (or SIO pin) will
I2CMODE
be connected to the IO bit in SCCtl (or SCECtl) register rather than the TX
FIFO. See the description for the Protocol Mode Register for more detail.
STXCtl.6
–
STXCtl.5
TXFULL
TX FIFO is full. Additional writes may corrupt the contents of the FIFO. This
bit it will remain set as long as the TX FIFO is full. Generates TX_Event
interrupt upon going full.
TXEMTY
1 = TX FIFO is empty, 0 = TX FIFO is not empty. If there is data in the TX
FIFO, the circuit will transmit it to the smart card if in transmit mode. In T=1
mode, if the LASTTX bit is set and the hardware is configured to transmit the
CRC/LRC, the TXEMTY will not be set until the CRC/LRC is transmitted. In
T=0, if the LASTTX bit is set, TXEMTY will be set after the last word has
been successfully transmitted to the smart card. Generates TXEVNT
interrupt upon going empty.
TXUNDR
TX Underrrun – (Read only) Asserted when a transmit under-run condition
has occurred. An under-run condition is defined as an empty TX FIFO when
the last data word has been successfully transmitted to the smart card and
the LASTTX bit was not set. No special processing is performed by the
hardware if this condition occurs. Cleared when read by firmware. This bit
generates TXERR interrupt.
LASTTX
Last TX Byte – Set by firmware (in both T=0 and T=1) when the last byte in
the current message has been written into the transmit FIFO. In T=1 mode,
the CRC/LRC will be appended to the message. Should be set after the last
byte has been written into the transmit FIFO. Should be cleared by firmware
before writing first byte of next message into the transmit FIFO. Used in T=0
to determine when to set TXEMTY.
STXCtl.1
TX/RXB
1 = Transmit mode, 0 = Receive mode. Configures the hardware to be
receiving from or transmitting to the smart card. Determines which counters
should be enabled. This bit should be set to receive mode prior to switching
to another interface. Setting and resetting this bit shall initialize the CRC
logic. If LASTTX is set, this bit can be reset to RX mode and UART logic will
automatically change mode to RX when TX operation is completed
(TX_Empty =1).
STXCtl.0
BREAKD
Break Detected – (Read only) 1 = A break has been detected on the I/O line
indicating that the smart card detected a parity error. Cleared when read.
This bit generates TXERR interrupt.
STXCtl.4
STXCtl.3
STXCtl.2
Rev. 1.4
93
73S1215F Data Sheet
DS_1215F_003
STX Data Register (STXData): 0xFE07 Å 0x00
Table 87: The STXData Register
MSB
LSB
STXDAT.7
STXDAT.6
STXDAT.5
STXDAT.4
Bit
STXDAT.3
STXDAT.2
STXDAT.1
STXDAT.0
Function
STXData.7
STXData.6
STXData.5
STXData.4
STXData.3
STXData.2
Data to be transmitted to smart card. Gets stored in the TX FIFO and then extracted by
the hardware and sent to the selected smart card. When the MPU reads this register,
the byte pointer is changed to effectively “read out” the data. Thus, two reads will
always result in an “empty” FIFO condition. The contents of the FIFO registers are not
cleared, but will be overwritten by writes.
STXData.1
STXData.0
SRX Control/Status Register (SRXCtl): 0xFE08 Å 0x00
This register is used to monitor reception of data from the smart card.
Table 88: The SRXCtl Register
MSB
LSB
BIT9DAT
–
LASTRX
CRCERR
RXFULL
RXEMTY
RXOVRR PARITYE
Bit
Symbol
Function
SRXCtl.7
BIT9DAT
Bit 9 Data – When in sync mode and with MODE9/8B set, this bit will contain
the data on IO (or SIO) pin that was sampled on the ninth CLK (or SCLK) rising
edge. This is used to read data in synchronous 9-bit formats.
SRXCtl.6
–
SRXCtl.5
LASTRX
Last RX Byte – User sets this bit during the reception of the last byte. When
byte is received and this bit is set, logic checks CRC to match 0x1D0F (T=1
mode) or LRC to match 00h (T=1 mode), otherwise a CRC or LRC error is
asserted.
SRXCtl.4
CRCERR
(Read only) 1 = CRC (or LRC) error has been detected.
SRXCtl.3
RXFULL
(Read only) RX FIFO is full. Status bit to indicate RX FIFO is full.
SRXCtl.2
RXEMTY
(Read only) RX FIFO is empty. This is only a status bit and does not generate
a RX interrupt.
SRXCtl.1
RXOVRR
RX Overrun – (Read Only) Asserted when a receive-over-run condition has
occurred. An over-run is defined as a byte was received from the smart card
when the RX FIFO was full. Invalid data may be in the receive FIFO. Firmware
should take appropriate action. Cleared when read. Additional writes to the
RX FIFO are discarded when a RXOVRR occurs until the overrun condition is
cleared. Will generate RXERR interrupt.
SRXCtl.0
PARITYE
Parity Error – (Read only) 1 = The logic detected a parity error on incoming
data from the smart card. Cleared when read. Will generate RXERR interrupt.
94
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
SRX Data Register (SRXData): 0xFE09 Å 0x00
Table 89: The SRXData Register
MSB
LSB
SRXDAT.7 SRXDAT.6 SRXDAT.5 SRXDAT.4 SRXDAT.3 SRXDAT.2 SRXDAT.1 SRXDAT.0
Bit
Function
SRXData.7
SRXData.6
SRXData.5
SRXData.4
SRXData.3
(Read only) Data received from the smart card. Data received from the smart card
gets stored in a FIFO that is read by the firmware.
SRXData.2
SRXData.1
SRXData.0
Rev. 1.4
95
73S1215F Data Sheet
DS_1215F_003
Smart Card Control Register (SCCtl): 0xFE0A Å 0x21
This register is used to monitor reception of data from the smart card.
Table 90: The SCCtl Register
MSB
LSB
RSTCRD
Bit
IO
IOD
C8
C4
CLKLVL
CLKOFF
Symbol
Function
SCCtl.7
RSTCRD
1 = Asserts the RST (set RST = 0) to the smart card interface, 0 = Deassert the RST (set RST = 1) to the smart card interface. Can be used to
extend RST to the smart card. Refer to the RLength register description.
This bit is operational in all modes and can be used to extend RST during
activation or perform a “Warm Reset” as required. In auto-sequence
mode, this bit should be set = 0 to allow the sequencer to de-assert RST
per the RLength parameters.
In sync mode (see the SPrtcol register) the sense of this bit is noninverted, if set =1 , RST = 1, if set = 0, RST = 0. Rlen has no effect on
Reset in sync mode.
SCCtl.6
–
SCCtl.5
IO
Smart Card I/O. Read is state of I/O signal (Caution, this signal is not
synchronized to the MPU clock). In Bypass mode, write value is state of
signal on I/O. In sync mode, this bit will contain the value of I/O pin on
the latest rising edge of CLK.
SCCtl.4
IOD
Smart Card I/O Direction control Bypass mode or sync mode. 1 = input
(default), 0 = output.
C8
Smart Card C8. When C8 is an output, the value written to this bit will
appear on the C8 line. The value read when C8 is an output is the value
stored in the register. When C8 is an input, the value read is the value
on the C8 pin (Caution, this signal is not synchronized to the MPU clock).
When C8 is an input, the value written will be stored in the register but
not presented to the C8 pin.
SCCtl.2
C4
Smart Card C4. When C4 is an output, the value written to this bit will
appear on the C4 line. The value read when C4 is an output is the value
stored in the register. When C4 is an input, the value read is the value
on the C4 pin (Caution, this signal is not synchronized to the MPU clock).
When C4 is an input, the value written will be stored in the register but
not presented to the C4 pin.
SCCtl.1
CLKLVL
1 = High, 0 = Low. If CLKOFF is set = 1, the CLK to smart card will be at
the logic level indicated by this bit. If in bypass mode, this bit directly
controls the state of CLK.
SCCtl.0
CLKOFF
0 = CLK is enabled. 1 = CLK is not enabled. When asserted, the CLK
will stop at the level selected by CLKLVL. This bit has no effect if in
bypass mode.
SCCtl.3
96
–
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
External Smart Card Control Register (SCECtl): 0xFE0B Å 0x00
Used to directly set and sample signals of External Smart Card interface. There are three modes of
asynchronous operation, an “automatic sequence” mode, and bypass mode. Clock stop per the ISO
7816-3 interface is also supported but firmware must handle the protocol for SIO and SCLK for I2C clock
stop and start. Control for Reset (to make RST signal), activation control, voltage select, etc. should be
handled via the I2C interface when using external 73S73S8010x devices. USR(n) pins shall be used for
C4, C8 functions if necessary.
