SAM7L128/64 - Complete

AT91SAM ARM-based Flash MCU
SAM7L128/SAM7L64
DATASHEET
Description
The AT91SAM7L128/64 are low power members of Atmel’s Smart ARM Microcontroller family based on the 32bit ARM7™ RISC processor and high-speed Flash memory.
• AT91SAM7L128 features a 128 Kbyte high-speed Flash and a total of 6 Kbytes SRAM.
• AT91SAM7L64 features a 64 Kbyte high-speed Flash and a total of 6 Kbytes SRAM.
They also embed a large set of peripherals, including a Segment LCD Controller and a complete set of system
functions minimizing the number of external components.
These devices provide an ideal migration path for 8-bit microcontroller users looking for additional performance,
extended memory and higher levels of system integration with strong constraints on power consumption.
Featuring innovative power reduction modes and ultra-low-power operation, the AT91SAM7L128/64 is tailored
for battery operated applications such as calculators, toys, remote controls, medical devices, mobile phone
accessories and wireless sensors.
The embedded Flash memory can be programmed in-system via the JTAG-ICE interface or via a parallel interface on a production programmer prior to mounting. Built-in lock bits and a security bit protect the firmware from
accidental overwrite and preserve its confidentiality.
The AT91SAM7L128/64 system controller includes a reset controller capable of managing the power-on
sequence of the microcontroller and the complete system. Correct device operation can be monitored by a builtin brownout detector and a watchdog running off an integrated oscillator.
By combining the ARM7TDMI processor with on-chip Flash and SRAM, and a wide range of peripheral functions, including USART, SPI, External Bus Timer Counter, RTC and Analog-to-Digital Converters on a
monolithic chip, the AT91SAM7L128/64 microcontroller is a powerful device that provides a flexible, cost-effective solution to many embedded control applications.
6257B–ATARM–01-Feb-13
1. Features
• Incorporates the ARM7TDMI® ARM® Thumb® Processor
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– High-performance 32-bit RISC Architecture
– High-density 16-bit Instruction Set
– Leader in MIPS/Watt
– EmbeddedICE™ In-circuit Emulation, Debug Communication Channel Support
Internal High-speed Flash
– 128 Kbytes (AT91SAM7L128), Organized in 512 Pages of 256 Bytes Single Plane
– 64 Kbytes (AT91SAM7L64), Organized In 256 Pages of 256 Bytes Single Plane
– Single Cycle Access at Up to 15 MHz in Worst Case Conditions
– 128-bit Read Access
– Page Programming Time: 4.6 ms, Including Page Auto Erase, Full Erase Time: 10 ms
– 10,000 Write Cycles, 10-year Data Retention Capability, Sector Lock Capabilities, Flash Security Bit
– Fast Flash Programming Interface for High Volume Production
Internal High-speed SRAM, Single-cycle Access at Maximum Speed
– 6 Kbytes
• 2 Kbytes Directly on Main Supply That Can Be Used as Backup SRAM
• 4 Kbytes in the Core
Memory Controller (MC)
– Enhanced Embedded Flash Controller, Abort Status and Misalignment Detection
Enhanced Embedded Flash Controller (EEFC)
– Interface of the Flash Block with the 32-bit Internal Bus
– Increases Performance in ARM and Thumb Mode with 128-bit Wide Memory Interface
Reset Controller (RSTC)
– Based on Zero-power Power-on Reset and Fully Programmble Brownout Detector
– Provides External Reset Signal Shaping and Reset Source Status
Clock Generator (CKGR)
– Low-power 32 kHz RC Oscillator, 32 kHz On-chip Oscillator, 2 MHz Fast RC Oscillator and one PLL
Supply Controller (SUPC)
– Minimizes Device Power Consumption
– Manages the Different Supplies On Chip
– Supports Multiple Wake-up Sources
Power Management Controller (PMC)
– Software Power Optimization Capabilities, Including Active and Four Low Power Modes:
• Idle Mode: No Processor Clock
• Wait Mode: No Processor Clock, Voltage Regulator Output at Minimum
• Backup Mode: Voltage Regulator and Processor Switched Off
• Off (Power Down) Mode: Entire Chip Shut Down Except for Force Wake Up Pin (FWUP) that Re-activates the Device.
100 nA Current Consumption.
In Active Mode, Dynamic Power Consumption <30 mA at 36 MHz
– Three Programmable External Clock Signals
– Handles Fast Start Up
Advanced Interrupt Controller (AIC)
– Individually Maskable, Eight-level Priority, Vectored Interrupt Sources
– Two External Interrupt Sources and One Fast Interrupt Source, Spurious Interrupt Protected
Debug Unit (DBGU)
– Two-wire UART and Support for Debug Communication Channel interrupt, Programmable ICE Access Prevention
Periodic Interval Timer (PIT)
– 20-bit Programmable Counter plus 12-bit Interval Counter
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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• Windowed Watchdog (WDT)
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– 12-bit Key-protected Programmable Counter
– Provides Reset or Interrupt Signals to the System
– Counter may be Stopped While the Processor is in Debug State or in Idle Mode
Real-time Clock (RTC)
– Two Hundred Year Calendar with Alarm
– Runs Off the Internal RC or Crystal Oscillator
Three Parallel Input/Output Controllers (PIOA, PIOB, PIOC)
– Eighty Programmable I/O Lines Multiplexed with up to Two Peripheral I/Os
– Input Change Interrupt Capability on Each I/O Line
– Individually Programmable Open-drain, Pull-up resistor and Synchronous Output
Eleven Peripheral DMA Controller (PDC) Channels
One Segment LCD Controller
– Display Capacity of Forty Segments and Ten Common Terminals
– Software Selectable LCD Output Voltage (Contrast)
Two Universal Synchronous/Asynchronous Receiver Transmitters (USART)
– Individual Baud Rate Generator, IrDA® Infrared Modulation/Demodulation
– Support for ISO7816 T0/T1 Smart Card, Hardware Handshaking, RS485 Support
– Manchester Encoder/Decoder
– Full Modem Line Support on USART1
One Master/Slave Serial Peripheral Interface (SPI)
– 8- to 16-bit Programmable Data Length, Four External Peripheral Chip Selects
One Three-channel 16-bit Timer/Counter (TC)
– Three External Clock Inputs, Two Multi-purpose I/O Pins per Channel
– Double PWM Generation, Capture/Waveform Mode, Up/Down Capability
One Four-channel 16-bit PWM Controller (PWMC)
One Two-wire Interface (TWI)
– Master, Multi-Master and Slave Mode Support, All Atmel® Two-wire EEPROMs and I2C compatible Devices Supported
– General Call Supported in Slave Mode
One 4-channel 10-bit Analog-to-Digital Converter, Four Channels Multiplexed with Digital I/Os
SAM-BA® Boot Assistant
– Default Boot Program
– Interface with SAM-BA Graphic User Interface
– In Application Programming Function (IAP)
IEEE® 1149.1 JTAG Boundary Scan on All Digital Pins
Four High-current Drive I/O lines, Up to 4 mA Each
Power Supplies
– Embedded 1.8V Regulator, Drawing up to 60 mA for the Core with Programmable Output Voltage
– Single Supply 1.8V - 3.6V
Fully Static Operation: Up to 36 MHz at 85⋅ C, Worst Case Conditions
Available in a 128-lead LQFP Green and a 144-ball LFBGA Green Package
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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2. Block Diagram
AT91SAM7L128/64 Block Diagram
TDI
TDO
TMS
TCK
ICE
JTAG
SCAN
Charge
Pump
ARM7TDMI
Processor
JTAGSEL
System Controller
2 MHz RCOSC
TST
CAPP1
CAPM1
CAPP2
CAPM2
VDDINLCD
VDD3V6
LCD
Voltage
Regulator
VDDLCD
1.8 V
Voltage
Regulator
VDDIO1
GND
VDDOUT
VDDIO2
IRQ0-IRQ1
PIO
FIQ
AIC
PCK0-PCK2
VDDCORE
CLKIN
PLLRC
PLL
XIN
XOUT
VDDIO1
VDDIO1
VDDIO2
Memory Controller
PMC
SRAM
OSC
Embedded
Flash
Controller
Address
Decoder
32k RCOSC
Abort
Status
Misalignment
Detection
2 Kbytes( Back-up)
4 Kbytes (Core)
VDDCORE
Flash
BOD
POR
ERASE
64/128 Kbytes
Supply
Controller
Peripheral Bridge
NRST
ROM (12 Kbytes)
Peripheral Data
Controller
11 Channels
NRSTB
Fast Flash
Programming
Interface
FWUP
VDDIO1
APB
PGMRDY
PGMNVALID
PGMNOE
PGMCK
PGMM0-PGMM3
PGMD0-PGMD15
PGMNCMD
PGMEN0-PGMEN2
SAM-BA
RTC
PIT
PIO
WDT
DRXD
DTXD
DBGU
PWM0
PWM1
PWM2
PWM3
TCLK0
TCLK1
TCLK2
TIOA0
TIOB0
TIOA1
TIOB1
TIOA2
TIOB2
PWMC
PDC
PDC
Timer Counter
PIOA (26 IOs)
TC0
PIOB (24 IOs)
TC1
PDC
SEG00-SEG39
COM0-COM9
LCD Controller
TWI
PDC
PDC
SPI
RXD0
TXD0
SCK0
RTS0
CTS0
RXD1
TXD1
SCK1
RTS1
CTS1
DCD1
DSR1
DTR1
RI1
PDC
USART0
PDC
PDC
PDC
PDC
ADC
USART1
PIO
TC2
PIOC (30 IOs)
PIO
Figure 2-1.
TWD
TWCK
NPCS0
NPCS1
NPCS2
NPCS3
MISO
MOSI
SPCK
ADTRG
AD0
AD1
AD2
AD3
ADVREF
PDC
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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3. Signal Description
Table 3-1.
Signal Name
Signal Description List
Function
Type
Active
Level
Voltage
Reference Comments
Power
VDDIO1
I/O Lines (PIOC) and Voltage Regulator
Power Supply
Power
VDDOUT
Voltage Regulator Output
Power
VDDCORE
Core Power Supply
Power
Connected externally to VDDOUT
VDDINLCD
Charge Pump Power Supply
Power
From 1.80V to 3.6V
VDD3V6
Charge Pump Output
Power
VDDLCD
LCD Voltage Regulator Power Supply
Power
VDDIO2
LCD Voltage Regulator Output
and
LCD I/O Lines Power Supply (PIOA and
PIOB)
Power
1.80V to 3.6V
CAPP1
Charge pump capacitor 1
Power
CAPM1
Charge pump capacitor 1
Power
Capacitor needed between CAPP1
and CAPM1.
CAPP2
Charge pump capacitor 2
Power
CAPM2
Charge pump capacitor 2
Power
FWUP
Force Wake-up
Input
WKUP0-15
Wake-up inputs used in Backup mode and
Fast Start-up inputs in Wait mode
Input
GND
Ground
From 1.80V to 3.6V
Capacitor needed between CAPP2
and CAPM2.
Low
VDDIO1
Needs external Pull-up.
VDDIO1
Ground
Clocks, Oscillators and PLLs
XIN
32 kHz Oscillator Input
Input
VDDIO1
XOUT
32 kHz Oscillator Output
Output
VDDIO1
CLKIN
Main Clock input
Input
VDDIO1
PCK0 - PCK2
Programmable Clock Output
PLLRC
PLL Filter
Input
PLLRCGND
PLL RC Filter Ground
Power
Should be tied low when not used.
Output
VDDCORE
Must not be connected to external
Ground.
ICE and JTAG
TCK
Test Clock
Input
VDDIO1
No internal pull-up resistor
TDI
Test Data In
Input
VDDIO1
No internal pull-up resistor
TDO
Test Data Out
Output
VDDIO1
TMS
Test Mode Select
Input
VDDIO1
No internal pull-up resistor
JTAGSEL
JTAG Selection
Input
VDDIO1
Internal Pull-down resistor
VDDIO1
Internal Pull-down (15 kΩ) resistor
Flash Memory
ERASE
Flash and NVM Configuration Bits Erase
Command
Input
High
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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Table 3-1.
Signal Name
Signal Description List (Continued)
Function
Type
Active
Level
Voltage
Reference Comments
Reset/Test
I/O
Low
VDDIO1
Internal Pull-up (100 kΩ) resistor
Test Mode Select
Input
High
VDDIO1
Internal Pull-down (15 kΩ) resistor
Asynchronous Master Reset
Input
Low
VDDIO1
Internal Pull-up (15 kΩ) resistor
NRST
Microcontroller Reset
TST
NRSTB
Debug Unit
DRXD
Debug Receive Data
Input
DTXD
Debug Transmit Data
Output
AIC
IRQ0 - IRQ1
External Interrupt Inputs
Input
FIQ
Fast Interrupt Input
Input
PIO
PA0 - PA25
Parallel IO Controller A
I/O
VDDIO2
Pulled-up input at reset
PB0 - PB23
Parallel IO Controller B
I/O
VDDIO2
Pulled-up input at reset
PC0 - PC29
Parallel IO Controller C
I/O
VDDIO1
Pulled-up input at reset
USART
SCK0 - SCK1
Serial Clock
I/O
TXD0 - TXD1
Transmit Data
I/O
RXD0 - RXD1
Receive Data
Input
RTS0 - RTS1
Request To Send
CTS0 - CTS1
Clear To Send
Input
DCD1
Data Carrier Detect
Input
DTR1
Data Terminal Ready
DSR1
Data Set Ready
Input
RI1
Ring Indicator
Input
Output
Output
Timer/Counter
TCLK0 - TCLK2 External Clock Inputs
Input
TIOA0 - TIOA2
Timer Counter I/O Line A
I/O
TIOB0 - TIOB2
Timer Counter I/O Line B
I/O
PWM Controller
PWM0 - PWM3 PWM Channels
Output
Serial Peripheral Interface
MISO
Master In Slave Out
I/O
MOSI
Master Out Slave In
I/O
SPCK
SPI Serial Clock
I/O
NPCS0
SPI Peripheral Chip Select 0
I/O
Low
Output
Low
NPCS1-NPCS3 SPI Peripheral Chip Select 1 to 3
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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Table 3-1.
Signal Name
Signal Description List (Continued)
Function
Type
Active
Level
Voltage
Reference Comments
Two-Wire Interface
TWD
Two-wire Serial Data
I/O
TWCK
Two-wire Serial Clock
I/O
Analog-to-Digital Converter
AD0-AD3
Analog Inputs
Input
ADTRG
ADC Trigger
Input
ADVREF
ADC Reference
VDDCORE
Analog
VDDCORE
Fast Flash Programming Interface
PGMEN0PGMEN2
Programming Enabling
Input
VDDIO1
PGMM0PGMM3
Programming Mode
Input
VDDIO1
PGMD0PGMD15
Programming Data
I/O
VDDIO1
PGMRDY
Programming Ready
Output
High
VDDIO1
PGMNVALID
Data Direction
Output
Low
VDDIO1
PGMNOE
Programming Read
Input
Low
VDDIO1
PGMCK
Programming Clock
Input
PGMNCMD
Programming Command
Input
VDDIO1
Low
VDDIO1
Segmented LCD Controller
COM[9:0]
Common Terminals
Output
VDDIO2
SEG[39:0]
Segment Terminals
Output
VDDIO2
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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4. Package and Pinout
The AT91SAM7L128/64 is available in:
• 20 x 14 mm 128-lead LQFP package with a 0.5 mm lead-pitch
• 10 x 10 mm 144-ball LFBGA package with a 0.8 mm pitch.
The part is also available in die delivery.
4.1
128-lead LQFP Package Outline
Figure 4-1 shows the orientation of the 128-lead LQFP package.
A detailed mechanical description is given in the Mechanical Characteristics section of the product datasheet.
Figure 4-1.
128-lead LQFP Package Outline (Top View)
102
65
103
64
128
39
1
38
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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4.2
128-lead LQFP Package Pinout
Table 4-1.
Pinout for 128-lead LQFP Package
1
TST
33
VDDLCD
65
PB21
97
PC10/PGMM3
2
VDDCORE
34
VDD3V6
66
PB22
98
PC11/PGMD0
3
PA0
35
CAPM2
67
PB23
99
PC12/PGMD1
4
PA1
36
CAPP2
68
GND
100
VDDCORE
5
PA2
37
CAPM1
69
ADVREF
101
PC13/PGMD2
6
PA3
38
CAPP1
70
AD3
102
PC14/PGMD3
7
PA4
39
VDDINLCD
71
AD2
103
PC15/PGMD4
8
PA5
40
GND
72
AD1
104
PC16/PGMD5
9
PA6
41
PB0
73
AD0
105
PC17/PGMD6
10
PA7
42
PB1
74
VDDOUT
106
PC18/PGMD7
11
PA8
43
PB2
75
VDDIO1
107
PC19/PGMD8
12
PA9
44
PB3
76
GND
108
PC20/PGMD9
13
PA10
45
PB4
77
PC28
109
PC21/PGMD10
14
GND
46
PB5
78
PC29
110
PC22/PGMD11
15
VDDIO2
47
PB6
79
NRST
111
PC23/PGMD12
16
PA11
48
PB7
80
ERASE
112
PC24/PGMD13
17
PA12
49
PB8
81
TCK
113
PC25/PGMD14
18
PA13
50
PB9
82
TMS
114
PC26/PGMD15
19
PA14
51
PB10
83
JTAGSEL
115
PC27
20
PA15
52
PB11
84
VDDCORE
116
TDI
21
PA16
53
PB12
85
VDDIO1
117
TDO
22
PA17
54
PB13
86
GND
118
FWUP
23
PA18
55
VDDIO2
87
PC0/PGMEN0
119
VDDIO1
24
PA19
56
GND
88
PC1/PGMEN1
120
GND
25
PA20
57
PB14
89
PC2/PGMEN2
121
PLLRC
26
PA21
58
PB15
90
PC3/PGMNCMD
122
PLLRCGND
27
PA22
59
PB16
91
PC4/PGMRDY
123
GND
28
VDDCORE
60
PB17
92
PC5/PGMNOE
124
VDDCORE
29
PA23
61
PB18
93
PC6/PGMNVALID
125
CLKIN
30
PA24
62
VDDCORE
94
PC7/PGMM0
126
NRSTB
31
PA25
63
PB19
95
PC8/PGMM1
127
XIN/PGMCK
32
VDDIO2
64
PB20
96
PC9/PGMM2
128
XOUT
SAM7L128/64 [DATASHEET]
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4.3
144-ball LFBGA Package Outline
Figure 4-2 shows the orientation of the 144-ball LFBGA package.
A detailed mechanical description is given in the Mechanical Characteristics section of the product datasheet.
Figure 4-2.
144-ball LFBGA Package Outline (Top View)
12
11
10
9
8
7
6
5
4
3
2
1
Ball A1
A B C D E F G H J K L M
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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4.4
144-ball LFBGA Pinout
Table 4-2.
SAM7L128/64 Pinout for 144-ball LFBGA Package
Pin
Signal Name
Pin
Signal Name
Pin
Signal Name
Pin
Signal Name
A1
XOUT
D1
PA6
G1
VDD3V6
K1
CAPM1
A2
XIN/PGCMK
D2
PA5
G2
PA17
K2
VDDIO2
A3
VDDCORE
D3
PA7
G3
PA16
K3
VDDIO2
A4
GND
D4
NC
G4
PA15
K4
PA25
A5
PLLRCGND
D5
PC26/PGMD15
G5
GND
K5
PB3
A6
PLLRC
D6
PC25/PGMD14
G6
GND
K6
PB10
A7
PC24/PGMD13
D7
PC21/PGMD10
G7
GND
K7
PB13
A8
PC23//PGMD12
D8
PC18/PGMD7
G8
VDDIO1
K8
PB15
A9
PC17/PGMD6
D9
PC6/PGMNVALID
G9
NRST
K9
PB20
A10
NC
D10
PC7/PGMM0
G10
TMS
K10
VDDCORE
A11
PC14
D11
PC4/PGMRDY
G11
ERASE
K11
VDDCORE
A12
PC12
D12
PC3/PGMNCMD
G12
VDDOUT
K12
AD2
B1
PA1
E1
VDDIO2
H1
CAPM2
L1
CAPP1
B2
PA0
E2
PA10
H2
PA22
L2
VDDIO2
B3
NRSTB
E3
PA9
H3
PA19
L3
VDDIO2
B4
TST
E4
PA11
H4
PA18
L4
PB4
B5
TDO
E5
PA8
H5
GND
L5
PB5
B6
PC27
E6
VDDIO1
H6
GND
L6
PB11
B7
GND
E7
VDDIO1
H7
GND
L7
PB12
B8
NC
E8
VDDIO1
H8
VDDCORE
L8
PB17
B9
PC20/PGMD9
E9
PC5/PGMNOE
H9
PC29
L9
PB19
B10
PC15/PGMD4
E10
PC0/PGMEN0
H10
VDDCORE
L10
PB22
B11
PC13/PGMD2
E11
PC2/PGMEN2
H11
PC28
L11
PB23
B12
PC11/PGMD0
E12
VDDCORE
H12
AD0
L12
AD3
C1
PA3
F1
VDDLCD
J1
CAPP2
M1
VDDINLCD
C2
PA4
F2
PA13
J2
PA23
M2
PB0
C3
PA2
F3
PA14
J3
PA24
M3
PB1
C4
CLKIN
F4
PA12
J4
PA21
M4
PB2
C5
FWUP
F5
GND
J5
PA20
M5
PB6
C6
TDI
F6
GND
J6
PB8
M6
PB7
C7
PC22/PGMD11
F7
GND
J7
PB9
M7
VDDIO2
C8
PC19/PGMD8
F8
VDDIO1
J8
PB14
M8
PB16
C9
PC16/PGMD5
F9
TCK
J9
VDDCORE
M9
PB18
C10
PC9/PGMM2
F10
JTAGSEL
J10
VDDCORE
M10
PB21
C11
PC10/PGMM3
F11
PC1/PGMEN1
J11
VDDCORE
M11
GND
C12
PC8/PGMM1
F12
VDDIO1
J12
AD1
M12
ADVREF
SAM7L128/64 [DATASHEET]
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5. Power Considerations
5.1
Power Supplies
The AT91SAM7L128/64 has six types of power supply pins and integrates a voltage regulator, allowing the device
to be supplied with only one voltage. The six power supply pin types are:
• VDDOUT pin. It is the output of the voltage regulator. Output voltage can be programmed from 1.55V to 1.80V
by steps of 100 mV.
• VDDIO1 pin. It powers the voltage regulator input and all the PIOC IO lines (1.8V-3.6V). VDDIO1 voltage must
be above 2.2V to allow the chip to start-up (POR threshold).
• VDDIO2 pin. It powers the PIOA and PIOB I/O lines (1.8V-3.6V). It is also the output of the LCD voltage
regulator. The output voltage can be programmed from 2.4V to 3.4V with 16 steps.
• VDDCORE pin. It powers the logic of the device, the PLL, the 2 MHz Fast RC oscillator, the ADC and the Flash
memory. It must be connected to the VDDOUT pin with a decoupling capacitor.
• VDDINLCD pin. It powers the charge pump which can be used as LCD Regulator power supply. Voltage ranges
from 1.8V to 3.6V.
No separate ground pins are provided for the different power supplies. Only GND pins are provided and should be
connected as shortly as possible to the system ground plane.
5.2
Low Power Modes
The various low power modes of the AT91SAM7L128/64 are described below.
5.2.1
Off (Power Down) Mode
In off (power down) mode, the entire chip is shut down. Only a low level on the FWUP pin can wake up the
AT91SAM7L128/64 (by a push-button for example). Internally, except for the FWUP pin through VDDIO1, none of
the chip is supplied.
Once the internal main power switch has been activated by FWUP, the 32 kHz RC oscillator and the Supply Controller are supplied, then the core and peripherals are reset and the AT91SAM7L128/64 enters in active mode.
Refer to the System Controller Block Diagram, Figure 9-1 on page 29.
At first power-up, if FWUP is tied high, the device enters off mode. The PIOA and PIOB pins’ states are undefined.
PIOC and NRST pins are initialized as high impedance inputs.
Once the device enters active mode, the core and the parallel input/output controller are reset. Then, if the chip
enters off mode, PIOA and PIOB pins are configured as inputs with pull-ups and PIOC pins as high impedance
inputs.
Current consumption in this mode is typically 100 nA.
5.2.2
Backup Mode
In backup mode, the supply controller, the zero-power power-on reset and the 32 kHz oscillator (software selectable internal RC or external crystal) remain running. The voltage regulator and the core are switched off.
Prior to entering this mode, the RTC, the backup SRAM, the brownout detector, the charge pump, the LCD voltage
regulator and the LCD controller can be set on or off separately.
Table 5-1 on page 13 shows an example of backup mode with backup SRAM and RTC running.
When entering this mode, all PIO pins keep their previous states, they are reinitialized as inputs with pull-ups at
wake-up.
The AT91SAM7L128/64 can be awakened from this mode through the FWUP pin, an event on WUP0-15 pins, or
an RTC alarm or brownout event.
Current consumption is 3.5 µA typical without the LCD controller running.
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5.2.3
Wait Mode
In wait mode, the voltage regulator must be set in deep mode. Voltage regulator output voltage should be set at a
minimum voltage to decrease leakage in the digital core. No clock is running in the core. From this mode, a fast
start-up is available (refer to Section 5.4 ”Fast Start-Up”).
In this mode, all PIO pins keep their previous states.
5.2.4
Idle Mode
The processor is in idle mode which means that the processor has no clock but the Master clock (MCK) remains
running. The processor can also be wakened by an IRQ or FIQ.
5.2.5
Active Mode
The total dynamic power consumption is less than 30 mA at full speed (36 MHz) when running out of the Flash.
The power management controller can be used to adapt the frequency and the regulator output voltage can be
adjusted to optimize power consumption.
5.2.6
Low Power Mode Summary Table
The modes detailed above are the main modes. In off mode, no options are available but once the shutdown controller is set to on, each part can be set to on, or off, separately and more modes can be active. The table below
shows a summary of the configurations of the low power modes.
Table 5-1.
Mode
Low Power Mode Configuration Summary
FWUP
Off Mode
SUPC,
32 kHz
Oscillator,
POR
Backup
RTC
SRAM
Regulator
(Deep Mode)
Core
X
Potential Wake-up
Sources
Consumption(2)(3)
FWUP pin
Wake-up Time(1)
100 nA typ
< 5 ms
3.5 µA typ
< 0.5 ms
FWUP pin
Backup Mode
(with SRAM and
RTC)
X
X
X
WUP0-15 pins
X
BOD alarm
RTC alarm
Wait Mode (with
SRAM and RTC)
X
X
Idle Mode
X
X
Notes:
X
X
X
X
X
X
X
Fast start-up through
9 µA typ
WUP0-15 pins
< 2 µs (in case of
fast start-up)
IRQs
(4)
(4)
FIQ
1. When considering wake-up time, the time required to start the PLL is not taken into account. Once started, the
AT91SAM7128/L64 works with the 2 MHz Fast RC oscillator. The user has to add the PLL start-up time if it is needed in the
system. The wake-up time is defined as the time taken for wake up until the first instruction is fetched.
2. The external LCD current consumption and the external loads on PIOs are not taken into account in the calculation.
3. BOD current consumption is not included.
4. Depends on MCK frequency.
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5.3
Wake-up Sources
The wake-up events allow the device to exit from backup mode. When a wake-up event is detected, the supply
controller performs a sequence which automatically reenables the voltage regulator and the backup SRAM power
supply, if it is not already enabled.
Figure 5-1.
Wake Up Sources
BODEN
brown_out
RTCEN
rtc_alarm
Core
Supply
Restart
FWUPDBC
SLCK
FWUPEN
FWUP
Falling
Edge
Detector
WKUPT0
WKUP0
WKUPIS0
WKUPDBC
WKUPEN1
WKUPIS1
SLCK
WKUPS
Debouncer
Falling/Rising
Edge
Detector
WKUPT15
WKUP15
WKUPEN0
Falling/Rising
Edge
Detector
WKUPT1
WKUP1
FWUP
Debouncer
WKUPEN15
WKUPIS15
Falling/Rising
Edge
Detector
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5.4
Fast Start-Up
The SAM7L128/64 allows the processor to restart in a few microseconds while the processor is in wait mode. A
fast start up can occur upon detection of a low level on one of the 16 wake-up inputs.
The fast restart circuitry, as shown in Figure 5-2, is fully asynchronous and provides a fast start-up signal to the
power management controller. As soon as the fast start-up signal is asserted, the PMC automatically restarts the
embedded 2 MHz Fast RC oscillator, switches the master clock on this 2 MHz clock and reenables the processor
clock, if it is disabled.
Figure 5-2.
Fast Start-Up Circuitry
FSTT0
WKUP0
FSTT1
fast_restart
WKUP1
FSTT15
WKUP15
5.5
Voltage Regulator
The AT91SAM7L128/64 embeds a voltage regulator that is managed by the supply controller. This internal regulator is only intended to supply the internal core of AT91SAM7L128/64. It features three different operating modes:
• In normal mode, the voltage regulator consumes less than 30 µA static current and draws 60 mA of output
current.
• In deep mode, the current consumption of the voltage regulator is less than 8.5 µA. It can draw up to 1 mA of
output current. The default output voltage is 1.80V and the start-up time to reach normal mode is inferior to 400
µs.
• In shutdown mode, the voltage regulator consumes less than 1 µA while its output is driven internally to GND.
The default output voltage is 1.80V and the start-up time to reach normal mode is inferior to 400 µs.
Furthermore, in normal and deep modes, the regulator output voltage can be programmed by software with 4 different steps within the range of 1.55V to 1.80V. The default output voltage is 1.80V in both normal and deep
modes. The voltage regulator can regulate 1.80V output voltage as long as the input voltage is above 1.95V. Below
1.95V input voltage, the output voltage remains above 1.65V.
Output voltage adjusting ability allows current consumption reduction on VDDCORE and also enables programming a lower voltage when the input voltage is lower than 1.95V.
At 1.55V, the Flash is still functional but with slower read access time. Programming or erasing the Flash is not
possible under these conditions. MCK maximum frequency is 25 MHz with VDDCORE at 1.55V (1.45V minimum).
The regulator has an indicator that can be used by the software to show that the output voltage has the correct
value (output voltage has reached at least 80% of the typical voltage). This flag is used by the supply controller.
This feature is only possible when the voltage regulator is in normal mode at 1.80V.
Adequate output supply decoupling is mandatory for VDDOUT in order to reduce ripple and avoid oscillations. One
external 2.2 µF (or 3.3 µF) X7R capacitor must be connected between VDDOUT and GND.
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Adequate input supply decoupling is mandatory for VDDIO1 in order to improve startup stability and reduce source
voltage drop. The input decoupling capacitor should be placed close to the chip. For example, two capacitors can
be used in parallel, 100 nF NPO and 4.7 µF X7R.
5.6
LCD Power Supply
The AT91SAM7L128/64 embeds an on-chip LCD power supply comprising a regulated charge pump and an
adjustable voltage regulator.
The regulated charge pump output delivers 3.6V as long as its input is supplied between 1.8V and 3.6V. The regulated charge pump only requires two external flying capacitors and one external tank capacitor to operate.
Adequate input supply decoupling is mandatory for VDDINLCD in order to improve startup stability and reduce
source voltage drop. The input decoupling capacitor should be placed close to the chip.
Current consumption of the charge pump and LCD bias when active is 350 µA (max case).
The regulated charge pump can be used to supply the LCD voltage regulator or as a 3.6V voltage reference delivering up to 4 mA.
The LCD voltage regulator output voltage is software selectable from 2.4V to 3.4V with 16 levels. Its input should
be supplied in the range of 2.5 to 3.6V. The LCD voltage regulator can be supplied by the regulated charge pump
output or by an external supply.
When the LCD voltage regulator is not used, its output must be connected to an external source in order to supply
the PIOA and PIOB I/O lines.
Figure 5-3 below shows the typical schematics needed:
Figure 5-3.
The Charge Pump Supplies the LCD Regulator
R = 10Ω VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
External supply
CAPP2
VDDINLCD
CAPM2
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Figure 5-4.
The LCD Regulator is Externally Supplied
R = 10Ω
External supply
VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
If the charge pump is not needed, the user can apply an external voltage. See Figure 5-5 below:
Figure 5-5.
The Charge Pump and the LCD Regulator are Not Used
External supply
VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
Please note that in this topology, switching time enhancement buffers are not available. (Refer Section 10.13 ”Segment LCD Controller”.)
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5.7
Typical Powering Schematics
The AT91SAM7L128/64 supports a 1.8V-3.6V single supply mode. The internal regulator input connected to the
source and its output feeds VDDCORE. Figure 5-6 shows the power schematics to be used.
Figure 5-6.
3.3V System Single Power Supply Schematic
R = 10Ω
VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
Main Supply (1.8V-3.6V)
VDDIO1
Voltage
Regulator
VDDOUT
VDDCORE
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6. I/O Line Considerations
6.1
JTAG Port Pins
TMS, TDI and TCK are schmitt trigger inputs. TMS, TDI and TCK do not integrate a pull-up resistor.
TDO is an output, driven at up to VDDIO, and has no pull-up resistor.
The JTAGSEL pin is used to select the JTAG boundary scan when asserted at a high level. The JTAGSEL pin integrates a permanent pull-down resistor of about 15 kΩ to GND, so that it can be left unconnected for normal
operations.
6.2
Test Pin
The TST pin is used for manufacturing test or fast programming mode of the AT91SAM7L128/64 when asserted
high. The TST pin integrates a permanent pull-down resistor of about 15 kΩ to GND, so that it can be left unconnected for normal operations.
To enter fast programming mode, the TST and CLKIN pins must be tied high while FWUP is tied low.
6.3
NRST Pin
The NRST pin is bidirectional. It is handled by the on-chip reset controller and can be driven low to provide a reset
signal to the external components or asserted low externally to reset the microcontroller. There is no constraint on
the length of the reset pulse and the reset controller can guarantee a minimum pulse length.
The NRST pin integrates a permanent pull-up resistor to VDDIO1 of about 100 kΩ.
6.4
NRSTB Pin
The NRSTB pin is input only and enables asynchronous reset of the AT91SAM7L128/64 when asserted low. The
NRSTB pin integrates a permanent pull-up resistor of about 15 kΩ. This allows connection of a simple push button
on the NRBST pin as a system-user reset.
In all modes, this pin will reset the chip. It can be used as an external system reset source.
In harsh environments, it is recommended to add an external capacitor (10 nF) between NRSTB and VDDIO1.
NRSTB pin must not be connected to VDDIO1. There must not be an external pull-up on NRSTB.
6.5
ERASE Pin
The ERASE pin is used to reinitialize the Flash content and some of its NVM bits. It integrates a permanent pulldown resistor of about 15 kΩ to GND, so that it can be left unconnected for normal operations.
This pin is debounced by SCLK to improve the glitch tolerance. When the ERASE pin is tied high during less than
100 ms, it is not taken into account. The pin must be tied high during more than 220 ms to perform the reinitialization of the Flash.
6.6
PIO Controller Lines
All the I/O lines; PA0 to PA25, PB0 to PB23, PC0 to PC29 integrate a programmable pull-up resistor. Programming
of this pull-up resistor is performed independently for each I/O line through the PIO controllers. All I/Os have input
schmitt triggers.
Typical pull-up value is 100 kΩ.
Maximum frequency is:
• 36 MHz under 25 pF of load on PIOC
• 36 MHz under 25 pF of load on PIOA and PIOB
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6.7
I/O Line Current Drawing
The PIO lines PC5 to PC8 are high-drive current capable. Each of these I/O lines can drive up to 4 mA permanently. The remaining I/O lines can draw only 2 mA.
Each I/O is designed to achieve very small leakage. However, the total current drawn by all the I/O lines cannot
exceed 150 mA.
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7. Processor and Architecture
7.1
ARM7TDMI Processor
• RISC processor based on ARMv4T Von Neumann Architecture
– Runs at up to 36 MHz, providing 0.9 MIPS/MHz
• Two instruction sets
– ARM® high-performance 32-bit instruction set
– Thumb high code density 16-bit instruction set
• Three-stage pipeline architecture
– Instruction Fetch (F)
– Instruction Decode (D)
– Execute (E)
7.2
Debug and Test Features
• Integrated embedded in-circuit emulator
– Two watchpoint units
– Test access port accessible through a JTAG protocol
– Debug communication channel
• Debug Unit
– Two-pin UART
– Debug communication channel interrupt handling
– Chip ID Register
• IEEE1149.1 JTAG Boundary-scan on all digital pins
7.3
Memory Controller
• Programmable Bus Arbiter
– Handles requests from the ARM7TDMI and the Peripheral DMA Controller
• Address decoder provides selection signals for
– Five internal 1 Mbyte memory areas
– One 256 Mbyte embedded peripheral area
• Abort Status Registers
– Source, Type and all parameters of the access leading to an abort are saved
– Facilitates debug by detection of bad pointers
• Misalignment Detector
– Alignment checking of all data accesses
– Abort generation in case of misalignment
• Remap Command
– Remaps the SRAM in place of the embedded non-volatile memory
– Allows handling of dynamic exception vectors
– Peripheral protection against write and/or user access
• Enhanced Embedded Flash Controller
– Embedded Flash interface, up to three programmable wait states
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– Prefetch buffer, buffering and anticipating the 16-bit requests, reducing the required wait states
– Key-protected program, erase and lock/unlock sequencer
– Single command for erasing, programming and locking operations
– Interrupt generation in case of forbidden operation
7.4
Peripheral DMA Controller
• Handles data transfer between peripherals and memories
• Eleven channels
– Two for each USART
– Two for the Debug Unit
– Two for the Serial Peripheral Interface
– Two for the Two Wire Interface
– One for the Analog-to-digital Converter
• Low bus arbitration overhead
– One Master Clock cycle needed for a transfer from memory to peripheral
– Two Master Clock cycles needed for a transfer from peripheral to memory
• Next Pointer management for reducing interrupt latency requirements
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8. Memories
• 128 Kbytes of Flash Memory (AT91SAM7L128)
– Single plane
– One bank of 512 pages of 256 bytes
– Fast access time, 15 MHz single-cycle access in Worst Case conditions
– Page programming time: 4.6 ms, including page auto-erase
– Page programming without auto-erase: 2.3 ms
– Full chip erase time: 10 ms
– 10,000 write cycles, 10-year data retention capability
– 16 lock bits, each protecting 16 lock regions of 32 pages
– Protection Mode to secure contents of the Flash
• 64 Kbytes of Flash Memory (AT91SAM7L64)
– Single plane
– One bank of 256 pages of 256 bytes
– Fast access time, 15 MHz single-cycle access in Worst Case conditions
– Page programming time: 4.6 ms, including page auto-erase
– Page programming without auto-erase: 2.3 ms
– Full chip erase time: 10 ms
– 10,000 write cycles, 10-year data retention capability
– 8 lock bits, each protecting 8 lock regions of 32 pages
– Protection Mode to secure contents of the Flash
• 6 Kbytes of Fast SRAM
– Single-cycle access at full speed
– 2 Kbytes of Backup SRAM
– 4 Kbytes of Core SRAM
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Figure 8-1.