Table 91: The SCECtl Register
MSB
LSB
–
–
SIO
Bit
Symbol
SCECtl.7
–
SCECtl.6
–
SIOD
–
–
SCLKLVL SCLKOFF
Function
SCECtl.5
SIO
External Smart Card I/O. Bit when read indicates state of pin SIO for
SIOD = 1 (Caution, this signal is not synchronized to the MPU clock), when
written, sets state of pin SIO for SIOD = 0. Ignored if not in bypass or sync
modes. In sync mode, this bit will contain the value of IO pin on the latest
rising edge of SCLK.
SCECtl.4
SIOD
1 = input, 0 = output. External Smart Card I/O Direction control. Ignored if
not in bypass or sync modes.
SCECtl.3
–
SCECtl.2
–
SCECtl.1
SCLKLVL
Sets the state of SCLK when disabled by SCLKOFF bit. If in bypass mode,
this bit directly controls the state of SCLK.
SCECtl.0
SCLKOFF
0 = SCLK enabled, 1 = SCLK disabled. When disabled, SCLK level is
determined by SCLKLVL. This bit has no effect if in bypass mode.
Rev. 1.4
97
73S1215F Data Sheet
DS_1215F_003
C4/C8 Data Direction Register (SCDIR): 0xFE0C Å 0x00
This register determines the direction of the internal interface C4/C8 lines. After reset, all signals are
tri-stated.
Table 92: The SCDIR Register
MSB
LSB
–
–
–
–
C8D
C4D
Bit
Symbol
SCDIR.7
–
SCDIR.6
–
SCDIR.5
–
SCDIR.4
–
SCDIR.3
C8D
1 = input, 0 = output. Smart Card C8 direction.
SCDIR.2
C4D
1 = input, 0 = output. Smart Card C4 direction.
SCDIR.1
–
SCDIR.0
–
98
–
–
Function
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Protocol Mode Register (SPrtcol): 0xFE0D Å 0x03
This register determines the protocol to be use when communicating with the selected smart card. This
register should be updated as required when switching between smart card interfaces.
Table 93: The SPrtcol Register
MSB
LSB
SCISYN
Bit
SPrtcol.7
MOD9/8B SCESYN
0
TMODE
CRCEN
CRCMS
RCVATR
Symbol
Function
SCISYN
Smart Card Internal Synchronous mode – Configures internal smart card
interface for synchronous mode. This mode routes the internal interface
buffers for RST, IO, C4, C8 to SCCtl register bits for direct firmware control.
CLK is generated by the ETU counter.
MOD9/8B
Synchronous 8/9 bit mode select – For sync mode, in protocols with 9-bit
words, set this bit. The first eight bits read go into the RX FIFO and the
ninth bit read will be stored in the IO (or SIO) data bit of the SRXCtl
register.
SPrtcol.5
SCESYN
Smart Card External Synchronous mode – Configures External Smart Card
interface for synchronous mode. This mode routes the external smart card
interface buffers for SIO to SCECtl register bits for direct firmware control.
SCLK is generated by the ETU counter.
SPrtcol.4
0
SPrtcol.3
TMODE
Protocol mode select – 0: T=0, 1: T=1. Determines which smart card
protocol is to be used during message processing.
SPrtcol.2
CRCEN
CRC Enable – 1 = Enabled, 0 = Disabled. Enables the
checking/generation of CRC/LRC while in T=1 mode. Has no effect in T=0
mode. If enabled and a message is being transmitted to the smart card,
the CRC/LRC will be inserted into the message stream after the last TX
byte is transmitted to the smart card. If enabled, CRC/LRC will be checked
on incoming messages and the value made available to the firmware via
the CRC LS/MS registers.
SPrtcol.1
CRCMS
CRC Mode Select - 1 = CRC, 0 = LRC. Determines type of checking
algorithm to be used.
SPrtcol.0
RCVATR
Receive ATR – 1 = Enable ATR timeout, 0 = Disable ATR timeout. Set by
firmware after the smart card has been turned on and the hardware is
expecting ATR.
SPrtcol.6
Rev. 1.4
Reserved bit, must always be set to 0.
99
73S1215F Data Sheet
DS_1215F_003
SC Clock Configuration Register (SCCLK): 0xFE0F Å 0x0C
This register controls the internal smart card (CLK) clock generation.
Table 94: The SCCLK Register
MSB
LSB
–
–
ICLKFS.5 ICLKFS.4 ICLKFS.3 ICLKFS.2 ICLKFS.1 ICLKFS.0
Bit
Symbol
Function
SCCLK.7
–
SCCLK.6
–
SCCLK.5
ICLKFS.5
SCCLK.4
ICLKFS.4
SCCLK.3
ICLKFS.3
SCCLK.2
ICLKFS.2
SCCLK.1
ICLKFS.1
SCCLK.0
ICLKFS.0
Internal Smart Card CLK Frequency Select – Division factor to determine
internal smart card CLK frequency. MCLK clock is divided by (register
value + 1) to clock the ETU divider, and then by 2 to generate CLK. Default
ratio is 13. The programmed value in this register is applied to the divider
after this value is written, in such a manner as to produce a glitch-free
output, regardless of the selection of active interface. A register value = 0
will default to the same effect as register value = 1.
External SC Clock Configuration Register (SCECLK): 0xFE10 Å 0x0C
This register controls the external smart card (SCLK) clock generation.
Table 95: The SCECLK Register
MSB
LSB
–
–
Bit
Symbol
SCECLK.7
–
SCECLK.6
–
SCECLK.5
ECLKFS.5
SCECLK.4
ECLKFS.4
SCECLK.3
ECLKFS.3
SCECLK.2
ECLKFS.2
SCECLK.1
ECLKFS.1
SCECLK.0
ECLKFS.0
100
ECLKFS.5
ECLKFS.4
ECLKFS.3
ECLKFS.2
ECLKFS.1
ECLKFS.0
Function
External Smart Card CLK Frequency Select – Division factor to determine
external smart card CLK frequency. MCLK clock is divided by (register
value + 1) to clock the ETU divider, and then by 2 to generate SCLK.
Default ratio is 13. The programmed value in this register is applied to the
divider after this value is written, in such a manner as to produce a glitchfree output, regardless of the selection of active interface. A register value
= 0 will default to the same effect as register value = 1.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Parity Control Register (SParCtl): 0xFE11 Å 0x00
This register provides the ability to configure the parity circuitry on the smart card interface. The settings
apply to both integrated smart card interfaces.
Table 96: The SParCtl Register
MSB
–
LSB
DISPAR BRKGEN BRKDET RETRAN
DISCRX
INSPE
FORCPE
Bit
Symbol
SParCtl.7
–
SParCtl.6
DISPAR
Disable Parity Check – 1 = disabled, 0 = enabled. If enabled, the UART
will check for even parity (the number of 1’s including the parity bit is even)
on every character. This also applies to the TS during ATR.
SParCtl.5
BRKGEN
Break Generation Disable – 1 = disabled, 0 = enabled. If enabled, and T=0
protocol, the UART will generate a Break to the smart card if a parity error
is detected on a receive character. No Break will be generated if parity
checking is disabled. This also applies to TS during ATR.
SParCtl.4
BRKDET
Break Detection Disable – 1 = disabled, 0 = enabled. If enabled, and T=0
protocol, the UART will detect the generation of a Break by the smart card.
SParCtl.3
RETRAN
Retransmit Byte – 1 = enabled, 0 = disabled. If enabled and a Break is
detected from the smart card (Break Detection must be enabled), the last
character will be transmitted again. This bit applies to T=0 protocol.
SParCtl.2
DISCRX
Discard Received Byte – 1 = enabled, 0 = disabled. If enabled and a parity
error is detected (Parity checking must be enabled), the last character
received will be discarded. This bit applies to T=0 protocol.
SParCtl.1
INSPE
SParCtl.0
FORCPE
Rev. 1.4
Function
Insert Parity Error – 1 = enabled, 0 = disabled. Used for test purposes. If
enabled, the UART will insert a parity error in every character transmitted
by generating odd parity instead of even parity for the character.
Force Parity Error – 1 = enabled, 0 = disabled. Used for test purposes. If
enabled, the UART will generate a parity error on a character received from
the smart card.
101
73S1215F Data Sheet
DS_1215F_003
Byte Control Register (SByteCtl): 0xFE12 Å 0x2C
This register controls the processing of characters and the detection of the TS byte. When receiving, a
Break is asserted at 10.5 ETU after the beginning of the start bit. Break from the card is sampled at 11
ETU.
Table 97: The SByteCtl Register
MSB
–
LSB
DETTS
DIRTS
BRKDUR.1
BRKDUR.0
–
–
–
Table 98: The SByteCtl Bit Functions
Bit
Symbol
SByteCtl.7
–
Function
DETTS
Detect TS Byte – 1 = Next Byte is TS, 0 = Next byte is not TS. When
set, the hardware will treat the next character received as the TS and
determine if direct or indirect convention is being used. Direct
convention is the default used if firmware does not set this bit prior to
transmission of TS by the smart card to the firmware. The hardware will
check parity and generate a break as defined by the DISPAR and
BRKGEN bits in the parity control register. This bit is cleared by
hardware after TS is received. TS is decoded before being stored in
the receive FIFO.
SByteCtl.5
DIRTS
Direct Mode TS Select – 1 = direct mode, 0 = indirect mode.
Set/cleared by hardware when TS is processed indicating either
direct/indirect mode of operation. When switching between smart
cards, the firmware should write the bit appropriately since this register
is not unique to an individual smart card (firmware should keep track of
this bit).
SByteCtl.4
BRKDUR.1
SByteCtl.3
BRKDUR.0
SByteCtl.2
–
SByteCtl.1
–
SByteCtl.0
–
SByteCtl.6
102
Break Duration Select – 00 = 1 ETU, 01 = 1.5 ETU, 10 = 2 ETU, 11 =
reserved. Determines the length of a Break signal which is generated
when detecting a parity error on a character reception in T=0 mode.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
FD Control Register (FDReg): 0xFE13 Å 0x11
This register uses the transmission factors F and D to set the ETU (baud) rate. The values in this register
are mapped to the ISO 7816 conversion factors as described below. The CLK signal for each interface is
created by dividing a high-frequency, intermediate signal (MSCLK) by 2. The ETU baud rate is created
by dividing MSCLK by 2 times the Fi/Di ratio specified by the codes below. For example, if FI = 0001 and
DI = 0001, the ratio of Fi/Di is 372/1. Thus the ETU divider is configured to divide by 2 * 372 = 744. The
maximum supported F/D ratio is 4096.
Table 99: The FDReg Register
MSB
LSB
FVAL.3
FVAL.2
FVAL.1
FVAL.0
DVAL.3
DVAL.2
DVAL.1
DVAL.0
Table 100: Divider Ratios Provided by the ETU Counter
FI (code)
0000
0001
0010
0011
0100
0101
0110
0111
Fi (ratio)
372
372
558
744
1116
1488
1860
1860⊕
FCLK max
4
5
6
8
12
16
20
20⊕
FI(code)
1000
1001
1010
1011
1100
1101
1110
1111
Fi(ratio)
512⊕
512
768
1024
1536
2048
2048⊕
2048⊕
FCLK max
5⊕
5
7.5
10
15
20
20⊕
20⊕
DI(code)
0000
0001
0010
0011
0100
0101
0110
0111
Di(ratio)
1⊕
1
2
4
8
16
32
32⊕
DI(code)
1000
1001
1010
1011
1100
1101
1110
1111
Di(ratio)
12
20
16⊕
16⊕
16⊕
16⊕
16⊕
16⊕
Note: values marked with ⊕ are not included in the ISO definition and arbitrary values have been
assigned.
The values given below are used by the ETU divider to create the ETU clock. The entries that are not
shaded will result in precise CLK/ETU per ISO requirements. Shaded areas are not precise but are
within 1% of the target value.
Rev. 1.4
103
73S1215F Data Sheet
DS_1215F_003
Table 101: Divider Values for the ETU Clock
Di
code
Fi code
F→
D↓
0000
372
0001
372
0010
558
0011
744
0100
1116
0101
1488
0001
0010
0011
0100
1000
0101
1001
0110
1
2
4
8
12
16
20
32
744
372
186
93
62
47
37
23
744
372
186
93
62
47
37
23
1116
558
279
138
93
70
56
35
1488
744
372
186
124
93
74
47
2232
1116
558
279
186
140
112
70
2976
1488
744
372
248
186
149
93
Di
code
Fi code
F→
D↓
0110
1860
1001
512
1010
768
1011
1024
1100
1536
1101
2048
0001
0010
0011
0100
1000
0101
1001
0110
1
2
4
8
12
16
20
32
3720
1860
930
465
310
233
186
116
1024
512
256
128
85
64
51
32
1536
768
384
192
128
96
77
48
2048
1024
512
256
171
128
102
64
3072
1536
768
384
256
192
154
96
4096
2048
1024
512
341
256
205
128
Table 102: The FDReg Bit Functions
Bit
Symbol
FDReg.7
FVAL.3
FDReg.6
FVAL.2
FDReg.5
FVAL.1
FDReg.4
FVAL.0
FDReg.3
DVAL.3
FDReg.2
DVAL.2
FDReg.1
DVAL.1
FDReg.0
DVAL.0
104
Function
Refer to Table 101 above. This value is converted per the table to set the
divide ratio used to generate the baud rate (ETU). Default, also used for
ATR, is 0001 (Fi = 372). This value is used by the selected interface.
Refer to Table 101 above. This value is used to set the divide ratio used to
generate the smart card CLK. Default, also used for ATR, is 0001 (Di = 1).
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
CRC MS Value Registers (CRCMsB): 0xFE14 Å 0xFF, (CRCLsB): 0xFE15 Å 0xFF
Table 103: The CRCMsB Register
MSB
CRC.15
LSB
CRC.14
CRC.13
CRC.12
CRC.11
CRC.10
CRC.9
CRC.8
Table 104: The CRCLsB Register
MSB
CRC.7
LSB
CRC.6
CRC.5
CRC.4
CRC.3
CRC.2
CRC.1
CRC.0
The 16-bit CRC value forms the TX CRC word in TX mode (write value) and the RX CRC in RX mode
(read value). The initial value of CRC to be used when generating a CRC to be transmitted at the end of
a message (after the last TX byte is sent) when enabled in T=1 mode. Should be reloaded at the
beginning of every message to be transmitted. When using CRC, the both CRC registers should be
initialized to FF. When using LRC the CRCLsB Value register should be loaded to 00. When receiving a
message, the firmware should load this with the initial value and then read this register to get the final
value at the end of the message. These registers need to be reloaded for each new message to be
received. When in LRC mode, bits (7:0) are used and bits (15:8) are undefined. During LRC/CRC
checking and generation, this register is updated with the current value and can be read to aid in
debugging. This information will be transmitted to the smart card using the timing specified by the Guard
Time register. When checking CRC/LRC on an incoming message (CRC/LRC is checked against the
data and CRC/LRC), the firmware reads the final value after the message has been received and
determines if an error occurred (= 0x1D0F (CRC_ no error, else error; = 0 (LRC) no error, else error).
When a message is received, the CRC/LRC is stored in the FIFO. The polynomial used to generate and
16
12
5
check CRC is x + x + x +1. When in indirect convention, the CRC is generated prior to the conversion
into indirect convention. When in indirect convention, the CRC is checked after the conversion out of
indirect convention. For a given message, the CRC generated (and readable from this register) will be
the same whether indirect or direct convention is used to transmit the data to the smart card. The
CRCLsB / CRCMsB registers will be updated with CRC/LRC whenever bits are being received or
transmitted from/to the smart card (even if CRCEN is not set and in mode T1). They are available to the
firmware to use if desired.
Rev. 1.4
105
73S1215F Data Sheet
DS_1215F_003
Block Guard Time Register (BGT): 0xFE16 Å 0x10
This register contains the Extra Guard Time Value (EGT) most-significant bit. The Extra Guard Time
indicates the minimum time between the leading edges of the start bit of consecutive characters. The
delay is depends on the T=0/T=1 mode. Used in transmit mode. This register also contains the Block
Guard Time (BGT) value. Block Guard Time is the minimum time between the leading edge of the start
bit of the last character received and the leading edge of the start bit of the first character transmitted.
This should not be set less than the character length. The transmission of the first character will be held
off until BGT has elapsed regardless of the TX data and TX/RX control bit timing.
Table 105: The BGT Register
MSB
LSB
EGT.8
–
Bit
Symbol
BGT.7
EGT.8
BGT.6
–
BGT.5
–
BGT.4
BGT.4
BGT.3
BGT.3
BGT.2
BGT.2
BGT.1
BGT.1
BGT.0
BGT.0
–
BGT.4
BGT.3
BGT.1
BGT.2
BGT.0
Function
Most-significant bit for 9-bit EGT timer. See EGT below.