Memory Mapping
Internal Memory Mapping
0x0000 0000
Note:
(1) Can be ROM, Flash or SRAM
depending on GPNVM1 and REMAP
Boot Memory (1)
1 MBytes
0x000F FFFF
0x0010 0000
0x001F FFFF
0x0020 0000
0x002F FFFF
0x0030 0000
Flash before Remap
SRAM after Remap
Internal Flash
1 MBytes
Internal SRAM
(Core) 4 kbytes
1 MBytes
Internal SRAM
(Back-up) 2 kbytes
0x003F FFFF
0x0040 0000
Address Memory Space
0x0000 0000
Internal ROM
System Controller Mapping
0x004F FFFF
0x0050 0000
Internal Memories
0xFFFF F000
256 MBytes
Reserved
0x0FFF FFFF
0x1000 0000
0x0FFF FFFF
Reserved
0xFFF9 FFFF
0xFFFA 0000
0xFFFA 3FFF
0xFFFA 4000
0xFFFB 3FFF
0xFFFB 4000
0xFFFB 7FFF
0xFFFB 8000
0xFFFB BFFF
0xFFFB C000
0xEFFF FFFF
0xF000 0000
0xFFFB FFFF
0xFFFC 0000
0xFFFC 3FFF
0xFFFC 4000
Internal Peripherals
0xFFFF FFFF
256M Bytes
TC0, TC1, TC2 16 Kbytes
SLCDC
16 Kbytes
TWI
16 Kbytes
Reserved
0xFFFE 3FFF
0xFFFE 4000
0xFFFF FFFF
512 Bytes/
128 registers
PIOC
512 Bytes/
128 registers
PMC
USART1
16 Kbytes
0xFFFF FD0F
0xFFFF FD10
0xFFFF FD2F
0xFFFF FD30
16 Kbytes
Reserved
ADC
16 Kbytes
Reserved
SPI
Reserved
0xFFFF EFFF
0xFFFF F000
PIOB
Reserved
0xFFFF FCFF
0xFFFF FD00
PWMC
0xFFFD FFFF
0xFFFE 0000
512 Bytes/
128 registers
0xFFFF FBFF
0xFFFF FC00
16 Kbytes
Reserved
0xFFFD BFFF
0xFFFD C000
PIOA
0xFFFF F9FF
0xFFFF FA00
USART0
0xFFFC BFFF
0xFFFC C000
0xFFFD 7FFF
0xFFFD 8000
512 Bytes/
128 registers
0xFFFF F7FF
0xFFFF F800
Reserved
0xFFFC 7FFF
0xFFFC 8000
0xFFFC FFFF
0xFFFD 0000
DBGU
0xFFFF F1FF
0xFFFF F200
0xFFFF F5FF
0xFFFF F600
Peripheral Mapping
14 x 256 MBytes
3,584 MBytes
512 Bytes/
128 registers
0xFFFF F3FF
0xFFFF F400
0xF000 0000
Undefined
(Abort)
253 MBytes
AIC
0xFFFF FD3F
0xFFFF FD40
0xFFFF FD4F
0xFFFF FD50
0xFFFF FD5F
0xFFFF FD60
0xFFFF FD7F
0xFFFF FD80
RSTC
SUPC
256 Bytes/
64 registers
16 Bytes/
4 registers
32 Bytes/
8 registers
Reserved
PIT
WDT
RTC
16 Bytes/
4 registers
16 Bytes/
4 registers
32 Bytes/
8 registers
Reserved
16 Kbytes
0xFFFF FEFF
0xFFFF FF00
MC
SYSC
256 Bytes/
64 registers
0xFFFF FFFF
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8.1
8.1.1
8.1.1.1
Embedded Memories
Internal Memories
Internal SRAM
The AT91SAM7L128/64 embeds a high-speed 4-Kbyte SRAM bank and a 2-Kbyte backup SRAM bank. The
backup SRAM is directly supplied on 1.8V-3.6V supply domain.
The 4-Kbyte Core SRAM is supplied by VDDCORE which is connected to the output of the voltage regulator.
After reset and until the Remap Command is performed, the 4-Kbyte Core SRAM is only accessible at address
0x0020 0000. The 2-Kbyte Backup SRAM is accessible at address 0x0030 0000.
After remap, the 4-Kbyte Core SRAM also becomes available at address 0x0.
The user can see the 6 Kbytes of SRAM contiguously at address 0x002F F000.
8.1.1.2
Internal ROM
The AT91SAM7L128/64 embeds an Internal ROM. The ROM is always mapped at address 0x0040 0000. The
ROM contains the FFPI and SAM-BA program.
ROM size is 12 Kbytes.
8.1.1.3
Internal Flash
• The AT91SAM7L128 features one bank of 128 Kbytes of Flash.
• The AT91SAM7L64 features one bank of 64 Kbytes of Flash.
At any time, the Flash is mapped to address 0x0010 0000.
A general purpose NVM (GPNVM1) bit is used to boot either on the ROM (default) or from the Flash.
This GPNVM1 bit can be cleared or set respectively through the commands “Clear General-purpose NVM Bit” and
“Set General-purpose NVM Bit” of the EEFC User Interface.
Setting the GPNVM Bit 1 selects the boot from the Flash, clearing it selects the boot from the ROM. Asserting
ERASE clears the GPNVM Bit 1 and thus selects the boot from the ROM by default.
Figure 8-2.
Internal Memory Mapping with GPNVM Bit 1 = 0 (default)
0x0000 0000
ROM Before Remap
0x000F FFFF Core SRAM (4 Kbytes) After Remap
1 Mbyte
0x0010 0000
Internal FLASH
1 Mbyte
Internal SRAM (Core)
4 Kbytes
1 Mbyte
Internal SRAM (Backup)
2 Kbytes
1 Mbyte
Internal ROM
12 Kbytes
1 Mbyte
0x001F FFFF
0x0020 0000
256 Mbytes
0x002F FFFF
0x0030 0000
0x003F FFFF
0x0040 0000
0x004F FFFF
0x0050 0000
Undefined Areas
(Abort)
251 Mbytes
0x0FFF FFFF
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Figure 8-3.
Internal Memory Mapping with GPNVM Bit 1 = 1
0x0000 0000
0x000F FFFF
Flash Before Remap
Core SRAM (4 Kbytes) After Remap
1 Mbyte
Internal FLASH
1 Mbyte
Internal SRAM (Core)
4 Kbytes
1 Mbyte
Internal SRAM (Backup)
2 Kbytes
1 Mbyte
Internal ROM
12 Kbytes
1 Mbyte
0x0010 0000
0x001F FFFF
0x0020 0000
0x002F FFFF
0x0030 0000
256 Mbytes
0x003F FFFF
0x0040 0000
0x004F FFFF
0x0050 0000
251 Mbytes
Undefined Areas
(Abort)
0x0FFF FFFF
8.1.2
8.1.2.1
Embedded Flash
Flash Overview
• The Flash of the AT91SAM7L128 is organized in 512 pages (single plane) of 256 bytes.
• The Flash of the AT91SAM7L64 is organized in 256 pages (single plane) of 256 bytes.
The Flash contains a 128-byte write buffer, accessible through a 32-bit interface.
8.1.2.2
Flash Power Supply
The Flash is supplied by VDDCORE through a power switch controlled by the Supply Controller.
8.1.2.3
Enhanced Embedded Flash Controller
The Enhanced Embedded Flash Controller (EEFC) manages accesses performed by the masters of the system. It
enables reading the Flash and writing the write buffer. It also contains a User Interface, mapped within the Memory
Controller on the APB.
The Enhanced Embedded Flash Controller ensures the interface of the Flash block with the 32-bit internal bus. Its
128-bit wide memory interface increases performance. It also manages the programming, erasing, locking and
unlocking sequences of the Flash using a full set of commands. One of the commands returns the embedded
Flash descriptor definition that informs the system about the Flash organization, thus making the software generic.
8.1.2.4
Lock Regions
The AT91SAM7L128 Embedded Flash Controller manages 16 lock bits to protect 16 regions of the flash against
inadvertent flash erasing or programming commands. The AT91SAM7L128 contains 16 lock regions and each lock
region contains 32 pages of 256 bytes. Each lock region has a size of 8 Kbytes.
The AT91SAM7L64 Embedded Flash Controller manages 8 lock bits to protect 8 regions of the flash against inadvertent flash erasing or programming commands. The AT91SAM7L64 contains 8 lock regions and each lock region
contains 32 pages of 256 bytes. Each lock region has a size of 8 Kbytes.
If a locked-region’s erase or program command occurs, the command is aborted and the EEFC triggers an
interrupt.
The 16 NVM bits are software programmable through the EEFC User Interface. The command “Set Lock Bit”
enables the protection. The command “Clear Lock Bit” unlocks the lock region.
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Asserting the ERASE pin clears the lock bits, thus unlocking the entire Flash.
8.1.2.5
Security Bit Feature
The AT91SAM7L128/64 features a security bit, based on a specific General Purpose NVM bit (GPNVM bit 0).
When the security is enabled, any access to the Flash, either through the ICE interface or through the Fast Flash
Programming Interface, is forbidden. This ensures the confidentiality of the code programmed in the Flash.
This security bit can only be enabled, through the command “Set General Purpose NVM Bit 0” of the EEFC User
Interface. Disabling the security bit can only be achieved by asserting the ERASE pin at 1, and after a full Flash
erase is performed. When the security bit is deactivated, all accesses to the Flash are permitted.
It is important to note that the assertion of the ERASE pin should always be longer than 200 ms.
As the ERASE pin integrates a permanent pull-down, it can be left unconnected during normal operation. However,
it is safer to connect it directly to GND for the final application.
8.1.2.6
Calibration Bits
NVM bits are used to calibrate the brownout detector and the voltage regulator. These bits are factory configured
and cannot be changed by the user. The ERASE pin has no effect on the calibration bits.
8.1.2.7
GPNVM Bits
The AT91SAM7L128/64 features two GPNVM bits that can be cleared or set respectively through the commands
“Clear GPNVM Bit” and “Set GPNVM Bit” of the EEFC User Interface..
Table 8-1.
8.1.3
General-purpose Non-volatile Memory Bits
GPNVMBit[#]
Function
0
Security bit
1
Boot mode selection
Fast Flash Programming Interface
The Fast Flash Programming Interface allows programming the device through either a serial JTAG interface or
through a multiplexed fully-handshaked parallel port. It allows gang programming with market-standard industrial
programmers.
The FFPI supports read, page program, page erase, full erase, lock, unlock and protect commands.
The Fast Flash Programming Interface is enabled and the Fast Programming Mode is entered when TST and
CLKIN are tied high while FWUP is tied low.
• The Flash of the AT91SAM7L128 is organized in 512 pages of 256 bytes (single plane).
• The Flash of the AT91SAM7L64 is organized in 256 pages of 256 bytes (single plane).
The Flash contains a 128-byte write buffer, accessible through a 32-bit interface.
8.1.4
SAM-BA Boot
The SAM-BA Boot is a default Boot Program which provides an easy way to program in-situ the on-chip Flash
memory.
The SAM-BA Boot Assistant supports serial communication via the DBGU.
The SAM-BA Boot provides an interface with SAM-BA Graphic User Interface (GUI).
The SAM-BA Boot resides in ROM and is mapped at address 0x0 when GPNVM bit 1 is set to 0.
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9. System Controller
The System Controller manages all vital blocks of the microcontroller, interrupts, clocks, power, time, debug and
reset.
The System Controller Block Diagram is shown in Figure 9-1 on page 29.
9.1
System Controller Mapping
The System Controller peripherals are all mapped to the highest 4 Kbytes of address space, between addresses
0xFFFF F000 and 0xFFFF FFFF. Figure 8-1 on page 24 shows the mapping of the System Controller. Note that
the Memory Controller configuration user interface is also mapped within this address space
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Figure 9-1.
System Controller Block Diagram
VDDIO1
FWUP
vr_on
vr_mode
vr_ok
Software Controlled
Voltage Regulator
VDDOUT
supply_on
Supply
Controller
NRSTB
Zero-Power
Power-on Reset
CAPM1-CAPP1
lcd_mode
LCD
Charge
Pump
lcd_out
bod_on
Brownout
Detector
CAPM2-CAPP2
VDDLCD
brown_out
VDDLCD
LCD Power Supply
WKUP0 - WKUP15
lcd_nreset
rtc_on
Segment
LCD
Controller
lcd_eof
SLCK
SEG0 - SEG39
COM0 - COM7
rtc_nreset
RTC
SLCK
rtc_alarm
PIOA - PIOB
osc32k_xtal_en
core_nreset
XIN
XOUT
Xtal 32 kHz
Oscillator
Embedded
32 kHz RC
Oscillator
ADVREF
ADC
osc32k_sel
AD0 - AD3
Slow Clock
SLCK
PIOC
osc32k_rc_en
sram_on
SRAM
4 kbytes
SRAM 2 Kbytes
Peripherals
Backup Power Supply
core_nreset
Reset
Controller
NRST
proc_nreset
periph_nreset
ice_nreset
Memory
Controller
VDDCORE
Peripheral
Bridge
ARM7TDMI
FSTT0 - FSTT15
SLCK
Embedded
2 MHz RC
Oscillator
Main Clock
MAINCK
FCIN
SLCK
Power
Management
Controller
Master Clock
MCK
Periodic
Interval
Timer
PLLCK
PLL
PLLRC
Flash
SLCK
Watchdog
Timer
Core Power Supply
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9.2
Supply Controller (SUPC)
The Supply Controller controls the power supplies of each section of the product:
• the processor and the peripherals
• the Flash memory
• the backup SRAM
• the LCD controller, the charge pump and the LCD voltage regulator
• the Real Time Clock
The Supply Controller has its own reset circuitry and is clocked by the 32 kHz Slow clock generator.
The reset circuitry is based on the NRSTB pin, a zero-power power-on reset cell and a brownout detector cell. The
zero-power power-on reset allows the Supply Controller to start properly, while the software-programmable brownout detector allows detection of either a battery discharge or main voltage loss.
The Slow Clock generator is based on a 32 kHz crystal oscillator and an embedded 32 kHz RC oscillator. The Slow
Clock defaults to the RC oscillator, but the software can enable the crystal oscillator and select it as the Slow Clock
source.
The Supply Controller starts up the device by sequentially enabling the internal power switches and the Voltage
Regulator, then it generates the proper reset signals to the core power supply.
It also enables to set the system in different low power modes and to wake it up from a wide range of events.
9.3
Reset Controller
• Based on one power-on reset cell and a brownout detector
• Status of the last reset; either power-up reset, software reset, user reset, watchdog reset, brownout reset
• Controls the internal resets and the NRST pin output
• Allows to shape a signal on the NRST line, guaranteeing that the length of the pulse meets any requirement.
9.3.1
Brownout Detector (BOD) and Power-on Reset
The AT91SAM7L128/64 embeds one zero-power power-on reset and a brownout detection circuit. Both monitor
VDDIO1.
The zero-power power-on reset circuit is always active. It provides an internal reset signal to the
AT91SAM7L128/64 for power-on and power-off operations and ensures a proper reset for the Supply Controller.
The brownout detection circuit is disabled by default and can be enabled by software. It monitors VDDIO1.
The brownout detection circuit is factory calibrated.
The threshold is programmable via software. It can be selected from 1.9V to 3.4V with 100 mV steps. It can be programmed to generate either a wake-up alarm or a reset.
It can be used to wake up the chip from backup mode if the supply drops below a selected threshold (to warn the
end user about a discharged battery for example) and to reset the chip when the voltage is too low.
BOD current consumption is 25 µA, typically.
To decrease current consumption, the software can disable the brownout detector, especially in low-power mode.
The software can also configure the BOD in “switched” mode. In this mode, an internal state machine switches on
and off periodically and stores the output of the BOD.
This decreases the current consumption (inferior to 2 µA) while the detection is still active. This feature is suitable
in low-power mode where voltage detection is still needed.
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9.4
Clock Generator
The clock generator embeds one low-power RC oscillator, one fast RC oscillator, one crystal oscillator and one
PLL with the following characteristics:
• RC Oscillator ranges between 22 kHz and 42 kHz
• Fast RC Oscillator ranges between 1.5 MHz and 2.5 MHz
• Crystal Oscillator at 32 kHz (can be bypassed)
• PLL output ranges between 18 MHz and 47 MHz
It provides SLCK, MAINCK and PLLCK.
The Supply Controller selects between the internal RC oscillator and the 32 kHz crystal oscillator. The unused
oscillator is disabled so that power consumption is optimized.
The 2 MHz Fast RC oscillator is the default selected clock (MAINCK) which is used at start-up . The user can
select an external clock (CLKIN) through software.
The PLL needs an external RC filter and starts up in a very short time (inferior to 1 ms).
Figure 9-2.
Clock Generator Block Diagram
Clock Generator
MCK_SEL
CLKIN
Main Clock
MAINCK
Embedded
2 MHz RC
Oscillator
OSCSEL
Embedded
32 kHz RC
Oscillator
Slow Clock
SLCK
XIN
Xtal 32 kHz
Oscillator
XOUT
SLCK
PLL and
Divider
PLL Clock
PLLCK
PLLRC
Status
Control
Power
Management
Controller
9.5
Power Management Controller
The Power Management Controller uses the clock generator outputs to provide:
• The Processor Clock PCK
• The Master Clock MCK
• All the peripheral clocks, independently controllable
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• Three programmable clock outputs PCKx
The Master Clock (MCK) is programmable from a few hundred Hz to the maximum operating frequency of the
device.
The Processor Clock (PCK) switches off when entering processor idle mode, thus allowing reduced power consumption while waiting for an interrupt.
The LCD Controller clock is SCLK.
Figure 9-3.
Power Management Controller Block Diagram
Processor
Clock
Controller
Master Clock Controller
SLCK
MAINCK
PLLCK
PCK
int
Idle Mode
Prescaler
/1,/2,/4,...,/64
MCK
Peripherals
Clock Controller
periph_clk[2..14]
ON/OFF
Programmable Clock Controller
SLCK
MAINCK
PLLCK
9.6
Prescaler
/1,/2,/4,...,/64
pck[0..2]
Advanced Interrupt Controller
• Controls the interrupt lines (nIRQ and nFIQ) of an ARM Processor
• Individually maskable and vectored interrupt sources
– Source 0 is reserved for the Fast Interrupt Input (FIQ)
– Source 1 is reserved for system peripherals (RTC, PIT, EFC, PMC, DBGU, etc.)
– Other sources control the peripheral interrupts or external interrupts
– Programmable edge-triggered or level-sensitive internal sources
– Programmable positive/negative edge-triggered or high/low level-sensitive external sources
• 8-level Priority Controller
– Drives the normal interrupt nIRQ of the processor
– Handles priority of the interrupt sources
– Higher priority interrupts can be served during service of lower priority interrupt
• Vectoring
– Optimizes interrupt service routine branch and execution
– One 32-bit vector register per interrupt source
– Interrupt vector register reads the corresponding current interrupt vector
• Protect Mode
– Easy debugging by preventing automatic operations
• Fast Forcing
– Permits redirecting any interrupt source on the fast interrupt
• General Interrupt Mask
– Provides processor synchronization on events without triggering an interrupt
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9.7
Debug Unit
• Comprises:
– One two-pin UART
– One Interface for the Debug Communication Channel (DCC) support
– One set of Chip ID Registers
– One Interface providing ICE Access Prevention
• Two-pin UART
– USART-compatible User Interface
– Programmable Baud Rate Generator
– Parity, Framing and Overrun Error
– Automatic Echo, Local Loopback and Remote Loopback Channel Modes
• Debug Communication Channel Support
– Offers visibility of COMMRX and COMMTX signals from the ARM Processor
• Chip ID Registers
– Identification of the device revision, sizes of the embedded memories, set of peripherals
– Chip ID is 0x2733 0740 (VERSION 0) for AT91SAM7L128
– Chip ID is 0x2733 0540 (VERSION 0) for AT91SAM7L64
9.8
Period Interval Timer
• 20-bit programmable counter plus 12-bit interval counter
9.9
Watchdog Timer
• 12-bit key-protected Programmable Counter running on prescaled SLCK
• Provides reset or interrupt signals to the system
• Counter may be stopped while the processor is in debug state or in idle mode
9.10
Real-time Clock
• Two Hundred Year Calendar
• Programmable Periodic Interrupt
• Time, Date and Alarm 32-bit Parallel Load
9.11
PIO Controllers
• Three PIO Controllers.
– PIO A controls 26 I/O lines
– PIO B controls 24 I/O lines
– PIO C controls 30 I/O lines
• Fully programmable through set/clear registers
• Multiplexing of two peripheral functions per I/O line
• For each I/O line (whether assigned to a peripheral or used as general-purpose I/O)
– Input change interrupt
– Half a clock period glitch filter
– Multi-drive option enables driving in open drain
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– Programmable pull-up on each I/O line
– Pin data status register, supplies visibility of the level on the pin at any time
• Synchronous output, provides Set and Clear of several I/O lines in a single write
10. Peripherals
10.1
User Interface
The User Peripherals are mapped in the 256 MBytes of the address space between 0xF000 0000 and 0xFFFF
EFFF. Each peripheral is allocated 16 Kbytes of address space.
A complete memory map is presented in Figure 8-1 on page 24.
10.2
Peripheral Identifiers
The AT91SAM7L128/64 embeds a wide range of peripherals. Table 10-1 defines the Peripheral Identifiers of the
AT91SAM7L128/64. Unique peripheral identifiers are defined for both the Advanced Interrupt Controller and the
Power Management Controller.
Table 10-1.
Peripheral Identifiers
Peripheral
Peripheral
Peripheral
External
ID
Mnemonic
Name
Interrupt
0
AIC
Advanced Interrupt Controller
FIQ
(1)
1
SYSIRQ
System Interrupt
2
PIOA
Parallel I/O Controller A
3
PIOB
Parallel I/O Controller B
4
PIOC
Parallel I/O Controller C
5
SPI
Serial Peripheral Interface
6
US0
USART 0
7
US1
USART 1
8
Reserved
9
TWI
Two-wire Interface
10
PWMC
PWM Controller
11
SLCDC
Segmented LCD Controller
12
TC0
Timer/Counter 0
13
TC1
Timer/Counter 1
14
TC2
Timer/Counter 2
(1)
15
ADC
16 - 29
Reserved
30
AIC
Advanced Interrupt Controller
IRQ0
31
AIC
Advanced Interrupt Controller
IRQ1
Note:
Analog-to Digital Converter
1. Setting SYSIRQ and ADC bits in the clock set/clear registers of the PMC has no effect. The System Controller and
ADC are continuously clocked. The ADC clock is automatically started for the first conversion. In Sleep Mode the
ADC clock is automatically stopped after each conversion.
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10.3
Peripheral Multiplexing on PIO Lines
The AT91SAM7L128/64 features three PIO controllers, PIOA, PIOB and PIOC, that multiplex the I/O lines of the
peripheral set.
PIO Controller A, B and C control respectively 26, 24 and 30 lines. Each line can be assigned to one of two peripheral functions, A or B.
Table 10-2 on page 36 defines how the I/O lines of the peripherals A, B or the analog inputs are multiplexed on the
PIO Controller A, B and C. The two columns “Function” and “Comments” have been inserted for the user’s own
comments; they may be used to track how pins are defined in an application.
Note that some peripheral functions that are output only may be duplicated in the table.
At reset, all I/O lines are automatically configured as input with the programmable pull-up enabled, so that the
device is maintained in a static state as soon as a reset is detected.
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10.4
PIO Controller A Multiplexing
Table 10-2.
Multiplexing on PIO Controller A
PIO Controller A
I/O Line
Peripheral A
Peripheral B
Application Usage
Extra Function
PA0
COM0
PA1
COM1
PA2
COM2
PA3
COM3
PA4
COM4
PA5
COM5
PA6
SEG0
PA7
SEG1
PA8
SEG2
PA9
SEG3
PA10
SEG4
PA11
SEG5
PA12
SEG6
PA13
SEG7
PA14
SEG8
PA15
SEG9
PA16
SEG10
PA17
SEG11
PA18
SEG12
PA19
SEG13
PA20
SEG14
PA21
SEG15
PA22
SEG16
PA23
SEG17
PA24
SEG18
PA25
SEG19
Function
Comments
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10.5
PIO Controller B Multiplexing
Table 10-3.
Multiplexing on PIO Controller B
PIO Controller B
I/O Line
Peripheral A
Peripheral B
Application Usage
Extra Function
PB0
SEG20
PB1
SEG21
PB2
SEG22
PB3
SEG23
PB4
SEG24
PB5
SEG25
PB6
SEG26
PB7
SEG27
PB8
SEG28
PB9
SEG29
PB10
SEG30
PB11
SEG31
PB12
NPCS3
SEG32
PB13
NPCS2
SEG33
PB14
NPCS1
SEG34
PB15
RTS1
SEG35
PB16
RTS0
SEG36
PB17
DTR1
SEG37
PB18
PWM0
SEG38
PB19
PWM1
SEG39
PB20
PWM2
COM6
PB21
PWM3
COM7
PB22
NPCS1
PCK1
COM8
PB23
PCK0
NPCS3
COM9
Function
Comments
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10.6
PIO Controller C Multiplexing
Table 10-4.
Multiplexing on PIO Controller C
PIO Controller C
I/O Line
Peripheral A
Peripheral B
Application Usage
Extra Functions
Function
PC0
CTS1
PWM2
PGMEN0/WKUP0
PC1
DCD1
TIOA2
PGMEN1/WKUP1(1)(2)
PC2
DTR1
TIOB2
PGMEN2/WKUP2(1)(2)
PC3
DSR1
TCLK1
PGMNCMD/WKUP3(1)(2)
PC4
RI1
TCLK2
PGMRDY/WKUP4(1)(2)
PC5
IRQ1
NPCS2
PGMNOE/WKUP5(1)(2)
PC6
NPCS1
PCK2
PC7
PWM0
TIOA0
PGMMO/High drive
PC8
PWM1
TIOB0
PGMM1/High drive
PC9
PWM2
SCK0
PGMM2/High drive
PC10
TWD
NPCS3
PGMM3/High drive
PC11
TWCK
TCLK0
PGMD0/WKUP7(1)(2)
PC12
RXD0
NPCS3
PGMD1/WKUP8(1)(2)
PC13
TXD0
PCK0
PGMD2/WKUP9(1)(2)
PC14
RTS0
ADTRG
PGMD3/WKUP10(1)(2)
PC15
CTS0
PWM3
PGMD4/WKUP11(1)(2)
PC16
DRXD
NPCS1
PGMD5
PC17
DTXD
NPCS2
PGMD6
PC18
NPCS0
PWM0
PGMD7
PC19
MISO
PWM1
PGMD8
PC20
MOSI
PWM2
PGMD9
PC21
SPCK
PWM3
PGMD10
PC22
NPCS3
TIOA1
PGMD11
PC23
PCK0
TIOB1
PGMD12
PC24
RXD1
PCK1
PGMD13
PC25
TXD1
PCK2
PGMD14
PC26
RTS0
FIQ
PGMD15/WKUP12(1)(2)
PC27
NPCS2
IRQ0
WKUP13(1)(2)
PC28
SCK1
PWM0
WKUP14(1)(2)
PC29
RTS1
PWM1
WKUP15(1)(2)
Notes:
Comments
(1)(2)
PGMNVALID/WKUP6(1)(
2)
1. Wake-Up source in Backup mode (managed by the SUPC).
2. Fast Start-Up source in Wait mode (managed by the PMC).
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10.7
Serial Peripheral Interface
• Supports communication with external serial devices
– Four chip selects with external decoder allow communication with up to 15 peripherals
– Serial memories, such as DataFlash® and 3-wire EEPROMs
– Serial peripherals, such as ADCs, DACs, LCD Controllers, CAN Controllers and Sensors
– External co-processors
• Master or slave serial peripheral bus interface
– 8- to 16-bit programmable data length per chip select
– Programmable phase and polarity per chip select
– Programmable transfer delays per chip select, between consecutive transfers and between clock and
data
– Programmable delay between consecutive transfers
– Selectable mode fault detection
– Maximum frequency at up to Master Clock
10.8
Two Wire Interface
• Master, Multi-Master and Slave Mode Operation
• Compatibility with Atmel two-wire interface, serial memory and I2C compatible devices
• One, two or three bytes for slave address
• Sequential read/write operations
• Bit Rate: Up to 400 kbit/s
• General Call Supported in Slave Mode
• Connecting to PDC channel capabilities optimizes data transfers in Master Mode only
– One channel for the receiver, one channel for the transmitter
– Next buffer support
10.9
USART
• Programmable Baud Rate Generator
• 5- to 9-bit full-duplex synchronous or asynchronous serial communications
– 1, 1.5 or 2 stop bits in Asynchronous Mode
– 1 or 2 stop bits in Synchronous Mode
– Parity generation and error detection
– Framing error detection, overrun error detection
– MSB or LSB first
– Optional break generation and detection
– By 8 or by 16 over-sampling receiver frequency
– Hardware handshaking RTS - CTS
– Modem Signals Management DTR-DSR-DCD-RI on USART1
– Receiver time-out and transmitter timeguard
– Multi-drop Mode with address generation and detection
– Optional Manchester Encoding
• RS485 with driver control signal
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• ISO7816, T = 0 or T = 1 Protocols for interfacing with smart cards
– NACK handling, error counter with repetition and iteration limit
• IrDA modulation and demodulation
– Communication at up to 115.2 Kbps
• Test Modes
– Remote Loopback, Local Loopback, Automatic Echo
10.10 Timer Counter
• Three 16-bit Timer Counter Channels
– Three output compare or two input capture
• Wide range of functions including:
– Frequency measurement
– Event counting
– Interval measurement
– Pulse generation
– Delay timing
– Pulse Width Modulation
– Up/down capabilities
• Each channel is user-configurable and contains:
– Three external clock inputs
• Five internal clock inputs, as defined in Table 10-5
Table 10-5.
Timer Counter Clock Assignment
TC Clock input
Clock
TIMER_CLOCK1
MCK/2
TIMER_CLOCK2
MCK/8
TIMER_CLOCK3
MCK/32
TIMER_CLOCK4
MCK/128
TIMER_CLOCK5
MCK/1024
– Two multi-purpose input/output signals
– Two global registers that act on all three TC channels
10.11 PWM Controller
• Four channels, one 16-bit counter per channel
• Common clock generator, providing thirteen different clocks
– One Modulo n counter providing eleven clocks
– Two independent linear dividers working on modulo n counter outputs
• Independent channel programming
– Independent enable/disable commands
– Independent clock selection
– Independent period and duty cycle, with double buffering
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– Programmable selection of the output waveform polarity
– Programmable center or left aligned output waveform
10.12 Analog-to-Digital Converter
• 4-channel ADC supplied by the internal voltage regulator
• 10-bit 460 Ksamples/sec. or 8-bit 660 Ksamples/sec. Successive Approximation Register ADC
• ±2 LSB Integral Non Linearity, ±1 LSB Differential Non Linearity
• Integrated 4-to-1 multiplexer
• External voltage reference for better accuracy on low voltage inputs
• Individual enable and disable of each channel
• Multiple trigger sources
– Hardware or software trigger
– External trigger pin
– Timer Counter 0 to 2 outputs TIOA0 to TIOA2 trigger
• Sleep Mode and conversion sequencer
– Automatic wakeup on trigger and back to sleep mode after conversions of all enabled channels
10.13 Segment LCD Controller
The Segment LCD Controller/driver is intended for monochrome passive liquid crystal display (LCD) with up to 10
common terminals and up to 40 segment terminals.
• 40 segments and 10 common terminals display capacity
• Support static, 1/2, 1/3, 1/4, 1/5, 1/6, 1/7, 1/8, 1/9 and 1/10 Duty
• Support static, 1/2, 1/3, 1/4 Bias
• Power-save mode display
• Software-selectable low-power waveform capability
• Flexible frame frequency selection
• Segment and common pins, not needed for driving the display, can be used as ordinary I/O pins
• Switching time enhancement internal buffers
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11. ARM7TDMI Processor Overview
11.1
Overview
The ARM7TDMI core executes both the 32-bit ARM and 16-bit Thumb instruction sets, allowing the user to trade
off between high performance and high code density.The ARM7TDMI processor implements Von Neuman architecture, using a three-stage pipeline consisting of Fetch, Decode, and Execute stages.
The main features of the ARM7tDMI processor are:
• ARM7TDMI Based on ARMv4T Architecture
• Two Instruction Sets
– ARM High-performance 32-bit Instruction Set
– Thumb High Code Density 16-bit Instruction Set
• Three-Stage Pipeline Architecture
– Instruction Fetch (F)
– Instruction Decode (D)
– Execute (E)
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11.2
ARM7TDMI Processor
For further details on ARM7TDMI, refer to the following ARM documents:
ARM Architecture Reference Manual (DDI 0100E)
ARM7TDMI Technical Reference Manual (DDI 0210B)
11.2.1
Instruction Type
Instructions are either 32 bits long (in ARM state) or 16 bits long (in THUMB state).
11.2.2
Data Type
ARM7TDMI supports byte (8-bit), half-word (16-bit) and word (32-bit) data types. Words must be aligned to fourbyte boundaries and half words to two-byte boundaries.
Unaligned data access behavior depends on which instruction is used where.
11.2.3
ARM7TDMI Operating Mode
The ARM7TDMI, based on ARM architecture v4T, supports seven processor modes:
User: The normal ARM program execution state
FIQ: Designed to support high-speed data transfer or channel process
IRQ: Used for general-purpose interrupt handling
Supervisor: Protected mode for the operating system
Abort mode: Implements virtual memory and/or memory protection
System: A privileged user mode for the operating system
Undefined: Supports software emulation of hardware coprocessors
Mode changes may be made under software control, or may be brought about by external interrupts or exception
processing. Most application programs execute in User mode. The non-user modes, or privileged modes, are
entered in order to service interrupts or exceptions, or to access protected resources.
11.2.4
ARM7TDMI Registers
The ARM7TDMI processor has a total of 37 registers:
• 31 general-purpose 32-bit registers
• 6 status registers
These registers are not accessible at the same time. The processor state and operating mode determine which
registers are available to the programmer.
At any one time 16 registers are visible to the user. The remainder are synonyms used to speed up exception
processing.
Register 15 is the Program Counter (PC) and can be used in all instructions to reference data relative to the current
instruction.
R14 holds the return address after a subroutine call.
R13 is used (by software convention) as a stack pointer.
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Table 11-1.
ARM7TDMI ARM Modes and Registers Layout
User and
System Mode
Supervisor
Mode
Abort Mode
Undefined
Mode
Interrupt
Mode
Fast Interrupt
Mode
R0
R0
R0
R0
R0
R0
R1
R1
R1
R1
R1
R1
R2
R2
R2
R2
R2
R2
R3
R3
R3
R3
R3
R3
R4
R4
R4
R4
R4
R4
R5
R5
R5
R5
R5
R5
R6
R6
R6
R6
R6
R6
R7
R7
R7
R7
R7
R7
R8
R8
R8
R8
R8
R8_FIQ
R9
R9
R9
R9
R9
R9_FIQ
R10
R10
R10
R10
R10
R10_FIQ
R11
R11
R11
R11
R11
R11_FIQ
R12
R12
R12
R12
R12
R12_FIQ
R13
R13_SVC
R13_ABORT
R13_UNDEF
R13_IRQ
R13_FIQ
R14
R14_SVC
R14_ABORT
R14_UNDEF
R14_IRQ
R14_FIQ
PC
PC
PC
PC
PC
PC
CPSR
CPSR
CPSR
CPSR
CPSR
CPSR
SPSR_SVC
SPSR_ABORT
SPSR_UNDEF
SPSR_IRQ
SPSR_FIQ
Mode-specific banked registers
Registers R0 to R7 are unbanked registers. This means that each of them refers to the same 32-bit physical register in all processor modes. They are general-purpose registers, with no special uses managed by the architecture,
and can be used wherever an instruction allows a general-purpose register to be specified.
Registers R8 to R14 are banked registers. This means that each of them depends on the current mode of the
processor.
11.2.4.1
Modes and Exception Handling
All exceptions have banked registers for R14 and R13.
After an exception, R14 holds the return address for exception processing. This address is used to return after the
exception is processed, as well as to address the instruction that caused the exception.
R13 is banked across exception modes to provide each exception handler with a private stack pointer.
The fast interrupt mode also banks registers 8 to 12 so that interrupt processing can begin without having to save
these registers.
A seventh processing mode, System Mode, does not have any banked registers. It uses the User Mode registers.
System Mode runs tasks that require a privileged processor mode and allows them to invoke all classes of
exceptions.
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11.2.4.2
Status Registers
All other processor states are held in status registers. The current operating processor status is in the Current Program Status Register (CPSR). The CPSR holds:
• four ALU flags (Negative, Zero, Carry, and Overflow)
• two interrupt disable bits (one for each type of interrupt)
• one bit to indicate ARM or Thumb execution
• five bits to encode the current processor mode
All five exception modes also have a Saved Program Status Register (SPSR) that holds the CPSR of the task
immediately preceding the exception.
11.2.4.3
Exception Types
The ARM7TDMI supports five types of exception and a privileged processing mode for each type. The types of
exceptions are:
• fast interrupt (FIQ)
• normal interrupt (IRQ)
• memory aborts (used to implement memory protection or virtual memory)
• attempted execution of an undefined instruction
• software interrupts (SWIs)
Exceptions are generated by internal and external sources.
More than one exception can occur in the same time.
When an exception occurs, the banked version of R14 and the SPSR for the exception mode are used to save
state.
To return after handling the exception, the SPSR is moved to the CPSR, and R14 is moved to the PC. This can be
done in two ways:
• by using a data-processing instruction with the S-bit set, and the PC as the destination
• by using the Load Multiple with Restore CPSR instruction (LDM)
11.2.5
ARM Instruction Set Overview
The ARM instruction set is divided into:
• Branch instructions
• Data processing instructions
• Status register transfer instructions
• Load and Store instructions
• Coprocessor instructions
• Exception-generating instructions
ARM instructions can be executed conditionally. Every instruction contains a 4-bit condition code field (bit[31:28]).
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Table 11-2 gives the ARM instruction mnemonic list.
Table 11-2.
11.2.6
ARM Instruction Mnemonic List
Mnemonic
Operation
Mnemonic
Operation
MOV
Move
CDP
Coprocessor Data Processing
ADD
Add
MVN
Move Not
SUB
Subtract
ADC
Add with Carry
RSB
Reverse Subtract
SBC
Subtract with Carry
CMP
Compare
RSC
Reverse Subtract with Carry
TST
Test
CMN
Compare Negated
AND
Logical AND
TEQ
Test Equivalence
EOR
Logical Exclusive OR
BIC
Bit Clear
MUL
Multiply
ORR
Logical (inclusive) OR
SMULL
Sign Long Multiply
MLA
Multiply Accumulate
SMLAL
Signed Long Multiply Accumulate
UMULL
Unsigned Long Multiply
MSR
Move to Status Register
UMLAL
Unsigned Long Multiply Accumulate
B
Branch
MRS
Move From Status Register
BX
Branch and Exchange
BL
Branch and Link
LDR
Load Word
SWI
Software Interrupt
LDRSH
Load Signed Halfword
STR
Store Word
LDRSB
Load Signed Byte
STRH
Store Half Word
LDRH
Load Half Word
STRB
Store Byte
LDRB
Load Byte
STRBT
Store Register Byte with Translation
LDRBT
Load Register Byte with Translation
STRT
Store Register with Translation
LDRT
Load Register with Translation
STM
Store Multiple
LDM
Load Multiple
SWPB
Swap Byte
SWP
Swap Word
MRC
Move From Coprocessor
MCR
Move To Coprocessor
STC
Store From Coprocessor
LDC
Load To Coprocessor
Thumb Instruction Set Overview
The Thumb instruction set is a re-encoded subset of the ARM instruction set.
The Thumb instruction set is divided into:
• Branch instructions
• Data processing instructions
• Load and Store instructions
• Load and Store Multiple instructions
• Exception-generating instruction
In Thumb mode, eight general-purpose registers, R0 to R7, are available that are the same physical registers as
R0 to R7 when executing ARM instructions. Some Thumb instructions also access to the Program Counter (ARM
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Register 15), the Link Register (ARM Register 14) and the Stack Pointer (ARM Register 13). Further instructions
allow limited access to the ARM registers 8 to 15.
Table 11-3 gives the Thumb instruction mnemonic list.
Table 11-3.