Time in ETUs between the start bit of the last received character to start bit
of the first character transmitted to the smart card. Default value is 22.
Extra Guard Time Register (EGT): 0xFE17 Å 0x0C
This register contains the Extra Guard Time Value (EGT) least-significant byte. The Extra Guard Time
indicates the minimum time between the leading edges of the start bit of consecutive characters. The
delay is depends on the T=0/T=1 mode. Used in transmit mode.
Table 106: The EGT Register
MSB
EGT.7
Bit
LSB
EGT.6
EGT.5
EGT.4
EGT.3
EGT.1
EGT.2
EGT.0
Function
EGT.7
EGT.6
EGT.5
EGT.4
EGT.3
EGT.2
Time in ETUs between start bits of consecutive characters. In T=0 mode, the minimum is
1. In T=0, the leading edge of the next start bit may be delayed if there is a break detected
from the smart card. Default value is 12. In T=0 mode, regardless of the value loaded, the
minimum value is 12, and for T=1 mode, the minimum value is 11.
EGT.1
EGT.0
106
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Block Wait Time Registers (BWTB0): 0xFE1B Å 0x00, (BWTB1): 0xFE1A Å 0x00, (BWTB2):
0xFE19 Å 0x00, (BWTB3): 0xFE18 Å 0x00
Table 107: The BWTB0 Register
MSB
LSB
BWT.7
BWT.6
BWT.5
BWT.4
BWT.3
BWT.1
BWT.2
BWT.0
Table 108: The BWTB1 Register
MSB
LSB
BWT.15
BWT.14
BWT.13
BWT.12
BWT.11
BWT.10
BWT.9
BWT.8
Table 109: The BWTB2 Register
MSB
LSB
BWT.23
BWT.22
BWT.21
BWT.20
BWT.19
BWT.18
BWT.17
BWT.16
Table 110: The BWTB3 Register
MSB
LSB
–
–
–
–
BWT.27
BWT.26
BWT.25
BWT.24
These registers (BWTB0, BWTB1, BWTB2, BWTB3) are used to set the Block Waiting Time(27:0)
(BWT). All of these parameters define the maximum time the 73S1215F will have to wait for a character
from the smart card. These registers serve a dual purpose. When T=1, these registers are used to set
up the block wait time. The block wait time defines the time in ETUs between the beginning of the last
character sent to smart card and the start bit of the first character received from smart card. It can be
used to detect an unresponsive card and should be loaded by firmware prior to writing the last TX byte.
When T = 0, these registers are used to set up the work wait time. The work wait time is defined as the
time between the leading edge of two consecutive characters being sent to or from the card. If a timeout
occurs, an interrupt is generated to the firmware. The firmware can then take appropriate action. A Wait
Time Extension (WTX) is supported with the 28-bit BWT.
Character Wait Time Registers (CWTB0): 0xFE1D Å 0x00, (CWTB1): 0xFE1C Å 0x00
Table 111: The CWTB0 Register
MSB
CWT.7
LSB
CWT.6
CWT.5
CWT.4
CWT.3
CWT.1
CWT.2
CWT.0
Table 112: The CWTB1 Register
MSB
CWT.15
LSB
CWT.14
CWT.13
CWT.12
CWT.11
CWT.10
CWT.9
CWT.8
These registers (CWTB0, CWTB1) are used to hold the Character Wait Time(15:0) (CWT) or Initial Waiting
Time(15:0) (IWT) depending on the situation. Both the IWT and the CWT measure the time in ETUs
between the leading edge of the start of the current character received from the smart card and the leading
edge of the start of the next character received from the smart card. The only difference is the mode in
which the card is operating. When T=1 these registers are used to configure the CWT and these registers
configure the IWT when the ATR is being received. These registers should be loaded prior to receiving
characters from the smart card. Firmware must manage which time is stored in the register. If a timeout
occurs, an interrupt is generated to the firmware. The firmware can then take appropriate action.
Rev. 1.4
107
73S1215F Data Sheet
DS_1215F_003
ATR Timeout Registers (ATRLsB): 0xFE20 Å 0x00, (ATRMsB): 0xFE1F Å 0x00
Table 113: The ATRLsB Register
MSB
LSB
ATRTO.7
ATRTO.6
ATRTO.5
ATRTO.4
ATRTO.3
ATRTO.1
ATRTO.2 ATRTO.0
Table 114: The ATRMsB Register
MSB
LSB
ATRTO.15
ATRTO.14
ATRTO.13
ATRTO.12 ATRTO.11 ATRTO.10 ATRTO.9 ATRTO.8
These registers (ATRLsB and ATRLsB) form the ATR timeout (ATRTO [15:0]) parameter. Time in ETU
between the leading edge of the first character and leading edge of the last character of the ATR
response. Timer is enabled when the RCVATR is set and starts when leading edge of the first start bit is
received and disabled when the RCVATR is cleared. An ATR timeout is generated if this time is
exceeded.
TS Timeout Register (STSTO): 0xFE21 Å 0x00
Table 115: The STSTO Register
MSB
TST0.7
LSB
TST0.6
TST0.5
TST0.4
TST0.3
TST0.1
TST0.2
TST0.0
The TS timeout is the time in ETU between the de-assertion of smart card reset and the leading edge of
the TS character in the ATR (when DETTS is set). The timer is started when smart card reset is
de-asserted. An ATR timeout is generated if this time is exceeded (MUTE card).
Reset Time Register (RLength): 0xFE22 Å 0x70
Table 116: The RLength Register
MSB
RLen.7
LSB
RLen.6
RLen.5
RLen.4
RLen.3
RLen.1
RLen.2
RLen.0
Time in ETUs that the hardware delays the de-assertion of RST. If set to zero and RSTCRD = 0, the
hardware adds no extra delay and the hardware will release RST after VCCOK is asserted during
power-up. If set to one, it will delay the release of RST by the time in this register. When the firmware
sets the RSTCRD bit, the hardware will assert reset (RST = 0 on pin). When firmware clears the bit, the
hardware will release RST after the delay specified in Rlen. If firmware sets the RSTCRD bit prior to
instructing the power to be applied to the smart card, the hardware will not release RST after power-up
until RLen after the firmware clears the RSTCRD bit. This provides a means to power up the smart card
and hold it in reset until the firmware wants to release the RST to the selected smart card. Works with
the selected smart card interface.
108
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
Shaded locations indicate functions that are not provided in sync mode.
Table 117: Smart Card SFR Table
Name
SCSel
SCInt
Address
FE00
FE01
SCIE
FE02
VccCtl
VccTmr
CRDCtl
STXCtl
STXData
SRXCtl
SRXData
SCCtl
SCECtl
SCDIR
SPrtcol
SCCLK
SCECLK
SParCtl
SByteCtl
FDReg
CRCMsB
CRCLsB
BGT
EGT
BWTB3
BWTB2
BWTB1
BWTB0
CWTB1
CWTB0
ATRMsB
ATRLsB
STSTO
RLength
FE03
FE04
FE05
FE06
FE07
FE08
FE09
FE0A
FE0B
FE0C
FE0D
FE0F
FE10
FE11
FE12
FE13
FE14
FE15
FE16
FE17
FE18
FE19
FE1A
FE1B
FE1C
FE1D
FE1F
FE20
FE21
FE22
Rev. 1.4
b7
b6
b5
b4
WAITTO/
RLIEN
WTOI/
RLIEN
VCCSEL.1
CRDEVT
VCCTMR
RXDAVl
b3
b2
SelSC(1:0)
TXEVNT
TXSENT
CDEVNT
VTMREN
RXDAEN
TXEVEN
RDYST
VCCOK
DEBOUN
I2CMODE
VCCSEL.0 VDDFLT
OFFTMR(3:0)
CDETEN
TXFULL
BIT9DAT
LASTRX
RSTCRD
IO
SIO
SCISYN
MOD9/8B
SCESYN
DISPAR
BRKGEN
DETTS
DIRTS
FVAL(3:0)
EGT8
TXSNTEN
b1
BYPASS
TXERR
b0
RXERR
TXERR
RXERR
SCPWRDN
VCCTMR(3:0)
PUENB
PDEN
LASTTX
TX/RXB
DETPOL
TXEMTY TXUNDR
TXDATA(7:0)
CRCERR RXFULL
RXEMTY
RXOVRR
RXDATA(7:0)
IOD
C8
C4
CLKLVL
SIOD
SCLKLVL
C8D
C4D
0
TMODE
CRCEN
CRCMS
ICLKFS(5:0)
ECLKFS(5:0)
BRKDET
RTRAN
DISCRX
INSPE
BRKDUR (1:0)
DVAL (3:0)
CRC(15:8)
CRC(7:0)
BGT(4:0)
EGT(7:0)
BWT(27:24)
BWT(23:16)
BWT(15:8)
BWT(7:0)
CWT(15:8)
CWT(7:0)
ATRTO(15:8)
ATRTO(7:0)
TSTO(7:0)
RLen(7:0)
CARDIN
BREAKD
PARITYE
CLKOFF
SCLKOFF
109
RCVATR
FORCPE
73S1215F Data Sheet
DS_1215F_003
1.7.16 VDD Fault Detect Function
The 73S1215F contains a circuit to detect a low-voltage condition on the supply voltage VDD. If enabled,
it will deactivate the active internal smart card interface when VDD falls below the VDD Fault threshold. The
register configures the VDD Fault threshold for the nominal default of 2.3V* or a user selectable threshold.
The user’s code may load a different value using the FOVRVDDF bit =1 after the power-up cycle has
completed
VDDFault Control Register (VDDFCtl): 0xFFD4 Å 0x00
Table 118: The VDDFCtl Register
MSB
LSB
–
FOVRVDDF VDDFLTEN
Bit
Symbol
VDDFCtl.7
–
–
STXDAT.3
VDDFTH.2 VDDFTH.1 VDDFTH.0
Function
VDDFCtl.6
Setting this bit high will allow the VDDFLT(2:0) bits set in this register to
FOVRVDDF control the VDDFault threshold. When this bit is set low, the VDDFault
threshold will be set to the factory default setting of 2.3V*.
VDDFCtl.5
VDDFLTEN Set = 1 will disable VDD Fault operation.
VDDFCtl.4
–
VDDFCtl.3
–
VDDFCtl.2
VDDFTH.2
VDDFCtl.1
VDDFTH.1
VDDFCtl.0
VDDFTH.0
VDD Fault Threshold.
Bit value(2:0)
000
001
010
011
100
101
110
111
VDDFault voltage
2.3 (nominal default)
2.4
2.5
2.6
2.7
2.8
2.9
3.0
* Note: The VDD Fault factory default can be set to any threshold as defined by bits VDDFTH(2:0). The
73S1215F has the capability to burn fuses at the factory to set the factory default to any of these
voltages. Contact Teridian for further details.
110
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
2 Typical Application Schematic
OPTIONAL LCD DISPLAY SYSTEM
16 CHARACTER BY 2 LINES
U5
J6
6
C17
0.1uF
R5
NC
DB7
15
DB6
14
13
USR2
DB5
12
USR1
DB3
DB2
DB1
DB0
E
R/W*
RS
VO
VDD
GND
DB4
11
10
9
8
7
USR0
C24
C25
22pF
22pF
22pF
22pF
C29 +
C30
1uF
0.1uF
D7
LED3
D6
LED1
D5
LED2
D4
LED0
RV1
10K
2
USR3
32.768kHz
C23
200k
USB_CONN_4
6
12.000MHz
C22
100k
USR4
1M
Y2
5
24
Y1
3
R3
R34
USR5
R4
1
24
CW
GND
2
R2
4
DVCC
5.0V
3
USR6
D+5VDC
4
2
D+
1
D+
5
3
GND
1
GND
GND
LCD
BRIGHTNESS
ADJUST
Host Serial TX
Host Serial RX
S7
3
1
3
1
4
S17
3
3
1
W
3
SW_MOM
1
S18
3
1
S23
3
1
X
3
SW_MOM
S14
3
S19
3
1
3
1
Y
3
SW_MOM
S15
3
1
S20
3
3
1
Z
3
SW_MOM
3
C
1
S21
USR6
SW_MOM
1
S26
USR5
USR4
USR3
USR2
3
D
3
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
TXD
COL4
USR7
ROW0
ROW1
USR6
ROW2
GND
DP
DM
VDD
USR5
USR4
USR3
USR8
USR2
ROW3
ISBR
SEC
RESET
VDD
PRES
I/O
AUX1
AUX2
VCC
RST
GND
CLK
PRESB
VPC
TEST
TBUS0
INT2
73S1215F
3.3V
U6
C27
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
3.3V
1
2
3
4
5
6
7
8
+
R10
10uF
10k
R1
1
2
3
4
5
6
7
8
0
9
10
E
SW_MOM
S31
S16
SW_MOM
ENTER
1
3
B
CLR
1
S11
SW_MOM
SW_MOM
S25
3
SW_MOM
1
SW_MOM
/
S30
3
DOWN
SW_MOM
1
S10
S6
A
UP
9
S24
1
SW_MOM
SW_MOM
0
S29
1
6
SW_MOM
1
3
3
SW_MOM
SW_MOM
8
.
S28
3
S9
S5
ON/CE
3
SW_MOM
SW_MOM
1
S13
1
SW_MOM
5
7
1
1
SW_MOM
SW_MOM
S22
3
3
F3
SW_MOM
SW_MOM
1
S8
S4
SW_MOM
2
1
S12
1
SW_MOM
SW_MOM
1
3
F2
F1
SW_MOM
1
S3
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
3.3V
1
RXD
COL3
ANAIN
COL2
COL1
COL0
X12OUT
X12IN
GND
X32IN
X32OUT
SDA
SCL
LED3
LED1
LED2
LED0
3
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
S2
R6
C14
C15
C16
20K
27p
27p
0.47uF
J1
C1
C2
C3
C5
C6
C7
SW1
SW2
SMARTCARD
SLOT #1
SIM/SAM Connector
J4
VCC
RST
CLK
C4
GND
VPP
I/O
C8
SW-1
SW-2
Smart Card Connector
5.0V
SW_MOM
1
S32
3
3.3V
USR1
USR0
1
USR1
USR0
ROW4
ROW5
CPUCLK
ERST
TCLK
VDD
TBUS3
GND
RXTX
NC
TBUS2
SCLK
TBUS1
SIO
INT3
30-SWITCH
KEYPAD
20K
F
SW_MOM
R7
C3
0.1uF
C4
C5
0.1uF
0.1uF
C2
C6
10uF
0.1uF
Figure 26: 73S1215F Typical Application Schematic
Rev. 1.4
111
73S1215F Data Sheet
DS_1215F_003
3 Electrical Specification
3.1 Absolute Maximum Ratings
Operation outside these rating limits may cause permanent damage to the device. The smart card
interface pins are protected against short circuits to VCC, ground, and each other.
Parameter
Rating
DC Supply voltage, VDD
-0.5 to 4.0 VDC
Supply Voltage VPC
-0.5 to 6.5 VDC
Storage Temperature
-60 to 150°C
Pin Voltage (except card interface)
-0.3 to (VDD+0.5) VDC
Pin Voltage (card interface)
-0.3 to (VCC+0.5) VDC
ESD tolerance (except card interface)
+/- 2KV
ESD tolerance (card interface)
+/- 6KV
Pin Current
± 200 mA
Note: ESD testing on smart card pins is HBM condition, 3 pulses, each polarity referenced to ground.
Note: Smart Card pins are protected against shorts between any combinations of Smart Card pins.
3.2 Recommended Operating Conditions
Unless otherwise noted all specifications are valid over these temperatures and supply voltage ranges:
Parameter
Rating
DC Voltage Supply VDD
2.7 to 3.6 VDC
DC Voltage Supply VDD for USB operation
3.0 to 3.6 VDC
Supply Voltage VPC for Class A-B-C Reader
4.75 to 6.0 VDC
Ambient Operating Temperature (Ta)
-40°C to +85°C
112
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
3.3 Digital IO Characteristics
These requirements pertain to digital I/O pin types with consideration of the specific pin function and
configuration. The LED(3:0) pins have pull-ups that may be enabled. The Row pins have 100KΩ pullups.
Symbol
Parameter
Conditions
Min.
Voh
Output level, high
Ioh =-2mA
Vol
Output level, low
Vih
Typ.
Max.
Unit
0.8 *VDD
VDD
V
Iol=2mA
0
0.3
V
Input voltage, high
2.7v < VDD <3.6v
1.8
VDD+0.3
V
Vil
Input voltage, low
2.7v < VDD <3.6v
-0.3
0.6
V
Ileak
Leakage current
0 < Vin < VDD
All output modes
disabled, pull-up/downs
disabled
-5
5
μA
Ipu
Pull-up current
If provided and enabled,
Vout < 0.1v
-5
Ipd
Pull-down current
If provided and enabled,
Vout > VDD – 0.1v
Symbol
Parameter
Iled
μA
5
μA
Conditions
Min.
Typ.
Max.