Thumb Instruction Mnemonic List
Mnemonic
Operation
Mnemonic
Operation
MOV
Move
MVN
Move Not
ADD
Add
ADC
Add with Carry
SUB
Subtract
SBC
Subtract with Carry
CMP
Compare
CMN
Compare Negated
TST
Test
NEG
Negate
AND
Logical AND
BIC
Bit Clear
EOR
Logical Exclusive OR
ORR
Logical (inclusive) OR
LSL
Logical Shift Left
LSR
Logical Shift Right
ASR
Arithmetic Shift Right
ROR
Rotate Right
MUL
Multiply
B
Branch
BL
Branch and Link
BX
Branch and Exchange
SWI
Software Interrupt
LDR
Load Word
STR
Store Word
LDRH
Load Half Word
STRH
Store Half Word
LDRB
Load Byte
STRB
Store Byte
LDRSH
Load Signed Halfword
LDRSB
Load Signed Byte
LDMIA
Load Multiple
STMIA
Store Multiple
PUSH
Push Register to stack
POP
Pop Register from stack
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12. Debug and Test Features
12.1
Overview
The AT91SAM7L Series Microcontrollers feature a number of complementary debug and test capabilities. A common JTAG/ICE (Embedded ICE) port is used for standard debugging functions, such as downloading code and
single-stepping through programs. The Debug Unit provides a two-pin UART that can be used to upload an application into internal SRAM. It manages the interrupt handling of the internal COMMTX and COMMRX signals that
trace the activity of the Debug Communication Channel.
A set of dedicated debug and test input/output pins gives direct access to these capabilities from a PC-based test
environment.
Block Diagram
Figure 12-1. Debug and Test Block Diagram
TMS
TCK
TDI
ICE/JTAG
TAP
Boundary
TAP
JTAGSEL
TDO
ICE
POR
Reset
and
Test
TST
ARM7TDMI
PIO
12.2
PDC
DTXD
DBGU
DRXD
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12.3
Application Examples
12.3.1
Debug Environment
Figure 12-2 shows a complete debug environment example. The ICE/JTAG interface is used for standard debugging functions, such as downloading code and single-stepping through the program.
Figure 12-2. Application Debug Environment Example
Host Debugger
ICE/JTAG
Interface
ICE/JTAG
Connector
AT91SAMLxx
RS232
Connector
Terminal
AT91SAM7Lxx-based Application Board
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12.3.2
Test Environment
Figure 12-3 shows a test environment example. Test vectors are sent and interpreted by the tester. In this example, the “board in test” is designed using a number of JTAG-compliant devices. These devices can be connected to
form a single scan chain.
Figure 12-3. Application Test Environment Example
Test Adaptor
Tester
JTAG
Interface
ICE/JTAG
Connector
Chip n
AT91SAM7Lxx
Chip 2
Chip 1
AT91SAM7Lxx-based Application Board In Test
12.4
Debug and Test Pin Description
Table 12-1.
Pin Name
Debug and Test Pin List
Function
Type
Active Level
Input/Output
Low
Input
High
Reset/Test
NRST
Microcontroller Reset
TST
Test Mode Select
ICE and JTAG
TCK
Test Clock
Input
TDI
Test Data In
Input
TDO
Test Data Out
TMS
Test Mode Select
Input
JTAGSEL
JTAG Selection
Input
Output
Debug Unit
DRXD
Debug Receive Data
Input
DTXD
Debug Transmit Data
Output
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12.5
Functional Description
12.5.1
Test Pin
One dedicated pin, TST, is used to define the device operating mode. The user must make sure that this pin is tied
at low level to ensure normal operating conditions. Other values associated with this pin are reserved for manufacturing test.
12.5.2
EmbeddedICE™ (Embedded In-circuit Emulator)
The ARM7TDMI EmbeddedICE is supported via the ICE/JTAG port.The internal state of the ARM7TDMI is examined through an ICE/JTAG port.
The ARM7TDMI processor contains hardware extensions for advanced debugging features:
• In halt mode, a store-multiple (STM) can be inserted into the instruction pipeline. This exports the contents of
the ARM7TDMI registers. This data can be serially shifted out without affecting the rest of the system.
• In monitor mode, the JTAG interface is used to transfer data between the debugger and a simple monitor
program running on the ARM7TDMI processor.
There are three scan chains inside the ARM7TDMI processor that support testing, debugging, and programming of
the Embedded ICE. The scan chains are controlled by the ICE/JTAG port.
Embedded ICE mode is selected when JTAGSEL is low. It is not possible to switch directly between ICE and JTAG
operations. A chip reset must be performed after JTAGSEL is changed.
For further details on the Embedded ICE, see the ARM7TDMI (Rev4) Technical Reference Manual (DDI0210B).
12.5.3
Debug Unit
The Debug Unit provides a two-pin (DXRD and TXRD) USART that can be used for several debug and trace purposes and offers an ideal means for in-situ programming solutions and debug monitor communication. Moreover,
the association with two peripheral data controller channels permits packet handling of these tasks with processor
time reduced to a minimum.
The Debug Unit also manages the interrupt handling of the COMMTX and COMMRX signals that come from the
ICE and that trace the activity of the Debug Communication Channel.The Debug Unit allows blockage of access to
the system through the ICE interface.
A specific register, the Debug Unit Chip ID Register, gives information about the product version and its internal
configuration.
Table 12-2.
AT91SAM7Lxx Chip IDs
Chip Name
Chip ID
AT91SAM7L64
0x27330540
AT91SAM7L128
0x27330740
For further details on the Debug Unit, see the Debug Unit section.
12.5.4
IEEE 1149.1 JTAG Boundary Scan
IEEE 1149.1 JTAG Boundary Scan allows pin-level access independent of the device packaging technology.
IEEE 1149.1 JTAG Boundary Scan is enabled when TST, JTAGSEL are high and CLKIN, FWUP and RNRSTB are
tied low. VDDCORE must be externally supplied between 1.8V and 1.95V. The SAMPLE, EXTEST and BYPASS
functions are implemented. In ICE debug mode, the ARM processor responds with a non-JTAG chip ID that identifies the processor to the ICE system. This is not IEEE 1149.1 JTAG-compliant.
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It is not possible to switch directly between JTAG and ICE operations. A chip reset must be performed after JTAGSEL is changed.
A Boundary-scan Descriptor Language (BSDL) file is provided to set up test.
12.5.4.1
JTAG Boundary-scan Register
The Boundary-scan Register (BSR) contains 160 bits that correspond to active pins and associated control signals.
Each AT91SAM7Lxx input/output pin corresponds to a 3-bit register in the BSR. The OUTPUT bit contains data
that can be forced on the pad. The INPUT bit facilitates the observability of data applied to the pad. The CONTROL
bit selects the direction of the pad.
For more information, please refer to BDSL files which are available for the SAM7L Series.
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12.5.5
ID Code Register
Access: Read-only
31
30
29
28
27
VERSION
23
22
26
25
24
PART NUMBER
21
20
19
18
17
16
10
9
8
PART NUMBER
15
14
13
12
11
PART NUMBER
7
6
MANUFACTURER IDENTITY
5
4
3
2
1
MANUFACTURER IDENTITY
0
1
• VERSION[31:28]: Product Version Number
Set to 0x0.
• PART NUMBER[27:12]: Product Part Number
Chip Name
Chip ID
AT91SAM7L64
0x5B23
AT91SAM7L128
0x5B1E
• MANUFACTURER IDENTITY[11:1]
Set to 0x01F.
• Bit[0] Required by IEEE Std. 1149.1.
Set to 0x1.
Chip Name
JTAG ID Code
AT91SAM7L64
05B2_303F
AT91SAM7L128
05B1_E03F
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13. Reset Controller (RSTC)
13.1
Overview
The Reset Controller (RSTC), based on a zero-power power-on reset cell, handles all the resets of the system
without any external components. It reports which reset occurred last.
The Reset Controller also drives independently or simultaneously the external reset and the peripheral and processor resets.
13.2
Block Diagram
Figure 13-1. Reset Controller Block Diagram
Reset Controller
core_backup_reset
rstc_irq
vddcore_nreset
user_reset
NRST
nrst_out
NRST
Manager
Reset
State
Manager
proc_nreset
periph_nreset
exter_nreset
WDRPROC
wd_fault
SLCK
13.3
Functional Description
13.3.1
Reset Controller Overview
The Reset Controller is made up of an NRST Manager and a Reset State Manager. It runs at Slow Clock and generates the following reset signals:
• proc_nreset: Processor reset line. It also resets the Watchdog Timer.
• periph_nreset: Affects the whole set of embedded peripherals.
• nrst_out: Drives the NRST pin.
These reset signals are asserted by the Reset Controller, either on external events or on software action. The
Reset State Manager controls the generation of reset signals and provides a signal to the NRST Manager when an
assertion of the NRST pin is required.
The NRST Manager shapes the NRST assertion during a programmable time, thus controlling external device
resets.
The Reset Controller Mode Register (RSTC_MR), allowing the configuration of the Reset Controller, is powered
with VDDIO1, so that its configuration is saved as long as VDDIO1 is on.
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13.3.2
NRST Manager
The NRST Manager samples the NRST input pin and drives this pin low when required by the Reset State Manager. Figure 13-2 shows the block diagram of the NRST Manager.
Figure 13-2. NRST Manager
RSTC_MR
URSTIEN
RSTC_SR
URSTS
NRSTL
rstc_irq
RSTC_MR
URSTEN
Other
interrupt
sources
user_reset
NRST
RSTC_MR
ERSTL
nrst_out
External Reset Timer
exter_nreset
13.3.2.1
NRST Signal or Interrupt
The NRST Manager samples the NRST pin at Slow Clock speed. When the line is detected low, a User Reset is
reported to the Reset State Manager.
However, the NRST Manager can be programmed to not trigger a reset when an assertion of NRST occurs. Writing the bit URSTEN at 0 in RSTC_MR disables the User Reset trigger.
The level of the pin NRST can be read at any time in the bit NRSTL (NRST level) in RSTC_SR. As soon as the pin
NRST is asserted, the bit URSTS in RSTC_SR is set. This bit clears only when RSTC_SR is read.
The Reset Controller can also be programmed to generate an interrupt instead of generating a reset. To do so, the
bit URSTIEN in RSTC_MR must be written at 1.
13.3.2.2
NRST External Reset Control
The Reset State Manager asserts the signal ext_nreset to assert the NRST pin. When this occurs, the “nrst_out”
signal is driven low by the NRST Manager for a time programmed by the field ERSTL in RSTC_MR. This assertion
duration, named EXTERNAL_RESET_LENGTH, lasts 2(ERSTL+1) Slow Clock cycles. This gives the approximate
duration of an assertion between 60 µs and 2 seconds. Note that ERSTL at 0 defines a two-cycle duration for the
NRST pulse.
This feature allows the Reset Controller to shape the NRST pin level, and thus to guarantee that the NRST line is
driven low for a time compliant with potential external devices connected on the system reset.
As the ERSTL field is within RSTC_MR register, which is backed-up, it can be used to shape the system power-up
reset for devices requiring a longer startup time than the Slow Clock Oscillator.
Please note that the NRST output is in high impedance state when the chip is in OFF mode.
13.3.3
Brownout Manager
The Brownout manager is embedded within the Supply Controller, please refer to the Supply Controller section for
a detailed description.
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13.3.4
Reset States
The Reset State Manager handles the different reset sources and generates the internal reset signals. It reports
the reset status in the field RSTTYP of the Status Register (RSTC_SR). The update of the field RSTTYP is performed when the processor reset is released.
13.3.4.1
General Reset
A general reset occurs when a Power-on-reset is detected, an Asynchronous Master Reset (NRSTB pin ) is
requested, a Brownout or a Voltage regulation loss is detected by the Supply controller. The vddcore_nreset signal
is asserted by the Supply Controller when a general reset occurs.
All the reset signals are released and the field RSTTYP in RSTC_SR reports a General Reset. As the RSTC_MR is
reset, the NRST line rises 2 cycles after the vddcore_nreset, as ERSTL defaults at value 0x0.
Figure 13-3 shows how the General Reset affects the reset signals.
Figure 13-3. General Reset State
SLCK
Any
Freq.
MCK
power_on_reset
Processor Startup
= 2 cycles
proc_nreset
RSTTYP
XXX
0x0 = General Reset
XXX
periph_nreset
NRST
(nrst_out)
EXTERNAL RESET LENGTH
= 2 cycles
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13.3.4.2
Backup Reset
A Backup reset occurs when the chip returns from Backup mode. The core_backup_reset signal is asserted by the
Supply Controller when a Backup reset occurs.
The field RSTTYP in RSTC_SR is updated to report a Backup Reset.
13.3.4.3
User Reset
The User Reset is entered when a low level is detected on the NRST pin and the bit URSTEN in RSTC_MR is at 1.
The NRST input signal is resynchronized with SLCK to insure proper behavior of the system.
The User Reset is entered as soon as a low level is detected on NRST. The Processor Reset and the Peripheral
Reset are asserted.
The User Reset is left when NRST rises, after a two-cycle resynchronization time and a 3-cycle processor startup.
The processor clock is re-enabled as soon as NRST is confirmed high.
When the processor reset signal is released, the RSTTYP field of the Status Register (RSTC_SR) is loaded with
the value 0x4, indicating a User Reset.
The NRST Manager guarantees that the NRST line is asserted for EXTERNAL_RESET_LENGTH Slow Clock
cycles, as programmed in the field ERSTL. However, if NRST does not rise after EXTERNAL_RESET_LENGTH
because it is driven low externally, the internal reset lines remain asserted until NRST actually rises.
Figure 13-4. User Reset State
SLCK
MCK
Any
Freq.
NRST
Resynch.
2 cycles
Resynch.
2 cycles
Processor Startup
= 2 cycles
proc_nreset
RSTTYP
Any
XXX
0x4 = User Reset
periph_nreset
NRST
(nrst_out)
>= EXTERNAL RESET LENGTH
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13.3.4.4
Software Reset
The Reset Controller offers several commands used to assert the different reset signals. These commands are
performed by writing the Control Register (RSTC_CR) with the following bits at 1:
• PROCRST: Writing PROCRST at 1 resets the processor and the watchdog timer.
• PERRST: Writing PERRST at 1 resets all the embedded peripherals, including the memory system, and, in
particular, the Remap Command. The Peripheral Reset is generally used for debug purposes.
• EXTRST: Writing EXTRST at 1 asserts low the NRST pin during a time defined by the field ERSTL in the Mode
Register (RSTC_MR).
The software reset is entered if at least one of these bits is set by the software. All these commands can be performed independently or simultaneously. The software reset lasts 3 Slow Clock cycles.
The internal reset signals are asserted as soon as the register write is performed. This is detected on the Master
Clock (MCK). They are released when the software reset is left, i.e.; synchronously to SLCK.
If EXTRST is set, the nrst_out signal is asserted depending on the programming of the field ERSTL. However, the
resulting falling edge on NRST does not lead to a User Reset.
If and only if the PROCRST bit is set, the Reset Controller reports the software status in the field RSTTYP of the
Status Register (RSTC_SR). Other Software Resets are not reported in RSTTYP.
As soon as a software operation is detected, the bit SRCMP (Software Reset Command in Progress) is set in the
Status Register (RSTC_SR). It is cleared as soon as the software reset is left. No other software reset can be performed while the SRCMP bit is set, and writing any value in RSTC_CR has no effect.
Figure 13-5. Software Reset
SLCK
MCK
Any
Freq.
Write RSTC_CR
Resynch. Processor Startup
1 cycle
= 2 cycles
proc_nreset
if PROCRST=1
RSTTYP
Any
XXX
0x3 = Software Reset
periph_nreset
if PERRST=1
NRST
(nrst_out)
if EXTRST=1
EXTERNAL RESET LENGTH
8 cycles (ERSTL=2)
SRCMP in RSTC_SR
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13.3.4.5
W
atchdog Reset
The Watchdog Reset is entered when a watchdog fault occurs. This state lasts 3 Slow Clock cycles.
When in Watchdog Reset, assertion of the reset signals depends on the WDRPROC bit in WDT_MR:
• If WDRPROC is 0, the Processor Reset and the Peripheral Reset are asserted. The NRST line is also asserted,
depending on the programming of the field ERSTL. However, the resulting low level on NRST does not result in
a User Reset state.
• If WDRPROC = 1, only the processor reset is asserted.
The Watchdog Timer is reset by the proc_nreset signal. As the watchdog fault always causes a processor reset if
WDRSTEN is set, the Watchdog Timer is always reset after a Watchdog Reset, and the Watchdog is enabled by
default and with a period set to a maximum.
When the WDRSTEN in WDT_MR bit is reset, the watchdog fault has no impact on the reset controller.
Figure 13-6. Watchdog Reset
SLCK
MCK
Any
Freq.
wd_fault
Processor Startup
= 2 cycles
proc_nreset
RSTTYP
Any
XXX
0x2 = Watchdog Reset
periph_nreset
Only if
WDRPROC = 0
NRST
(nrst_out)
EXTERNAL RESET LENGTH
8 cycles (ERSTL=2)
13.3.5
Reset State Priorities
The Reset State Manager manages the following priorities between the different reset sources, given in descending order:
• General Reset
• Backup Reset
• Watchdog Reset
• Software Reset
• User Reset
Particular cases are listed below:
• When in User Reset:
– A watchdog event is impossible because the Watchdog Timer is being reset by the proc_nreset signal.
– A software reset is impossible, since the processor reset is being activated.
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• When in Software Reset:
– A watchdog event has priority over the current state.
– The NRST has no effect.
• When in Watchdog Reset:
– The processor reset is active and so a Software Reset cannot be programmed.
– A User Reset cannot be entered.
13.3.6
Reset Controller Status Register
The Reset Controller status register (RSTC_SR) provides several status fields:
• RSTTYP field: This field gives the type of the last reset, as explained in previous sections.
• SRCMP bit: This field indicates that a Software Reset Command is in progress and that no further software
reset should be performed until the end of the current one. This bit is automatically cleared at the end of the
current software reset.
• NRSTL bit: The NRSTL bit of the Status Register gives the level of the NRST pin sampled on each MCK rising
edge.
• URSTS bit: A high-to-low transition of the NRST pin sets the URSTS bit of the RSTC_SR register. This
transition is also detected on the Master Clock (MCK) rising edge (see Figure 13-7). If the User Reset is
disabled (URSTEN = 0) and if the interruption is enabled by the URSTIEN bit in the RSTC_MR register, the
URSTS bit triggers an interrupt. Reading the RSTC_SR status register resets the URSTS bit and clears the
interrupt.
Figure 13-7.
Reset Controller Status and Interrupt
MCK
read
RSTC_SR
Peripheral Access
2 cycle
resynchronization
2 cycle
resynchronization
NRST
NRSTL
URSTS
rstc_irq
if (URSTEN = 0) and
(URSTIEN = 1)
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13.4
Reset Controller (RSTC) User Interface
Table 13-1.
Register Mapping
Offset
Register
Name
Access
Reset
0x00
Control Register
RSTC_CR
Write-only
-
0x04
Status Register
RSTC_SR
Read-only
0x0000_0000
0x08
Mode Register
RSTC_MR
Read-write
0x0000_0000
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13.4.1
Name:
Reset Controller Control Register
RSTC_CR
Access Type:
31
Write-only
30
29
28
27
26
25
24
KEY
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
8
–
7
–
6
–
5
–
4
–
3
EXTRST
2
PERRST
1
–
0
PROCRST
• PROCRST: Processor Reset
0 = No effect.
1 = If KEY is correct, resets the processor.
• PERRST: Peripheral Reset
0 = No effect.
1 = If KEY is correct, resets the peripherals.
• EXTRST: External Reset
0 = No effect.
1 = If KEY is correct, asserts the NRST pin.
• KEY: Password
Should be written at value 0xA5. Writing any other value in this field aborts the write operation.
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13.4.2
Name:
Reset Controller Status Register
RSTC_SR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
SRCMP
16
NRSTL
15
–
14
–
13
–
12
–
11
–
10
9
RSTTYP
8
7
–
6
–
5
–
4
–
3
–
2
–
1
–
0
URSTS
• URSTS: User Reset Status
0 = No high-to-low edge on NRST happened since the last read of RSTC_SR.
1 = At least one high-to-low transition of NRST has been detected since the last read of RSTC_SR.
• RSTTYP: Reset Type
Reports the cause of the last processor reset. Reading this RSTC_SR does not reset this field.
RSTTYP
Reset Type
Comments
0
0
0
General Reset
First power-up Reset (Power-on Reset or NRSTB asserted)
0
0
1
Backup Reset
Return from Backup mode
0
1
0
Watchdog Reset
Watchdog fault occurred
0
1
1
Software Reset
Processor reset required by the software
1
0
0
User Reset
NRST pin detected low
• NRSTL: NRST Pin Level
Registers the NRST Pin Level at Master Clock (MCK).
• SRCMP: Software Reset Command in Progress
0 = No software command is being performed by the reset controller. The reset controller is ready for a software command.
1 = A software reset command is being performed by the reset controller. The reset controller is busy.
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13.4.3
Name:
Reset Controller Mode Register
RSTC_MR
Access Type:
31
Read-write
30
29
28
27
26
25
24
17
–
16
–
9
8
1
–
0
URSTEN
KEY
23
–
22
–
21
–
20
–
19
–
18
–
15
–
14
–
13
–
12
–
11
10
7
–
6
–
5
4
URSTIEN
3
–
ERSTL
2
–
• URSTEN: User Reset Enable
0 = The detection of a low level on the pin NRST does not generate a User Reset.
1 = The detection of a low level on the pin NRST triggers a User Reset.
• URSTIEN: User Reset Interrupt Enable
0 = USRTS bit in RSTC_SR at 1 has no effect on rstc_irq.
1 = USRTS bit in RSTC_SR at 1 asserts rstc_irq if URSTEN = 0.
• ERSTL: External Reset Length
This field defines the external reset length. The external reset is asserted during a time of 2(ERSTL+1) Slow Clock cycles. This
allows assertion duration to be programmed between 60 µs and 2 seconds.
• KEY: Password
Should be written at value 0xA5. Writing any other value in this field aborts the write operation.
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14. Real-time Clock (RTC)
14.1
Overview
The Real-time Clock (RTC) peripheral is designed for very low power consumption.
It combines a complete time-of-day clock with alarm and a two-hundred-year Gregorian calendar, complemented
by a programmable periodic interrupt. The alarm and calendar registers are accessed by a 32-bit data bus.
The time and calendar values are coded in binary-coded decimal (BCD) format. The time format can be 24-hour
mode or 12-hour mode with an AM/PM indicator.
Updating time and calendar fields and configuring the alarm fields are performed by a parallel capture on the 32-bit
data bus. An entry control is performed to avoid loading registers with incompatible BCD format data or with an
incompatible date according to the current month/year/century.
14.2
Block Diagram
Figure 14-1. RTC Block Diagram
Crystal Oscillator: SLCK
32768 Divider
Bus Interface
Bus Interface
Time
Date
Entry
Control
Interrupt
Control
RTC Interrupt
14.3
Product Dependencies
14.3.1
Power Management
The Real-time Clock is continuously clocked at 32768 Hz. The Power Management Controller has no effect on
RTC behavior.
14.3.2
Interrupt
The RTC Interrupt is connected to interrupt source 1 (IRQ1) of the advanced interrupt controller. This interrupt line
is due to the OR-wiring of the system peripheral interrupt lines (System Timer, Real Time Clock, Power Management Controller, Memory Controller, etc.). When a system interrupt occurs, the service routine must first determine
the cause of the interrupt. This is done by reading the status registers of the above system peripherals
successively.
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14.4
Functional Description
The RTC provides a full binary-coded decimal (BCD) clock that includes century (19/20), year (with leap years),
month, date, day, hours, minutes and seconds.
The valid year range is 1900 to 2099, a two-hundred-year Gregorian calendar achieving full Y2K compliance.
The RTC can operate in 24-hour mode or in 12-hour mode with an AM/PM indicator.
Corrections for leap years are included (all years divisible by 4 being leap years, including year 2000). This is correct up to the year 2099.
After hardware reset, the calendar is initialized to Thursday, January 1, 1998.
14.4.1
Reference Clock
The reference clock is Slow Clock (SLCK). It can be driven by the Atmel cell OSC55 or OSC56 (or an equivalent
cell) and an external 32.768 kHz crystal.
During low power modes of the processor (idle mode), the oscillator runs and power consumption is critical. The
crystal selection has to take into account the current consumption for power saving and the frequency drift due to
temperature effect on the circuit for time accuracy.
14.4.2
Timing
The RTC is updated in real time at one-second intervals in normal mode for the counters of seconds, at one-minute
intervals for the counter of minutes and so on.
Due to the asynchronous operation of the RTC with respect to the rest of the chip, to be certain that the value read
in the RTC registers (century, year, month, date, day, hours, minutes, seconds) are valid and stable, it is necessary
to read these registers twice. If the data is the same both times, then it is valid. Therefore, a minimum of two and a
maximum of three accesses are required.
14.4.3
Alarm
The RTC has five programmable fields: month, date, hours, minutes and seconds.
Each of these fields can be enabled or disabled to match the alarm condition:
• If all the fields are enabled, an alarm flag is generated (the corresponding flag is asserted and an interrupt
generated if enabled) at a given month, date, hour/minute/second.
• If only the “seconds” field is enabled, then an alarm is generated every minute.
Depending on the combination of fields enabled, a large number of possibilities are available to the user ranging
from minutes to 365/366 days.
14.4.4
Error Checking
Verification on user interface data is performed when accessing the century, year, month, date, day, hours, minutes, seconds and alarms. A check is performed on illegal BCD entries such as illegal date of the month with
regard to the year and century configured.
If one of the time fields is not correct, the data is not loaded into the register/counter and a flag is set in the validity
register. The user can not reset this flag. It is reset as soon as an acceptable value is programmed. This avoids any
further side effects in the hardware. The same procedure is done for the alarm.
The following checks are performed:
1. Century (check if it is in range 19 - 20)
2. Year (BCD entry check)
3. Date (check range 01 - 31)
4. Month (check if it is in BCD range 01 - 12, check validity regarding “date”)
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5. Day (check range 1 - 7)
6. Hour (BCD checks: in 24-hour mode, check range 00 - 23 and check that AM/PM flag is not set if RTC is
set in 24-hour mode; in 12-hour mode check range 01 - 12)
7. Minute (check BCD and range 00 - 59)
8. Second (check BCD and range 00 - 59)
Note:
14.4.5
If the 12-hour mode is selected by means of the RTC_MODE register, a 12-hour value can be programmed and the
returned value on RTC_TIME will be the corresponding 24-hour value. The entry control checks the value of the
AM/PM indicator (bit 22 of RTC_TIME register) to determine the range to be checked.
Updating Time/Calendar
To update any of the time/calendar fields, the user must first stop the RTC by setting the corresponding field in the
Control Register. Bit UPDTIM must be set to update time fields (hour, minute, second) and bit UPDCAL must be
set to update calendar fields (century, year, month, date, day).
Then the user must poll or wait for the interrupt (if enabled) of bit ACKUPD in the Status Register. Once the bit
reads 1, it is mandatory to clear this flag by writing the corresponding bit in RTC_SCCR. The user can now write to
the appropriate Time and Calendar register.
Once the update is finished, the user must reset (0) UPDTIM and/or UPDCAL in the Control
When entering programming mode of the calendar fields, the time fields remain enabled. When entering the programming mode of the time fields, both time and calendar fields are stopped. This is due to the location of the
calendar logic circuity (downstream for low-power considerations). It is highly recommended to prepare all the
fields to be updated before entering programming mode. In successive update operations, the user must wait at
least one second after resetting the UPDTIM/UPDCAL bit in the RTC_CR (Control Register) before setting these
bits again. This is done by waiting for the SEC flag in the Status Register before setting UPDTIM/UPDCAL bit. After
resetting UPDTIM/UPDCAL, the SEC flag must also be cleared.
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Figure 14-2. Update Sequence
Begin
Prepare TIme or Calendar Fields
Set UPDTIM and/or UPDCAL
bit(s) in RTC_CR
Read RTC_SR
Polling or
IRQ (if enabled)
ACKUPD
=1?
No
Yes
Clear ACKUPD bit in RTC_SCCR
Update Time andor Calendar values in
RTC_TIMR/RTC_CALR
Clear UPDTIM and/or UPDCAL bit in
RTC_CR
End
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14.5
Real-time Clock (RTC) User Interface
Table 14-1.
Offset
Register Mapping
Register
Name
Access
Reset
0x00
Control Register
RTC_CR
Read-write
0x0
0x04
Mode Register
RTC_MR
Read-write
0x0
0x08
Time Register
RTC_TIMR
Read-write
0x0
0x0C
Calendar Register
RTC_CALR
Read-write
0x01819819
0x10
Time Alarm Register
RTC_TIMALR
Read-write
0x0
0x14
Calendar Alarm Register
RTC_CALALR
Read-write
0x01010000
0x18
Status Register
RTC_SR
Read-only
0x0
0x1C
Status Clear Command Register
RTC_SCCR
Write-only
---
0x20
Interrupt Enable Register
RTC_IER
Write-only
---
0x24
Interrupt Disable Register
RTC_IDR
Write-only
---
0x28
Interrupt Mask Register
RTC_IMR
Read-only
0x0
0x2C
Valid Entry Register
RTC_VER
Read-only
0x0
0xFC
Reserved Register
–
–
–
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14.5.1
Name:
RTC Control Register
RTC_CR
Access Type: Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
–
–
–
–
–
–
15
14
13
12
11
10
–
–
–
–
–
–
16
CALEVSEL
9
8
TIMEVSEL
7
6
5
4
3
2
1
0
–
–
–
–
–
–
UPDCAL
UPDTIM
• UPDTIM: Update Request Time Register
0 = No effect.
1 = Stops the RTC time counting.
Time counting consists of second, minute and hour counters. Time counters can be programmed once this bit is set and
acknowledged by the bit ACKUPD of the Status Register.
• UPDCAL: Update Request Calendar Register
0 = No effect.
1 = Stops the RTC calendar counting.
Calendar counting consists of day, date, month, year and century counters. Calendar counters can be programmed once
this bit is set.
• TIMEVSEL: Time Event Selection
The event that generates the flag TIMEV in RTC_SR (Status Register) depends on the value of TIMEVSEL.
0 = Minute change.
1 = Hour change.
2 = Every day at midnight.
3 = Every day at noon.
• CALEVSEL: Calendar Event Selection
The event that generates the flag CALEV in RTC_SR depends on the value of CALEVSEL.
0 = Week change (every Monday at time 00:00:00).
1 = Month change (every 01 of each month at time 00:00:00).
2, 3 = Year change (every January 1 at time 00:00:00).
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14.5.2
Name:
RTC Mode Register
RTC_MR
Access Type: Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
HRMOD
• HRMOD: 12-/24-hour Mode
0 = 24-hour mode is selected.
1 = 12-hour mode is selected.
All non-significant bits read zero.
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14.5.3
Name:
RTC Time Register
RTC_TIMR
Access Type: Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
AMPM
15
14
10
9
8
2
1
0
HOUR
13
12
–
7
11
MIN
6
5
–
4
3
SEC
• SEC: Current Second
The range that can be set is 0 - 59 (BCD).
The lowest four bits encode the units. The higher bits encode the tens.
• MIN: Current Minute
The range that can be set is 0 - 59 (BCD).
The lowest four bits encode the units. The higher bits encode the tens.
• HOUR: Current Hour
The range that can be set is 1 - 12 (BCD) in 12-hour mode or 0 - 23 (BCD) in 24-hour mode.
• AMPM: Ante Meridiem Post Meridiem Indicator
This bit is the AM/PM indicator in 12-hour mode.
0 = AM.
1 = PM.
All non-significant bits read zero.
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14.5.4
Name:
RTC Calendar Register
RTC_CALR
Access Type: Read-write
31
30
–
–
23
22
29
28
27
14
25
24
18
17
16
DATE
21
20
19
DAY
15
26
MONTH
13
12
11
10
9
8
3
2
1
0
YEAR
7
6
5
–
4
CENT
• CENT: Current Century
The range that can be set is 19 - 20 (BCD).
The lowest four bits encode the units. The higher bits encode the tens.
• YEAR: Current Year
The range that can be set is 00 - 99 (BCD).
The lowest four bits encode the units. The higher bits encode the tens.
• MONTH: Current Month
The range that can be set is 01 - 12 (BCD).
The lowest four bits encode the units. The higher bits encode the tens.
• DAY: Current Day in Current Week
The range that can be set is 1 - 7 (BCD).
The coding of the number (which number represents which day) is user-defined as it has no effect on the date counter.
• DATE: Current Day in Current Month
The range that can be set is 01 - 31 (BCD).
The lowest four bits encode the units. The higher bits encode the tens.
All non-significant bits read zero.
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14.5.5
Name:
RTC Time Alarm Register
RTC_TIMALR
Access Type: Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
21
20
19
18
17
16
10
9
8
2
1
0
23
22
HOUREN
AMPM
15
14
HOUR
13
12
MINEN
7
11
MIN
6
5
SECEN
4
3
SEC
• SEC: Second Alarm
This field is the alarm field corresponding to the BCD-coded second counter.
• SECEN: Second Alarm Enable
0 = The second-matching alarm is disabled.
1 = The second-matching alarm is enabled.
• MIN: Minute Alarm
This field is the alarm field corresponding to the BCD-coded minute counter.
• MINEN: Minute Alarm Enable
0 = The minute-matching alarm is disabled.
1 = The minute-matching alarm is enabled.
• HOUR: Hour Alarm
This field is the alarm field corresponding to the BCD-coded hour counter.
• AMPM: AM/PM Indicator
This field is the alarm field corresponding to the BCD-coded hour counter.
• HOUREN: Hour Alarm Enable
0 = The hour-matching alarm is disabled.
1 = The hour-matching alarm is enabled.
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14.5.6
Name:
RTC Calendar Alarm Register
RTC_CALALR
Access Type: Read-write
31
30
DATEEN
–
29
28
27
26
25
24
18
17
16
DATE
23
22
21
MTHEN
–
–
20
19
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
MONTH
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
–
• MONTH: Month Alarm
This field is the alarm field corresponding to the BCD-coded month counter.
• MTHEN: Month Alarm Enable
0 = The month-matching alarm is disabled.
1 = The month-matching alarm is enabled.
• DATE: Date Alarm
This field is the alarm field corresponding to the BCD-coded date counter.
• DATEEN: Date Alarm Enable
0 = The date-matching alarm is disabled.
1 = The date-matching alarm is enabled.
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14.5.7
Name:
RTC Status Register
RTC_SR
Access Type: Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
CALEV
TIMEV
SEC
ALARM
ACKUPD
• ACKUPD: Acknowledge for Update
0 = Time and calendar registers cannot be updated.
1 = Time and calendar registers can be updated.
• ALARM: Alarm Flag
0 = No alarm matching condition occurred.
1 = An alarm matching condition has occurred.
• SEC: Second Event
0 = No second event has occurred since the last clear.
1 = At least one second event has occurred since the last clear.
• TIMEV: Time Event
0 = No time event has occurred since the last clear.
1 = At least one time event has occurred since the last clear.
The time event is selected in the TIMEVSEL field in RTC_CTRL (Control Register) and can be any one of the following
events: minute change, hour change, noon, midnight (day change).
• CALEV: Calendar Event
0 = No calendar event has occurred since the last clear.
1 = At least one calendar event has occurred since the last clear.
The calendar event is selected in the CALEVSEL field in RTC_CR and can be any one of the following events: week
change, month change and year change.
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14.5.8
Name:
RTC Status Clear Command Register
RTC_SCCR
Access Type: Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
CALCLR
TIMCLR
SECCLR
ALRCLR
ACKCLR
• ACKCLR: Acknowledge Clear
0 = No effect.
1 = Clears corresponding status flag in the Status Register (RTC_SR).
• ALRCLR: Alarm Clear
0 = No effect.
1 = Clears corresponding status flag in the Status Register (RTC_SR).
• SECCLR: Second Clear
0 = No effect.
1 = Clears corresponding status flag in the Status Register (RTC_SR).
• TIMCLR: Time Clear
0 = No effect.
1 = Clears corresponding status flag in the Status Register (RTC_SR).
• CALCLR: Calendar Clear
0 = No effect.
1 = Clears corresponding status flag in the Status Register (RTC_SR).
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14.5.9
Name:
RTC Interrupt Enable Register
RTC_IER
Access Type: Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
CALEN
TIMEN
SECEN
ALREN
ACKEN
• ACKEN: Acknowledge Update Interrupt Enable
0 = No effect.
1 = The acknowledge for update interrupt is enabled.
• ALREN: Alarm Interrupt Enable
0 = No effect.
1 = The alarm interrupt is enabled.
• SECEN: Second Event Interrupt Enable
0 = No effect.
1 = The second periodic interrupt is enabled.
• TIMEN: Time Event Interrupt Enable
0 = No effect.
1 = The selected time event interrupt is enabled.
• CALEN: Calendar Event Interrupt Enable
0 = No effect.
• 1 = The selected calendar event interrupt is enabled.
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14.5.10
Name:
RTC Interrupt Disable Register
RTC_IDR
Access Type: Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
CALDIS
TIMDIS
SECDIS
ALRDIS
ACKDIS
• ACKDIS: Acknowledge Update Interrupt Disable
0 = No effect.
1 = The acknowledge for update interrupt is disabled.
• ALRDIS: Alarm Interrupt Disable
0 = No effect.
1 = The alarm interrupt is disabled.
• SECDIS: Second Event Interrupt Disable
0 = No effect.
1 = The second periodic interrupt is disabled.
• TIMDIS: Time Event Interrupt Disable
0 = No effect.
1 = The selected time event interrupt is disabled.
• CALDIS: Calendar Event Interrupt Disable
0 = No effect.
1 = The selected calendar event interrupt is disabled.
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14.5.11
Name:
RTC Interrupt Mask Register
RTC_IMR
Access Type:Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
CAL
TIM
SEC
ALR
ACK
• ACK: Acknowledge Update Interrupt Mask
0 = The acknowledge for update interrupt is disabled.
1 = The acknowledge for update interrupt is enabled.
• ALR: Alarm Interrupt Mask
0 = The alarm interrupt is disabled.
1 = The alarm interrupt is enabled.
• SEC: Second Event Interrupt Mask
0 = The second periodic interrupt is disabled.
1 = The second periodic interrupt is enabled.
• TIM: Time Event Interrupt Mask
0 = The selected time event interrupt is disabled.
1 = The selected time event interrupt is enabled.
• CAL: Calendar Event Interrupt Mask
0 = The selected calendar event interrupt is disabled.
1 = The selected calendar event interrupt is enabled.
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14.5.12
Name:
RTC Valid Entry Register
RTC_VER
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
NVCALALR
NVTIMALR
NVCAL
NVTIM
• NVTIM: Non-valid Time
0 = No invalid data has been detected in RTC_TIMR (Time Register).
1 = RTC_TIMR has contained invalid data since it was last programmed.
• NVCAL: Non-valid Calendar
0 = No invalid data has been detected in RTC_CALR (Calendar Register).
1 = RTC_CALR has contained invalid data since it was last programmed.
• NVTIMALR: Non-valid Time Alarm
0 = No invalid data has been detected in RTC_TIMALR (Time Alarm Register).
1 = RTC_TIMALR has contained invalid data since it was last programmed.
• NVCALALR: Non-valid Calendar Alarm
0 = No invalid data has been detected in RTC_CALALR (Calendar Alarm Register).
1 = RTC_CALALR has contained invalid data since it was last programmed.
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15. Periodic Interval Timer (PIT)
15.1
Overview
The Periodic Interval Timer (PIT) provides the operating system’s scheduler interrupt. It is designed to offer maximum accuracy and efficient management, even for systems with long response time.
15.2
Block Diagram
Figure 15-1. Periodic Interval Timer
PIT_MR
PIV
=?
PIT_MR
PITIEN
set
0
PIT_SR
PITS
pit_irq
reset
0
MCK
Prescaler
0
0
1
12-bit
Adder
1
read PIT_PIVR
20-bit
Counter
MCK/16
CPIV
PIT_PIVR
CPIV
PIT_PIIR
PICNT
PICNT
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15.3
Functional Description
The Periodic Interval Timer aims at providing periodic interrupts for use by operating systems.
The PIT provides a programmable overflow counter and a reset-on-read feature. It is built around two counters: a
20-bit CPIV counter and a 12-bit PICNT counter. Both counters work at Master Clock /16.
The first 20-bit CPIV counter increments from 0 up to a programmable overflow value set in the field PIV of the
Mode Register (PIT_MR). When the counter CPIV reaches this value, it resets to 0 and increments the Periodic
Interval Counter, PICNT. The status bit PITS in the Status Register (PIT_SR) rises and triggers an interrupt, provided the interrupt is enabled (PITIEN in PIT_MR).
Writing a new PIV value in PIT_MR does not reset/restart the counters.
When CPIV and PICNT values are obtained by reading the Periodic Interval Value Register (PIT_PIVR), the overflow counter (PICNT) is reset and the PITS is cleared, thus acknowledging the interrupt. The value of PICNT gives
the number of periodic intervals elapsed since the last read of PIT_PIVR.
When CPIV and PICNT values are obtained by reading the Periodic Interval Image Register (PIT_PIIR), there is no
effect on the counters CPIV and PICNT, nor on the bit PITS. For example, a profiler can read PIT_PIIR without
clearing any pending interrupt, whereas a timer interrupt clears the interrupt by reading PIT_PIVR.
The PIT may be enabled/disabled using the PITEN bit in the PIT_MR register (disabled on reset). The PITEN bit
only becomes effective when the CPIV value is 0. Figure 15-2 illustrates the PIT counting. After the PIT Enable bit
is reset (PITEN= 0), the CPIV goes on counting until the PIV value is reached, and is then reset. PIT restarts counting, only if the PITEN is set again.
The PIT is stopped when the core enters debug state.
Figure 15-2. Enabling/Disabling PIT with PITEN
APB cycle
APB cycle
MCK
15
restarts MCK Prescaler
MCK Prescaler 0
PITEN
CPIV
PICNT
0
1
PIV - 1
0
PIV
1
0
1
0
PITS (PIT_SR)
APB Interface
read PIT_PIVR
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15.4
Periodic Interval Timer (PIT) User Interface
Table 15-1.
Register Mapping
Offset
Register
Name
Access
Reset
0x00
Mode Register
PIT_MR
Read-write
0x000F_FFFF
0x04
Status Register
PIT_SR
Read-only
0x0000_0000
0x08
Periodic Interval Value Register
PIT_PIVR
Read-only
0x0000_0000
0x0C
Periodic Interval Image Register
PIT_PIIR
Read-only
0x0000_0000
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15.4.1
Periodic Interval Timer Mode Register
Register Name:
PIT_MR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
23
–
22
–
21
–
20
–
19
18
15
14
13
12
25
PITIEN
24
PITEN
17
16
PIV
11
10
9
8
3
2
1
0
PIV
7
6
5
4
PIV
• PIV: Periodic Interval Value
Defines the value compared with the primary 20-bit counter of the Periodic Interval Timer (CPIV). The period is equal to
(PIV + 1).
• PITEN: Period Interval Timer Enabled
0 = The Periodic Interval Timer is disabled when the PIV value is reached.
1 = The Periodic Interval Timer is enabled.
• PITIEN: Periodic Interval Timer Interrupt Enable
0 = The bit PITS in PIT_SR has no effect on interrupt.
1 = The bit PITS in PIT_SR asserts interrupt.
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15.4.2
Periodic Interval Timer Status Register
Register Name:
PIT_SR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
–
6
–
5
–
4
–
3
–
2
–
1
–
0
PITS
• PITS: Periodic Interval Timer Status
0 = The Periodic Interval timer has not reached PIV since the last read of PIT_PIVR.
1 = The Periodic Interval timer has reached PIV since the last read of PIT_PIVR.
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15.4.3
Periodic Interval Timer Value Register
Register Name:
PIT_PIVR
Access Type:
31
Read-only
30
29
28
27
26
19
18
25
24
17
16
PICNT
23
22
21
20
PICNT
15
14
CPIV
13
12
11
10
9
8
3
2
1
0
25
24
17
16
CPIV
7
6
5
4
CPIV
Reading this register clears PITS in PIT_SR.
• CPIV: Current Periodic Interval Value
Returns the current value of the periodic interval timer.
• PICNT: Periodic Interval Counter
Returns the number of occurrences of periodic intervals since the last read of PIT_PIVR.
15.4.4
Periodic Interval Timer Image Register
Register Name:
PIT_PIIR
Access Type:
31
Read-only
30
29
28
27
26
19
18
PICNT
23
22
21
20
PICNT
15
14
CPIV
13
12
11
10
9
8
3
2
1
0
CPIV
7
6
5
4
CPIV
• CPIV: Current Periodic Interval Value
Returns the current value of the periodic interval timer.
• PICNT: Periodic Interval Counter
Returns the number of occurrences of periodic intervals since the last read of PIT_PIVR.
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16. Watchdog Timer (WDT)
16.1
Overview
The Watchdog Timer can be used to prevent system lock-up if the software becomes trapped in a deadlock. It features a 12-bit down counter that allows a watchdog period of up to 16 seconds (slow clock at 32.768 kHz). It can
generate a general reset or a processor reset only. In addition, it can be stopped while the processor is in debug
mode or idle mode.
16.2
Block Diagram
Figure 16-1. Watchdog Timer Block Diagram
write WDT_MR
WDT_MR
WDV
WDT_CR
WDRSTT
reload
1
0
12-bit Down
Counter
WDT_MR
WDD
reload
Current
Value
1/128
SLCK
<= WDD
WDT_MR
WDRSTEN
= 0
wdt_fault
(to Reset Controller)
set
set
read WDT_SR
or
reset
WDERR
reset
WDUNF
reset
wdt_int
WDFIEN
WDT_MR
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16.3
Functional Description
The Watchdog Timer can be used to prevent system lock-up if the software becomes trapped in a deadlock. It is
supplied with VDDCORE. It restarts with initial values on processor reset.
The Watchdog is built around a 12-bit down counter, which is loaded with the value defined in the field WDV of the
Mode Register (WDT_MR). The Watchdog Timer uses the Slow Clock divided by 128 to establish the maximum
Watchdog period to be 16 seconds (with a typical Slow Clock of 32.768 kHz).
After a Processor Reset, the value of WDV is 0xFFF, corresponding to the maximum value of the counter with the
external reset generation enabled (field WDRSTEN at 1 after a Backup Reset). This means that a default Watchdog is running at reset, i.e., at power-up. The user must either disable it (by setting the WDDIS bit in WDT_MR) if
he does not expect to use it or must reprogram it to meet the maximum Watchdog period the application requires.
The Watchdog Mode Register (WDT_MR) can be written only once. Only a processor reset resets it. Writing the
WDT_MR register reloads the timer with the newly programmed mode parameters.
In normal operation, the user reloads the Watchdog at regular intervals before the timer underflow occurs, by writing the Control Register (WDT_CR) with the bit WDRSTT to 1. The Watchdog counter is then immediately
reloaded from WDT_MR and restarted, and the Slow Clock 128 divider is reset and restarted. The WDT_CR register is write-protected. As a result, writing WDT_CR without the correct hard-coded key has no effect. If an
underflow does occur, the “wdt_fault” signal to the Reset Controller is asserted if the bit WDRSTEN is set in the
Mode Register (WDT_MR). Moreover, the bit WDUNF is set in the Watchdog Status Register (WDT_SR).
To prevent a software deadlock that continuously triggers the Watchdog, the reload of the Watchdog must occur
while the Watchdog counter is within a window between 0 and WDD, WDD is defined in the WatchDog Mode Register WDT_MR.
Any attempt to restart the Watchdog while the Watchdog counter is between WDV and WDD results in a Watchdog
error, even if the Watchdog is disabled. The bit WDERR is updated in the WDT_SR and the “wdt_fault” signal to
the Reset Controller is asserted.
Note that this feature can be disabled by programming a WDD value greater than or equal to the WDV value. In
such a configuration, restarting the Watchdog Timer is permitted in the whole range [0; WDV] and does not generate an error. This is the default configuration on reset (the WDD and WDV values are equal).
The status bits WDUNF (Watchdog Underflow) and WDERR (Watchdog Error) trigger an interrupt, provided the bit
WDFIEN is set in the mode register. The signal “wdt_fault” to the reset controller causes a Watchdog reset if the
WDRSTEN bit is set as already explained in the reset controller programmer Datasheet. In that case, the processor and the Watchdog Timer are reset, and the WDERR and WDUNF flags are reset.
If a reset is generated or if WDT_SR is read, the status bits are reset, the interrupt is cleared, and the “wdt_fault”
signal to the reset controller is deasserted.
Writing the WDT_MR reloads and restarts the down counter.
While the processor is in debug state or in idle mode, the counter may be stopped depending on the value programmed for the bits WDIDLEHLT and WDDBGHLT in the WDT_MR.
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Figure 16-2. Watchdog Behavior
Watchdog Error
Watchdog Underflow
if WDRSTEN is 1
FFF
if WDRSTEN is 0
Normal behavior
WDV
Forbidden
Window
WDD
Permitted
Window
0
Watchdog
Fault
WDT_CR = WDRSTT
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16.4
Watchdog Timer (WDT) User Interface
Table 16-1.
Offset
Register Mapping
Register
Name
Access
Reset
0x00
Control Register
WDT_CR
Write-only
-
0x04
Mode Register
WDT_MR
Read-write Once
0x3FFF_2FFF
0x08
Status Register
WDT_SR
Read-only
0x0000_0000
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16.4.1
Watchdog Timer Control Register
Register Name:
WDT_CR
Access Type:
31
Write-only
30
29
28
27
26
25
24
KEY
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
–
6
–
5
–
4
–
3
–
2
–
1
–
0
WDRSTT
• WDRSTT: Watchdog Restart
0: No effect.
1: Restarts the Watchdog.
• KEY: Password
Should be written at value 0xA5. Writing any other value in this field aborts the write operation.
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16.4.2
Watchdog Timer Mode Register
Register Name:
WDT_MR
Access Type:
Read-write Once
31
–
30
–
29
WDIDLEHLT
28
WDDBGHLT
27
26
23
22
21
20
19
18
11
10
25
24
17
16
9
8
1
0
WDD
WDD
15
WDDIS
14
13
12
WDRPROC
WDRSTEN
WDFIEN
7
6
5
4
WDV
3
2
WDV
• WDV: Watchdog Counter Value
Defines the value loaded in the 12-bit Watchdog Counter.
• WDFIEN: Watchdog Fault Interrupt Enable
0: A Watchdog fault (underflow or error) has no effect on interrupt.
1: A Watchdog fault (underflow or error) asserts interrupt.
• WDRSTEN: Watchdog Reset Enable
0: A Watchdog fault (underflow or error) has no effect on the resets.
1: A Watchdog fault (underflow or error) triggers a Watchdog reset.
• WDRPROC: Watchdog Reset Processor
0: If WDRSTEN is 1, a Watchdog fault (underflow or error) activates all resets.
1: If WDRSTEN is 1, a Watchdog fault (underflow or error) activates the processor reset.
• WDD: Watchdog Delta Value
Defines the permitted range for reloading the Watchdog Timer.
If the Watchdog Timer value is less than or equal to WDD, writing WDT_CR with WDRSTT = 1 restarts the timer.
If the Watchdog Timer value is greater than WDD, writing WDT_CR with WDRSTT = 1 causes a Watchdog error.
• WDDBGHLT: Watchdog Debug Halt
0: The Watchdog runs when the processor is in debug state.
1: The Watchdog stops when the processor is in debug state.
• WDIDLEHLT: Watchdog Idle Halt
0: The Watchdog runs when the system is in idle mode.
1: The Watchdog stops when the system is in idle state.
• WDDIS: Watchdog Disable
0: Enables the Watchdog Timer.
1: Disables the Watchdog Timer.
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16.4.3
Watchdog Timer Status Register
Register Name:
WDT_SR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
–
6
–
5
–
4
–
3
–
2
–
1
WDERR
0
WDUNF
• WDUNF: Watchdog Underflow
0: No Watchdog underflow occurred since the last read of WDT_SR.
1: At least one Watchdog underflow occurred since the last read of WDT_SR.
• WDERR: Watchdog Error
0: No Watchdog error occurred since the last read of WDT_SR.
1: At least one Watchdog error occurred since the last read of WDT_SR.
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17. Supply Controller (SUPC)
17.1
Overview
The Supply Controller (SUPC) controls the supply voltages of the system. In a typical application, the Supply Controller allows supply of the device directly from a double NiMH or NiCd battery or from a double CR2031 Lithium
battery or from any Lithium rechargeable battery.
The Supply Controller offers a wide range of Low Power Modes, including:
• Off Mode, current consumption reduced to below 1 microamp, exits on the assertion of the Force Wake Up pin
(FWUP)
• Backup Mode, current consumption reduced to a few microamps for Clock and SRAM retention, exits on
multiple wake-up sources
• Running Mode, reaches a 30-MIPS performance level
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17.2
Block Diagram
Figure 17-1. Supply Controller Block Diagram
VDDIO1
vdd_on
F W UP
VDD_S W
rt_on
s upply_on
fwup
rtc_alarm
rt_nres et
bod_in
Brownout
Detector
RTC
s low_clock
bod_on
bod_thres hold
s ram_on
Zero-power
poweron_res et
Power-on
Reset
SRAM
Backup
lcd_pump_on
os c32k_xtal_en
os c32k_s el
Embedded
32 kHz RC
Oscillator
XIN
XO UT
Supply
Controller
lcd_out
Memory
Controller
VDDINLC D
LCD
Charge
Pump
VDD3V6
LCD
Voltage
Regulator
VDDLC D
VDDIO 2
lcd_nres et
S LC K
s low_clock
Xtal 32 kHz
Oscillator
s low_clock
lcd_eof
LCD
Controller
vr_s tandby
vr_vdd
os c32k_rc_en
vr_deep
VDDIO 1
Voltage
Regulator
VDDC O R E
vr_ok
NR S T B
vddcore_nres et
W K UP 0-W K UP 15
s low_clock
Reset
Controller
Power
Management
Controller
flas h_on
AP B
Flash
Memory
Controller
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17.3
Supply Controller Functional Description
17.3.1
Supply Controller Overview
The Supply Controller controls the power supplies of each section of the product:
• The Backup, including the Supply Controller, a part of the Reset Controller and the Slow Clock switcher
• The backup SRAM
• The Clock, including the Real Time Clock
• The Flash Memory
• The CORE, including the other part of the Reset Controller, the Processor and the Peripherals
• the LCD controller, the charge pump and the LCD voltage regulator
The Supply Controller has its own reset circuitry and is clocked by the 32 kHz Slow clock generator.
The reset circuitry is based on the NRSTB pin, a zero-power power-on reset cell and a brownout detector cell. The
zero-power power-on reset allows the Supply Controller to start properly, while the software-programmable Brownout Detector detects either a battery discharge or main voltage loss.
The Slow Clock generator is based on a 32 kHz crystal oscillator and an embedded 32 kHz RC oscillator. The Slow
Clock defaults to the RC oscillator, but the software can enable the crystal oscillator and select it as the Slow Clock
source.
The Supply Controller starts up the device by sequentially enabling the internal power switches and the Voltage
Regulator, then generates the proper reset signals to the core power supply.
It also sets the system in different low power modes and wakes it up from a wide range of events.
17.3.2
Slow Clock Generator
The Supply Controller embeds a slow clock generator that is supplied with the backup power supply. As soon as
FWUP is asserted, both the crystal oscillator and the embedded RC oscillator are powered up, but only the embedded RC oscillator is enabled. This allows the slow clock to be valid in a short time (about 100 µs).
The user can select the crystal oscillator to be the source of the slow clock, as it provides a more accurate frequency. The command is made by writing the Supply Controller Control Register, SUPC_CR, with the XTALSEL
bit at 1. This results in a sequence which first enables the crystal oscillator, then waits for 32,768 slow clock cycles,
then switches the slow clock on the output of the crystal oscillator and then disables the RC oscillator to save
power. The switch of the slow clock source is glitch free. The OSCSEL bit of the Supply Controller Status Register,
SUPC_SR, allows knowing when the switch sequence is done.
Coming back on the RC oscillator is only possible by shutting down the backup power supply.
If the user does not need the crystal oscillator, the XIN and XOUT pins should be left unconnected.
The user can also set the crystal oscillator in bypass mode instead of connecting a crystal. In this case, the user
has to provide the external clock signal on the XIN. The input characteristics of the XIN pin are given in the product
electrical characteristics section. In order to set the bypass mode, the OSCBYPASS bit of the Supply Controller
Mode Register (SUPC_MR) needs to be set at 1.
17.3.3
Brownout Detector
The Supply Controller embeds a Brownout Detector.
The Brownout Detector can be used to prevent the processor from falling into an unpredictable state if the power
supply drops below a certain level or to detect a battery discharge.
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The threshold of the Brownout Detector is programmable. It can be selected from 1.9V to 3.4V by steps of 100 mV.
This threshold is programmed in the BODTH field of the Supply Controller Brownout Mode Register,
SUPC_BOMR.
The Brownout Detector can also be enabled during one slow clock period of either 32, 256 or 2048 slow clock periods. This can be configured by programming the BODSMPL field in SUPC_BOMR.
Enabling the Brownout Detector for such reduced times allows to divide the typical Brownout Detector power consumption respectively by factors of 32, 256 or 2048, if the user does not need a continuous monitoring of the
VDDIO1 Power Supply.
The Brownout Detector can either generate a reset of the Core or a wake up of the Core Power Supply. Generating
a Core reset when a brownout occurs is enabled by writing the BODRSTEN bit to 1 in SUPC_BOMR.
Waking up the Core Power Supply when a brownout occurs can be enabled by programming the BODEN bit to 1 in
the Supply Controller Wake Up Mode Register, SUPC_WUMR.
17.3.4
Backup Power Supply Reset
17.3.4.1
Raising the Backup Power Supply
Powering VDDIO1 does not power the device since FWUP is not asserted. If the FWUP pin is not used, it shall be
connected to GND.
When the FWUP pin is tied to GND, the backup power supply is enabled. The RC oscillator is powered up and the
zero-power power-on reset cell maintains its output for a time longer than the startup of the RC oscillator. During
this time, the Supply Controller is entirely reset. When this signal is released a counter is started for 30 slow clock
cycles. This is the debouncing of the Force Wake Up pin. If the FWUP pin is not maintained low, the backup power
supply is powered off.
If the FWUP pin is maintained low, the signal, supply_on is asserted, thus auto-maintaining the backup power supply. The FWUP pin becomes a wake up source.
At the same time the supply_on signal is asserted, the voltage regulator, the Flash Memory and the SRAM are
powered up according to the User Interface reset state. The voltage regulator starts and provides the vr_ok signal
as soon as its output is valid. This results in releasing the vddcore_nreset signal to the Reset Controller after the
vr_ok signal has been confirmed as being valid for at least one slow clock cycle.
At the same time the voltage regulator is powered up, the Supply Controller and all of the devices supplied by the
backup power supply, are correctly started. The Supply Controller also sets the status bit, FWUPS in the Supply
Controller Status Register, SUPC_SR. This status bit is cleared as soon as SUPC_SR is read and indicates the
first power up of the backup power supply.
Reading FWUPS to 0 means SUPC_SR has already been read since the power up of the backup power supply
and thus, it is not necessary to initialize the Supply Controller.
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Figure 17-2. Raising the Backup Power Supply
30 Slow Clock Cycles = about 1ms
at least 1 Slow Clock Cycle
FWUP
Backup Power Supply
Zero-Power Power-On
Reset Cell output
RC Oscillator output
supply_on
sram_on
vr_standby
vr_ok
vddcore_nreset
17.3.4.2
NRSTB Asynchronous Reset Pin
The NRSTB pin is an asynchronous reset input, which acts exactly like the zero-power power-on reset cell.
As soon as NRSTB is tied to GND, the supply controller is reset and all the system parts are powered off.
When NRSTB is released, the system can start as described in Section 17.3.4.1 ”Raising the Backup Power
Supply”.
Figure 17-3. NRSTB Reset when FWUP = 0
30 Slow Clock Cycles = about 1ms
at least 1 Slow Clock Cycle
NRSTB
FWUP
RC Oscillator
output
supply_on
sram_on
vr_standby
vr_ok
vddcore_nreset
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Figure 17-4. NRSTB Reset when FWUP = 1 and NRSTB is Released Before FWUP = 0
30 Slow Clock Cycles = about 1 ms
at least 1 Slow Clock Cycle
NRSTB
FWUP
RC Oscillator
output
supply_on
sram_on
vr_standby
vr_ok
core_nreset
Figure 17-5. NRSTB Reset when FWUP = 1 and NRSTB is Released After FWUP = 0
30 Slow Clock Cycles = about 1 ms
at least 1 Slow Clock Cycle
NRSTB
FWUP
RC Oscillator
output
supply_on
sram_on
vr_standby
vr_ok
core_nreset
17.3.5
Core Reset
The Supply Controller manages the vddcore_nreset signal to the Reset Controller, as described previously in Section 17.3.4 ”Backup Power Supply Reset”. The vddcore_nreset signal is normally asserted before shutting down
the core power supply and released as soon as the core power supply is correctly regulated.
There are two additional sources which can be programmed to activate vddcore_nreset:
• the brownout detector
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• voltage regulation loss
17.3.5.1
Brownout Detector Reset
The Brownout Detector is capable of generating a reset of the system. This can be enabled by setting the
BODRSTEN bit in the Supply Controller Mode Register, SUPC_MR.
If BODRSTEN is set and a brownout is detected, the vddcore_nreset signal is immediately activated for a minimum
of 2 slow clock cycles.
17.3.5.2
Voltage Regulation Loss Reset
The voltage regulator provides the vr_ok signal which indicates that the regulation is operating as programmed. If
this signal is lost for longer than 1 slow clock period while the voltage regulator is enabled, the Supply Controller
can assert vddcore_nreset. This feature is enabled by writing the bit, VRRSTEN (Voltage Regulator Reset Enable)
to 1 in the Supply Controller Mode Register, SUPC_MR and if the voltage regulator is set in normal mode
(VRMODE is at 0).
When the voltage regulator is in deep mode, this feature is not enabled.
If VRRSTEN is set and the voltage regulation is lost (output voltage of the regulator too low), the vddcore_nreset
signal is asserted for a minimum of 2 slow clock periods and then released if vr_ok has been reactivated. The
VRRSTS bit is set in the Supply Controller Status Register, SUPC_SR, so that the user can know the source of the
last reset.
Until vr_ok is deactivated, the vddcore_nreset signal remains active.
17.3.6
Power Supply Control
17.3.6.1
Controlling the Backup Power Supply
The backup power supply can be controlled by the main power switch. This main power switch can only be
enabled by tying the FWUP pin to GND. As soon as the power has risen, the Supply Controller maintains the main
power switch closed by asserting the signal, supply_on.
The main power switch can be opened by the software by writing the Supply Controller Control Register SUPC_CR
with the shutdown bit, SHDW set at 1.
Writing SUPC_CR with SHDW set at 1 results in the following actions:
• asserts the vddcore_nreset signal then switches off the voltage regulator
• if the LCD charge pump is enabled, asserts the lcd_nreset signal then disables the LCD charge pump
• asserts the Flash Memory reset signal and disables the Flash Memory power supply
• disables the SRAM power supply
• asserts the Clock reset signal, rt_nreset, then disables the Clock power supply
• releases the supply_on signal, thus switching off the backup power supply and enters Off Mode.
The shutdown sequence led by writing SHDW is described in Figure 17-6 on page 106.
It is also possible to wait the current frame of the LCD Controller before shutting down the LCD Controller power
supply. This can be done by writing the SHDWEOF bit to 1, instead of the SHDW bit.
If SHDWEOF is set, the sequence is exactly the same, except the end_of_frame signal shall be asserted for at
least one slow clock cycle before the lcd_nreset signal is asserted and the charge pump is disabled.
The shutdown sequence led by writing SHDWEOF is described in Figure 17-7 on page 107.
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Figure 17-6. Shutdown of the Backup Power Supply After Writing SHDW at 1
slow_clock
write_shdw
write_shdw_slck
vddcore_nreset
vr_standby
flash_off
flash_poe
VDDCORE
sram_on
lcd_nreset
lcd_pump_on
rt_nreset
rt_on
supply_on
VDDBU
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Figure 17-7. Shutdown of the Backup Power Supply After Writing SHDWEOF at 1
slow_clock
write_shdweof
write_shdweof_slck
lcd_eof
vddcore_nreset
vr_standby
flash_off
flash_poe
VDDCORE
sram_on
lcd_nreset
lcd_pump_on
rt_nreset
rt_on
supply_on
VDDBU
17.3.6.2
Controlling the Voltage Regulator
The Supply Controller can be used to control the embedded 1.8V voltage regulator.
The VRVDD field in the Supply Controller Mode Register, SUPC_MR, allows to select the output voltage between
1.55V and 1.80V, depending on the performance required by the processor.
The VRDEEP field in the Supply Controller Mode Register, SUPC_MR, allows to switch the voltage regulator into
deep mode, thus reducing its leakage current to a minimum.
The programmer can switch off the voltage regulator, and thus put the device in Backup Mode, by writing the Supply Controller Control Register, SUPC_CR, with the VROFF bit at 1. This asserts the vddcore_nreset signal after
the write resynchronization time which lasts, in the worse case, 2 slow clock cycles. Once the vddcore_nreset sig-
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nal is asserted, the processor and the peripherals are stopped 1 slow clock cycle before the core power supply
becomes off.
The loss of voltage regulation while the core power supply is enabled can be programmed to generate a reset by
writing the VRRSTEN bit to 1 in the Supply Controller Mode Register, SUPC_MR.
17.3.6.3
Controlling the SRAM Power Supply
The Supply Controller can be used to switch on or off the power supply of the backup SRAM by opening or closing
the SRAM power switch. This power switch is controlled by the SRAMON bit of the Supply Controller Mode Register, SUPC_MR. However, the battery backup SRAM is automatically switched on when the core power supply is
enabled, as the processor requires the SRAM as data memory space (Please refer to Figure 17-2 on page 103).
• If SRAMON is written to 1, there is no immediate effect, but the SRAM will be left powered when the Supply
Controller enters backup mode, thus retaining its content.
• If SRAMON is written to 0, there is no immediate effect, but the SRAM will be switched off when the Supply
Controller enters backup mode. The SRAM is automatically switched on at the exit of the backup mode.
17.3.6.4
Controlling the Clock Alarm Power Supply
The Supply Monitor can be used to switch on or off the power supply of the Clock Alarm (Real Time Clock (RTC))
by opening or closing the corresponding power switch. This power switch is controlled by the RTON bit in
SUPC_MR. After a backup reset, the Clock is not supplied (RTON = 0).
The status of the Clock Power supply can be seen through the status register (RTS in SUPC_ SR).
• If RTON is written to 1 while it is at 0, after the write resynchronization time (about 2 slow clock cycles), the
Clock power switch is closed by setting the signal, rt_on at 1, then after one slow clock cycle, the rt_nreset
signal is released. This ensures that the Clock is always properly cleared when its power rises.
• If RTON is written to 0 while it is at 1, after the write resynchronization time (about 2 slow clock cycles), the
rt_nreset signal is asserted, then after one slow clock cycle, the Clock power switch is opened by resetting the
signal, rt_on at 0.
There are several restrictions concerning the write of the RTON field:
• The user must check that the previous power supply switch operation is done before writing RTON again. To do
that, the user must check that the RTS flag has the correct value. If RTON is written to 0, the RTS flag is reset at
0. If RTON is written to 1, the RTS flag is set at 1.
• Writing RTON at 1 while it is already at 1 or writing RTON at 0 while it is already at 0 is forbidden and has no
effect.
17.3.6.5
Controlling the LCD Voltage Regulator Power Supply
The Supply Controller can be used to select the power supply source of the LCD voltage regulator. The LCD voltage regulator can either be supplied through an external power supply or by the embedded charge pump.
This selection is done by the LCDMODE field in the SUPC_MR register. After a backup reset, the LCDMODE field
is at 0x0, it means that no power supply source is selected and the LCD Controller reset signal, lcd_nreset is
asserted.
The status of the LCD Controller Reset can be seen through the LCDS field in the status register, SUPC_ SR.
• If LCDMODE is written to 0x2 while it is at 0x0 or 0x1, after the write resynchronization time (about 2 slow clock
cycles), the external power supply source is selected by setting the output signal, lcd_ext_on at 1, then after
one slow clock cycle, the reset signal, lcd_nreset is released.
• If LCDMODE is written to 0x0 while it is at 0x2, after the write resynchronization time (about 2 slow clock
cycles), the reset signal, lcd_nreset is asserted, then after one slow clock cycle, the external power supply
source is deselected by resetting the output signal, lcd_ext_on at 0.
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• If LCDMODE is written to 0x1 while it is at 0x2, after the write resynchronization time (about 2 slow clock
cycles), the Supply Controller waits for the End of Frame, then the reset signal, lcd_nreset is asserted, then
after one slow clock cycle, the external power supply source is deselected by resetting the output signal,
lcd_ext_on at 0.
• If LCDMODE is written to 0x3 while it is at 0x0 or 0x1, after the write resynchronization time (about 2 slow clock
cycles), the internal power supply source is selected and the embedded charge pump turned on by setting the
output signal, lcd_int_on at 1, then after 15 slow clock cycles, the reset signal, lcd_nreset is released.
• If LCDMODE is written to 0x0 while it is at 0x3, after the write resynchronization time (about 2 slow clock
cycles), the reset signal, lcd_nreset is asserted, then after one slow clock cycle, the internal power supply
source is deselected and the embedded charge pump turned off by resetting the output signal, lcd_int_on at 0.
• If LCDMODE is written to 0x1 while it is at 0x3, after the write resynchronization time (about 2 slow clock
cycles), the Supply Controller waits for the End of Frame, then the reset signal, lcd_nreset is asserted, then
after one slow clock cycle, the internal power supply source is deselected and the embedded charge pump
turned off by resetting the output signal, lcd_int_on at 0.
There are several restrictions concerning the write of the LCDMODE field:
• The user must check that the previous power supply selection is done before writing LCDMODE again. To do
that, the user must check that the LCDS flag has the correct value. If LCDMODE is written to 0x0 or 0x1, the
LCDS flag is reset at 0. If LCDMODE is written to 0x0 or 0x1, the LCDS flag is set at 1.
• Writing LCDMODE to 0x2 while it is at 0x3 or writing LCDMODE to 0x3 while it is at 0x2 is forbidden and has no
effect.
• Before writing LCDMODE to 0x2, the user must ensure that the external power supply is ready and supplies the
VDDLCD pad.
• Before writing LCDMODE to 0x3, the user must ensure that the external power supply doesn’t supply the
VDDLCD pad.
17.3.6.6
Controlling the Flash Memory Power Supply
The Supply Controller can be used to switch on or off the power supply of the Flash Memory by opening or closing
the Flash Memory power switch (connected to VDDCORE). This power switch is controlled by the FLASHON bit of
the Supply Controller Mode Register (SUPC_MR). Before setting FLASHON to 1 or 0, the user needs to program
SUPC_FWUT correctly. Based on this counter the Supply Controller will correctly manage the control of the Flash
Memory (refer to the wake-up time of the Flash Memory in the Electrical Characteristics section of the product
datasheet).
The Flash Memory is automatically switched on when the core power supply is enabled at start up.
The status of the Flash Memory, i.e., ready to use, or not ready, can be seen through the FLASHS field in the status register SUPC_ SR.
• If FLASHON is written to 1 while it is at 0, after one main clock cycle, the Flash Memory power switch is closed
by resetting the flash_off signal at 0, then after ninety main clock cycles the FLASHS flag signal is set at 1. This
ensures that the Flash Memory is always properly cleared when its power rises.
• If FLASHON is written to 0 while it is at 1, after one main clock cycle, the flag FLASHS is reset to 0, then two
main clock cycles after, the Flash Memory power switch is opened by setting the signal, flash_off at 1.
There are several restrictions concerning the write of the FLASHON field:
• The user must check that the previous power supply switch operation is done before writing FLASHON again.
To do that, the user must check that the FLASHS flag has the correct value. If FLASHON is written to 0, the
FLASHS flag is reset at 0. If FLASHON is written to 1, the FLASHS flag is set at 1.
• Writing FLASHON at 1 while it is already at 1 or writing FLASHON at 0 while it is already at 0 is forbidden and
has no effect.
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17.3.7
Wake Up Sources
The wake up events allow the device to exit backup mode. When a wake up event is detected, the Supply Controller performs a sequence which automatically reenables the core power supply, and the SRAM power supply, if it is
not already enabled.
Figure 17-8. Wake Up Sources
BODEN
brown_out
RTCEN
rtc_alarm
Core
Supply
Restart
FWUPDBC
SLCK
FWUPEN
FWUP
Falling/Rising
Edge
Detector
WKUPT0
WKUP0
WKUPIS0
WKUPDBC
WKUPEN1
WKUPIS1
WKUPS
SLCK
Debouncer
Falling/Rising
Edge
Detector
WKUPT15
WKUP15
WKUPEN0
Falling/Rising
Edge
Detector
WKUPT1
WKUP1
FWUP
Debouncer
WKUPEN15
WKUPIS15
Falling/Rising
Edge
Detector
17.3.7.1
Force W
ake Up
The Force Wake Up pin, FWUP is used to start up the backup power supply, as described in the previous paragraphs. Then, when supply_on is asserted by the Supply Controller, the FWUP can be used as a wake up source
with a programmable debouncing period.
The FWUP pin is enabled as a wake up source by writing the FWUPEN bit to 1 in the Supply Controller Wake Up
Mode Register, SUPC_WUMR. Then, the FWUPDBC field in the same register selects the debouncing period,
which can be selected between 3, 32, 512, 4,096 or 32,768 slow clock cycles. This corresponds respectively to
about 100 µs, about 1 ms, about 16 ms, about 128 ms and about 1 second (for a typical slow clock frequency of 32
kHz). Programming FWUPDBC to 0x0 selects an immediate wake up, i.e., the FWUP must be low during a minimum of one slow clock period to wake up the core power supply.
If the FWUP pin is asserted for a time longer than the debouncing period, a wake up of the core power supply is
started and the FWUP bit in the Supply Controller Status Register, SUPC_SR, is set and remains high until the
register is read.
17.3.7.2
W
ake Up Inputs
The wake up inputs, WKUP0 to WKUP15, can be programmed to perform a wake up of the core power supply.
Each input can be enabled by writing to 1 the corresponding bit, WKUPEN0 to WKUPEN 15, in the Wake Up Inputs
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Register, SUPC_WUIR. The wake up level can be selected with the corresponding polarity bit, WKUPPL0 to
WKUPPL15, also located in SUPC_WUIR.
All the resulting signals are wired-ORed to trigger a debounce counter, which can be programmed with the WKUPDBC field in the Supply Controller Wake Up Mode Register, SUPC_WUMR. The WKUPDBC field can select a
debouncing period of 3, 32, 512, 4,096 or 32,768 slow clock cycles. This corresponds respectively to about 100 µs,
about 1 ms, about 16 ms, about 128 ms and about 1 second (for a typical slow clock frequency of 32 kHz). Programming WKUPDBC to 0x0 selects an immediate wake up, i.e., an enabled WKUP pin must be active according
to its polarity during a minimum of one slow clock period to wake up the core power supply.
If an enabled WKUP pin is asserted for a time longer than the debouncing period, a wake up of the core power supply is started and the signals, WKUP0 to WKUP15 as shown in Figure 17-8, are latched in the Supply Controller
Status Register, SUPC_SR. This allows the user to identify the source of the wake up, however, if a new wake up
condition occurs, the primary information is lost. No new wake up can be detected since the primary wake up condition has disappeared.
17.3.7.3
Clock Alarms
The RTC alarm can generate a wake up of the core power supply. This can be enabled by writing, the bit RTCEN
to 1 in the Supply Controller Wake Up Mode Register, SUPC_WUMR.
The Supply Controller does not provide any status as the information is available in the User Interface of the Real
Time Clock.
17.3.7.4
Brownout Detector
The brownout detector can generate a wake up of the core power supply. This can be enabled by writing the
BODEN bit to 1 in the Supply Controller Mode Register, SUPC_MR.
The Supply Controller provides two status bits in the Supply Controller Status Register for the brownout detector
which allow to determine whether the last wake up was due to the brownout detector:
• the BROWNOUT bit provides real time information, which is updated at each measurement cycle or updated at
each Slow Clock cycle, if the measurement is continuous
• the BODS bit provides saved information and shows a brownout has occurred since the last read of SUPC_SR
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17.4
Supply Controller (SUPC) User Interface
The User Interface of the Supply Controller is part of the System Controller User Interface.
17.4.1
System Controller (SYSC) User Interface
Table 17-1.
System Controller Registers
Offset
System Controller Peripheral
Name
0x00-0x0c
Reset Controller
RSTC
0x10-0x2C
Supply Controller
SUPC
0x40-0x4C
Periodic Interval Counter
PIT
0x50-0x5C
Watchdog
WDT
0x60-0x7C
Real Time Clock
RTC
17.4.2
Supply Controller (SUPC) User Interface
Table 17-2.
Register Mapping
Offset
Register
Name
Access
Reset
0x00
Supply Controller Control Register
SUPC_CR
Write-only
N/A
0x04
Supply Controller Brownout Mode Register
SUPC_BOMR
Read-write
0x0000_0000
0x08
Supply Controller Mode Register
SUPC_MR
Read-write
0x0008_0a00
0x0C
Supply Controller Wake Up Mode Register
SUPC_WUMR
Read-write
0x0000_0000
0x10
Supply Controller Wake Up Inputs Register
SUPC_WUIR
Read-write
0x0000_0000
0x14
Supply Controller Status Register
SUPC_SR
Read-only
0x0000_0800
0x18
Supply Controller Flash Wake-up Timer Register
SUPC_FWUTR
Read-write
0x0000_005a
0x1C
Reserved
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17.4.3
Supply Controller Control Register
Register Name:
SUPC_CR
Access Type:
31
Write-only
30
29
28
27
26
25
24
KEY
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
8
–
7
–
6
–
5
–
4
–
3
XTALSEL
2
VROFF
1
SHDWEOF
0
SHDW
• SHDW: Shut Down Command
0 = No effect.
1 = If KEY is correct, enters the device in off mode.
• SHDWEOF: Shut Down After End of Frame
0 = No effect.
1 = If KEY is correct, enters the device in off mode at the End of Frame from the LCD Controller.
• VROFF: Voltage Regulator Off
0 = No effect.
1 = If KEY is correct, asserts vddcore_nreset and stops the voltage regulator..
• XTALSEL: Crystal Oscillator Select
0 = No effect.
1 = If KEY is correct, switches the slow clock on the crystal oscillator output.
• KEY: Password
Should be written to value 0xA5. Writing any other value in this field aborts the write operation.
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17.4.4
Supply Controller Brownout Mode Register
Register Name:
SUPC_BOMR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
BODRSTEN
11
–
10
9
BODSMPL
8
7
–
6
–
5
–
4
–
3
2
1
0
BODTH
• BODTH: Brownout Threshold
BODTH
Brownout Threshold
0x0
1.9 V
0x1
2.0 V
0x2
2.1 V
0x3
2.2 V
0x4
2.3 V
0x5
2.4 V
0x6
2.5 V
0x7
2.6 V
0x8
2.7 V
0x9
2.8 V
0xA
2.9 V
0xB
3.0 V
0xC
3.1 V
0xD
3.2 V
0xE
3.3 V
0xF
3.4 V
• BODSMPL: Brownout Sampling Period
BODSMPL
Brownout Sampling Period
0x0
Brownout Detector disabled
0x1
Continuous Brownout Detector
0x2
Brownout Detector enabled one SLCK period every 32 SLCK periods
0x3
Brownout Detector enabled one SLCK period every 256 SLCK periods
0x4
Brownout Detector enabled one SLCK period every 2,048 SLCK periods
0x5-0x7
Reserved
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• BODRSTEN: Brownout Reset Enable
0 = The core reset signal, vddcore_nreset is not affected when a brownout occurs.