Unit
LED drive current
Vout = 1.3V,
2.7v < VDD < 3.6v
1.7
3.4
8.5
2
4
10
2.3
4.6
11.5
mA
Iolkrow
Keypad Row output
low current
0.0v < Voh < 0.1v
when pull-up R is
enabled
-40
-100
μA
Iolkcol
Keypad column
output high current
0.0v < Voh < 0.1v
when col. is pulled low
-1.5
-3
mA
Rev. 1.4
113
73S1215F Data Sheet
DS_1215F_003
3.4 Oscillator Interface Requirements
Symbol
Parameter
Condition
Min
Typ.
Max
Unit
Low-Power Oscillator Requirements. No External Load Beside The Crystal And Capacitor Is
Permitted On Xout32.
Pxtal
IIL
Power In Crystal
Input Leakage Current
GND < Vin < VDD
-5
1
Μw
5
Μa
High-Frequency Oscillator (Xin) Parameters. XIN Is Used As Input For External Clock For Test
Purposes Only. A Resistor Connecting X12in To X12out Is Required, Value = 1MΩ.
VILX12IN
Input Low Voltage –
X12IN
VIHX12IN
Input High Voltage – X12IN
IILXTAL
Input Current –
X12IN
Fxtal
Crystal Resonant
Frequency
-0.3
0.3*VDD
V
0.7*VDD
Vdd+.0.3
V
GND < Vin < Vdd
-10
10
Μa
Fundamental
Mode
6
12
Mhz
Max
Unit
+3%
V
3.5 DC Characteristics: Analog Input
Symbol
Parameter
VTHTOL
Voltage Threshold
Tolerance
114
Condition
Min
Selected Threshold
Value
-3%
Typ.
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
3.6 USB Interface Requirements
Parameter
Condition
Min
Typ.
Max
Unit
Receiver Parameters
Differential input sensitivity
VDI
|(DP)-(DM)|
0.2
V
Differential common mode
range
VCM
Includes VDI range
0.8
2.5
V
Single ended receiver
threshold
VSE
0.8
2.0
V
0.3
V
Transmitter Levels
Low Level Output Voltage
VOL
USBCon = 1 (DP
pullup enabled)
High Level Output Voltage
VOH
15KΩ resistor to
ground
VDD – 0.1V
VDD
V
Driver output resistance
ZDRV
Steady state drive1
28
44
Ω
PD Pullup Resistor (to VDD)
Zpu
USBCon = 1
1.2
1.8
kΩ
Output Resistance (1)
1.5
Transceiver Power Requirements
1
Operating supply
current(output)
IPSO
Outputs enabled
5
mA
Operating supply current
(input)
IPSI
Outputs Hi-Z
1
mA
Supply current in powerdown IPDN
10
nA
Supply current in suspend.
10
nA
IPSS
External source (series) termination resistors of 24Ω must be included on circuit board.
Rev. 1.4
115
73S1215F Data Sheet
DS_1215F_003
Parameter
Condition
Min
Typ.
Max
Unit
CL = 50pf, series 24Ω, 1% source termination resistor included
Rise Time
USBTR
10% to 90%
4
20
ns
Fall Time
USBTF
90% to 10%
4
20
ns
Rise/fall time matching
TRFM
(USBTR/USBTF)
90
111.11
%
Output signal crossover
voltage
VCRS
Includes VDI range
1.3
2.0
V
Source Jitter to Next
Transition
TDJ1
Measured as in Figure
7-49 of USB 2.0 Spec
-3.5
3.5
ns
Source Jitter For Paired
Transitions
TDJ2
Measured as in Figure 749 of USB 2.0 Spec (1) (2)
-4
4
ns
TJR1
Measure as in Figure 7-51
of USB 2.0 Spec.
Characterized but not
production tested.
-18.5
18.5
ns
TJR2
Measure as in Figure 7-51
of USB 2.0 Spec.
Characterized but not
production tested.
-9
9
ns
175
ns
Receiver Jitter to Next
Transition
Receiver Jitter for Paired
Transitions
Source SE0 interval of
EOP
TEOPT
Figure 7-50 of USB 2.0
Spec
160
Receiver SEO interval of
EOP
TEOPR
Figure 7-50 of USB 2.0
Spec. (3)
82
ns
(1) For both transitions of differential signaling.
(2) Excluding first transition from the Idle state.
(3) Must accept as valid EOP.
116
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
3.7 Smart Card Interface Requirements
Symbol
Parameter
Condition
Min
Typ.
Max
Unit
Card Power Supply (VCC) Regulator
General conditions, -40°C < T < 85°C, 4.75V < VPC < 6.0V, 2.7V < VDD < 3.6V
VCC
Card supply Voltage
including ripple and
noise
Inactive mode
-0.1
0.1
V
Inactive mode, ICC = 1mA
-0.1
0.4
V
Active mode; ICC <65mA; 5V
4.65
5.25
V
Active mode; ICC <65mA; 5V, NDS
condition
4.75
5.25
V
Active mode; ICC < 65mA; 3V
2.85
3.15
V
Active mode; ICC < 40mA; 1.8V
1.68
1.92
V
Active mode; single pulse of 100mA for
2μs; 5 volt, fixed load = 25mA
4.6
5.25
V
Active mode; single pulse of 100mA for
2μs; 3v, fixed load = 25mA
2.7
3.15
V
Active mode; current pulses of 40nAs
with peak |ICC | <200mA, t <400ns; 5V
4.6
5.25
V
Active mode; current pulses of 40nAs
with peak |ICC | <200mA, t <400ns; 5V
4.65
5.25
V
Active mode; current pulses of 40nAs
with peak |ICC | <200mA,t <400ns; 3V
2.7
3.15
V
Active mode; current pulses of 20nAs
with peak |ICC | <100mA,t <400ns; 1.8V
1.62
1.92
V
fRIPPLE = 20kHz – 200MHz
350
mV
Static load current, VCC>1.65
40
mA
Static load current, VCC>4.6 or 2.7 volts
as selected
90
VCCrip
VCC Ripple
ICCmax
Card supply output
current
ICCF
ICC fault current
VSR
Vcc slew rate, rise
Rise rate on activate C=1.0μF
Vcc slew rate, fall
Fall rate on deactivate, C=1.0μF
VSF
Vrdy
CF
Rev. 1.4
Vcc ready voltage
(VCCOK = 1)
External filter
capacitor (VCC to
GND)
Class A, B (5V and 3V)
100
180
Class C (1.8V)
60
130
mA
0.06
0.15
0.25
V/μ
s
0.075
0.15
0.6
V/μ
s
5V operation, Vcc rising
4.6
V
3V operation, Vcc rising
2.75
V
1.8V operation, Vcc rising
1.65
V
CF should be ceramic with low ESR
(<100MΩ).
1
3.3
μF
117
73S1215F Data Sheet
Symbol
Parameter
DS_1215F_003
Condition
Min
Typ.
Max
Unit
Interface Requirements – Data Signals: I/O, AUX1 and AUX2
VOH
Output level, high (I/O,
AUX1, AUX2)
IOH =0
0.9 * VCC
VCC+0.1
V
IOH = -40μA
0.75 VCC
VCC+0.1
V
VOL
Output level, low (I/O,
AUX1, AUX2)
IOL=1mA
0.15 *VCC
V
VIH
Input level, high (I/O,
AUX1, AUX2)
0.6 * VCC
VCC+0.30
V
VIL
Input level, low (I/O, AUX1,
AUX2)
-0.15
0.2 * VCC
V
VINACT
Output voltage when
outside of session
IOL = 0
0.1
V
IOL = 1mA
0.3
V
ILEAK
Input leakage
VIH = VCC
10
μA
IIL
Input current, low (I/O,
AUX1, AUX2)
VIL = 0
0.65
mA
ISHORTL
Short circuit output current
For output low,
shorted to VCC
through 33Ω
15
mA
ISHORTH
Short circuit output current
For output high,
shorted to ground
through 33Ω
15
mA
tR, tF
Output rise time, fall times
For I/O, AUX1,
AUX2, CL = 80pF,
10% to 90%.