1 = The core reset signal, vddcore_nreset is asserted when a brownout occurs.
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17.4.5
Supply Controller Mode Register
Register Name:
SUPC_MR
Access Type:
31
Read-write
30
29
28
27
26
25
24
KEY
23
–
22
–
21
–
20
OSCBYPASS
19
FLASHON
18
RTON
17
SRAMON
16
–
15
–
14
–
13
–
12
VRRSTEN
11
10
VRVDD
9
8
VRDEEP
7
–
6
–
5
4
3
2
1
0
LCDMODE
LCDOUT
• LCDOUT: LCD Charge Pump Output Voltage Selection
LCDOUT
LCD Charge Pump Output Voltage
0x0
2.400 V
0x1
2.467 V
0x2
2.533 V
0x3
2.600 V
0x4
2.667 V
0x5
2.733 V
0x6
2.800 V
0x7
2.867 V
0x8
2.933 V
0x9
3.000 V
0xA
3.067 V
0xB
3.133 V
0xC
3.200 V
0xD
3.267 V
0xE
3.333 V
0xF
3.400 V
• LCDMODE: LCD Power Supply Mode
LCDMODE
LCD Controller Power Supply
0x0
The internal supply source and the external supply source are both deselected and the on-chip charge
pump is turned off.
0x1
At the End of Frame from the LCD Controller, the internal supply source and the external supply source are
both deselected and the on-chip charge pump is turned off.
0x2
The external supply source is selected.
0x3
The internal supply source is selected and the on-chip charge pump is turned on.
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• VRDEEP: Voltage Regulator Deep Mode
0 = Voltage Regulator Deep Mode is disabled.
1 = Voltage Regulator Deep Mode is enabled.
• VRVDD: Voltage Regulator Output Voltage Selection
VRVDD
Voltage Regulator Output Voltage
0x0
Reserved
0x1
Reserved
0x2
1.55V
0x3
1.65V
0x4
1.75V
0x5 - 0x7
1.80V
• VRRSTEN: Voltage Regulation Loss Reset Enable
0 = Losing the voltage regulation does not affect the core reset signal, vddcore_nreset.
1 = Losing the voltage regulation asserts the core reset signal, vddcore_nreset.
• SRAMON: SRAM On
0 = SRAM (Backup) switched off in backup mode.
1 = SRAM (Backup) switched on in backup mode.
• RTON: Real Time Clock Alarm Power Switch On
0 = Real Time Clock Alarm switched off.
1 = Real Time Clock Alarm switched on.
• FLASHON: Flash Memory Power Switch On
0 = Flash Memory switched off.
1 = Flash Memory switched on.
• OSCBYPASS: Oscillator Bypass
0 = No effect. Clock selection depends on XTALSEL value.
1 = The 32-KHz XTAL oscillator is selected and is put in bypass mode.
• KEY: Password Key
Should be written to value 0xA5. Writing any other value in this field aborts the write operation.
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17.4.6
Supply Controller Wake Up Mode Register
Register Name:
SUPC_WUMR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
13
WKUPDBC
12
11
–
10
9
FWUPDBC
8
7
–
6
–
5
–
4
–
3
RTCEN
2
–
1
BODEN
0
FWUPEN
• FWUPEN: Force Wake Up Enable
0 = The Force Wake Up pin has no wake up effect.
1 = The Force Wake Up pin low forces the wake up of the core power supply.
• BODEN: Brownout Wake Up Enable
0 = The brownout alarm signal has no wake up effect.
1 = The brownout alarm signal forces the wake up of the core power supply.
• RTCEN: Real Time Clock Wake Up Enable
0 = The RTC alarm signal has no wake up effect.
1 = The RTC alarm signal forces the wake up of the core power supply.
• FWUPDBC: Force Wake Up Debouncer
FWUPDBC
Force Wake Up Debouncer
0x0
Immediate, no debouncing, detected active at least on one Slow Clock edge.
0x1
FWUP shall be low for at least 3 SLCK periods
0x2
FWUP shall be low for at least 32 SLCK periods
0x3
FWUP shall be low for at least 512 SLCK periods
0x4
FWUP shall be low for at least 4,096 SLCK periods
0x5
FWUP shall be low for at least 32,768 SLCK periods
0x6-0x7
Reserved
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• WUPDBC: Wake Up Inputs Debouncer
WUPDBC
Wake Up Inputs Debouncer
0x0
Immediate, no debouncing, detected active at least on one Slow Clock edge.
0x1
An enabled wake-up input shall be active for at least 3 SLCK periods
0x2
An enabled wake-up input shall be active for at least 32 SLCK periods
0x3
An enabled wake-up input shall be active for at least 512 SLCK periods
0x4
An enabled wake-up input shall be active for at least 4,096 SLCK periods
0x5
An enabled wake-up input shall be active for at least 32,768 SLCK periods
0x6-0x7
Reserved
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17.4.7
System Controller Wake Up Inputs Register
Register Name:
SDC_WUIR
Access Type:
Read-write
31
WKUPT15
30
WKUPT14
29
WKUPT13
28
WKUPT12
27
WKUPT11
26
WKUPT10
25
WKUPT9
24
WKUPT8
23
WKUPT7
22
WKUPT6
21
WKUPT5
20
WKUPT4
19
WKUPT3
18
WKUPT2
17
WKUPT1
16
WKUPT0
15
WKUPEN15
14
WKUPEN14
13
WKUPEN13
12
WKUPEN12
11
WKUPEN11
10
WKUPEN10
9
WKUPEN9
8
WKUPEN8
7
WKUPEN7
6
WKUPEN6
5
WKUPEN5
4
WKUPEN4
3
WKUPEN3
2
WKUPEN2
1
WKUPEN1
0
WKUPEN0
• WKUPEN0 - WKUPEN15: Wake Up Input Enable 0 to 15
0 = The corresponding wake-up input has no wake up effect.
1 = The corresponding wake-up input forces the wake up of the core power supply.
• WKUPT0 - WKUPT15: Wake Up Input Transition 0 to 15
0 = A high to low level transition on the corresponding wake-up input forces the wake up of the core power supply.
1 = A low to high level transition on the corresponding wake-up input forces the wake up of the core power supply.
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17.4.8
Supply Controller Status Register
Register Name:
SUPC_SR
Access Type:
Read-write
31
WKUPIS15
30
WKUPIS14
29
WKUPIS13
28
WKUPIS12
27
WKUPIS11
26
WKUPIS10
25
WKUPIS9
24
WKUPIS8
23
WKUPIS7
22
WKUPIS6
21
WKUPIS5
20
WKUPIS4
19
WKUPIS3
18
WKUPIS2
17
WKUPIS1
16
WKUPIS0
15
–
14
–
13
–
12
FWUPIS
11
FLASHS
10
RTS
9
–
8
LCDS
7
OSCSEL
6
BROWNOUT
5
BODS
4
BODRSTS
3
VRRSTS
2
BODWS
1
WKUPS
0
FWUPS
• FWUPS: FWUP Wake Up Status
0 = No wake up due to the assertion of the FWUP pin has occurred since the last read of SUPC_SR.
1 = At least one wake up due to the assertion of the FWUP pin has occurred since the last read of SUPC_SR.
• WKUPS: WKUP Wake Up Status
0 = No wake up due to the assertion of the WKUP pins has occurred since the last read of SUPC_SR.
1 = At least one wake up due to the assertion of the WKUP pins has occurred since the last read of SUPC_SR.
• BODWS: Brownout Detection Wake Up Status
0 = No wake up due to a brownout detection has occurred since the last read of SUPC_SR.
1 = At least one wake up due to a brownout detection has occurred since the last read of SUPC_SR.
• VRRSTS: Voltage Regulation Loss Reset Status
0 = No voltage regulation loss has generated a core reset since the last read of the SUPC_SR.
1 = At least one voltage regulation loss has generated a core reset since the last read of the SUPC_SR.
• BODRSTS: Brownout Detection Reset Status
0 = No brownout detection has generated a core reset since the last read of the SUPC_SR.
1 = At least one brownout detection has generated a core reset since the last read of the SUPC_SR.
• BODS: Brownout Detector Status
0 = No brownout has been detected since the last read of SUPC_SR.
1 = At least one brownout has been detected since the last read of SUPC_SR.
• BROWNOUT: Brownout Detector Output Status
0 = The brownout detector detected VDDIO1 higher than its threshold at its last measurement.
1 = The brownout detector detected VDDIO1 lower than its threshold at its last measurement.
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• OSCSEL: 32-kHz Oscillator Selection Status
0 = The slow clock, SLCK is generated by the embedded 32-kHz RC oscillator.
1 = The slow clock, SLCK is generated by the 32-kHz crystal oscillator.
• LCDS: LCD Status
0 = The LCD Controller is off and cannot be used.
1 = The LCD Controller is on and can be used.
• RTS: Clock Status
0 = The Clock is off and cannot be used.
1 = The Clock is on and can be used.
• FLASHS: Flash Memory Status
0 = The Flash Memory is off and cannot be used.
1 = The Flash Memory is on and can be used.
• FWUPIS: FWUP Input Status
0 = FWUP input is tied low.
1 = FWUP input is tied high.
• WKUPIS0-WKUPIS15: WKUP Input Status 0 to 15
0 = The corresponding wake-up input is disabled, or was inactive at the time the debouncer triggered a wake up event.
1 = The corresponding wake-up input was active at the time the debouncer triggered a wake up event.
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17.4.9
Supply Controller Flash Wake Up Timer Register
Register Name:
SUPC_FWUTR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
7
6
5
4
3
2
1
8
FWUT
0
FWUT
• FWUT: Flash Wake Up Timer
Before waking up the Flash Memory (through the FLASHON bit in SUPC_MR), this field must be correctly set. Refer to the
Electrical Characteristics section of the product datasheet to obtain the wake-up time of the Flash Memory.
FWUT = (Maximum wake-up time of the Flash Memory in µs) x (Maximum Master Clock Frequency during the wake-up of
the Flash Memory in MHz)/ 2.
This number must be rounded up. The value 0 is not allowed.
For example, for a maximum wake-up time of 60 µs, and a maximum MCK frequency of 3 MHz during the wake up, FWUP
is: 60 x 3 / 2 = 90 = 0x5A.
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18. Memory Controller (MC)
18.1
Overview
The Memory Controller (MC) manages the ASB bus and controls accesses requested by the masters, typically the
ARM7TDMI processor and the Peripheral DMA Controller. It features a bus arbiter, an address decoder, an abort status, a
misalignment detector and an Embedded Flash Controller.
18.2
Block Diagram
Figure 18-1. Memory Controller Block Diagram
Memory Controller
ASB
ARM7TDMI
Processor
Embedded
Flash
Controller
Abort
Internal
Flash
Abort
Status
Internal
RAM
Bus
Arbiter
Address
Decoder
Misalignment
Detector
User
Interface
Peripheral
DMA
Controller
APB
Bridge
Peripheral 0
Peripheral 1
APB
From Master
to Slave
Peripheral N
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18.3
Functional Description
The Memory Controller handles the internal ASB bus and arbitrates the accesses of up to three masters.
It is made up of:
• A bus arbiter
• An address decoder
• An abort status
• A misalignment detector
• An Enhanced Embedded Flash Controller
The MC handles only little-endian mode accesses. The masters work in little-endian mode only.
18.3.1
Bus Arbiter
The Memory Controller has a simple, hard-wired priority bus arbiter that gives the control of the bus to one of the
two masters. The Peripheral DMA Controller has the highest priority, the ARM processor has the lowest one.
18.3.2
Address Decoder
The Memory Controller features an Address Decoder that first decodes the four highest bits of the 32-bit address
bus and defines three separate areas:
• One 256-Mbyte address space for the internal memories
• One 256-Mbyte address space reserved for the embedded peripherals
• An undefined address space of 3584 Mbytes representing fourteen 256-Mbyte areas that return an Abort if
accessed
Figure 18-2 shows the assignment of the 256-Mbyte memory areas.
Figure 18-2. Memory Areas
256 Mbytes
0x0000 0000
Internal Memories
0x0FFF FFFF
0x1000 0000
Undefined
(Abort)
14 x 256 Mbytes
3,584 Mbytes
0xEFFF FFFF
256 Mbytes
0xF000 0000
Peripherals
0xFFFF FFFF
18.3.2.1
Internal Memory Mapping
Within the Internal Memory address space, the Address Decoder of the Memory Controller decodes eight more
address bits to allocate 1-Mbyte address spaces for the embedded memories.
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The allocated memories are accessed all along the 1-Mbyte address space and so are repeated n times within this
address space, n equaling 1 Mbyte divided by the size of the memory.
When the address of the access is undefined within the internal memory area, the Address Decoder returns an
Abort to the master.
18.3.2.2
Internal Memory Area 0
The first 32 bytes of Internal Memory Area 0 contain the ARM processor exception vectors, in particular, the Reset
Vector at address 0x0.
Before execution of the remap command, the ROM or Flash is mapped into Internal Memory Area 0, depending on
the GPNVM Bit 0 state. After the remap command, the 4Kb internal core SRAM at address 0x0020 0000 is
mapped into Internal Memory Area 0. The memory mapped into Internal Memory Area 0 is accessible in both its
original location and at address 0x0. The user can see the 6 Kbytes contiguously at address 0x002F F000.
Figure 18-3 and Figure 18-4 illustrate the Internal memory mapping in accrodance to the GPNVM Bit 0 state.
Figure 18-3. Internal Memory Mapping with GPNVM Bit 0 = 0
0x0000 0000
0x000F FFFF
ROM Before Remap
Core SRAM (4 Kbytes) After Remap
1 Mbyte
Internal FLASH
1 Mbyte
Internal SRAM (Core)
4 Kbytes
1 Mbyte
Internal SRAM (Backup)
2 Kbytes
1 Mbyte
Internal ROM
12 Kbytes
1 Mbyte
0x0010 0000
0x001F FFFF
0x0020 0000
256 Mbytes
0x002F FFFF
0x0030 0000
0x003F FFFF
0x0040 0000
0x004F FFFF
0x0050 0000
Undefined Areas
(Abort)
251 Mbytes
0x0FFF FFFF
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Figure 18-4. Internal Memory Mapping with GPNVM Bit 0 = 1
0x0000 0000
0x000F FFFF
Flash Before Remap
Core SRAM (4 Kbytes) After Remap
1 Mbyte
Internal FLASH
1 Mbyte
Internal SRAM (Core)
4 Kbytes
1 Mbyte
Internal SRAM (Backup)
2 Kbytes
1 Mbyte
Internal ROM
12 Kbytes
1 Mbyte
0x0010 0000
0x001F FFFF
0x0020 0000
0x002F FFFF
0x0030 0000
256 Mbytes
0x003F FFFF
0x0040 0000
0x004F FFFF
0x0050 0000
Undefined Areas
(Abort)
251 Mbytes
0x0FFF FFFF
18.3.3
Remap Command
After execution, the Remap Command causes the Internal SRAM to be accessed through the Internal Memory
Area 0.
As the ARM vectors (Reset, Abort, Data Abort, Prefetch Abort, Undefined Instruction, Interrupt, and Fast Interrupt)
are mapped from address 0x0 to address 0x20, the Remap Command allows the user to redefine dynamically
these vectors under software control.
The Remap Command is accessible through the Memory Controller User Interface by writing the MC_RCR
(Remap Control Register) RCB field to one.
The Remap Command can be cancelled by writing the MC_RCR RCB field to one, which acts as a toggling command. This allows easy debug of the user-defined boot sequence by offering a simple way to put the chip in the
same configuration as after a reset.
18.3.4
Abort Status
There are two reasons for an abort to occur:
• access to an undefined address
• an access to a misaligned address.
When an abort occurs, a signal is sent back to all the masters, regardless of which one has generated the access.
However, only the ARM7TDMI can take an abort signal into account, and only under the condition that it was generating an access. The Peripheral DMA Controller and the EMAC do not handle the abort input signal. Note that
the connections are not represented in Figure 18-1.
To facilitate debug or for fault analysis by an operating system, the Memory Controller integrates an Abort Status
register set.
The full 32-bit wide abort address is saved in MC_AASR. Parameters of the access are saved in MC_ASR and
include:
• the size of the request (field ABTSZ)
• the type of the access, whether it is a data read or write, or a code fetch (field ABTTYP)
• whether the access is due to accessing an undefined address (bit UNDADD) or a misaligned address (bit
MISADD)
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• the source of the access leading to the last abort (bits MST_EMAC, MST_PDC and MST_ARM)
• whether or not an abort occurred for each master since the last read of the register (bits SVMST_EMAC,
SVMST_PDC and SVMST_ARM) unless this information is loaded in MST bits
In the case of a Data Abort from the processor, the address of the data access is stored. This is useful, as searching for which address generated the abort would require disassembling the instructions and full knowledge of the
processor context.
In the case of a Prefetch Abort, the address may have changed, as the prefetch abort is pipelined in the ARM processor. The ARM processor takes the prefetch abort into account only if the read instruction is executed and it is
probable that several aborts have occurred during this time. Thus, in this case, it is preferable to use the content of
the Abort Link register of the ARM processor.
18.3.5
Enhanced Embedded Flash Controller
The Enhanced Embedded Flash Controller (EEFC) manages accesses performed by the masters of the system. It
enables reading the Flash and writing the write buffer. It also contains a User Interface, mapped within the Memory
Controller on the APB.
The Enhanced Embedded Flash Controller ensures the interface of the Flash block with the 32-bit internal bus. Its
128-bit wide memory interface increases performance. It also manages the programming, erasing, locking and
unlocking sequences of the Flash using a full set of commands. One of the commands returns the embedded
Flash descriptor definition that informs thus making the software generic.
18.3.6
Misalignment Detector
The Memory Controller features a Misalignment Detector that checks the consistency of the accesses.
For each access, regardless of the master, the size of the access and the bits 0 and 1 of the address bus are
checked. If the type of access is a word (32-bit) and the bits 0 and 1 are not 0, or if the type of the access is a halfword (16-bit) and the bit 0 is not 0, an abort is returned to the master and the access is cancelled. Note that the
accesses of the ARM processor when it is fetching instructions are not checked.
The misalignments are generally due to software bugs leading to wrong pointer handling. These bugs are particularly difficult to detect in the debug phase.
As the requested address is saved in the Abort Status Register and the address of the instruction generating the
misalignment is saved in the Abort Link Register of the processor, detection and fix of this kind of software bugs is
simplified.
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18.4
Memory Controller (MC) User Interface
Base Address: 0xFFFFFF00
Table 18-1.
Memory Controller (MC) Register Mapping
Offset
Register
Name
Access
0x00
Reset
MC Remap Control Register
MC_RCR
Write-only
0x04
MC Abort Status Register
MC_ASR
Read-only
0x0
0x08
MC Abort Address Status Register
MC_AASR
Read-only
0x0
0x10-0x5C
Reserved
0x60
EFC0 Configuration Registers
See the Embedded Flash Controller Section
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18.4.1
MC Remap Control Register
Register Name:
MC_RCR
Access Type:
Write-only
Offset:
0x0
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
RCB
• RCB: Remap Command Bit
0: No effect.
1: This Command Bit acts on a toggle basis: writing a 1 alternatively cancels and restores the remapping of the page zero
memory devices.
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18.4.2
MC Abort Status Register
Register Name:
MC_ASR
Access Type:
Read-only
Reset Value:
0x0
Offset:
0x04
31
30
29
28
27
26
25
24
–
–
–
–
–
SVMST_ARM
SVMST_PDC
SVMST_EMAC
23
22
21
20
19
18
17
16
–
–
–
–
–
MST_ARM
MST_PDC
MST_EMAC
15
14
13
12
11
10
9
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
MISADD
UNDADD
ABTTYP
8
ABTSZ
• UNDADD: Undefined Address Abort Status
0: The last abort was not due to the access of an undefined address in the address space.
1: The last abort was due to the access of an undefined address in the address space.
• MISADD: Misaligned Address Abort Status
0: The last aborted access was not due to an address misalignment.
1: The last aborted access was due to an address misalignment.
• ABTSZ: Abort Size Status
ABTSZ
Abort Size
0
0
Byte
0
1
Half-word
1
0
Word
1
1
Reserved
• ABTTYP: Abort Type Status
ABTTYP
Abort Type
0
0
Data Read
0
1
Data Write
1
0
Code Fetch
1
1
Reserved
• MST_EMAC: EMAC Abort Source
0: The last aborted access was not due to the EMAC.
1: The last aborted access was due to the EMAC.
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• MST_PDC: PDC Abort Source
0: The last aborted access was not due to the PDC.
1: The last aborted access was due to the PDC.
• MST_ARM: ARM Abort Source
0: The last aborted access was not due to the ARM.
1: The last aborted access was due to the ARM.
• SVMST_EMAC: Saved EMAC Abort Source
0: No abort due to the EMAC occurred since the last read of MC_ASR or it is notified in the bit MST_EMAC.
1: At least one abort due to the EMAC occurred since the last read of MC_ASR.
• SVMST_PDC: Saved PDC Abort Source
0: No abort due to the PDC occurred since the last read of MC_ASR or it is notified in the bit MST_PDC.
1: At least one abort due to the PDC occurred since the last read of MC_ASR.
• SVMST_ARM: Saved ARM Abort Source
0: No abort due to the ARM occurred since the last read of MC_ASR or it is notified in the bit MST_ARM.
1: At least one abort due to the ARM occurred since the last read of MC_ASR.
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18.4.3
MC Abort Address Status Register
Register Name:
MC_AASR
Access Type:
Read-only
Reset Value:
0x0
Offset:
0x08
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
ABTADD
23
22
21
20
ABTADD
15
14
13
12
ABTADD
7
6
5
4
ABTADD
• ABTADD: Abort Address
This field contains the address of the last aborted access.
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19. Enhanced Embedded Flash Controller (EEFC)
19.1
Overview
The Enhanced Embedded Flash Controller (EEFC) ensures the interface of the Flash block with the 32-bit internal
bus. Its 128-bit wide memory interface increases performance. It also manages the programming, erasing, locking
and unlocking sequences of the Flash using a full set of commands. One of the commands returns the embedded
Flash descriptor definition that informs the system about the Flash organization, thus making the software generic.
19.2
Product Dependencies
19.2.1
Power Management
The Enhanced Embedded Flash Controller (EEFC) is continuously clocked. The Power Management Controller
has no effect on its behavior.
19.2.2
Interrupt Sources
The Enhanced Embedded Flash Controller (EEFC) interrupt line is connected to the Memory Controller internal
source of the Advanced Interrupt Controller. Using the Enhanced Embedded Flash Controller (EEFC) interrupt
requires the AIC to be programmed first. The EEFC interrupt is generated only on FRDY bit rising. To know the
Flash status, MC Flash Status Register should be read each time a system interrupt (SYSIRQ, periph ID = 0)
occurs.
19.3
Functional Description
19.3.1
Embedded Flash Organization
The embedded Flash interfaces directly with the 32-bit internal bus. The embedded Flash is composed of:
• One memory plane organized in several pages of the same size.
• Two 128-bit read buffers used for code read optimization.
• One 128-bit read buffer used for data read optimization.
• One write buffer that manages page programming. The write buffer size is equal to the page size. This buffer is
write-only and accessible all along the 1 MByte address space, so that each word can be written to its final
address.
• Several lock bits used to protect write/erase operation on several pages (lock region). A lock bit is associated
with a lock region composed of several pages in the memory plane.
• Several bits that may be set and cleared through the Enhanced Embedded Flash Controller (EEFC) interface,
called General Purpose Non Volatile Memory bits (GPNVM bits).
The embedded Flash size, the page size, the lock regions organization and GPNVM bits definition are described in
the product definition section. The Enhanced Embedded Flash Controller (EEFC) returns a descriptor of the Flash
controlled after a get descriptor command issued by the application (see “Getting Embedded Flash Descriptor” on
page 141).
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Figure 19-1. Embedded Flash Organization
Memory Plane
Start Address
Page 0
Lock Region 0
Lock Bit 0
Page (m-1)
Lock Region 1
Lock Region (n-1)
Start Address + Flash size -1
Lock Bit 1
Lock Bit (n-1)
Page (n*m-1)
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19.3.2
Read Operations
An optimized controller manages embedded Flash reads, thus increasing performance when the processor is running in ARM and Thumb mode by means of the 128-bit wide memory interface.
The Flash memory is accessible through 8-, 16- and 32-bit reads.
As the Flash block size is smaller than the address space reserved for the internal memory area, the embedded
Flash wraps around the address space and appears to be repeated within it.
The read operations can be performed with or without wait states. Wait states must be programmed in the field
FWS (Flash Read Wait State) in the Flash Mode Register (MC_FMR). Defining FWS to be 0 enables the singlecycle access of the embedded Flash. Refer to the Electrical Characteristics for more details.
19.3.2.1
Code Read Optimization
A system of 2 x 128-bit buffers is added in order to optimize sequential Code Fetch.
Note:
Immediate consecutive code read accesses are not mandatory to benefit from this optimization.
Figure 19-2. Code Read Optimization in ARM Mode for FWS = 0
Master Clock
ARM Request
(32-bit)
@Byte 0
Flash Access
Buffer 0 (128bits)
Note:
@Byte 8
Bytes 0-15
Bytes 16-31
@Byte 12
@Byte 16
@Byte 24
Bytes 0-3
@Byte 28
@Byte 32
Bytes 32-47
XXX
XXX
@Byte 20
Bytes 0-15
XXX
Buffer 1 (128bits)
Data To ARM
@Byte 4
Bytes 32-47
Bytes 16-31
Bytes 4-7
Bytes 8-11
Bytes 12-15
Bytes 16-19
Bytes 20-23
Bytes 24-27
Bytes 28-31
When FWS is equal to 0, all the accesses are performed in a single-cycle access.
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Figure 19-3. Code Read Optimization in ARM Mode for FWS = 3
Master Clock
ARM Request
(32-bit)
Flash Access
Buffer 0 (128bits)
Note:
@20
@12 @16
@24
@28 @32
@36 @40
Bytes 32-47
Bytes 16-31
Bytes 0-15
@48 @52
Bytes 32-47
Bytes 16-31
XXX
XXX
@44
Bytes 48-63
Bytes 0-15
XXX
Buffer 1 (128bits)
Data To ARM
@8
@4
@Byte 0
0-3
4-7
8-11
12-15
16-19
20-23
24-27
28-31 32-35
36-39
40-43
44-47
48-51
When FWS is included between 1 and 3, in case of sequential reads, the first access takes (FWS+1) cycles, the other ones only
1 cycle.
Figure 19-4. Code Read Optimization in ARM Mode for FWS = 4
Master Clock
ARM Request
(32-bit)
@4
@Byte 0
Flash Access
Buffer 0 (128bits)
Bytes 0-15
Note:
@12 @16
@20
@24
@28 @32
Bytes 48-63
Bytes 32-47
Bytes 0-15
Bytes 16-31
XXX
XXX
@36 @40
Bytes 32-47
Bytes 16-31
XXX
Buffer 1 (128bits)
Data To ARM
@8
0-3
4-7
8-11
12-15
16-19
20-23
24-27
28-31
32-35
36-39
When FWS is included between 4 and 10, in case of sequential reads, the first access takes (FWS+1) cycles, each first access
of the 128-bit read (FWS-2) cycles, and the others only 1 cycle.
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19.3.2.2
Data Read Optimization
The organization of the Flash in 128 bits is associated with two 128-bit prefetch buffers and one 128-bit data read
buffer, thus providing maximum system performance. This buffer is added in order to start access at the following
data during the second read. This speeds up sequential data reads if, for example, FWS is equal to 1 (see Figure
19-5).
Note:
No consecutive data read accesses are mandatory to benefit from this optimization.
Figure 19-5. Data Read Optimization in ARM Mode for FWS = 1
Master Clock
ARM Request
(32-bit)
@4
@Byte 0
Flash Access
XXX
19.3.3
@ 12
@ 24
@ 28
4-7
8-11
@ 36
Bytes 32-47
Bytes 0-15
Bytes 0-3
@ 32
Bytes 16-31
XXX
XXX
@ 20
@ 16
Bytes 0-15
Buffer (128bits)
Data To ARM
@8
Bytes 16-31
16-19
12-15
20-23
24-27
28-31
32-35
Flash Commands
The Enhanced Embedded Flash Controller (EEFC) offers a set of commands such as programming the memory
Flash, locking and unlocking lock regions, consecutive programming and locking and full Flash erasing, etc.
Commands and read operations can be performed in parallel only on different memory planes. Code can be
fetched from one memory plane while a write or an erase operation is performed on another.
Table 19-1.
Set of Commands
Command
Value
Mnemonic
Get Flash Descriptor
0x0
GETD
Write page
0x1
WP
Write page and lock
0x2
WPL
Erase page and write page
0x3
EWP
Erase page and write page then lock
0x4
EWPL
Erase all
0x5
EA
Set Lock Bit
0x8
SLB
Clear Lock Bit
0x9
CLB
Get Lock Bit
0xA
GLB
Set GPNVM Bit
0xB
SGPB
Clear GPNVM Bit
0xC
CGPB
Get GPNVM Bit
0xD
GGPB
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In order to perform one of these commands, the Flash Command Register (MC_FCR) has to be written with the
correct command using the field FCMD. As soon as the MC_FCR register is written, the FRDY flag and the field
FVALUE in the MC_FRR register are automatically cleared. Once the current command is achieved, then the
FRDY flag is automatically set. If an interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt
line of the Memory Controller is activated.
All the commands are protected by the same keyword, which has to be written in the 8 highest bits of the MC_FCR
register.
Writing MC_FCR with data that does not contain the correct key and/or with an invalid command has no effect on
the whole memory plane, but the FCMDE flag is set in the MC_FSR register. This flag is automatically cleared by a
read access to the MC_FSR register.
When the current command writes or erases a page in a locked region, the command has no effect on the whole
memory plane, but the FLOCKE flag is set in the MC_FSR register. This flag is automatically cleared by a read
access to the MC_FSR register.
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Figure 19-6. Command State Chart
Read Status: MC_FSR
No
Check if FRDY flag Set
Yes
Write FCMD and PAGENB in Flash Command Register
Read Status: MC_FSR
No
Check if FRDY flag Set
Yes
Check if FLOCKE flag Set
Yes
Locking region violation
No
Check if FCMDE flag Set
Yes
Bad keyword violation
No
Command Successfull
19.3.3.1
Getting Embedded Flash Descriptor
This command allows the system to learn about the Flash organization. The system can take full advantage of this
information. For instance, a device could be replaced by one with more Flash capacity, and so the software is able
to adapt itself to the new configuration.
To get the embedded Flash descriptor, the application writes the GETD command in the MC_FCR register. The
first word of the descriptor can be read by the software application in the MC_FRR register as soon as the FRDY
flag in the MC_FSR register rises. The next reads of the MC_FRR register provide the following word of the
descriptor. If extra read operations to the MC_FRR register are done after the last word of the descriptor has been
returned, then the MC_FRR register value is 0 until the next valid command
.
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Table 19-2.
Flash Descriptor Definition
Symbol
Word Index
Description
FL_ID
0
Flash Interface Description
FL_SIZE
1
Flash size in bytes
FL_PAGE_SIZE
2
Page size in bytes
FL_NB_PLANE
3
Number of planes.
FL_PLANE[0]
4
Number of bytes in the first plane.
4 + FL_NB_PLANE - 1
Number of bytes in the last plane.
FL_NB_LOCK
4 + FL_NB_PLANE
Number of lock bits. A bit is associated
with a lock region. A lock bit is used to
prevent write or erase operations in the
lock region.
FL_LOCK[0]
4 + FL_NB_PLANE + 1
Number of bytes in the first lock region.
...
FL_PLANE[FL_NB_PLANE-1]
...
19.3.3.2
W
rite Commands
Several commands can be used to program the Flash.
Flash technology requires that an erase is done before programming. The full memory plane can be erased at the
same time, or several pages can be erased at the same time (refer to “Erase Commands” on page 143). Also, a
page erase can be automatically done before a page write using EWP or EWPL commands.
After programming, the page (the whole lock region) can be locked to prevent miscellaneous write or erase
sequences. The lock bit can be automatically set after page programming using WPL or EWPL commands.
Data to be written are stored in an internal latch buffer. The size of the latch buffer corresponds to the page size.
The latch buffer wraps around within the internal memory area address space and is repeated as many times as
the number of pages within this address space.
Note:
Writing of 8-bit and 16-bit data is not allowed and may lead to unpredictable data corruption.
Write operations are performed in a number of wait states equal to the number of wait states for read operations.
Data are written to the latch buffer before the programming command is written to the Flash Command Register
MC_FCR. The sequence is as follows:
• Write the full page, at any page address, within the internal memory area address space.
• Programming starts as soon as the page number and the programming command are written to the Flash
Command Register. The FRDY bit in the Flash Programming Status Register (MC_FSR) is automatically
cleared.
• When programming is completed, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If
an interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
Two errors can be detected in the MC_FSR register after a programming sequence:
• a Command Error: a bad keyword has been written in the MC_FCR register.
• a Lock Error: the page to be programmed belongs to a locked region. A command must be previously run to
unlock the corresponding region.
By using the WP command, a page can be programmed in several steps if it has been erased before (see Figure
19-7).
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Figure 19-7. Example of Partial Page Programming
32-bit wide
32-bit wide
FF
X words
X words
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
CA
FE
CA FE
CA
CA
FE
FE
CA FE
CA FE
FF FF
...
FF FF
FF FF
FF
FF
FF
DE CA DE CA
...
DE CA DE CA
DE CA DE CA
FF FF
...
FF FF
FF FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF FF
...
FF FF
FF FF
FF
CA FE
FF
FF
CA FE
CA FE
FF FF
...
FF FF
FF FF
FF
FF
FF
FF
FF
FF
FF FF
...
FF FF
FF FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
X words
...
FF
FF
FF
X words
FF
FF
FF
Step 1.
Erase All Flash
So Page Y erased
32-bit wide
...
FF
FF
...
FF
Step 2.
Programming of the second part of Page Y
FF
...
FF
FF
FF
CA
FE
CA
CA
FE
FE
FF
FF
...
FF FF
...
FF FF
FF FF
FF
FF
FF
Step 3.
Programming of the third part of Page Y
19.3.3.3
Erase Commands
Erase commands are allowed only on unlocked regions.
The erase sequence is:
• Erase starts as soon as one of the erase commands and the FARG field are written in the Flash Command
Register.
• When the programming completes, the FRDY bit in the Flash Programming Status Register (MC_FSR) rises. If
an interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
Two errors can be detected in the MC_FSR register after a programming sequence:
• a Command Error: a bad keyword has been written in the MC_FCR register.
• a Lock Error: at least one page to be erased belongs to a locked region. The erase command has been refused,
no page has been erased. A command must be previously run to unlock the corresponding region.
19.3.3.4
Lock Bit Protection
Lock bits are associated with several pages in the embedded Flash memory plane. This defines lock regions in the
embedded Flash memory plane. They prevent writing/erasing protected pages.
The lock sequence is:
• The Set Lock command (SLB) and a page number to be protected are written in the Flash Command Register.
• When the locking completes, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If an
interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
• If the lock bit number is greater than the total number of lock bits, then the command has no effect. The result of
the SLB command can be checked running a GLB (Get Lock Bit) command.
One error can be detected in the MC_FSR register after a programming sequence:
• a Command Error: a bad keyword has been written in the MC_FCR register.
It is possible to clear lock bits previously set. Then the locked region can be erased or programmed. The unlock
sequence is:
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• The Clear Lock command (CLB) and a page number to be unprotected are written in the Flash Command
Register.
• When the unlock completes, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If an
interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
• If the lock bit number is greater than the total number of lock bits, then the command has no effect.
One error can be detected in the MC_FSR register after a programming sequence:
• a Command Error: a bad keyword has been written in the MC_FCR register.
The status of lock bits can be returned by the Enhanced Embedded Flash Controller (EEFC). The Get Lock Bit status sequence is:
• The Get Lock Bit command (GLB) is written in the Flash Command Register. FARG field is meaningless.
• When the command completes, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If an
interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
• Lock bits can be read by the software application in the MC_FRR register. The first word read corresponds to
the 32 first lock bits, next reads providing the next 32 lock bits as long as it is meaningful. Extra reads to the
MC_FRR register return 0.
For example, if the third bit of the first word read in the MC_FRR is set, then the third lock region is locked.
One error can be detected in the MC_FSR register after a programming sequence:
• a Command Error: a bad keyword has been written in the MC_FCR register.
Note:
Access to the Flash in read is permitted when a set, clear or get lock bit command is performed.
19.3.3.5
GPNVM Bit
GPNVM bits do not interfere with the embedded Flash memory plane. Refer to the product definition section for
information on the GPNVM Bit Action.
The set GPNVM bit sequence is:
• Start the Set GPNVM Bit command (SGPB) by writing the Flash Command Register with the SGPB command
and the number of the GPNVM bit to be set.
• When the GPVNM bit is set, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If an
interrupt was enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
• If the GPNVM bit number is greater than the total number of GPNVM bits, then the command has no effect. The
result of the SGPB command can be checked by running a GGPB (Get GPNVM Bit) command.
One error can be detected in the MC_FSR register after a programming sequence:
• A Command Error: a bad keyword has been written in the MC_FCR register.
It is possible to clear GPNVM bits previously set. The clear GPNVM bit sequence is:
• Start the Clear GPNVM Bit command (CGPB) by writing the Flash Command Register with CGPB and the
number of the GPNVM bit to be cleared.
• When the clear completes, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If an
interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
• If the GPNVM bit number is greater than the total number of GPNVM bits, then the command has no effect.
One error can be detected in the MC_FSR register after a programming sequence:
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• A Command Error: a bad keyword has been written in the MC_FCR register.
The status of GPNVM bits can be returned by the Enhanced Embedded Flash Controller (EEFC). The sequence is:
• Start the Get GPNVM bit command by writing the Flash Command Register with GGPB. The FARG field is
meaningless.
• When the command completes, the bit FRDY in the Flash Programming Status Register (MC_FSR) rises. If an
interrupt has been enabled by setting the bit FRDY in MC_FMR, the interrupt line of the Memory Controller is
activated.
• GPNVM bits can be read by the software application in the MC_FRR register. The first word read corresponds
to the 32 first GPNVM bits, following reads provide the next 32 GPNVM bits as long as it is meaningful. Extra
reads to the MC_FRR register return 0.
For example, if the third bit of the first word read in the MC_FRR is set, then the third GPNVM bit is active.
One error can be detected in the MC_FSR register after a programming sequence:
• a Command Error: a bad keyword has been written in the MC_FCR register.
Note:
Access to the Flash in read is permitted when a set, clear or get GPNVM bit command is performed.
19.3.3.6
Security Bit Protection
When the security is enabled, access to the Flash, either through the ICE interface or through the Fast Flash Programming Interface, is forbidden. This ensures the confidentiality of the code programmed in the Flash.
The security bit is GPNVM0.
Disabling the security bit can only be achieved by asserting the ERASE pin at 1, and after a full Flash erase is performed. When the security bit is deactivated, all accesses to the Flash are permitted.
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19.4
Enhanced Embedded Flash Controller (EEFC) User Interface
The User Interface of the Enhanced Embedded Flash Controller (EEFC) is integrated within the Memory Controller with
base address 0xFFFF FF60.
Table 19-3.
Register Mapping
Offset
Register
Name
Access
Reset State
0x00
MC Flash Mode Register
MC_FMR
Read-write
0x0
0x04
MC Flash Command Register
MC_FCR
Write-only
–
0x08
MC Flash Status Register
MC_FSR
Read-only
0x00000001
0x0C
MC Flash Result Register
MC_FRR
Read-only
0x0
0x10
Reserved
–
–
–
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19.4.1
MC Flash Mode Register
Register Name:
MC_FMR
Access Type:
Read-write
Offset:
0x60
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
7
6
–
FWS
5
4
3
2
1
0
–
–
–
–
–
FRDY
• FRDY: Ready Interrupt Enable
0: Flash Ready does not generate an interrupt.
1: Flash Ready (to accept a new command) generates an interrupt.
• FWS: Flash Wait State
This field defines the number of wait states for read and write operations:
Number of cycles for Read/Write operations = FWS+1
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19.4.2
MC Flash Command Register
Register Name:
MC_FCR
Access Type:
Write-only
Offset:
0x64
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
FKEY
23
22
21
20
FARG
15
14
13
12
FARG
7
6
5
4
FCMD
• FCMD: Flash Command
This field defines the flash commands. Refer to “Flash Commands” on page 139.
• FARG: Flash Command Argument
Erase command
For erase all command, this field is meaningless.
Programming command
FARG defines the page number to be programmed.
Lock command
FARG defines the page number to be locked.
GPNVM command
FARG defines the GPNVM number.
Get Commands
Field is meaningless.
• FKEY: Flash Writing Protection Key
This field should be written with the value 0x5A to enable the command defined by the bits of the register. If the field is written with a different value, the write is not performed and no action is started.
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19.4.3
MC Flash Status Register
Register Name:
MC_FSR
Access Type:
Read-only
Offset:
0x68
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
FLOCKE
FCMDE
FRDY
• FRDY: Flash Ready Status
0: The Enhanced Embedded Flash Controller (EEFC) is busy.
1: The Enhanced Embedded Flash Controller (EEFC) is ready to start a new command.
When it is set, this flags triggers an interrupt if the FRDY flag is set in the MC_FMR register.
This flag is automatically cleared when the Enhanced Embedded Flash Controller (EEFC) is busy.
• FCMDE: Flash Command Error Status
0: No invalid commands and no bad keywords were written in the Flash Mode Register MC_FMR.
1: An invalid command and/or a bad keyword was/were written in the Flash Mode Register MC_FMR.
This flag is automatically cleared when MC_FSR is read or MC_FCR is written.
• FLOCKE: Flash Lock Error Status
0: No programming/erase of at least one locked region has happened since the last read of MC_FSR.
1: Programming/erase of at least one locked region has happened since the last read of MC_FSR.
This flag is automatically cleared when MC_FSR is read or MC_FCR is written.
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19.4.4
MC Flash Result Register
Register Name:
MC_FRR
Access Type:
Read-only
Offset:
0x6C
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
FVALUE
23
22
21
20
FVALUE
15
14
13
12
FVALUE
7
6
5
4
FVALUE
• FVALUE: Flash Result Value
The result of a Flash command is returned in this register. If the size of the result is greater than 32 bits, then the next
resulting value is accessible at the next register read.
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20. Fast Flash Programming Interface (FFPI)
20.1
Overview
The Fast Flash Programming Interface provides two solutions - parallel or serial - for high-volume programming
using a standard gang programmer. The parallel interface is fully handshaked and the device is considered to be a
standard EEPROM. Additionally, the parallel protocol offers an optimized access to all the embedded Flash functionalities. The serial interface uses the standard IEEE 1149.1 JTAG protocol. It offers an optimized access to all
the embedded Flash functionalities.
Although the Fast Flash Programming Mode is a dedicated mode for high volume programming, this mode is not
designed for in-situ programming.
20.2
Parallel Fast Flash Programming
20.2.1
Device Configuration
In Fast Flash Programming Mode, the device is in a specific test mode. Only a certain set of pins is significant.
Other pins must be left unconnected.
Figure 20-1. Parallel Programming Interface
VDDIO1
TST
VDDIO1
CLKIN
GND
FWUP
NCMD
PGMNCMD
VDDIO1
VDDIO2
RDY
PGMRDY
NOE
PGMNOE
NVALID
VDDCORE
PGMNVALID
MODE[3:0]
PGMM[3:0]
DATA[15:0]
PGMD[15:0]
0 - 10MHz
XIN
VDDLCD
GND
VDDINLCD
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Table 20-1.
Signal Name
Signal Description List
Function
Type
Active
Level
Comments
Power
VDDIO1
I/O Lines Power Supply
Power
Apply externally 2.2V-3.6V (1)
VDDIO2
I/O Lines Power Supply
Power
Apply externally 2.2V-3.6V (1)
VDDCORE
Core Power Supply
Power
Apply externally 1.80V-1.95V (1)
VDDOUT
Voltage Regulator Output
Power
Connect to VDDCORE. 2.2 µF
decoupling capacitor needed
VDDINLCD
Charge pump input
Power
Connect to ground
VDD3V6
Charge pump output
Power
Left unconnected (1)
VDDLCD
LCD voltage input
Power
Connect to VDDIO2 (1)
GND
Ground
Ground
Clocks
XIN
Clock Input
Input
0 to 10MHz (0-VDDIO1 square wave)
Test
TST
Test Mode Select
Input
High
Must be connected to VDDIO1
CLKIN
External clock input used to enter in
FFPI mode
Input
High
Must be connected to VDDIO1
FWUP
Wake-up pin
Input
Low
Must be connected to GND
Input
Low
Pulled-up input at reset
Output
High
Pulled-up input at reset
Input
Low
Pulled-up input at reset
Output
Low
Pulled-up input at reset
PIO
PGMNCMD
Valid command available
PGMRDY
0: Device is busy
1: Device is ready for a new command
PGMNOE
Output Enable (active high)
PGMNVALID
0: DATA[15:0] is in input mode
1: DATA[15:0] is in output mode
PGMM[3:0]
Specifies DATA type (See Table 20-2)
PGMD[15:0]
Bi-directional data bus
Note:
Input
Pulled-up input at reset
Input/Output
Pulled-up input at reset
1. See Figure 20-2 below.
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Figure 20-2. The Charge Pump and the LCD Regulator are Not Used
External supply
VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
20.2.2
Signal Names
Depending on the MODE settings, DATA is latched in different internal registers.
Table 20-2.
Mode Coding
MODE[3:0]
Symbol
Data
0000
CMDE
Command Register
0001
ADDR0
Address Register LSBs
0010
ADDR1
Address Register MSBs
0101
DATA
Data Register
Default
IDLE
No register
When MODE is equal to CMDE, then a new command (strobed on DATA[15:0] signals) is stored in the command
register.
Table 20-3.
Command Bit Coding
DATA[15:0]
Symbol
Command Executed
0x0011
READ
Read Flash
0x0012
WP
Write Page Flash
0x0022
WPL
Write Page and Lock Flash
0x0032
EWP
Erase Page and Write Page
0x0042
EWPL
Erase Page and Write Page then Lock
0x0013
EA
Erase All
0x0014
SLB
Set Lock Bit
0x0024
CLB
Clear Lock Bit
0x0015
GLB
Get Lock Bit
0x0034
SGPB
Set General Purpose NVM bit
0x0044
CGPB
Clear General Purpose NVM bit
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Table 20-3.
20.2.3
Command Bit Coding (Continued)
DATA[15:0]
Symbol
Command Executed
0x0025
GGPB
Get General Purpose NVM bit
0x0054
SSE
Set Security Bit
0x0035
GSE
Get Security Bit
0x001F
WRAM
Write Memory
0x001E
GVE
Get Version
Entering Programming Mode
The following algorithm puts the device in Parallel Programming Mode:
• Apply GND, TST, CLKIN, FWUP and the supplies as described in table 4.1.
• Apply XIN clock
• Wait for 20 ms
• Start a read or write handshaking.
20.2.4
Programmer Handshaking
A handshake is defined for read and write operations. When the device is ready to start a new operation (RDY signal set), the programmer starts the handshake by clearing the NCMD signal. The handshaking is achieved once
NCMD signal is high and RDY is high.
20.2.4.1
W
rite Handshaking
For details on the write handshaking sequence, refer to Figure 20-3 and Table 20-4.
Figure 20-3. Parallel Programming Timing, Write Sequence
NCMD
2
4
3
RDY
5
NOE
NVALID
DATA[15:0]
1
MODE[3:0]
Table 20-4.
Write Handshake
Step
Programmer Action
Device Action
Data I/O
1
Sets MODE and DATA signals
Waits for NCMD low
Input
2
Clears NCMD signal
Latches MODE and DATA
Input
3
Waits for RDY low
Clears RDY signal
Input
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Table 20-4.
Write Handshake
Step
Programmer Action
Device Action
Data I/O
4
Releases MODE and DATA signals
Executes command and polls NCMD high
Input
5
Sets NCMD signal
Executes command and polls NCMD high
Input
6
Waits for RDY high
Sets RDY
Input
20.2.4.2
Read Handshaking
For details on the read handshaking sequence, refer to Figure 20-4 and Table 20-5.
Figure 20-4.
Parallel Programming Timing, Read Sequence
NCMD
12
2
3
RDY
13
NOE
9
5
11
7
NVALID
6
4
DATA[15:0]
Adress IN
Z
8
10
Data OUT
X
IN
1
MODE[3:0]
Table 20-5.
ADDR
Read Handshake
Step
Programmer Action
Device Action
DATA I/O
1
Sets MODE and DATA signals
Waits for NCMD low
Input
2
Clears NCMD signal
Latch MODE and DATA
Input
3
Waits for RDY low
Clears RDY signal
Input
4
Sets DATA signal in tristate
Waits for NOE Low
Input
5
Clears NOE signal
6
Waits for NVALID low
7
Tristate
Sets DATA bus in output mode and outputs
the flash contents.
Output
Clears NVALID signal
Output
Waits for NOE high
Output
8
Reads value on DATA Bus
9
Sets NOE signal
10
Waits for NVALID high
Sets DATA bus in input mode
X
11
Sets DATA in output mode
Sets NVALID signal
Input
12
Sets NCMD signal
Waits for NCMD high
Input
13
Waits for RDY high
Sets RDY signal
Input
Output
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20.2.5
Device Operations
Several commands on the Flash memory are available. These commands are summarized in Table 20-3 on page
153. Each command is driven by the programmer through the parallel interface running several read/write handshaking sequences.
When a new command is executed, the previous one is automatically achieved. Thus, chaining a read command
after a write automatically flushes the load buffer in the Flash.
20.2.5.1
Flash Read Command
This command is used to read the contents of the Flash memory. The read command can start at any valid
address in the memory plane and is optimized for consecutive reads. Read handshaking can be chained; an internal address buffer is automatically increased.
Table 20-6.
Read Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
READ
2
Write handshaking
ADDR0
Memory Address LSB
3
Write handshaking
ADDR1
Memory Address
4
Read handshaking
DATA
*Memory Address++
5
Read handshaking
DATA
*Memory Address++
...
...
...
...
n
Write handshaking
ADDR0
Memory Address LSB
n+1
Write handshaking
ADDR1
Memory Address
n+2
Read handshaking
DATA
*Memory Address++
n+3
Read handshaking
DATA
*Memory Address++
...
...
...
...
20.2.5.2
Flash W
rite Command
This command is used to write the Flash contents.
The Flash memory plane is organized into several pages. Data to be written are stored in a load buffer that corresponds to a Flash memory page. The load buffer is automatically flushed to the Flash:
• before access to any page other than the current one
• when a new command is validated (MODE = CMDE)
The Write Page command (WP) is optimized for consecutive writes. Write handshaking can be chained; an internal address buffer is automatically increased.
Table 20-7.
Write Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
WP or WPL or EWP or EWPL
2
Write handshaking
ADDR0
Memory Address LSB
3
Write handshaking
ADDR1
Memory Address
4
Write handshaking
DATA
*Memory Address++
5
Write handshaking
DATA
*Memory Address++
...
...
...
...
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Table 20-7.
Write Command (Continued)
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
n
Write handshaking
ADDR0
Memory Address LSB
n+1
Write handshaking
ADDR1
Memory Address
n+2
Write handshaking
DATA
*Memory Address++
n+3
Write handshaking
DATA
*Memory Address++
...
...
...
...
The Flash command Write Page and Lock (WPL) is equivalent to the Flash Write Command. However, the lock
bit is automatically set at the end of the Flash write operation. As a lock region is composed of several pages, the
programmer writes to the first pages of the lock region using Flash write commands and writes to the last page of
the lock region using a Flash write and lock command.
The Flash command Erase Page and Write (EWP) is equivalent to the Flash Write Command. However, before
programming the load buffer, the page is erased.
The Flash command Erase Page and Write the Lock (EWPL) combines EWP and WPL commands.
20.2.5.3
Flash Full Erase Command
This command is used to erase the Flash memory planes.
All lock regions must be unlocked before the Full Erase command by using the CLB command. Otherwise, the
erase command is aborted and no page is erased.
Table 20-8.
Full Erase Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
EA
2
Write handshaking
DATA
0
20.2.5.4
Flash Lock Commands
Lock bits can be set using WPL or EWPL commands. They can also be set by using the Set Lock command
(SLB). With this command, several lock bits can be activated. A Bit Mask is provided as argument to the command. When bit 0 of the bit mask is set, then the first lock bit is activated.
In the same way, the Clear Lock command (CLB) is used to clear lock bits. All the lock bits are also cleared by the
EA command.
Table 20-9.
Set and Clear Lock Bit Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
SLB or CLB
2
Write handshaking
DATA
Bit Mask
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Lock bits can be read using Get Lock Bit command (GLB). The nth lock bit is active when the bit n of the bit mask
is set..
Table 20-10. Get Lock Bit Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
GLB
2
Read handshaking
DATA
Lock Bit Mask Status
0 = Lock bit is cleared
1 = Lock bit is set
20.2.5.5
Flash General-purpose NVM Commands
General-purpose NVM bits (GP NVM bits) can be set using the Set GPNVM command (SGPB). This command
also activates GP NVM bits. A bit mask is provided as argument to the command. When bit 0 of the bit mask is set,
then the first GP NVM bit is activated.
In the same way, the Clear GPNVM command (CGPB) is used to clear general-purpose NVM bits. All the generalpurpose NVM bits are also cleared by the EA command. The general-purpose NVM bit is deactivated when the
corresponding bit in the pattern value is set to 1.
Table 20-11. Set/Clear GP NVM Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
SGPB or CGPB
2
Write handshaking
DATA
GP NVM bit pattern value
General-purpose NVM bits can be read using the Get GPNVM Bit command (GGPB). The nth GP NVM bit is active
when bit n of the bit mask is set..
Table 20-12. Get GP NVM Bit Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
GGPB
DATA
GP NVM Bit Mask Status
0 = GP NVM bit is cleared
1 = GP NVM bit is set
2
Read handshaking
20.2.5.6
Flash Security Bit Command
A security bit can be set using the Set Security Bit command (SSE). Once the security bit is active, the Fast Flash
programming is disabled. No other command can be run. An event on the Erase pin can erase the security bit once
the contents of the Flash have been erased.
Table 20-13. Set Security Bit Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
SSE
2
Write handshaking
DATA
0
Once the security bit is set, it is not possible to access FFPI. The only way to erase the security bit is to erase the
Flash.
In order to erase the Flash, the user must perform the following:
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• Power-off the chip
• Power-on the chip with TST = 0 and FWUP =0
• Assert Erase during a period of more than 220 ms
• Power-off the chip
Then it is possible to return to FFPI mode and check that Flash is erased.
20.2.5.7
Memory W
rite Command
This command is used to perform a write access to any memory location.
The Memory Write command (WRAM) is optimized for consecutive writes. Write handshaking can be chained; an
internal address buffer is automatically increased.
Table 20-14. Write Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
WRAM
2
Write handshaking
ADDR0
Memory Address LSB
3
Write handshaking
ADDR1
Memory Address
4
Write handshaking
DATA
*Memory Address++
5
Write handshaking
DATA
*Memory Address++
...
...
...
...
n
Write handshaking
ADDR0
Memory Address LSB
n+1
Write handshaking
ADDR1
Memory Address
n+2
Write handshaking
DATA
*Memory Address++
n+3
Write handshaking
DATA
*Memory Address++
...
...
...
...
20.2.5.8
Get Version Command
The Get Version (GVE) command retrieves the version of the FFPI interface.
Table 20-15. Get Version Command
Step
Handshake Sequence
MODE[3:0]
DATA[15:0]
1
Write handshaking
CMDE
GVE
2
Write handshaking
DATA
Version
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20.3
Serial Fast Flash Programming
The Serial Fast Flash programming interface is based on IEEE Std. 1149.1 “Standard Test Access Port and
Boundary-Scan Architecture”. Refer to this standard for an explanation of terms used in this chapter and for a
description of the TAP controller states.
In this mode, data read/written from/to the embedded Flash of the device are transmitted through the JTAG interface of the device.
20.3.1
Device Configuration
In Serial Fast Flash Programming Mode, the device is in a specific test mode. Only a distinct set of pins is significant. Other pins must be left unconnected.
Figure 20-5. Serial Programming
VDDIO1
TST
VDDIO1
CLKIN
VDDCORE
GND
FWUP
VDDIO1
TDI
VDDIO2
TDO
VDDLCD
TMS
GND
TCK
0-10MHz
VDDINLCD
XIN
Table 20-16. Signal Description List
Signal Name
Function
Type
Active
Level
Comments
Power
VDDIO1
I/O Lines Power Supply
Power
Apply externally 2.2V-3.6V (1)
VDDIO2
I/O Lines Power Supply
Power
Apply externally 2.2V-3.6V (1)
VDDCORE
Core Power Supply
Power
Apply externally 1.80V-1.95V (1)
VDDOUT
Voltage Regulator Output
Power
Connect to VDDCORE. 2.2 µF
decoupling capacitor needed
VDDINLCD
Charge pump input
Power
Connect to ground
VDD3V6
Charge pump output
Power
Left unconnected (1)
VDDLCD
LCD voltage input
Power
Connect to VDDIO2 (1)
GND
Ground
Ground
Clocks
XIN
Clock Input
Input
0 to 10MHz (0-VDDIO1 square wave)
Test
TST
Test Mode Select
Input
High
Must be connected to VDDIO1
CLKIN
External clock input used to enter in
FFPI mode
Input
High
Must be connected to VDDIO1
FWUP
Wake-up pin
Input
Low
Must be connected to GND
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Table 20-16. Signal Description List (Continued)
Signal Name
Function
Type
Active
Level
Comments
JTAG
TCK
JTAG TCK
Input
-
Pulled-up input at reset
TDI
JTAG Test Data In
Input
-
Pulled-up input at reset
TDO
JTAG Test Data Out
Output
-
TMS
JTAG Test Mode Select
Input
-
Note:
Pulled-up input at reset
1. See Figure 20-6 below.
Figure 20-6. The Charge Pump and the LCD Regulator are Not Used
External supply
VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
20.3.2
Entering Serial Programming Mode
The following algorithm puts the device in Serial Programming Mode:
• Apply GND, TST, CLKIN, FWUP and the supplies as described in Table 20-1, “Signal Description List,” on
page 152.
• Apply XIN clock.
• Wait for 10 ms.
• Reset the TAP controller clocking 5 TCK pulses with TMS set.
• Shift 0x2 into the IR register (IR is 4 bits long, LSB first) without going through the Run-Test-Idle state.
• Shift 0x2 into the DR register (DR is 4 bits long, LSB first) without going through the Run-Test-Idle state.
• Shift 0xC into the IR register (IR is 4 bits long, LSB first) without going through the Run-Test-Idle state.
Note:
After reset, the device is clocked by the internal RC oscillator. Before clearing RDY signal, if an external clock ( > 32
kHz) is connected to XIN, then the device will switch on the external clock. Else, XIN input is not considered. An higher
frequency on XIN speeds up the programmer handshake.
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Table 20-17. Reset TAP Controller and Go to Select-DR-Scan
20.3.3
TDI
TMS
TAP Controller State
X
1
X
1
X
1
X
1
X
1
Test-Logic Reset
X
0
Run-Test/Idle
Xt
1
Select-DR-Scan
Read/Write Handshake
The read/write handshake is done by carrying out read/write operations on two registers of the device that are
accessible through the JTAG:
• Debug Comms Control Register: DCCR
• Debug Comms Data Register: DCDR
Access to these registers is done through the TAP 38-bit DR register comprising a 32-bit data field, a 5-bit address
field and a read/write bit. The data to be written is scanned into the 32-bit data field with the address of the register
to the 5-bit address field and 1 to the read/write bit. A register is read by scanning its address into the address field
and 0 into the read/write bit, going through the UPDATE-DR TAP state, then scanning out the data.
Refer to the ARM7TDMI reference manuel for more information on Comm channel operations.
Figure 20-7. TAP 8-bit DR Register
TDI
r/w
4
Address
0
31
Data
5
Address
Decoder
0
TDO
32
Debug Comms Control Register
Debug Comms Data Register
A read or write takes place when the TAP controller enters UPDATE-DR state. Refer to the IEEE 1149.1 for more
details on JTAG operations.
• The address of the Debug Comms Control Register is 0x04.
• The address of the Debug Comms Data Register is 0x05.
The Debug Comms Control Register is read-only and allows synchronized handshaking between the processor
and the debugger.
– Bit 1 (W): Denotes whether the programmer can read a data through the Debug Comms Data Register.
If the device is busy W = 0, then the programmer must poll until W = 1.
– Bit 0 (R): Denotes whether the programmer can send data from the Debug Comms Data Register. If R
= 1, data previously placed there through the scan chain has not been collected by the device and so
the programmer must wait.
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The write handshake is done by polling the Debug Comms Control Register until the R bit is cleared. Once cleared,
data can be written to the Debug Comms Data Register.
The read handshake is done by polling the Debug Comms Control Register until the W bit is set. Once set, data
can be read in the Debug Comms Data Register.
20.3.4
Device Operations
Several commands on the Flash memory are available. These commands are summarized in Table 20-3 on page
153. Commands are run by the programmer through the serial interface that is reading and writing the Debug
Comms Registers.
20.3.4.1
Flash Read Command
This command is used to read the Flash contents. The memory map is accessible through this command. Memory
is seen as an array of words (32-bit wide). The read command can start at any valid address in the memory plane.
This address must be word-aligned. The address is automatically incremented.
Table 20-18. Read Command
Read/Write
DR Data
Write
(Number of Words to Read) << 16 | READ
Write
Address
Read
Memory [address]
Read
Memory [address+4]
...
...
Read
Memory [address+(Number of Words to Read - 1)* 4]
20.3.4.2
Flash W
rite Command
This command is used to write the Flash contents. The address transmitted must be a valid Flash address in the
memory plane.
The Flash memory plane is organized into several pages. Data to be written is stored in a load buffer that corresponds to a Flash memory page. The load buffer is automatically flushed to the Flash:
• before access to any page than the current one
• at the end of the number of words transmitted
The Write Page command (WP) is optimized for consecutive writes. Write handshaking can be chained; an internal address buffer is automatically increased.
Table 20-19. Write Command
Read/Write
DR Data
Write
(Number of Words to Write) << 16 | (WP or WPL or EWP or EWPL)
Write
Address
Write
Memory [address]
Write
Memory [address+4]
Write
Memory [address+8]
Write
Memory [address+(Number of Words to Write - 1)* 4]
Flash Write Page and Lock command (WPL) is equivalent to the Flash Write Command. However, the lock bit is
automatically set at the end of the Flash write operation. As a lock region is composed of several pages, the pro-
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grammer writes to the first pages of the lock region using Flash write commands and writes to the last page of the
lock region using a Flash write and lock command.
Flash Erase Page and Write command (EWP) is equivalent to the Flash Write Command. However, before programming the load buffer, the page is erased.
Flash Erase Page and Write the Lock command (EWPL) combines EWP and WPL commands.
20.3.4.3
Flash Full Erase Command
This command is used to erase the Flash memory planes.
All lock bits must be deactivated before using the Full Erase command. This can be done by using the CLB
command.
Table 20-20. Full Erase Command
Read/Write
DR Data
Write
EA
20.3.4.4
Flash Lock Commands
Lock bits can be set using WPL or EWPL commands. They can also be set by using the Set Lock command
(SLB). With this command, several lock bits can be activated at the same time. Bit 0 of Bit Mask corresponds to the
first lock bit and so on.
In the same way, the Clear Lock command (CLB) is used to clear lock bits. All the lock bits can also be cleared by
the EA command.
Table 20-21. Set and Clear Lock Bit Command
Read/Write
DR Data
Write
SLB or CLB
Write
Bit Mask
Lock bits can be read using Get Lock Bit command (GLB). When a bit set in the Bit Mask is returned, then the corresponding lock bit is active.
Table 20-22. Get Lock Bit Command
Read/Write
DR Data
Write
GLB
Read
Bit Mask
20.3.4.5
Flash General-purpose NVM Commands
General-purpose NVM bits (GP NVM) can be set with the Set GPNVM command (SGPB). Using this command,
several GP NVM bits can be activated at the same time. Bit 0 of Bit Mask corresponds to the first GPNVM bit and
so on.
In the same way, the Clear GPNVM command (CGPB) is used to clear GP NVM bits. All the general-purpose NVM
bits are also cleared by the EA command.
Table 20-23. Set and Clear General-purpose NVM Bit Command
Read/Write
DR Data
Write
SGPB or CGPB
Write
Bit Mask
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GP NVM bits can be read using Get GPNVM Bit command (GGPB). When a bit set in the Bit Mask is returned,
then the corresponding GPNVM bit is set.
Table 20-24. Get General-purpose NVM Bit Command
Read/Write
DR Data
Write
GGPB
Read
Bit Mask
20.3.4.6
Flash Security Bit Command
Security bits can be set using Set Security Bit command (SSE). Once the security bit is active, the Fast Flash programming is disabled. No other command can be run. Only an event on the Erase pin can erase the security bit
once the contents of the Flash have been erased.
Table 20-25. Set Security Bit Command
Read/Write
DR Data
Write
SSE
Once the security bit is set, it is not possible to access FFPI. The only way to erase the security bit is to erase the
Flash.
In order to erase the Flash, the user must perform the following:
• Power-off the chip
• Power-on the chip with TST = 0 and FWUP=0
• Assert Erase during a period of more than 220 ms
• Power-off the chip
Then it is possible to return to FFPI mode and check that Flash is erased.
20.3.4.7
Memory W
rite Command
This command is used to perform a write access to any memory location.
The Memory Write command (WRAM) is optimized for consecutive writes. An internal address buffer is automatically increased.
Table 20-26. Write Command
Read/Write
DR Data
Write
(Number of Words to Write) << 16 | (WRAM)
Write
Address
Write
Memory [address]
Write
Memory [address+4]
Write
Memory [address+8]
Write
Memory [address+(Number of Words to Write - 1)* 4]
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20.3.4.8
Get Version Command
The Get Version (GVE) command retrieves the version of the FFPI interface.
Table 20-27. Get Version Command
Read/Write
DR Data
Write
GVE
Read
Version
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21. AT91SAM Boot Program
21.1
Overview
The Boot Program integrates different programs permitting download and/or upload into the different memories of
the product.
SAM-BA® Boot is executed at power-up only, if the device exits OFF mode and if the GPNVM bit 1 is set to 0.
Once running, SAM-BA™ Boot first initializes the Debug Unit serial port (DBGU) and the PLL frequency, then it
waits for transactions on the DBGU serial port.
21.2
Flow Diagram
The Boot Program implements the algorithm in Figure 21-1.
Figure 21-1. Boot Program Algorithm Flow Diagram
No
Device
Setup
21.3
AutoBaudrate
Sequence Successful ?
Yes
Run SAM-BA Boot
Device Initialization
Initialization follows the steps described below:
1. FIQ initialization
1. Stack setup for ARM supervisor mode
2. Setup the Embedded Flash Controller
3. PLL setup: PLL is initialized to generate a 30 MHz typical frequency
4. Switch Master Clock on PLL Clock divided by 2 (15 MHz MCK frequency)
5. Copy code into SRAM
6. C variable initialization
7. Disable of the Watchdog and enable of the user reset
8. Jump to SAM-BA Boot sequence (see “SAM-BA Boot” )
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21.4
SAM-BA Boot
The SAM-BA boot principle is to:
– Check if the AutoBaudrate sequence has succeeded (see Figure 21-2)
– Check if characters have been received on the DBGU
Figure 21-2. AutoBaudrate Flow Diagram
Device
Setup
Character '0x80'
received ?
No
Yes
Define baudrate
divisor value
Clock accurate
adjustment
Adjust PLL
MUL value
Character '#'
received ?
No
Test Communication
Yes
Send Character '>'
UART operational
Run SAM-BA Boot
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Once the communication interface is identified, the application runs in an infinite loop waiting for different commands as given in Table 21-1.
Table 21-1.
Commands Available through the SAM-BA Boot
Command
Action
Argument(s)
Example
O
write a byte
Address, Value#
O200001,CA#
o
read a byte
Address,#
o200001,#
H
write a half word
Address, Value#
H200002,CAFE#
h
read a half word
Address,#
h200002,#
W
write a word
Address, Value#
W200000,CAFEDECA#
w
read a word
Address,#
w200000,#
S
send a file
Address,#
S200000,#
R
receive a file
Address, NbOfBytes#
R200000,1234#
G
go
Address#
G200200#
V
display version
No argument
V#
• Write commands: Write a byte (O), a halfword (H) or a word (W) to the target.
– Address: Address in hexadecimal.
– Value: Byte, halfword or word to write in hexadecimal.
– Output: ‘>’.
• Read commands: Read a byte (o), a halfword (h) or a word (w) from the target.
– Address: Address in hexadecimal
– Output: The byte, halfword or word read in hexadecimal following by ‘>’
• Send a file (S): Send a file to a specified address
– Address: Address in hexadecimal
– Output: ‘>’.
Note:
There is a time-out on this command which is reached when the prompt ‘>’ appears before the end of the command
execution.
• Receive a file (R): Receive data into a file from a specified address
– Address: Address in hexadecimal
– NbOfBytes: Number of bytes in hexadecimal to receive
– Output: ‘>’
• Go (G): Jump to a specified address and execute the code
– Address: Address to jump in hexadecimal
– Output: ‘>’
• Get Version (V): Return the SAM-BA boot version
– Output: ‘>’
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21.4.1
DBGU Serial Port
Communication is performed through the DBGU serial port initialized to 115200 Baud, 8, n, 1.
The Send and Receive File commands use the Xmodem protocol to communicate. Any terminal performing this
protocol can be used to send the application file to the target. The size of the binary file to send depends on the
SRAM size embedded in the product. In all cases, the size of the binary file must be lower than the SRAM size
because the Xmodem protocol requires some SRAM memory to work.
21.4.2
Xmodem Protocol
The Xmodem protocol supported is the 128-byte length block. This protocol uses a two-character CRC-16 to guarantee detection of a maximum bit error.
Xmodem protocol with CRC is accurate provided both sender and receiver report successful transmission. Each
block of the transfer looks like:
<SOH><blk #><255-blk #><--128 data bytes--><checksum> in which:
– <SOH> = 01 hex
– <blk #> = binary number, starts at 01, increments by 1, and wraps 0FFH to 00H (not to 01)
– <255-blk #> = 1’s complement of the blk#.
– <checksum> = 2 bytes CRC16
Figure 21-3 shows a transmission using this protocol.
Figure 21-3. Xmodem Transfer Example
Host
Device
C
SOH 01 FE Data[128] CRC CRC
ACK
SOH 02 FD Data[128] CRC CRC
ACK
SOH 03 FC Data[100] CRC CRC
ACK
EOT
ACK
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21.5
In-Application Programming (IAP) Feature
The IAP feature is a function located in ROM that can be called by any software application.
When called, this function sends the desired FLASH command to the EEFC and waits for the FLASH to be ready
(looping while the FRDY bit is not set in the MC_FSR register).
Since this function is executed from ROM, this allows FLASH programming (like sector write) to be done by code
running in FLASH.
The IAP function entry point is retrieved by reading the SWI vector in ROM (0x400008).
This funtion takes one argument in parameter: the command to be sent to the EEFC.
This function returns the value of the MC_FSR register.
IAP software code example:
(unsigned int) (*IAP_Function)(unsigned long);
void main (void)
{
unsigned long FlashSectorNum = 200;
unsigned long flash_cmd = 0;
unsigned long flash_status = 0;
/* Initialize the function pointer (retrieve function address from SWI vector) */
IAP_Function = ((unsigned long) (*)(unsigned long)) 0x400008;
/* Send your data to the sector */
/* build the command to send to EFC */
flash_cmd =
(0x5A << 24) | (FlashSectorNum << 8) | AT91C_MC_FCMD_EWP;
/* Call the IAP function with appropriate command */
flash_status = IAP_Function (flash_cmd);
}
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21.6
Hardware and Software Constraints
Table 21-2.
Pins Driven during Boot Program Execution
Peripheral
Pin
PIO Line
DBGU
DRXD
PC16
DBGU
DTXD
PC17
Using a 32.768 KHz crystal is not mandatory since SAM-BA boot will automatically use the internal 32Khz RC
oscillator. PLL MUL parameter is automatically adapted to provide 115200 baudrate on the DBGU serial port.
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22. Peripheral DMA Controller (PDC)
22.1
Overview
The Peripheral DMA Controller (PDC) transfers data between on-chip serial peripherals such as the UART,
USART, SSC, SPI, MCI and the on- and off-chip memories. Using the Peripheral DMA Controller avoids processor
intervention and removes the processor interrupt-handling overhead. This significantly reduces the number of
clock cycles required for a data transfer and, as a result, improves the performance of the microcontroller and
makes it more power efficient.
The PDC channels are implemented in pairs, each pair being dedicated to a particular peripheral. One channel in
the pair is dedicated to the receiving channel and one to the transmitting channel of each UART, USART, SSC and
SPI.
The user interface of a PDC channel is integrated in the memory space of each peripheral. It contains:
• two 32-bit memory pointer registers (send and receive)
• two 16-bit transfer count registers (send and receive)
• two 32-bit registers for next memory pointer (send and receive)
• two 16-bit registesr for next transfer count (send and receive)
The peripheral triggers PDC transfers using transmit and receive signals. When the programmed data is transferred, an end of transfer interrupt is generated by the corresponding peripheral.
22.2
Block Diagram
Figure 22-1. Block Diagram
Peripheral
Peripheral DMA Controller
THR
PDC Channel 0
RHR
PDC Channel 1
Control
Control
Memory
Controller
Status & Control
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22.3
22.3.1
Functional Description
Configuration
The PDC channels user interface enables the user to configure and control the data transfers for each channel.
The user interface of a PDC channel is integrated into the user interface of the peripheral (offset 0x100), which it is
related to.
Per peripheral, it contains four 32-bit Pointer Registers (RPR, RNPR, TPR, and TNPR) and four 16-bit Counter
Registers (RCR, RNCR, TCR, and TNCR).
The size of the buffer (number of transfers) is configured in an internal 16-bit transfer counter register, and it is possible, at any moment, to read the number of transfers left for each channel.
The memory base address is configured in a 32-bit memory pointer by defining the location of the first address to
access in the memory. It is possible, at any moment, to read the location in memory of the next transfer and the
number of remaining transfers. The PDC has dedicated status registers which indicate if the transfer is enabled or
disabled for each channel. The status for each channel is located in the peripheral status register. Transfers can be
enabled and/or disabled by setting TXTEN/TXTDIS and RXTEN/RXTDIS in PDC Transfer Control Register. These
control bits enable reading the pointer and counter registers safely without any risk of their changing between both
reads.
The PDC sends status flags to the peripheral visible in its status-register (ENDRX, ENDTX, RXBUFF, and
TXBUFE).
ENDRX flag is set when the PERIPH_RCR register reaches zero.
RXBUFF flag is set when both PERIPH_RCR and PERIPH_RNCR reach zero.
ENDTX flag is set when the PERIPH_TCR register reaches zero.
TXBUFE flag is set when both PERIPH_TCR and PERIPH_TNCR reach zero.
These status flags are described in the peripheral status register.
22.3.2
Memory Pointers
Each peripheral is connected to the PDC by a receiver data channel and a transmitter data channel. Each channel
has an internal 32-bit memory pointer. Each memory pointer points to a location anywhere in the memory space
(on-chip memory or external bus interface memory).
Depending on the type of transfer (byte, half-word or word), the memory pointer is incremented by 1, 2 or 4,
respectively for peripheral transfers.
If a memory pointer is reprogrammed while the PDC is in operation, the transfer address is changed, and the PDC
performs transfers using the new address.
22.3.3
Transfer Counters
There is one internal 16-bit transfer counter for each channel used to count the size of the block already transferred
by its associated channel. These counters are decremented after each data transfer. When the counter reaches
zero, the transfer is complete and the PDC stops transferring data.
If the Next Counter Register is equal to zero, the PDC disables the trigger while activating the related peripheral
end flag.
If the counter is reprogrammed while the PDC is operating, the number of transfers is updated and the PDC counts
transfers from the new value.
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Programming the Next Counter/Pointer registers chains the buffers. The counters are decremented after each data
transfer as stated above, but when the transfer counter reaches zero, the values of the Next Counter/Pointer are
loaded into the Counter/Pointer registers in order to re-enable the triggers.
For each channel, two status bits indicate the end of the current buffer (ENDRX, ENDTX) and the end of both current and next buffer (RXBUFF, TXBUFE). These bits are directly mapped to the peripheral status register and can
trigger an interrupt request to the AIC.
The peripheral end flag is automatically cleared when one of the counter-registers (Counter or Next Counter Register) is written.
Note: When the Next Counter Register is loaded into the Counter Register, it is set to zero.
22.3.4
Data Transfers
The peripheral triggers PDC transfers using transmit (TXRDY) and receive (RXRDY) signals.
When the peripheral receives an external character, it sends a Receive Ready signal to the PDC which then
requests access to the system bus. When access is granted, the PDC starts a read of the peripheral Receive Holding Register (RHR) and then triggers a write in the memory.
After each transfer, the relevant PDC memory pointer is incremented and the number of transfers left is decremented. When the memory block size is reached, a signal is sent to the peripheral and the transfer stops.
The same procedure is followed, in reverse, for transmit transfers.
22.3.5
Priority of PDC Transfer Requests
The Peripheral DMA Controller handles transfer requests from the channel according to priorities fixed for each
product.These priorities are defined in the product datasheet.
If simultaneous requests of the same type (receiver or transmitter) occur on identical peripherals, the priority is
determined by the numbering of the peripherals.
If transfer requests are not simultaneous, they are treated in the order they occurred. Requests from the receivers
are handled first and then followed by transmitter requests.
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22.4
Peripheral DMA Controller (PDC) User Interface
Table 22-1.
Offset
Register Mapping
Register
Register Name
(1)
Access
Reset
0x100
Receive Pointer Register
PERIPH _RPR
Read-write
0x0
0x104
Receive Counter Register
PERIPH_RCR
Read-write
0x0
0x108
Transmit Pointer Register
PERIPH_TPR
Read-write
0x0
0x10C
Transmit Counter Register
PERIPH_TCR
Read-write
0x0
0x110
Receive Next Pointer Register
PERIPH_RNPR
Read-write
0x0
0x114
Receive Next Counter Register
PERIPH_RNCR
Read-write
0x0
0x118
Transmit Next Pointer Register
PERIPH_TNPR
Read-write
0x0
0x11C
Transmit Next Counter Register
PERIPH_TNCR
Read-write
0x0
0x120
PDC Transfer Control Register
PERIPH_PTCR
Write-only
-
0x124
PDC Transfer Status Register
PERIPH_PTSR
Read-only
0x0
Note:
1. PERIPH: Ten registers are mapped in the peripheral memory space at the same offset. These can be defined by the user
according to the function and the peripheral desired (DBGU, USART, SSC, SPI, MCI etc).
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22.4.1
PDC Receive Pointer Register
Register Name:
PERIPH_RPR
Access Type:
31
Read-write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
RXPTR
23
22
21
20
RXPTR
15
14
13
12
RXPTR
7
6
5
4
RXPTR
• RXPTR: Receive Pointer Address
Address of the next receive transfer.
22.4.2
PDC Receive Counter Register
Register Name:
PERIPH_RCR
Access Type:
31
Read-write
30
29
28
-23
22
21
20
-15
14
13
12
RXCTR
7
6
5
4
RXCTR
• RXCTR: Receive Counter Value
Number of receive transfers to be performed.