100
ns
tIR, tIF
Input rise, fall times
1
μs
RPU
Internal pull-up resistor
14
kΩ
FDMAX
Maximum data rate
1
MHz
Output stable for
>200ns
8
11
Reset and Clock for Card Interface, RST, CLK
VOH
Output level, high
IOH =-200μA
0.9 * VCC
VCC
V
VOL
Output level, low
IOL=200μA
0
0.15 *VCC
V
VINACT
Output voltage when
outside of session
IOL = 0
0.1
V
IOL = 1mA
0.3
V
IRST_LIM
Output current limit, RST
30
ICLK_LIM
Output current limit, CLK
70
CLKSR3V
CLK slew rate
VCC = 3V
0.3
V/ns
CLKSR5V
CLK slew rate
VCC = 5V
0.5
V/ns
tR, tF
δ
118
Output rise time, fall time
Duty cycle for CLK
CL = 35pF for CLK,
10% to 90%
CL = 200pF for RST,
10% to 90%
CL =35pF,
FCLK ≤ 20MHz
45
mA
8
ns
100
ns
55
%
Rev. 1.4
DS_1215F_003
3.7.1
73S1215F Data Sheet
DC Characteristics
Symbol
IDD
IPC
IPCOFF
Parameter
Supply Current
Supply Current
VPC supply current when
VCC = 0
Condition
Min
Typ.
Max
Unit
CPU clock @ 24MHz
30
35
mA
CPU clock @ 12MHz
22
25.5
mA
CPU clock @ 6MHz
16
19.5
mA
CPU clock @ 3.69MHz
14
17
mA
Power down
(-40 to 85 C)
8
50
μA
Power down (25 C)
6
13
μA
VCC on, ICC=0
I/O, AUX1, AUX2=high,
CLK not toggling
450
650
Power down
1
10
Smart card deactivated
345
μA
μA
3.8 Voltage / Temperature Fault Detection Circuits
Symbol
Parameter
VPCF
VPC fault
(VPC Voltage supervisor
threshold)
VCCF
VCCOK = 0
(VCC Voltage supervisor
threshold)
Condition
Min
Max
VCC >
VPC +
0.3
VPC<VCC, a transient
event
Unit
V
VCC = 5V
4.6
V
VCC= 3V
2.7
V
VCC= 1.8V
1.65
TF
Die over temperature
fault
115
ICCF
Vcc over current fault
110
Rev. 1.4
Typ.
145
°C
mA
119
73S1215F Data Sheet
DS_1215F_003
4 Equivalent Circuits
VDD
X12LIN
X12OUT
ESD
ESD
ENABLE
TTL
To
circuit
Figure 27: 12 MHz Oscillator Circuit
VDD
ENABLEb
X32OUT
>1MEG
X32LIN
ESD
ESD
TTL
To
circuit
Figure 28: 32kHz Oscillator Circuit
120
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
VDD
STRONG
PFET
Output
Disable
PIN
ESD
Data
From
circuit
TTL
To
circuit
STRONG
NFET
Figure 29: Digital I/O Circuit
VDD
Output
Disable
STRONG
PFET
PIN
Data
From
circuit
ESD
STRONG
NFET
Figure 30: Digital Output Circuit
Rev. 1.4
121
73S1215F Data Sheet
DS_1215F_003
VDD
VERY
WEAK
PFET
Pull-up
Disable
STRONG
PFET
Output
Disable
PIN
ESD
Data
From
circuit
STRONG
NFET
TTL
To
circuit
Figure 31: Digital I/O with Pull Up Circuit
VDD
STRONG
PFET
Output
Disable
PIN
ESD
Data
From
circuit
Pull-down
Enable
TTL
To
circuit
STRONG
NFET
VERY
WEAK
NFET
Figure 32: Digital I/O with Pull-Down Circuit
122
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
PIN
TTL
To
circuit
ESD
Figure 33: Digital Input Circuit
VDD
Pull-up
Disable
STRONG
PFET
Output
Disable
100k
OHM
PIN
ESD
Data
From
circuit
TTL
To
circuit
STRONG
NFET
Figure 34: Keypad Row Circuit
Rev. 1.4
123
73S1215F Data Sheet
DS_1215F_003
VDD
1200
OHMS
MEDIUM
PFET
Output
Disable
PIN
ESD
Data
From
circuit
TTL
To
circuit
STRONG
NFET
Figure 35: Keypad Column Circuit
124
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
VDD
STRONG
PFET
Pullup
Disable
PIN
ESD
Data
From
circuit
STRONG
NFET
TTL
To
circuit
Current Value
Control
0, 2, 4,
10mA
Figure 36: LED Circuit
This buffer has a
special input
threshold:
Vih>0.7*VDD
To Circuit
Logic
PIN
ESD
R= 20kΩ
Figure 37: Test and Security Pin Circuit
Rev. 1.4
125
73S1215F Data Sheet
DS_1215F_003
To
Comparator
Input
PIN
ESD
Figure 38: Analog Input Circuit
VCC
STRONG
PFET
ESD
From
circuit
PIN
ESD
STRONG
NFET
Figure 39: Smart Card Output Circuit
126
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
VCC
STRONG
PFET
ESD
RL=11K
125ns
DELAY
IO
PIN
From
circuit
To
circuit
CMOS
STRONG
NFET
ESD
Figure 40: Smart Card I/O Circuit
VDD
ESD
Pull-down
Enable
PIN
TTL
To
circuit
VERY
WEAK
NFET
ESD
Figure 41: PRES Input Circuit
Rev. 1.4
127
73S1215F Data Sheet
DS_1215F_003
VDD
VERY
WEAK
PFET
Pull-up
Enable
ESD
PIN
TTL
To
circuit
ESD
Figure 42: PRES Input Circuit
VDD
RP_ENb
VDD
1500 Ω
DP
DP_OUT
ZOUT=
20Ω
DP_IN
ESD
TTL
OUTPUT ENABLEb
IN_P
RCV_IN
DM_IN
TTL
IN_N
VDD
DM
DM_OUT
ZOUT=
20Ω
OUTPUT ENABLEb
ESD
Figure 43: USB Circuit
128
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
5 Package Pin Designation
5.1 68-pin QFN Pinout
X12OUT
XI2IN
GND
X32IN
X32OUT
SDA
SCL
LED3
LED1
LED2
LED0
11
10
8
6
5
4
3
2
1
7
COL1
COL0
13
9
ANAIN
COL2
15
12
COL3
16
14
RXD
17
CAUTION: Use handling procedures necessary
for a static sensitive component.
TXD
18
68
ISBR
COL4
19
67
SEC
USR7
20
66
ROW0
ROW1
USR6
21
65
22
64
RESET
VDD
PRES
23
63
IO
62
AUX1
AUX2
TERIDIAN
73S1215F
USR2
ROW3
33
53
TBUS0
34
52
INT2
61
60
59
48
49
50
SCLK
TBUS1
SIO
INT3
VCC
RST
GND
CLK
PRESB
51
47
58
NC
TBUS2
37
ROW4
ROW5
39
36
USR0
38
35
USR1
46
32
VPC
TEST
45
USR8
54
RXTX
55
44
31
GND
56
43
30
TBUS3
57
42
29
VDD
USR5
USR4
USR3
28
41
27
26
TCLK
DM
VDD
25
40
24
CPUCLK
ERST
ROW2
GND
DP
Figure 44: 73S1215F 68 QFN Pinout
Rev. 1.4
129
73S1215F Data Sheet
DS_1215F_003
5.2
.2 44-pin QFN Pinout
XI2IN
GND
SDA
SCL
LED1
LED0
SEC
RESET
8
7
6
5
4
3
1
2
X12OUT
9
10
RXD
ANA_IN
11
CAUTION: Use handling procedures necessary
for a static sensitive component.
12
44
VDD
13
43
PRES
USR6
GND
14
42
41
IO
AUX1
DP
16
40
AUX2
DM
17
39
VDD
USR5
USR4
18
19
37
VCC
RST
GND
20
36
CLK
USR3
21
35
PRESB
USR2
22
34
VPC
31
32
INT2
TEST
33
38
SIO
30
29
N/C
SCLK
27
VDD
RXTX
28
26
24
USR0
ERST
25
23
TCLK
TERIDIAN
73S1215F
15
USR1
TXD
USR7
Figure 45: 73S1215F 44 QFN Pinout
130
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
6 Packaging Information
6.1
68-Pin QFN Package Outline
Notes: 6.3mm x 6.3mm exposed pad area must remain UNCONNECTED (clear of PCB traces or
vias). Controlling dimensions are in mm.
0.65
8.00
7.75
0.85
0.2
0.00/0.05
68
1
2
3
7.75
8.00
TOP VIEW
12°
SEATING
PLANE
8.00
0.42
0.24/0.60
6.30
6.15/6.45
68
0.00/0.05
1
2
0.45
SIDE VIEW
PIN#1 ID
R0.20
0.20
0.15/0.25
3
0.42
0.24/0.60
SECTION "C-C"
6.30
6.40 8.00
6.15/6.45
SCALE: NONE
C C
CL
6.40
0.40
TERMINAL TIP
FOR ODD TERMINAL/SIDE
BOTTOM VIEW
Figure 46: 73S1215F 68 QFN Package Drawing
Rev. 1.4
131
73S1215F Data Sheet
6.2
DS_1215F_003
44-Pin QFN Package Outline
Notes: 5.1mm x 5.1mm exposed pad area must remain UNCONNECTED (clear of PCB traces or
vias). Controlling dimensions are in mm.