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22.4.3
PDC Transmit Pointer Register
Register Name:
PERIPH_TPR
Access Type:
31
Read-write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
TXPTR
23
22
21
20
TXPTR
15
14
13
12
TXPTR
7
6
5
4
TXPTR
• TXPTR: Transmit Pointer Address
Address of the transmit buffer.
22.4.4
PDC Transmit Counter Register
Register Name:
PERIPH_TCR
Access Type:
31
Read-write
30
29
28
-23
22
21
20
-15
14
13
12
TXCTR
7
6
5
4
TXCTR
• TXCTR: Transmit Counter Value
TXCTR is the size of the transmit transfer to be performed. At zero, the peripheral data transfer is stopped.
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22.4.5
PDC Receive Next Pointer Register
Register Name:
PERIPH_RNPR
Access Type:
31
Read-write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
RXNPTR
23
22
21
20
RXNPTR
15
14
13
12
RXNPTR
7
6
5
4
RXNPTR
• RXNPTR: Receive Next Pointer Address
RXNPTR is the address of the next buffer to fill with received data when the current buffer is full.
22.4.6
PDC Receive Next Counter Register
Register Name:
PERIPH_RNCR
Access Type:
31
Read-write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
-23
22
21
20
-15
14
13
12
RXNCR
7
6
5
4
RXNCR
• RXNCR: Receive Next Counter Value
RXNCR is the size of the next buffer to receive.
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22.4.7
PDC Transmit Next Pointer Register
Register Name:
PERIPH_TNPR
Access Type:
31
Read-write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
TXNPTR
23
22
21
20
TXNPTR
15
14
13
12
TXNPTR
7
6
5
4
TXNPTR
• TXNPTR: Transmit Next Pointer Address
TXNPTR is the address of the next buffer to transmit when the current buffer is empty.
22.4.8
PDC Transmit Next Counter Register
Register Name:
PERIPH_TNCR
Access Type:
31
Read-write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
-23
22
21
20
-15
14
13
12
TXNCR
7
6
5
4
TXNCR
• TXNCR: Transmit Next Counter Value
TXNCR is the size of the next buffer to transmit.
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22.4.9
PDC Transfer Control Register
Register Name:
PERIPH_PTCR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
TXTDIS
TXTEN
7
6
5
4
3
2
1
0
–
–
–
–
–
–
RXTDIS
RXTEN
• RXTEN: Receiver Transfer Enable
0 = No effect.
1 = Enables the receiver PDC transfer requests if RXTDIS is not set.
• RXTDIS: Receiver Transfer Disable
0 = No effect.
1 = Disables the receiver PDC transfer requests.
• TXTEN: Transmitter Transfer Enable
0 = No effect.
1 = Enables the transmitter PDC transfer requests.
• TXTDIS: Transmitter Transfer Disable
0 = No effect.
1 = Disables the transmitter PDC transfer requests
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22.4.10 PDC Transfer Status Register
Register Name:
PERIPH_PTSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
TXTEN
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
RXTEN
• RXTEN: Receiver Transfer Enable
0 = Receiver PDC transfer requests are disabled.
1 = Receiver PDC transfer requests are enabled.
• TXTEN: Transmitter Transfer Enable
0 = Transmitter PDC transfer requests are disabled.
1 = Transmitter PDC transfer requests are enabled.
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23. Advanced Interrupt Controller (AIC)
23.1
Overview
The Advanced Interrupt Controller (AIC) is an 8-level priority, individually maskable, vectored interrupt controller,
providing handling of up to thirty-two interrupt sources. It is designed to substantially reduce the software and realtime overhead in handling internal and external interrupts.
The AIC drives the nFIQ (fast interrupt request) and the nIRQ (standard interrupt request) inputs of an ARM processor. Inputs of the AIC are either internal peripheral interrupts or external interrupts coming from the product's
pins.
The 8-level Priority Controller allows the user to define the priority for each interrupt source, thus permitting higher
priority interrupts to be serviced even if a lower priority interrupt is being treated.
Internal interrupt sources can be programmed to be level sensitive or edge triggered. External interrupt sources
can be programmed to be positive-edge or negative-edge triggered or high-level or low-level sensitive.
The fast forcing feature redirects any internal or external interrupt source to provide a fast interrupt rather than a
normal interrupt.
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23.2
Block Diagram
Figure 23-1. Block Diagram
FIQ
AIC
ARM
Processor
IRQ0-IRQn
Up to
Thirty-two
Sources
Embedded
PeripheralEE
Embedded
nFIQ
nIRQ
Peripheral
Embedded
Peripheral
APB
23.3
Application Block Diagram
Figure 23-2. Description of the Application Block
OS-based Applications
Standalone
Applications
OS Drivers
RTOS Drivers
Hard Real Time Tasks
General OS Interrupt Handler
Advanced Interrupt Controller
External Peripherals
(External Interrupts)
Embedded Peripherals
23.4
AIC Detailed Block Diagram
Figure 23-3. AIC Detailed Block Diagram
Advanced Interrupt Controller
FIQ
PIO
Controller
Fast
Interrupt
Controller
External
Source
Input
Stage
ARM
Processor
nFIQ
nIRQ
IRQ0-IRQn
Embedded
Peripherals
Interrupt
Priority
Controller
Fast
Forcing
PIOIRQ
Internal
Source
Input
Stage
Processor
Clock
Power
Management
Controller
User Interface
Wake Up
APB
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23.5
I/O Line Description
Table 23-1.
I/O Line Description
Pin Name
Pin Description
Type
FIQ
Fast Interrupt
Input
IRQ0 - IRQn
Interrupt 0 - Interrupt n
Input
23.6
Product Dependencies
23.6.1
I/O Lines
The interrupt signals FIQ and IRQ0 to IRQn are normally multiplexed through the PIO controllers. Depending on
the features of the PIO controller used in the product, the pins must be programmed in accordance with their
assigned interrupt function. This is not applicable when the PIO controller used in the product is transparent on the
input path.
23.6.2
Power Management
The Advanced Interrupt Controller is continuously clocked. The Power Management Controller has no effect on the
Advanced Interrupt Controller behavior.
The assertion of the Advanced Interrupt Controller outputs, either nIRQ or nFIQ, wakes up the ARM processor
while it is in Idle Mode. The General Interrupt Mask feature enables the AIC to wake up the processor without
asserting the interrupt line of the processor, thus providing synchronization of the processor on an event.
23.6.3
Interrupt Sources
The Interrupt Source 0 is always located at FIQ. If the product does not feature an FIQ pin, the Interrupt Source 0
cannot be used.
The Interrupt Source 1 is always located at System Interrupt. This is the result of the OR-wiring of the system
peripheral interrupt lines, such as the System Timer, the Real Time Clock, the Power Management Controller and
the Memory Controller. When a system interrupt occurs, the service routine must first distinguish the cause of the
interrupt. This is performed by reading successively the status registers of the above mentioned system
peripherals.
The interrupt sources 2 to 31 can either be connected to the interrupt outputs of an embedded user peripheral or to
external interrupt lines. The external interrupt lines can be connected directly, or through the PIO Controller.
The PIO Controllers are considered as user peripherals in the scope of interrupt handling. Accordingly, the PIO
Controller interrupt lines are connected to the Interrupt Sources 2 to 31.
The peripheral identification defined at the product level corresponds to the interrupt source number (as well as the
bit number controlling the clock of the peripheral). Consequently, to simplify the description of the functional operations and the user interface, the interrupt sources are named FIQ, SYS, and PID2 to PID31.
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23.7
23.7.1
Functional Description
Interrupt Source Control
23.7.1.1
Interrupt Source Mode
The Advanced Interrupt Controller independently programs each interrupt source. The SRCTYPE field of the corresponding AIC_SMR (Source Mode Register) selects the interrupt condition of each source.
The internal interrupt sources wired on the interrupt outputs of the embedded peripherals can be programmed
either in level-sensitive mode or in edge-triggered mode. The active level of the internal interrupts is not important
for the user.
The external interrupt sources can be programmed either in high level-sensitive or low level-sensitive modes, or in
positive edge-triggered or negative edge-triggered modes.
23.7.1.2
Interrupt Source Enabling
Each interrupt source, including the FIQ in source 0, can be enabled or disabled by using the command registers;
AIC_IECR (Interrupt Enable Command Register) and AIC_IDCR (Interrupt Disable Command Register). This set
of registers conducts enabling or disabling in one instruction. The interrupt mask can be read in the AIC_IMR register. A disabled interrupt does not affect servicing of other interrupts.
23.7.1.3
Interrupt Clearing and Setting
All interrupt sources programmed to be edge-triggered (including the FIQ in source 0) can be individually set or
cleared by writing respectively the AIC_ISCR and AIC_ICCR registers. Clearing or setting interrupt sources programmed in level-sensitive mode has no effect.
The clear operation is perfunctory, as the software must perform an action to reinitialize the “memorization” circuitry activated when the source is programmed in edge-triggered mode. However, the set operation is available
for auto-test or software debug purposes. It can also be used to execute an AIC-implementation of a software
interrupt.
The AIC features an automatic clear of the current interrupt when the AIC_IVR (Interrupt Vector Register) is read.
Only the interrupt source being detected by the AIC as the current interrupt is affected by this operation. (See “Priority Controller” on page 189.) The automatic clear reduces the operations required by the interrupt service routine
entry code to reading the AIC_IVR. Note that the automatic interrupt clear is disabled if the interrupt source has the
Fast Forcing feature enabled as it is considered uniquely as a FIQ source. (For further details, See “Fast Forcing”
on page 193.)
The automatic clear of the interrupt source 0 is performed when AIC_FVR is read.
23.7.1.4
Interrupt Status
For each interrupt, the AIC operation originates in AIC_IPR (Interrupt Pending Register) and its mask in AIC_IMR
(Interrupt Mask Register). AIC_IPR enables the actual activity of the sources, whether masked or not.
The AIC_ISR register reads the number of the current interrupt (see “Priority Controller” on page 189) and the register AIC_CISR gives an image of the signals nIRQ and nFIQ driven on the processor.
Each status referred to above can be used to optimize the interrupt handling of the systems.
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23.7.1.5
Internal Interrupt Source Input Stage
Figure 23-4.
Internal Interrupt Source Input Stage
AIC_SMRI
(SRCTYPE)
Level/
Edge
Source i
AIC_IPR
AIC_IMR
Fast Interrupt Controller
or
Priority Controller
Edge
AIC_IECR
Detector
Set Clear
FF
AIC_ISCR
AIC_ICCR
AIC_IDCR
23.7.1.6
External Interrupt Source Input Stage
Figure 23-5. External Interrupt Source Input Stage
High/Low
AIC_SMRi
SRCTYPE
Level/
Edge
AIC_IPR
AIC_IMR
Source i
Fast Interrupt Controller
or
Priority Controller
AIC_IECR
Pos./Neg.
Edge
Detector
Set
AIC_ISCR
FF
Clear
AIC_IDCR
AIC_ICCR
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23.7.2
Interrupt Latencies
Global interrupt latencies depend on several parameters, including:
• The time the software masks the interrupts.
• Occurrence, either at the processor level or at the AIC level.
• The execution time of the instruction in progress when the interrupt occurs.
• The treatment of higher priority interrupts and the resynchronization of the hardware signals.
This section addresses only the hardware resynchronizations. It gives details of the latency times between the
event on an external interrupt leading in a valid interrupt (edge or level) or the assertion of an internal interrupt
source and the assertion of the nIRQ or nFIQ line on the processor. The resynchronization time depends on the
programming of the interrupt source and on its type (internal or external). For the standard interrupt, resynchronization times are given assuming there is no higher priority in progress.
The PIO Controller multiplexing has no effect on the interrupt latencies of the external interrupt sources.
23.7.2.1
External Interrupt Edge Triggered Source
Figure 23-6.
External Interrupt Edge Triggered Source
MCK
IRQ or FIQ
(Positive Edge)
IRQ or FIQ
(Negative Edge)
nIRQ
Maximum IRQ Latency = 4 Cycles
nFIQ
Maximum FIQ Latency = 4 Cycles
23.7.2.2
External Interrupt Level Sensitive Source
Figure 23-7.
External Interrupt Level Sensitive Source
MCK
IRQ or FIQ
(High Level)
IRQ or FIQ
(Low Level)
nIRQ
Maximum IRQ
Latency = 3 Cycles
nFIQ
Maximum FIQ
Latency = 3 cycles
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23.7.2.3
Internal Interrupt Edge Triggered Source
Figure 23-8.
Internal Interrupt Edge Triggered Source
MCK
nIRQ
Maximum IRQ Latency = 4.5 Cycles
Peripheral Interrupt
Becomes Active
23.7.2.4
Internal Interrupt Level Sensitive Source
Figure 23-9.
Internal Interrupt Level Sensitive Source
MCK
nIRQ
Maximum IRQ Latency = 3.5 Cycles
Peripheral Interrupt
Becomes Active
23.7.3
Normal Interrupt
23.7.3.1
Priority Controller
An 8-level priority controller drives the nIRQ line of the processor, depending on the interrupt conditions occurring
on the interrupt sources 1 to 31 (except for those programmed in Fast Forcing).
Each interrupt source has a programmable priority level of 7 to 0, which is user-definable by writing the PRIOR field
of the corresponding AIC_SMR (Source Mode Register). Level 7 is the highest priority and level 0 the lowest.
As soon as an interrupt condition occurs, as defined by the SRCTYPE field of the AIC_SMR (Source Mode Register), the nIRQ line is asserted. As a new interrupt condition might have happened on other interrupt sources since
the nIRQ has been asserted, the priority controller determines the current interrupt at the time the AIC_IVR (Interrupt Vector Register) is read. The read of AIC_IVR is the entry point of the interrupt handling which allows the
AIC to consider that the interrupt has been taken into account by the software.
The current priority level is defined as the priority level of the current interrupt.
If several interrupt sources of equal priority are pending and enabled when the AIC_IVR is read, the interrupt with
the lowest interrupt source number is serviced first.
The nIRQ line can be asserted only if an interrupt condition occurs on an interrupt source with a higher priority. If
an interrupt condition happens (or is pending) during the interrupt treatment in progress, it is delayed until the software indicates to the AIC the end of the current service by writing the AIC_EOICR (End of Interrupt Command
Register). The write of AIC_EOICR is the exit point of the interrupt handling.
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23.7.3.2
Interrupt Nesting
The priority controller utilizes interrupt nesting in order for the high priority interrupt to be handled during the service
of lower priority interrupts. This requires the interrupt service routines of the lower interrupts to re-enable the interrupt at the processor level.
When an interrupt of a higher priority happens during an already occurring interrupt service routine, the nIRQ line is
re-asserted. If the interrupt is enabled at the core level, the current execution is interrupted and the new interrupt
service routine should read the AIC_IVR. At this time, the current interrupt number and its priority level are pushed
into an embedded hardware stack, so that they are saved and restored when the higher priority interrupt servicing
is finished and the AIC_EOICR is written.
The AIC is equipped with an 8-level wide hardware stack in order to support up to eight interrupt nestings pursuant
to having eight priority levels.
23.7.3.3
Interrupt Vectoring
The interrupt handler addresses corresponding to each interrupt source can be stored in the registers AIC_SVR1
to AIC_SVR31 (Source Vector Register 1 to 31). When the processor reads AIC_IVR (Interrupt Vector Register),
the value written into AIC_SVR corresponding to the current interrupt is returned.
This feature offers a way to branch in one single instruction to the handler corresponding to the current interrupt, as
AIC_IVR is mapped at the absolute address 0xFFFF F100 and thus accessible from the ARM interrupt vector at
address 0x0000 0018 through the following instruction:
LDR
PC,[PC,# -&F20]
When the processor executes this instruction, it loads the read value in AIC_IVR in its program counter, thus
branching the execution on the correct interrupt handler.
This feature is often not used when the application is based on an operating system (either real time or not). Operating systems often have a single entry point for all the interrupts and the first task performed is to discern the
source of the interrupt.
However, it is strongly recommended to port the operating system on AT91 products by supporting the interrupt
vectoring. This can be performed by defining all the AIC_SVR of the interrupt source to be handled by the operating system at the address of its interrupt handler. When doing so, the interrupt vectoring permits a critical interrupt
to transfer the execution on a specific very fast handler and not onto the operating system’s general interrupt handler. This facilitates the support of hard real-time tasks (input/outputs of voice/audio buffers and software
peripheral handling) to be handled efficiently and independently of the application running under an operating
system.
23.7.3.4
Interrupt Handlers
This section gives an overview of the fast interrupt handling sequence when using the AIC. It is assumed that the
programmer understands the architecture of the ARM processor, and especially the processor interrupt modes and
the associated status bits.
It is assumed that:
1. The Advanced Interrupt Controller has been programmed, AIC_SVR registers are loaded with corresponding interrupt service routine addresses and interrupts are enabled.
2. The instruction at the ARM interrupt exception vector address is required to work with the vectoring
LDR PC, [PC, # -&F20]
When nIRQ is asserted, if the bit “I” of CPSR is 0, the sequence is as follows:
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1. The CPSR is stored in SPSR_irq, the current value of the Program Counter is loaded in the Interrupt link
register (R14_irq) and the Program Counter (R15) is loaded with 0x18. In the following cycle during fetch
at address 0x1C, the ARM core adjusts R14_irq, decrementing it by four.
2. The ARM core enters Interrupt mode, if it has not already done so.
3. When the instruction loaded at address 0x18 is executed, the program counter is loaded with the value
read in AIC_IVR. Reading the AIC_IVR has the following effects:
– Sets the current interrupt to be the pending and enabled interrupt with the highest priority. The current
level is the priority level of the current interrupt.
– De-asserts the nIRQ line on the processor. Even if vectoring is not used, AIC_IVR must be read in
order to de-assert nIRQ.
– Automatically clears the interrupt, if it has been programmed to be edge-triggered.
– Pushes the current level and the current interrupt number on to the stack.
– Returns the value written in the AIC_SVR corresponding to the current interrupt.
4. The previous step has the effect of branching to the corresponding interrupt service routine. This should
start by saving the link register (R14_irq) and SPSR_IRQ. The link register must be decremented by four
when it is saved if it is to be restored directly into the program counter at the end of the interrupt. For
example, the instruction SUB PC, LR, #4 may be used.
5. Further interrupts can then be unmasked by clearing the “I” bit in CPSR, allowing re-assertion of the nIRQ
to be taken into account by the core. This can happen if an interrupt with a higher priority than the current
interrupt occurs.
6. The interrupt handler can then proceed as required, saving the registers that will be used and restoring
them at the end. During this phase, an interrupt of higher priority than the current level will restart the
sequence from step 1.
Note:
If the interrupt is programmed to be level sensitive, the source of the interrupt must be cleared during this phase.
7. The “I” bit in CPSR must be set in order to mask interrupts before exiting to ensure that the interrupt is
completed in an orderly manner.
8. The End of Interrupt Command Register (AIC_EOICR) must be written in order to indicate to the AIC that
the current interrupt is finished. This causes the current level to be popped from the stack, restoring the
previous current level if one exists on the stack. If another interrupt is pending, with lower or equal priority
than the old current level but with higher priority than the new current level, the nIRQ line is re-asserted,
but the interrupt sequence does not immediately start because the “I” bit is set in the core. SPSR_irq is
restored. Finally, the saved value of the link register is restored directly into the PC. This has the effect of
returning from the interrupt to whatever was being executed before, and of loading the CPSR with the
stored SPSR, masking or unmasking the interrupts depending on the state saved in SPSR_irq.
Note:
23.7.4
The “I” bit in SPSR is significant. If it is set, it indicates that the ARM core was on the verge of masking an interrupt
when the mask instruction was interrupted. Hence, when SPSR is restored, the mask instruction is completed (interrupt is masked).
Fast Interrupt
23.7.4.1
Fast Interrupt Source
The interrupt source 0 is the only source which can raise a fast interrupt request to the processor except if fast forcing is used. The interrupt source 0 is generally connected to a FIQ pin of the product, either directly or through a
PIO Controller.
23.7.4.2
Fast Interrupt Control
The fast interrupt logic of the AIC has no priority controller. The mode of interrupt source 0 is programmed with the
AIC_SMR0 and the field PRIOR of this register is not used even if it reads what has been written. The field SRCTYPE of AIC_SMR0 enables programming the fast interrupt source to be positive-edge triggered or negative-edge
triggered or high-level sensitive or low-level sensitive
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Writing 0x1 in the AIC_IECR (Interrupt Enable Command Register) and AIC_IDCR (Interrupt Disable Command
Register) respectively enables and disables the fast interrupt. The bit 0 of AIC_IMR (Interrupt Mask Register) indicates whether the fast interrupt is enabled or disabled.
23.7.4.3
Fast Interrupt Vectoring
The fast interrupt handler address can be stored in AIC_SVR0 (Source Vector Register 0). The value written into
this register is returned when the processor reads AIC_FVR (Fast Vector Register). This offers a way to branch in
one single instruction to the interrupt handler, as AIC_FVR is mapped at the absolute address 0xFFFF F104 and
thus accessible from the ARM fast interrupt vector at address 0x0000 001C through the following instruction:
LDR
PC,[PC,# -&F20]
When the processor executes this instruction it loads the value read in AIC_FVR in its program counter, thus
branching the execution on the fast interrupt handler. It also automatically performs the clear of the fast interrupt
source if it is programmed in edge-triggered mode.
23.7.4.4
Fast Interrupt Handlers
This section gives an overview of the fast interrupt handling sequence when using the AIC. It is assumed that the
programmer understands the architecture of the ARM processor, and especially the processor interrupt modes and
associated status bits.
Assuming that:
1. The Advanced Interrupt Controller has been programmed, AIC_SVR0 is loaded with the fast interrupt service routine address, and the interrupt source 0 is enabled.
2. The Instruction at address 0x1C (FIQ exception vector address) is required to vector the fast interrupt:
LDR PC, [PC, # -&F20]
3. The user does not need nested fast interrupts.
When nFIQ is asserted, if the bit “F” of CPSR is 0, the sequence is:
1. The CPSR is stored in SPSR_fiq, the current value of the program counter is loaded in the FIQ link register (R14_FIQ) and the program counter (R15) is loaded with 0x1C. In the following cycle, during fetch at
address 0x20, the ARM core adjusts R14_fiq, decrementing it by four.
2. The ARM core enters FIQ mode.
3. When the instruction loaded at address 0x1C is executed, the program counter is loaded with the value
read in AIC_FVR. Reading the AIC_FVR has effect of automatically clearing the fast interrupt, if it has
been programmed to be edge triggered. In this case only, it de-asserts the nFIQ line on the processor.
4. The previous step enables branching to the corresponding interrupt service routine. It is not necessary to
save the link register R14_fiq and SPSR_fiq if nested fast interrupts are not needed.
5. The Interrupt Handler can then proceed as required. It is not necessary to save registers R8 to R13
because FIQ mode has its own dedicated registers and the user R8 to R13 are banked. The other registers, R0 to R7, must be saved before being used, and restored at the end (before the next step). Note that
if the fast interrupt is programmed to be level sensitive, the source of the interrupt must be cleared during
this phase in order to de-assert the interrupt source 0.
6. Finally, the Link Register R14_fiq is restored into the PC after decrementing it by four (with instruction
SUB PC, LR, #4 for example). This has the effect of returning from the interrupt to whatever was being
executed before, loading the CPSR with the SPSR and masking or unmasking the fast interrupt depending on the state saved in the SPSR.
Note:
The “F” bit in SPSR is significant. If it is set, it indicates that the ARM core was just about to mask FIQ interrupts when
the mask instruction was interrupted. Hence when the SPSR is restored, the interrupted instruction is completed (FIQ
is masked).
Another way to handle the fast interrupt is to map the interrupt service routine at the address of the ARM vector
0x1C. This method does not use the vectoring, so that reading AIC_FVR must be performed at the very beginning
of the handler operation. However, this method saves the execution of a branch instruction.
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23.7.4.5
Fast Forcing
The Fast Forcing feature of the advanced interrupt controller provides redirection of any normal Interrupt source on
the fast interrupt controller.
Fast Forcing is enabled or disabled by writing to the Fast Forcing Enable Register (AIC_FFER) and the Fast Forcing Disable Register (AIC_FFDR). Writing to these registers results in an update of the Fast Forcing Status
Register (AIC_FFSR) that controls the feature for each internal or external interrupt source.
When Fast Forcing is disabled, the interrupt sources are handled as described in the previous pages.
When Fast Forcing is enabled, the edge/level programming and, in certain cases, edge detection of the interrupt
source is still active but the source cannot trigger a normal interrupt to the processor and is not seen by the priority
handler.
If the interrupt source is programmed in level-sensitive mode and an active level is sampled, Fast Forcing results in
the assertion of the nFIQ line to the core.
If the interrupt source is programmed in edge-triggered mode and an active edge is detected, Fast Forcing results
in the assertion of the nFIQ line to the core.
The Fast Forcing feature does not affect the Source 0 pending bit in the Interrupt Pending Register (AIC_IPR).
The FIQ Vector Register (AIC_FVR) reads the contents of the Source Vector Register 0 (AIC_SVR0), whatever the
source of the fast interrupt may be. The read of the FVR does not clear the Source 0 when the fast forcing feature
is used and the interrupt source should be cleared by writing to the Interrupt Clear Command Register
(AIC_ICCR).
All enabled and pending interrupt sources that have the fast forcing feature enabled and that are programmed in
edge-triggered mode must be cleared by writing to the Interrupt Clear Command Register. In doing so, they are
cleared independently and thus lost interrupts are prevented.
The read of AIC_IVR does not clear the source that has the fast forcing feature enabled.
The source 0, reserved to the fast interrupt, continues operating normally and becomes one of the Fast Interrupt
sources.
Figure 23-10. Fast Forcing
Source 0 _ FIQ
AIC_IPR
Input Stage
Automatic Clear
AIC_IMR
nFIQ
Read FVR if Fast Forcing is
disabled on Sources 1 to 31.
AIC_FFSR
Source n
AIC_IPR
Input Stage
Priority
Manager
Automatic Clear
AIC_IMR
nIRQ
Read IVR if Source n is the current interrupt
and if Fast Forcing is disabled on Source n.
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23.7.5
Protect Mode
The Protect Mode permits reading the Interrupt Vector Register without performing the associated automatic operations. This is necessary when working with a debug system. When a debugger, working either with a Debug
Monitor or the ARM processor's ICE, stops the applications and updates the opened windows, it might read the
AIC User Interface and thus the IVR. This has undesirable consequences:
• If an enabled interrupt with a higher priority than the current one is pending, it is stacked.
• If there is no enabled pending interrupt, the spurious vector is returned.
In either case, an End of Interrupt command is necessary to acknowledge and to restore the context of the AIC.
This operation is generally not performed by the debug system as the debug system would become strongly intrusive and cause the application to enter an undesired state.
This is avoided by using the Protect Mode. Writing DBGM in AIC_DCR (Debug Control Register) at 0x1 enables
the Protect Mode.
When the Protect Mode is enabled, the AIC performs interrupt stacking only when a write access is performed on
the AIC_IVR. Therefore, the Interrupt Service Routines must write (arbitrary data) to the AIC_IVR just after reading
it. The new context of the AIC, including the value of the Interrupt Status Register (AIC_ISR), is updated with the
current interrupt only when AIC_IVR is written.
An AIC_IVR read on its own (e.g., by a debugger), modifies neither the AIC context nor the AIC_ISR. Extra
AIC_IVR reads perform the same operations. However, it is recommended to not stop the processor between the
read and the write of AIC_IVR of the interrupt service routine to make sure the debugger does not modify the AIC
context.
To summarize, in normal operating mode, the read of AIC_IVR performs the following operations within the AIC:
1. Calculates active interrupt (higher than current or spurious).
2. Determines and returns the vector of the active interrupt.
3. Memorizes the interrupt.
4. Pushes the current priority level onto the internal stack.
5. Acknowledges the interrupt.
However, while the Protect Mode is activated, only operations 1 to 3 are performed when AIC_IVR is read. Operations 4 and 5 are only performed by the AIC when AIC_IVR is written.
Software that has been written and debugged using the Protect Mode runs correctly in Normal Mode without modification. However, in Normal Mode the AIC_IVR write has no effect and can be removed to optimize the code.
23.7.6
Spurious Interrupt
The Advanced Interrupt Controller features protection against spurious interrupts. A spurious interrupt is defined as
being the assertion of an interrupt source long enough for the AIC to assert the nIRQ, but no longer present when
AIC_IVR is read. This is most prone to occur when:
• An external interrupt source is programmed in level-sensitive mode and an active level occurs for only a short
time.
• An internal interrupt source is programmed in level sensitive and the output signal of the corresponding
embedded peripheral is activated for a short time. (As in the case for the Watchdog.)
• An interrupt occurs just a few cycles before the software begins to mask it, thus resulting in a pulse on the
interrupt source.
The AIC detects a spurious interrupt at the time the AIC_IVR is read while no enabled interrupt source is pending.
When this happens, the AIC returns the value stored by the programmer in AIC_SPU (Spurious Vector Register).
The programmer must store the address of a spurious interrupt handler in AIC_SPU as part of the application, to
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enable an as fast as possible return to the normal execution flow. This handler writes in AIC_EOICR and performs
a return from interrupt.
23.7.7
General Interrupt Mask
The AIC features a General Interrupt Mask bit to prevent interrupts from reaching the processor. Both the nIRQ
and the nFIQ lines are driven to their inactive state if the bit GMSK in AIC_DCR (Debug Control Register) is set.
However, this mask does not prevent waking up the processor if it has entered Idle Mode. This function facilitates
synchronizing the processor on a next event and, as soon as the event occurs, performs subsequent operations
without having to handle an interrupt. It is strongly recommended to use this mask with caution.
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23.8
Advanced Interrupt Controller (AIC) User Interface
23.8.1
Base Address
The AIC is mapped at the address 0xFFFF F000. It has a total 4-Kbyte addressing space. This permits the vectoring feature, as the PC-relative load/store instructions of the ARM processor support only a ± 4-Kbyte offset.
Table 23-2.
Register Mapping
Offset
Register
Name
Access
Reset
0x00
Source Mode Register 0
AIC_SMR0
Read-write
0x0
0x04
Source Mode Register 1
AIC_SMR1
Read-write
0x0
---
---
---
---
---
0x7C
Source Mode Register 31
AIC_SMR31
Read-write
0x0
0x80
Source Vector Register 0
AIC_SVR0
Read-write
0x0
AIC_SVR1
Read-write
0x0
---
---
---
AIC_SVR31
Read-write
0x0
0x84
Source Vector Register 1
---
---
0xFC
Source Vector Register 31
0x100
Interrupt Vector Register
AIC_IVR
Read-only
0x0
0x104
FIQ Interrupt Vector Register
AIC_FVR
Read-only
0x0
0x108
Interrupt Status Register
AIC_ISR
Read-only
0x0
AIC_IPR
Read-only
0x0(1)
(2)
0x10C
Interrupt Pending Register
0x110
Interrupt Mask Register(2)
AIC_IMR
Read-only
0x0
0x114
Core Interrupt Status Register
AIC_CISR
Read-only
0x0
0x118 - 0x11C
Reserved
---
---
---
AIC_IECR
Write-only
---
AIC_IDCR
Write-only
---
0x120
Interrupt Enable Command Register
(2)
(2)
0x124
Interrupt Disable Command Register
0x128
(2)
Interrupt Clear Command Register
AIC_ICCR
Write-only
---
0x12C
Interrupt Set Command Register(2)
AIC_ISCR
Write-only
---
0x130
End of Interrupt Command Register
AIC_EOICR
Write-only
---
0x134
Spurious Interrupt Vector Register
AIC_SPU
Read-write
0x0
0x138
Debug Control Register
AIC_DCR
Read-write
0x0
0x13C
Reserved
---
---
---
AIC_FFER
Write-only
---
AIC_FFDR
Write-only
---
AIC_FFSR
Read-only
0x0
---
---
---
0x140
Fast Forcing Enable Register
(2)
0x144
Fast Forcing Disable Register
(2)
0x148
Fast Forcing Status Register
0x14C - 0x1E0
Reserved
0x1EC - 0x1FC
Reserved
Notes:
(2)
1. The reset value of this register depends on the level of the external interrupt source. All other sources are cleared at reset,
thus not pending.
2. PID2...PID31 bit fields refer to the identifiers as defined in the Peripheral Identifiers Section of the product datasheet.
3. Values in the Version Register vary with the version of the IP block implementation.
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23.8.2
AIC Source Mode Register
Register Name:
AIC_SMR0..AIC_SMR31
Access Type:
Read-write
Reset Value:
0x0
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
SRCTYPE
PRIOR
• PRIOR: Priority Level
Programs the priority level for all sources except FIQ source (source 0).
The priority level can be between 0 (lowest) and 7 (highest).
The priority level is not used for the FIQ in the related SMR register AIC_SMRx.
• SRCTYPE: Interrupt Source Type
The active level or edge is not programmable for the internal interrupt sources.
SRCTYPE
Internal Interrupt Sources
External Interrupt Sources
0
0
High level Sensitive
Low level Sensitive
0
1
Positive edge triggered
Negative edge triggered
1
0
High level Sensitive
High level Sensitive
1
1
Positive edge triggered
Positive edge triggered
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23.8.3
AIC Source Vector Register
Register Name:
AIC_SVR0..AIC_SVR31
Access Type:
Read-write
Reset Value:
0x0
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
VECTOR
23
22
21
20
VECTOR
15
14
13
12
VECTOR
7
6
5
4
VECTOR
• VECTOR: Source Vector
The user may store in these registers the addresses of the corresponding handler for each interrupt source.
23.8.4
AIC Interrupt Vector Register
Register Name:
AIC_IVR
Access Type:
Read-only
Reset Value:
0x0
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
IRQV
23
22
21
20
IRQV
15
14
13
12
IRQV
7
6
5
4
IRQV
• IRQV: Interrupt Vector Register
The Interrupt Vector Register contains the vector programmed by the user in the Source Vector Register corresponding to
the current interrupt.
The Source Vector Register is indexed using the current interrupt number when the Interrupt Vector Register is read.
When there is no current interrupt, the Interrupt Vector Register reads the value stored in AIC_SPU.
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23.8.5
AIC FIQ Vector Register
Register Name:
AIC_FVR
Access Type:
Read-only
Reset Value:
0x0
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
FIQV
23
22
21
20
FIQV
15
14
13
12
FIQV
7
6
5
4
FIQV
• FIQV: FIQ Vector Register
The FIQ Vector Register contains the vector programmed by the user in the Source Vector Register 0. When there is no
fast interrupt, the FIQ Vector Register reads the value stored in AIC_SPU.
23.8.6
AIC Interrupt Status Register
Register Name:
AIC_ISR
Access Type:
Read-only
Reset Value:
0x0
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
IRQID
• IRQID: Current Interrupt Identifier
The Interrupt Status Register returns the current interrupt source number.
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23.8.7
AIC Interrupt Pending Register
Register Name:
AIC_IPR
Access Type:
Read-only
Reset Value:
0x0
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
FIQ
• FIQ, SYS, PID2-PID31: Interrupt Pending
0 = Corresponding interrupt is not pending.
1 = Corresponding interrupt is pending.
23.8.8
AIC Interrupt Mask Register
Register Name:
AIC_IMR
Access Type:
Read-only
Reset Value:
0x0
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
FIQ
• FIQ, SYS, PID2-PID31: Interrupt Mask
0 = Corresponding interrupt is disabled.
1 = Corresponding interrupt is enabled.
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23.8.9
AIC Core Interrupt Status Register
Register Name:
AIC_CISR
Access Type:
Read-only
Reset Value:
0x0
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
NIRQ
NFIQ
• NFIQ: NFIQ Status
0 = nFIQ line is deactivated.
1 = nFIQ line is active.
• NIRQ: NIRQ Status
0 = nIRQ line is deactivated.
1 = nIRQ line is active.
23.8.10 AIC Interrupt Enable Command Register
Register Name:
AIC_IECR
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
FIQ
• FIQ, SYS, PID2-PID31: Interrupt Enable
0 = No effect.
1 = Enables corresponding interrupt.
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23.8.11 AIC Interrupt Disable Command Register
Register Name:
AIC_IDCR
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
FIQ
• FIQ, SYS, PID2-PID31: Interrupt Disable
0 = No effect.
1 = Disables corresponding interrupt.
23.8.12 AIC Interrupt Clear Command Register
Register Name:
AIC_ICCR
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
FIQ
• FIQ, SYS, PID2-PID31: Interrupt Clear
0 = No effect.
1 = Clears corresponding interrupt.
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23.8.13 AIC Interrupt Set Command Register
Register Name:
AIC_ISCR
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
FIQ
• FIQ, SYS, PID2-PID31: Interrupt Set
0 = No effect.
1 = Sets corresponding interrupt.
23.8.14 AIC End of Interrupt Command Register
Register Name:
AIC_EOICR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
–
The End of Interrupt Command Register is used by the interrupt routine to indicate that the interrupt treatment is complete.
Any value can be written because it is only necessary to make a write to this register location to signal the end of interrupt
treatment.
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23.8.15 AIC Spurious Interrupt Vector Register
Register Name:
AIC_SPU
Access Type:
Read-write
Reset Value:
0x0
31
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
SIVR
23
22
21
20
SIVR
15
14
13
12
SIVR
7
6
5
4
SIVR
• SIVR: Spurious Interrupt Vector Register
The user may store the address of a spurious interrupt handler in this register. The written value is returned in AIC_IVR in
case of a spurious interrupt and in AIC_FVR in case of a spurious fast interrupt.
23.8.16 AIC Debug Control Register
Register Name:
AIC_DCR
Access Type:
Read-write
Reset Value:
0x0
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
GMSK
PROT
• PROT: Protection Mode
0 = The Protection Mode is disabled.
1 = The Protection Mode is enabled.
• GMSK: General Mask
0 = The nIRQ and nFIQ lines are normally controlled by the AIC.
1 = The nIRQ and nFIQ lines are tied to their inactive state.
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23.8.17 AIC Fast Forcing Enable Register
Register Name:
AIC_FFER
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
–
• SYS, PID2-PID31: Fast Forcing Enable
0 = No effect.
1 = Enables the fast forcing feature on the corresponding interrupt.
23.8.18 AIC Fast Forcing Disable Register
Register Name:
AIC_FFDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
–
• SYS, PID2-PID31: Fast Forcing Disable
0 = No effect.
1 = Disables the Fast Forcing feature on the corresponding interrupt.
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23.8.19 AIC Fast Forcing Status Register
Register Name:
AIC_FFSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
SYS
–
• SYS, PID2-PID31: Fast Forcing Status
0 = The Fast Forcing feature is disabled on the corresponding interrupt.
1 = The Fast Forcing feature is enabled on the corresponding interrupt.
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24. Clock Generator
24.1
Overview
The Clock Generator is made up of one PLL, one fast RC oscillator, one slow RC oscillator and one 32,768 Hz
Crystal Oscillator.
It provides the following clocks:
• SLCK, the Slow Clock, which is the only permanent clock within the system (except in OFF mode)
• MAINCK is the output of the Main Clock selection: either CLKIN (external clock) or 2 MHz Fast RC Oscillator
• PLLCK is the output of the Divider and PLL block
The Clock Generator User Interface is embedded within the Power Management Controller and is described in
Section 25.9 ”Power Management Controller (PMC) User Interface”. However, the Clock Generator registers are
named CKGR_.
Figure 24-1. Clock Generator Block Diagram
Clock Generator
MCKSEL
CLKIN
Main Clock
MAINCK
Embedded
2 MHz RC
Oscillator
XTALSEL
(Supply Controller)
Embedded
32 kHz RC
Oscillator
Slow Clock
SLCK
XIN
Xtal 32 kHz
Oscillator
XOUT
SLCK
PLL and
Divider
PLL Clock
PLLCK
PLLRC
Status
Control
Power
Management
Controller
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24.2
Slow Clock
The Slow Clock is generated by the Slow Clock Crystal Oscillator or by the Slow Clock RC Oscillator.