0.65
7.00
6.75
0.85
0.2
0.00/0.05
44
1
2
3
6.75
7.00
TOP VIEW
12°
SEATING
PLANE
7.00
0.42
0.24/0.60
4.95/5.25
SIDE VIEW
PIN#1 ID
R0.20
5.10
44
0.00/0.05
1
0.45
0.23
0.18/0.30
2
3
0.42
0.24/0.60
SECTION "C-C"
5.10
5.00 7.00
4.95/5.25
SCALE: NONE
C C
CL
5.00
0.50
TERMINAL TIP
FOR ODD TERMINAL/SIDE
BOTTOM VIEW
Figure 47: 73S1215F 44 QFN Package Drawing
132
Rev. 1.4
DS_1215F_003
73S1215F Data Sheet
7 Ordering Information
Table 119 lists the order numbers and packaging marks used to identify 73S1215F products.
Table 119: Order Numbers and Packaging Marks
Part Description
Order Number
Packaging Mark
73S1215F 68-Pin QFN Lead Free
73S1215F-68IM/F
73S1215F68IM
73S1215F 68-Pin QFN Lead Free, Tape and Reel
73S1215F-68IMR/F
73S1215F68IM
73S1215F 44-Pin QFN Lead Free
73S1215F-44IM/F
73S1215FIM
73S1215F 44-Pin QFN Lead Free, Tape and Reel
73S1215F-44IMR/F
73S1215FIM
8 Related Documentation
The following 73S1215F documents are available from Teridian Semiconductor Corporation:
73S1215F Data Sheet (this document)
73S1215F Development Board Quick Start Guide
73S1215F Software Development Kit Quick Start Guide
73S1200/15F Evaluation Board User’s Guide
73S12xxF Software User’s Guide
73S12xxF Synchronous Card Design Application Note
9 Contact Information
For more information about Teridian Semiconductor products or to check the availability of the 73S1215F,
contact us at:
6440 Oak Canyon Road
Suite 100
Irvine, CA 92618-5201
Telephone: (714) 508-8800
FAX: (714) 508-8878
Email: [email protected]
For a complete list of worldwide sales offices, go to http://www.teridian.com.
Rev. 1.4
133
73S1215F Data Sheet
DS_1215F_003
Revision History
Revision
Date
Description
1.1
1.3
2/2/2007
11/6/2007
First publication.
On page 2, changed bullet from “ISO-7816 UART 9600 to 115kbps for
protocols T=0, T=1” to “ISO-7816 UART for protocols T=0, T=1”.
In Table 1, added Equivalent Circuit references.
In Table 3 and Table 5, removed the PREBOOT bit description.
In Section 1.4, updated program security description to remove pre-boot
and 32-cycle references.
In Section 1.4, changed the second bullet “Page zero of flash memory, the
preferred location for the user’s preboot code, may not be page-erased by
either MPT or ICE. Page zero may only be erased with global flash erase.
Note that global flash erase erases XRAM whether the SECURE bit is set
or not.” to “Page zero of flash memory may not be page-erased by either
MPU or ICE. Page zero may only be erased with global flash erase. Note
that global flash erase erases XRAM whether the SECURE bit is set or
not.”
In Section 1.7.1, changed “Mcount is configured in the MCLKCtl register
must be bound between a value of 1 to 7. The possible crystal or external
clock are shown in Table 12.“ to “Mcount is configured in the MCLKCtl
register must be bound between a value of 1 to 7. The possible crystal or
external clock frequencies for getting MCLK = 96MHz are shown in Table
12.”
In Table 12, removed the Mcount selections for 8, 9 and 10.
Added to the INT5Ctl description, “Note: The RTC based watchdog will be
enabled when set.”
In the BRCON description, changed “If BSEL = 1, the baud rate is derived
using timer 1.” to “If BSEL = 0, the baud rate is derived using timer 1.”
In Section 1.7.13, removed the following from the emulator port
description: “The signals of the emulator port have weak pull-ups. Adding
resistor footprints for signals E_RST, E_TCLK and E_RXTX on the PCB is
recommended. If necessary, adding 10KΩ pull-up resistors on E_TCLK
and E_RXTX and a 3KΩ on E_RST will help the emulator operate
normally if a problem arises.”
Changed last sentence of the DETTS bit description from “TS is decoded
prior to the FIFO and is stored in the receive FIFO,” to “TS is decoded
before being stored in the receive FIFO.”
In Section 1.7.15.1, added 230000 to the baud rate selections in bullet 7.
Changed the VDDFLT bit description to “If this bit is set = 0, the
CMDVCC3B and CMDVCC5B outputs are immediately set = 1 to signal to
the companion circuit to begin deactivation when there is a VDD Fault
event. If this bit is set = 1 and there is a VDD Fault, the firmware should
perform a deactivation sequence and then set CMDVCC3B or
CMDVCC5B = 1 to signal the companion circuit to set
VCC = 0.”
In Section 4, added equivalent circuit diagrams.
In Ordering Information, removed the leaded part numbers.
134
Rev. 1.4
DS_1215F_003
1.4
12/16/2008
73S1215F Data Sheet
In Table 1, added more description to the VCC, VPC, VDD, SCL, SDA,
PRES, SEC and TEST pins.
In Section 1.3.2, changed “FLSH_ERASE” to “ERASE” and
“FLSH_PGADR” to “PGADDR”. Added “The PGADDR register denotes
the page address for page erase. The page size is 512 (200h) bytes and
there are 128 pages within the flash memory. The PGADDR denotes the
upper seven bits of the flash memory address such that bit 7:1 of the
PGADDR corresponds to bit 15:9 of the flash memory address. Bit 0 of
the PGADDR is not used and is ignored.” In the description of the
PGADDR register, added “Note: the page address is shifted left by one bit
(see detailed description above).”
Changed the register address for ATRMsB from FE21 to FE1F.
In Table 5, changed “FLSHCRL” to “FLSHCTL”.
In Table 5, moved the TRIMPCtl bit description to FUSECtl and moved the
FUSECtl bit description to TRIMPCtl.
In Table 6, changed “PGADR” to “PGADDR”.
In Table 7, added PGADDR.
In Table 8, changed the reset value for RTCCtl from “0x81” to “0x00”.
Added the RTCTrim0 and ACOMP registers. Deleted the OMP, VRCtl,
LEDCal and LOCKCtl registers.
In Table 23, corrected the descriptions for TCON.2 and TCON.0.
In Table 62, added “Write data controls output level of pin LEDn. Read will
report level of pin LEDn.” to the description of LEDD3, LEDD2 and
LEDD1.
In Section 1.7.15.5 (number 3), deleted “If CLKOFF/SCLKOFF is high and
SYCKST is set=1(STXCtl, b7=1), Rlen=max will stop the clock at the
selected (CLKLVL or SCLKLVL) level.”
In Section 1.7.15.5, added “Synchronous card operation is broken down
into three primary types. These are commonly referred to as 2-wire,
3-wire and I2C synchronous cards. Each card type requires different
control and timing and therefore requires different algorithms to access.
Teridian has created an application note to provide detailed algorithms for
each card type. Refer to the application note titled 73S12xxF
Synchronous Card Design Application Note.”
In the VccVtl.0 bit description, deleted “When in power down mode, VDD =
0V. VDD can only be turned on by pressing the ON/OFF switch or by
application of 5V to VBUS. If VBUS power is available and SCPWRDN bit is
set, it has no effect until VBUS is removed and VDD will shut off.”
In Table 86 and Table 117, changed the SYCKST bit to I2CMODE.
In Figure 26, replaced the schematic with a new schematic.
Added Section 6, Ordering Information.
Added Section 7, Related Documentation.
Added Section 8, Contact Information.
Formatted the document per new standard. Added section numbering.
Rev. 1.4
135
73S1215F Data Sheet
DS_1215F_003
© 2008 Teridian Semiconductor Corporation. All rights reserved.
Teridian Semiconductor Corporation is a registered trademark of Teridian Semiconductor Corporation.
Windows is a registered trademark of Microsoft Corporation.
Signum Systems is a trademark of Signum Systems Corporation.
ExpressCard is a registered trademarks of PCMCIA.
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Teridian Semiconductor Corporation makes no warranty for the use of its products, other than expressly
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