The selection is made by writing the XTALSEL bit in the Supply Controller Control Register (SUPC_CR).
By default, the RC Oscillator is selected.
24.3
Slow Clock RC Oscillator
By default, the Slow Clock RC Oscillator is enabled and selected. The user has to take into account the possible
drifts of the RC Oscillator. More details are given in the section “DC Characteristics” of the product datasheet.
It can be disabled via the XTALSEL bit in the Supply Controller Control Register (SUPC_CR).
24.4
Slow Clock Crystal Oscillator
The Clock Generator integrates a 32,768 Hz low-power oscillator.The XIN and XOUT pins must be connected to a
32,768 Hz crystal. Two external capacitors must be wired as shown in Figure 24-2.More details are given in the
section “DC Characteristics” of the product datasheet.
Note that the user is not obliged to use the Slow Clock Crystal and can use the RC Oscillator instead. In this case,
XIN and XOUT can be left unconnected.
Figure 24-2. Typical Slow Clock Crystal Oscillator Connection
XIN
XOUT
GND
32,768 Hz
Crystal
The user can set the Slow Clock Crystal Oscillator in bypass mode instead of connecting a crystal. In this case, the
user has to provide the external clock signal on XIN. The input characteristics of the XIN pin under these conditions
are given in the product electrical characteristics section.
The programmer has to be sure to set the OSCBYPASS bit in the Supply Controller Mode Register (SUPC_MR)
and XTALSEL bit in the Supply Controller Control Register (SUPC_CR).
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24.5
Main Clock
Figure 24-3 shows the Main Clock block diagram.
Figure 24-3. Main Clock Block Diagram
MAINSELS
MCKSEL
CLKIN
1
MAINCK
Main Clock
MAINCKON
Embedded
2 MHz RC
Oscillator
MAINCKON
0
MAINRDY
MAINCKON
SLCK
Slow Clock
Main Clock
Frequency
Counter
MAINF
MAINFRDY
The Main Clock has two sources:
• 2 MHz Fast RC Oscillator which starts very quickly and is used at startup
• an external clock (CLKIN)
24.5.1
2 MHz Fast RC Oscillator
After reset, the 2 MHz Fast RC Oscillator is enabled and selected as MAINCK. MAINCK is the default clock
selected to start up the system.
Startup-up time specifications are provided in the “DC Characteristics” section of the product datasheet.
The software can disable or enable the 2 MHz Fast RC Oscillator with the MAINCKON bit in the Clock Generator
Main Oscillator Register (CKGR_MOR).
When disabling the Main Clock by clearing the MAINCKON bit in CKGR_MOR, the MAINRDY bit in the Power
Management Controller Status Register (PMC_SR) is automatically cleared, indicating the Main Clock is off.
Setting the MAINRDY bit in the Power Management Controller Interrupt Enable Register (PMC_IER) can trigger an
interrupt to the processor.
It is recommended to disable the Main Clock as soon as the processor no longer uses it and runs out of SLCK or
PLLCK.
Disabling the MAINCKON bit is also used to go into WAIT mode. The user sets the Main Clock as Master clock and
disables the Main Clock by clearing the MAINCKON bit.
To wake up from WAIT mode, a fast startup must be done. See Section 25.6 ”The Fast Startup”.
24.5.2
Main Clock Frequency Counter
The device features a Main Clock frequency counter that provides the frequency of the Main Clock.
The Main Clock frequency counter starts incrementing at the Main Clock speed after the next rising edge of the
Slow Clock as soon as MAINCKON is set to 1.Then, at the 16th falling edge of Slow Clock, the MAINFRDY bit in
the Clock Generator Main Clock Frequency Register (CKGR_MCFR) is set and the counter stops counting. Its
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value can be read in the MAINF field of CKGR_MCFR and gives the number of Main Clock cycles during 16 periods of Slow Clock, so that the frequency of the 2 MHz Fast RC Oscillator or CLKIN input signal can be determined.
24.5.3
External Clock CLKIN
The user can input a clock on the device. In this case, the user has to provide the external clock signal on the
CLKIN pin. The programmer has to be sure to set the MCKSEL bit in the Clock Generator Main Oscillator Register
(CKGR_MOR) to 1 for the external clock to operate properly.
The user can check the MAINSELS bit in the Power Management Status Register (PMC_SR) to check that the
selection has been completed.
Note that the user must be sure to put MCKSEL bit to 1 only when an external clock is applied on CLKIN. The user
does not need to check MAINRDY bit when switching to CLKIN.
Input characteristics of the CLKIN pin are given in the Electrical Characteristics section.
24.6
Divider and PLL Block
The PLL embeds an input divider to increase the accuracy of the resulting clock signals. However, the user must
respect the PLL minimum input frequency when programming the divider.
Figure 24-4 shows the block diagram of the divider and PLL block.
Figure 24-4. Divider and PLL Block Diagram
DIV
SLCK
MUL
Divider = 1
OUT
PLLCK
PLL
PLLRC
PLLCOUNT
PLL
Counter
SLCK
24.6.1
LOCK
PLL Filter
The PLL requires connection to an external second-order filter through the PLLRC pin. Figure 24-5 shows a schematic of these filters.
Figure 24-5. PLL Capacitors and Resistors
PLLRC
R
C2
PLL
C1
PLLRCGND
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Values of R, C1 and C2 to be connected to the PLLRC pin must be calculated as a function of the PLL input frequency, the PLL output frequency and the phase margin. A trade off has to be found between output signal
overshoot and startup time. See the product electrical PLL characteristics section.
Note that PLLRCGND must never be connected to GND.
24.6.2
Divider and Phase Lock Loop Programming
The divider can only be set at 1 when the PLL is activated. The PLL input is SLCK.
When the divider field (DIV) is set to 0, the output of the corresponding divider and the PLL output is a continuous
signal at level 0. On reset, each DIV field is set to 0, thus the corresponding PLL input clock is set to 0.
The PLL allows multiplication of the divider’s outputs. The PLL clock signal has a frequency that depends on the
respective source signal frequency and on the MUL parameter. The factor applied to the source signal frequency is
(MUL + 1). When MUL is written to 0, the corresponding PLL is disabled and its power consumption is saved. Reenabling the PLL can be performed by writing a value higher than 0 in the MUL field.
Whenever the PLL is re-enabled or one of its parameters is changed, the LOCK bit in PMC_SR is automatically
cleared. The values written in the PLLCOUNT field in CKGR_PLLR are loaded in the PLL counter. The PLL counter then decrements at the speed of the Slow Clock until it reaches 0. At this time, the LOCK bit is set in PMC_SR
and can trigger an interrupt to the processor. The user has to load the number of Slow Clock cycles required to
cover the PLL transient time into the PLLCOUNT field. The transient time depends on the PLL filter. The initial
state of the PLL and its target frequency can be calculated using a specific tool provided by Atmel.
Two PLL startup schemes are available:
• The fast startup scheme allows the PLL to reach at least 70% of its target frequency in less than 60 µs. In this
mode the STDMODE field must be set to 0x0 and the PLLCOUNT field can be programed at 0x01 in the
CKGR_PLLR register.
• The normal startup procedure of the PLL is performed when the STDMODE field of the CKGR_PLLR register is
set to 0x02. In this startup scheme, the PLLCOUNT field must be set with the relevant value function of the
programed PLL frequency.
Note that the STMODE field of the CKGR_PLLR register must be set to 0x02 when the PLL is shutdown.
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25. Power Management Controller (PMC)
25.1
Overview
The Power Management Controller (PMC) optimizes power consumption by controlling all system and user peripheral clocks. The PMC enables/disables the clock inputs to many of the peripherals and the ARM Processor.
The Power Management Controller provides the following clocks:
• MCK, the Master Clock, programmable from a few hundred Hz to the maximum operating frequency of the
device. It is available to the modules running permanently, such as the AIC and the Memory Controller.
• Processor Clock (PCK), switched off when entering processor in idle mode.
• Peripheral Clocks, typically MCK, provided to the embedded peripherals (USART, SPI, TWI, TC, etc.) and
independently controllable. In order to reduce the number of clock names in a product, the Peripheral Clocks
are named MCK in the product datasheet.
• Programmable Clock Outputs can be selected from the clocks provided by the clock generator and driven on
the PCKx pins.
25.2
Master Clock Controller
The Master Clock Controller provides selection and division of the Master Clock (MCK). MCK is the clock provided
to all the peripherals and the memory controller.
The Master Clock is selected from one of the clocks provided by the Clock Generator. Selecting the Slow Clock
provides a Slow Clock signal to the whole device. Selecting the Main Clock saves power consumption of the PLL.
The Master Clock Controller is made up of a clock selector and a prescaler. It also contains a Master Clock divider
which allows the processor clock to be faster than the Master Clock.
The Master Clock selection is made by writing the CSS field (Clock Source Selection) in PMC_MCKR (Master
Clock Register). The prescaler supports the division by a power of 2 of the selected clock between 1 and 64. The
PRES field in PMC_MCKR programs the prescaler.
Each time PMC_MCKR is written to define a new Master Clock, the MCKRDY bit is cleared in PMC_SR. It reads 0
until the Master Clock is established. Then, the MCKRDY bit is set and can trigger an interrupt to the processor.
This feature is useful when switching from a high-speed clock to a lower one, to inform the software when the
change is actually done.
Figure 25-1. Master Clock Controller
PMC_MCKR
PMC_MCKR
CSS
PRES
SLCK
MAINCK
Master Clock
Prescaler
MCK
PLLCK
To the Processor
Clock Controller (PCK)
25.3
Processor Clock Controller
The PMC features a Processor Clock Controller (PCK) that implements the processor idle mode. The processor
clock can be disabled by writing to 1 the PCK bit in the Power Management Controller System Clock Disable Register (PMC_SCDR). The status of this clock (at least for debug purposes) can be read in the System Clock Status
Register (PMC_SCSR).
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The processor clock is enabled after a reset and is automatically re-enabled by any enabled interrupt. The Processor Idle Mode is achieved by disabling the Processor Clock, which is automatically re-enabled by any enabled fast
or normal interrupt, or by the reset of the product.
When the Processor Clock is disabled, the current instruction is finished before the clock is stopped, but this does
not prevent data transfers from other masters of the system bus.
25.4
Peripheral Clock Controller
The Power Management Controller controls the clocks of each embedded peripheral by means of the Peripheral
Clock Controller. The user can individually enable and disable the Master Clock on the peripherals by writing into
the Peripheral Clock Enable (PMC_PCER) and Peripheral Clock Disable (PMC_PCDR) registers. The status of the
peripheral clock activity can be read in the Peripheral Clock Status Register (PMC_PCSR).
When a peripheral clock is disabled, the clock is immediately stopped. The peripheral clocks are automatically disabled after a reset.
In order to stop a peripheral, it is recommended that the system software wait until the peripheral has executed its
last programmed operation before disabling the clock. This is to avoid data corruption or erroneous behavior of the
system.
The bit number within the Peripheral Clock Control registers (PMC_PCER, PMC_PCDR, and PMC_PCSR) is the
Peripheral Identifier defined at the product level. Generally, the bit number corresponds to the interrupt source
number assigned to the peripheral.
25.5
Programmable Clock Output Controller
The PMC controls 3 signals to be output on external pins, PCKx. Each signal can be independently programmed
via the PMC_PCKx registers.
PCKx can be independently selected between the Slow Clock, the PLL output and the Main Clock by writing the
CSS field in PMC_PCKx Register. Each output signal can also be divided by a power of 2 between 1 and 64 by
writing the PRES (Prescaler) field in PMC_PCKx.
Each output signal can be enabled and disabled by writing 1 in the corresponding bit, PCKx of PMC_SCER and
PMC_SCDR, respectively. Status of the active programmable output clocks are given in the PCKx bits of
PMC_SCSR (System Clock Status Register).
Moreover, like the PCK, a status bit in PMC_SR indicates that the Programmable Clock is actually what has been
programmed in the Programmable Clock registers.
As the Programmable Clock Controller does not manage with glitch prevention when switching clocks, it is strongly
recommended to disable the Programmable Clock before any configuration change and to re-enable it after the
change is actually performed.
25.6
The Fast Startup
The SAM7L device allows the processor to restart in less than six microseconds while the device is in Wait mode.
A Fast Startup is enabled upon the detection of a low level on one of the 16 wake-up inputs.
The Fast Restart circuitry, as shown in Figure 25-2, is fully asynchronous and provides a fast startup signal to the
Power Management Controller. As soon as the fast startup signal is asserted, this automatically restarts the
embedded 2 MHz Fast RC oscillator, switches the Master Clock on the 2 MHz clock and re-enables the processor
clock if it is disabled.
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Figure 25-2. Fast Startup Circuitry
FSTT0
WKUP0
FSTT1
fast_restart
WKUP1
FSTT15
WKUP15
Each wake-up input pin can be enabled to generate a Fast Startup event by writing at 1 the corresponding bit in the
Fast Startup Mode Register SUPC_FSMR. Only a low level on the enabled wake-up input pins generates a Fast
Startup.
The user interface does not provide any status for Fast Startup, but the user can easily recover this information by
reading the PIO Controller.
25.7
Programming Sequence
1. Checking the Main Oscillator Frequency (Optional):
In some situations the user may need an accurate measure of the main clock frequency. This measure can be
accomplished via the CKGR_MCFR register.
Once the MAINFRDY field is set in CKGR_MCFR register, the user may read the MAINF field in CKGR_MCFR
register. This provides the number of main clock cycles within sixteen slow clock cycles.
2. Setting PLL and divider:
All parameters needed to configure PLL and the divider are located in the CKGR_PLLR register.
The DIV field is used to control the divider itself. It must be set to 1 when PLL is used. By default, DIV parameter is set to 0 which means that the divider is turned off.
The MUL field is the PLL multiplier factor. This parameter can be programmed between 0 and 2047. If MUL is
set to 0, PLL will be turned off, otherwise the PLL output frequency is PLL input frequency multiplied by (MUL +
1).
The PLLCOUNT field specifies the number of slow clock cycles before LOCK bit is set in the PMC_SR register
after CKGR_PLLR register has been written.
Once the PMC_PLL register has been written, the user must wait for the LOCK bit to be set in the PMC_SR
register. This can be done either by polling the status register or by waiting the interrupt line to be raised if the
associated interrupt to LOCK has been enabled in the PMC_IER register. All parameters in CKGR_PLLR can
be programmed in a single write operation. If at some stage one of the following parameters, MUL, DIV is modified, LOCK bit will go low to indicate that PLL is not ready yet. When PLL is locked, LOCK will be set again.
The user is constrained to wait for LOCK bit to be set before using the PLL output clock.
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Code Example:
write_register(CKGR_PLLR,0x3209A01)
If PLL and divider are enabled, the PLL input clock is the main clock. PLL output clock is PLL input clock multiplied by 801. Once CKGR_PLLR has been written, LOCK bit will be set after eight slow clock cycles.
3. Selection of Master Clock and Processor Clock
The Master Clock and the Processor Clock are configurable via the PMC_MCKR register.
The CSS field is used to select the Master Clock divider source. By default, the selected clock source is main
clock.
The PRES field is used to control the Master Clock prescaler. The user can choose between different values
(1, 2, 4, 8, 16, 32, 64). Master Clock output is prescaler input divided by PRES parameter. By default, PRES
parameter is set to 1 which means that master clock is equal to main clock.
Once the PMC_MCKR register has been written, the user must wait for the MCKRDY bit to be set in the
PMC_SR register. This can be done either by polling the status register or by waiting for the interrupt line to be
raised if the associated interrupt to MCKRDY has been enabled in the PMC_IER register.
The PMC_MCKR register must not be programmed in a single write operation. The preferred programming
sequence for the PMC_MCKR register is as follows:
• If a new value for CSS field corresponds to PLL Clock,
– Program the PRES field in the PMC_MCKR register.
– Wait for the MCKRDY bit to be set in the PMC_SR register.
– Program the CSS field in the PMC_MCKR register.
– Wait for the MCKRDY bit to be set in the PMC_SR register.
• If a new value for CSS field corresponds to Main Clock or Slow Clock,
– Program the CSS field in the PMC_MCKR register.
– Wait for the MCKRDY bit to be set in the PMC_SR register.
– Program the PRES field in the PMC_MCKR register.
– Wait for the MCKRDY bit to be set in the PMC_SR register.
If at some stage one of the following parameters, CSS or PRES, is modified, the MCKRDY bit will go low to
indicate that the Master Clock and the Processor Clock are not ready yet. The user must wait for MCKRDY bit
to be set again before using the Master and Processor Clocks.
Note:
IF PLLx clock was selected as the Master Clock and the user decides to modify it by writing in CKGR_PLLR, the
MCKRDY flag will go low while PLL is unlocked. Once PLL is locked again, LOCK goes high and MCKRDY is set.
While PLL is unlocked, the Master Clock selection is automatically changed to Slow Clock. For further information, see
Section 25.8.2 “Clock Switching Waveforms” on page 217.
Code Example:
write_register(PMC_MCKR,0x00000001)
wait (MCKRDY=1)
write_register(PMC_MCKR,0x00000011)
wait (MCKRDY=1)
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The Master Clock is main clock divided by 16.
The Processor Clock is the Master Clock.
4. Selection of Programmable clocks
Programmable clocks are controlled via registers; PMC_SCER, PMC_SCDR and PMC_SCSR.
Programmable clocks can be enabled and/or disabled via the PMC_SCER and PMC_SCDR registers. 3 Programmable clocks can be enabled or disabled. The PMC_SCSR provides a clear indication as to which
Programmable clock is enabled. By default all Programmable clocks are disabled.
PMC_PCKx registers are used to configure Programmable clocks.
The CSS field is used to select the Programmable clock divider source. Three clock options are available: main
clock, slow clock, PLLCK. By default, the clock source selected is slow clock.
The PRES field is used to control the Programmable clock prescaler. It is possible to choose between different
values (1, 2, 4, 8, 16, 32, 64). Programmable clock output is prescaler input divided by PRES parameter. By
default, the PRES parameter is set to 0 which means that master clock is equal to slow clock.
Once the PMC_PCKx register has been programmed, The corresponding Programmable clock must be
enabled and the user is constrained to wait for the PCKRDYx bit to be set in the PMC_SR register. This can be
done either by polling the status register or by waiting the interrupt line to be raised if the associated interrupt to
PCKRDYx has been enabled in the PMC_IER register. All parameters in PMC_PCKx can be programmed in a
single write operation.
If the CSS and PRES parameters are to be modified, the corresponding Programmable clock must be disabled
first. The parameters can then be modified. Once this has been done, the user must re-enable the Programmable clock and wait for the PCKRDYx bit to be set.
Code Example:
write_register(PMC_PCK0,0x00000015)
Programmable clock 0 is main clock divided by 32.
5. Enabling Peripheral Clocks
Once all of the previous steps have been completed, the peripheral clocks can be enabled and/or disabled via
registers PMC_PCER and PMC_PCDR.
15 peripheral clocks can be enabled or disabled. The PMC_PCSR provides a clear view as to which peripheral
clock is enabled.
Note:
Each enabled peripheral clock corresponds to Master Clock.
Code Examples:
write_register(PMC_PCER,0x00000110)
Peripheral clocks 4 and 8 are enabled.
write_register(PMC_PCDR,0x00000010)
Peripheral clock 4 is disabled.
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25.8
Clock Switching Details
25.8.1
Master Clock Switching Timings
Table 25-1 gives the worst case timings required for the Master Clock to switch from one selected clock to another
one. This is in the event that the prescaler is de-activated. When the prescaler is activated, an additional time of 64
clock cycles of the new selected clock has to be added.
Table 25-1.
Clock Switching Timings (Worst Case)
From
Main Clock
SLCK
PLL Clock
–
4 x SLCK +
2.5 x Main Clock
3 x PLL Clock +
4 x SLCK +
1 x Main Clock
0.5 x Main Clock +
4.5 x SLCK
–
3 x PLL Clock +
5 x SLCK
0.5 x Main Clock +
4 x SLCK +
PLLCOUNT x SLCK +
2.5 x PLLx Clock
2.5 x PLL Clock +
5 x SLCK +
PLLCOUNT x SLCK
2.5 x PLL Clock +
4 x SLCK +
PLLCOUNT x SLCK
To
Main Clock
SLCK
PLL Clock
25.8.2
Clock Switching Waveforms
Figure 25-3. Switch Master Clock from Slow Clock to PLL Clock
Slow Clock
PLL Clock
LOCK
MCKRDY
Master Clock
Write PMC_MCKR
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Figure 25-4. Switch Master Clock from Main Clock to Slow Clock
Slow Clock
Main Clock
MCKRDY
Master Clock
Write PMC_MCKR
Figure 25-5. Change PLL Programming
Slow Clock
PLLA Clock
LOCK
MCKRDY
Master Clock
Slow Clock
Write CKGR_PLLAR
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Figure 25-6. Programmable Clock Output Programming
PLL Clock
PCKRDY
PCKx Output
Write PMC_PCKx
Write PMC_SCER
Write PMC_SCDR
PLL Clock is selected
PCKx is enabled
PCKx is disabled
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25.9
Power Management Controller (PMC) User Interface
Table 25-2.
Register Mapping
Offset
Register
Name
Access
Reset
0x0000
System Clock Enable Register
PMC_SCER
Write-only
–
0x0004
System Clock Disable Register
PMC_SCDR
Write-only
–
0x0008
System Clock Status Register
PMC _SCSR
Read-only
0x0000_0001
0x000C
Reserved
–
–
0x0010
Peripheral Clock Enable Register
PMC _PCER
Write-only
N.A.
0x0014
Peripheral Clock Disable Register
PMC_PCDR
Write-only
–
0x0018
Peripheral Clock Status Register
PMC_PCSR
Read-only
0x0000_0000
0x001C
Reserved
–
–
0x0020
Main Oscillator Register
CKGR_MOR
Read-write
0x0000_0001
0x0024
Main Clock Frequency Register
CKGR_MCFR
Read-only
0x0000_0000
0x0028
PLL Register
CKGR_PLLR
Read-write
0x0000_3F00
0x0030
Master Clock Register
PMC_MCKR
Read-write
0x0000_0001
0x0038
Reserved
–
–
–
0x003C
Reserved
–
–
–
0x0040
Programmable Clock 0 Register
PMC_PCK0
Read-write
0x0000_0000
0x0044
Programmable Clock 1 Register
PMC_PCK1
Read-write
0x0000_0000
...
...
...
...
0x0060
Interrupt Enable Register
PMC_IER
Write-only
–
0x0064
Interrupt Disable Register
PMC_IDR
Write-only
–
0x0068
Status Register
PMC_SR
Read-only
0x0001_0008
0x006C
Interrupt Mask Register
PMC_IMR
Read-only
0x0000_0000
0x0070
Fast Startup Mode Register
PMC_FSMR
Read-write
0x0000_0000
...
–
–
0x0074 - 0x007C
Reserved
–
Read-only
–
0x0080- 0x00FC
Reserved
–
–
–
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25.9.1
PMC System Clock Enable Register
Register Name:
PMC_SCER
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
PCK2
PCK1
PCK0
1
0
7
6
5
4
3
2
–
–
–
–
–
–
-
• PCKx: Programmable Clock x Output Enable
0 = No effect.
1 = Enables the corresponding Programmable Clock output.
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25.9.2
PMC System Clock Disable Register
Register Name:
PMC_SCDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
PCK2
PCK1
PCK0
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
PCK
• PCK: Processor Clock Disable
0 = No effect.
1 = Disables the Processor clock. This is used to enter the processor in Idle Mode.
• PCKx: Programmable Clock x Output Disable
0 = No effect.
1 = Disables the corresponding Programmable Clock output.
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25.9.3
PMC System Clock Status Register
Register Name:
PMC_SCSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
PCK2
PCK1
PCK0
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
PCK
• PCK: Processor Clock Status
0 = The Processor clock is disabled.
1 = The Processor clock is enabled.
• PCKx: Programmable Clock x Output Status
0 = The corresponding Programmable Clock output is disabled.
1 = The corresponding Programmable Clock output is enabled.
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25.9.4
PMC Peripheral Clock Enable Register
Register Name:
PMC_PCER
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
-
-
• PIDx: Peripheral Clock x Enable
0 = No effect.
1 = Enables the corresponding peripheral clock.
Note:
PID2 to PID31 refer to identifiers as defined in the section “Peripheral Identifiers” in the product datasheet.
Note:
Programming the control bits of the Peripheral ID that are not implemented has no effect on the behavior of the PMC.
25.9.5
PMC Peripheral Clock Disable Register
Register Name:
PMC_PCDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
-
-
• PIDx: Peripheral Clock x Disable
0 = No effect.
1 = Disables the corresponding peripheral clock.
Note:
PID2 to PID31 refer to identifiers as defined in the section “Peripheral Identifiers” in the product datasheet.
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25.9.6
PMC Peripheral Clock Status Register
Register Name:
PMC_PCSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
PID31
PID30
PID29
PID28
PID27
PID26
PID25
PID24
23
22
21
20
19
18
17
16
PID23
PID22
PID21
PID20
PID19
PID18
PID17
PID16
15
14
13
12
11
10
9
8
PID15
PID14
PID13
PID12
PID11
PID10
PID9
PID8
7
6
5
4
3
2
1
0
PID7
PID6
PID5
PID4
PID3
PID2
–
–
• PIDx: Peripheral Clock x Status
0 = The corresponding peripheral clock is disabled.
1 = The corresponding peripheral clock is enabled.
Note:
PID2 to PID31 refer to identifiers as defined in the section “Peripheral Identifiers” in the product datasheet.
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25.9.7
PMC Clock Generator Main Oscillator Register
Register Name:
CKGR_MOR
Access Type:
Read-write
31
–
30
–
29
–
28
–
23
22
21
20
27
–
26
–
25
–
24
MCKSEL
19
18
17
16
KEY
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
–
6
–
5
–
4
–
3
–
2
–
1
–
0
MAINCKON
• KEY: Password
Should be written at value 0x37. Writing any other value in this field aborts the write operation.
• MAINCKON: 2 MHz RC Oscillator Enable
At start-up, the 2 MHz Fast RC Oscillator is enabled.
0 = The 2 MHz Fast RC Oscillator is disabled
1 = The 2 MHz Fast RC Oscillator is enabled.
• MCKSEL: Main Clock Selection
0 = The 2 MHz Fast RC Oscillator is selected
1 = The CLKIN input is selected.
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25.9.8
PMC Clock Generator Main Clock Frequency Register
Register Name:
CKGR_MCFR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
MAINFRDY
15
14
13
12
11
10
9
8
3
2
1
0
MAINF
7
6
5
4
MAINF
• MAINF: Main Clock Frequency
Gives the number of Main Clock cycles within 16 Slow Clock periods.
• MAINFRDY: Main Clock Ready
0 = MAINF value is not valid or the Main Oscillator is disabled.
1 = The Main Oscillator has been enabled previously and MAINF value is available.
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25.9.9
PMC Clock Generator PLL Register
Register Name:
CKGR_PLLR
Access Type:
Read-write
31
–
30
–
29
0
28
–
23
22
21
20
27
–
26
25
MUL
24
19
18
17
16
10
9
8
2
1
0
MUL
15
14
13
12
11
STMODE
7
PLLCOUNT
6
5
4
3
DIV
Possible limitations on PLL input frequencies and multiplier factors should be checked before using the PMC.
Warning: Bit 29 must always be set to 0 when programming the CKGR_PLLR register.
• DIV: Divider
DIV
Divider Selected
0
Divider output is 0
1
Divider is bypassed (DIV=1)
2 - 255
Reserved
• PLLCOUNT: PLL Counter
Specifies the number of Slow Clock cycles x8 before the LOCK bit is set in PMC_SR after CKGR_PLLR is written.
• STMODE: Start Mode
STMODE
Start Mode
0
Fast Startup
1
Reserved
2
Normal Startup
3
Reserved
STMODE must be set at 2 when the PLL is Off
• MUL: PLL Multiplier
0 = The PLL is deactivated.
1 up to 2047 = The PLL Clock frequency is the PLL input frequency multiplied by MUL + 1.
• 0: 0
0 = Bit 29 must always be programmed to 0 when programming this register.
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25.9.10 PMC Master Clock Register
Register Name:
PMC_MCKR
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
4
3
2
1
7
6
5
–
–
–
PRES
0
CSS
• CSS: Master Clock Selection
CSS
Clock Source Selection
0
0
Slow Clock is selected
0
1
Main Clock is selected
1
0
PLL Clock is selected
1
1
Reserved
• PRES: Processor Clock Prescaler
PRES
Processor Clock
0
0
0
Selected clock
0
0
1
Selected clock divided by 2
0
1
0
Selected clock divided by 4
0
1
1
Selected clock divided by 8
1
0
0
Selected clock divided by 16
1
0
1
Selected clock divided by 32
1
1
0
Selected clock divided by 64
1
1
1
Reserved
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25.9.11 PMC Programmable Clock Register
Register Name:
PMC_PCKx
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
4
3
2
1
7
6
5
–
–
–
PRES
0
CSS
• CSS: Master Clock Selection
CSS
Clock Source Selection
0
0
Slow Clock is selected
0
1
Main Clock is selected
1
0
PLL Clock is selected
1
1
Reserved
• PRES: Programmable Clock Prescaler
PRES
Programmable Clock
0
0
0
Selected clock
0
0
1
Selected clock divided by 2
0
1
0
Selected clock divided by 4
0
1
1
Selected clock divided by 8
1
0
0
Selected clock divided by 16
1
0
1
Selected clock divided by 32
1
1
0
Selected clock divided by 64
1
1
1
Reserved
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25.9.12 PMC Interrupt Enable Register
Register Name:
PMC_IER
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
PCKRDY2
PCKRDY1
PCKRDY0
7
6
5
4
3
2
1
0
–
–
–
–
MCKRDY
–
LOCK
MAINRDY
• MAINRDY: Main Clock Ready Interrupt Enable
• LOCK: PLL Lock Interrupt Enable
• MCKRDY: Master Clock Ready Interrupt Enable
• PCKRDYx: Programmable Clock Ready x Interrupt Enable
0 = No effect.
1 = Enables the corresponding interrupt.
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25.9.13 PMC Interrupt Disable Register
Register Name:
PMC_IDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
PCKRDY2
PCKRDY1
PCKRDY0
7
6
5
4
3
2
1
0
–
–
–
–
MCKRDY
–
LOCK
MAINRDY
• MAINRDY: Main Clock Ready Interrupt Disable
• LOCK: PLL Lock Interrupt Disable
• MCKRDY: Master Clock Ready Interrupt Disable
• PCKRDYx: Programmable Clock Ready x Interrupt Disable
0 = No effect.
1 = Disables the corresponding interrupt.
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25.9.14 PMC Status Register
Register Name:
PMC_SR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
MAINSELS
15
14
13
12
11
10
9
8
–
–
–
–
–
PCKRDY2
PCKRDY1
PCKRDY0
7
6
5
4
3
2
1
0
–
–
–
–
MCKRDY
–
LOCK
MAINRDY
• MAINRDY: MAINRDY Flag Status
0 = Main Clock is not ready
1 = Main Clock is ready
• LOCK: PLL Lock Status
0 = PLL is not locked
1 = PLL is locked.
• MCKRDY: Master Clock Status
0 = Master Clock is not ready.
1 = Master Clock is ready.
• PCKRDYx: Programmable Clock Ready Status
0 = Programmable Clock x is not ready.
1 = Programmable Clock x is ready.
• MAINSELS: MAINSELS Main Clock Selection Status
0 = Selection is in progress (default state)
1 = Selection is done
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25.9.15 PMC Interrupt Mask Register
Register Name:
PMC_IMR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
PCKRDY2
PCKRDY1
PCKRDY0
7
6
5
4
3
2
1
0
–
–
–
–
MCKRDY
–
LOCK
MAINRDY
• MAINRDY: Main Clock Ready Interrupt Mask
• LOCK: PLL Lock Interrupt Mask
• MCKRDY: Master Clock Ready Interrupt Mask
• PCKRDYx: Programmable Clock Ready x Interrupt Mask
0 = The corresponding interrupt is enabled.
1 = The corresponding interrupt is disabled.
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25.9.16 PMC Fast Startup Mode Register
Register Name:
PMC_FSMR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
FSTT15
14
FSTT14
13
FSTT13
12
FSTT12
11
FSTT11
10
FSTT10
9
FSTT9
8
FSTT8
7
FSTT7
6
FSTT6
5
FSTT5
4
FSTT4
3
FSTT3
2
FSTT2
1
FSTT1
0
FSTT0
• FSTT0 - FSTT15: Fast Start Input Enable 0 to 15
0 = The corresponding wake up input has no effect on the Power Management Controller.
1 = The corresponding wake up input enables a fast restart signal to the Power Management Controller.
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26. Debug Unit (DBGU)
26.1
Overview
The Debug Unit provides a single entry point from the processor for access to all the debug capabilities of Atmel’s
ARM-based systems.
The Debug Unit features a two-pin UART that can be used for several debug and trace purposes and offers an
ideal medium for in-situ programming solutions and debug monitor communications. Moreover, the association
with two peripheral data controller channels permits packet handling for these tasks with processor time reduced to
a minimum.
The Debug Unit also makes the Debug Communication Channel (DCC) signals provided by the In-circuit Emulator
of the ARM processor visible to the software. These signals indicate the status of the DCC read and write registers
and generate an interrupt to the ARM processor, making possible the handling of the DCC under interrupt control.
Chip Identifier registers permit recognition of the device and its revision. These registers inform as to the sizes and
types of the on-chip memories, as well as the set of embedded peripherals.
Finally, the Debug Unit features a Force NTRST capability that enables the software to decide whether to prevent
access to the system via the In-circuit Emulator. This permits protection of the code, stored in ROM.
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26.2
Block Diagram
Figure 26-1. Debug Unit Functional Block Diagram
Peripheral
Bridge
Peripheral DMA Controller
APB
Debug Unit
DTXD
Transmit
Power
Management
Controller
MCK
Parallel
Input/
Output
Baud Rate
Generator
Receive
DRXD
COMMRX
ARM
Processor
COMMTX
DCC
Handler
Chip ID
nTRST
ICE
Access
Handler
Interrupt
Control
dbgu_irq
Power-on
Reset
force_ntrst
Table 26-1.
Debug Unit Pin Description
Pin Name
Description
Type
DRXD
Debug Receive Data
Input
DTXD
Debug Transmit Data
Output
Figure 26-2. Debug Unit Application Example
Boot Program
Debug Monitor
Trace Manager
Debug Unit
RS232 Drivers
Programming Tool
Debug Console
Trace Console
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26.3
Product Dependencies
26.3.1
I/O Lines
Depending on product integration, the Debug Unit pins may be multiplexed with PIO lines. In this case, the programmer must first configure the corresponding PIO Controller to enable I/O lines operations of the Debug Unit.
26.3.2
Power Management
Depending on product integration, the Debug Unit clock may be controllable through the Power Management Controller. In this case, the programmer must first configure the PMC to enable the Debug Unit clock. Usually, the
peripheral identifier used for this purpose is 1.
26.3.3
Interrupt Source
Depending on product integration, the Debug Unit interrupt line is connected to one of the interrupt sources of the
Advanced Interrupt Controller. Interrupt handling requires programming of the AIC before configuring the Debug
Unit. Usually, the Debug Unit interrupt line connects to the interrupt source 1 of the AIC, which may be shared with
the real-time clock, the system timer interrupt lines and other system peripheral interrupts, as shown in Figure 261. This sharing requires the programmer to determine the source of the interrupt when the source 1 is triggered.
26.4
UART Operations
The Debug Unit operates as a UART, (asynchronous mode only) and supports only 8-bit character handling (with
parity). It has no clock pin.
The Debug Unit's UART is made up of a receiver and a transmitter that operate independently, and a common
baud rate generator. Receiver timeout and transmitter time guard are not implemented. However, all the implemented features are compatible with those of a standard USART.
26.4.1
Baud Rate Generator
The baud rate generator provides the bit period clock named baud rate clock to both the receiver and the
transmitter.
The baud rate clock is the master clock divided by 16 times the value (CD) written in DBGU_BRGR (Baud Rate
Generator Register). If DBGU_BRGR is set to 0, the baud rate clock is disabled and the Debug Unit's UART
remains inactive. The maximum allowable baud rate is Master Clock divided by 16. The minimum allowable baud
rate is Master Clock divided by (16 x 65536).
MCK
Baud Rate = ---------------------16 × CD
Figure 26-3. Baud Rate Generator
CD
CD
MCK
16-bit Counter
OUT
>1
1
0
Divide
by 16
Baud Rate
Clock
0
Receiver
Sampling Clock
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26.4.2
Receiver
26.4.2.1
Receiver Reset, Enable and Disable
After device reset, the Debug Unit receiver is disabled and must be enabled before being used. The receiver can
be enabled by writing the control register DBGU_CR with the bit RXEN at 1. At this command, the receiver starts
looking for a start bit.
The programmer can disable the receiver by writing DBGU_CR with the bit RXDIS at 1. If the receiver is waiting for
a start bit, it is immediately stopped. However, if the receiver has already detected a start bit and is receiving the
data, it waits for the stop bit before actually stopping its operation.
The programmer can also put the receiver in its reset state by writing DBGU_CR with the bit RSTRX at 1. In doing
so, the receiver immediately stops its current operations and is disabled, whatever its current state. If RSTRX is
applied when data is being processed, this data is lost.
26.4.2.2
Start Detection and Data Sampling
The Debug Unit only supports asynchronous operations, and this affects only its receiver. The Debug Unit receiver
detects the start of a received character by sampling the DRXD signal until it detects a valid start bit. A low level
(space) on DRXD is interpreted as a valid start bit if it is detected for more than 7 cycles of the sampling clock,
which is 16 times the baud rate. Hence, a space that is longer than 7/16 of the bit period is detected as a valid start
bit. A space which is 7/16 of a bit period or shorter is ignored and the receiver continues to wait for a valid start bit.
When a valid start bit has been detected, the receiver samples the DRXD at the theoretical midpoint of each bit. It
is assumed that each bit lasts 16 cycles of the sampling clock (1-bit period) so the bit sampling point is eight cycles
(0.5-bit period) after the start of the bit. The first sampling point is therefore 24 cycles (1.5-bit periods) after the falling edge of the start bit was detected.
Each subsequent bit is sampled 16 cycles (1-bit period) after the previous one.
Figure 26-4. Start Bit Detection
Sampling Clock
DRXD
True Start
Detection
D0
Baud Rate
Clock
Figure 26-5. Character Reception
Example: 8-bit, parity enabled 1 stop
0.5 bit
period
1 bit
period
DRXD
Sampling
D0
D1
True Start Detection
D2
D3
D4
D5
D6
Stop Bit
D7
Parity Bit
26.4.2.3
Receiver Ready
When a complete character is received, it is transferred to the DBGU_RHR and the RXRDY status bit in
DBGU_SR (Status Register) is set. The bit RXRDY is automatically cleared when the receive holding register
DBGU_RHR is read.
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Figure 26-6. Receiver Ready
DRXD
S
D0
D1
D2
D3
D4
D5
D6
D7
S
P
D0
D1
D2
D3
D4
D5
D6
D7
P
RXRDY
Read DBGU_RHR
26.4.2.4
Receiver Overrun
If DBGU_RHR has not been read by the software (or the Peripheral Data Controller) since the last transfer, the
RXRDY bit is still set and a new character is received, the OVRE status bit in DBGU_SR is set. OVRE is cleared
when the software writes the control register DBGU_CR with the bit RSTSTA (Reset Status) at 1.
Figure 26-7. Receiver Overrun
DRXD
S
D0
D1
D2
D3
D4
D5
D6
D7
P
S
stop
D0
D1
D2
D3
D4
D5
D6
D7
P
stop
RXRDY
OVRE
RSTSTA
26.4.2.5
Parity Error
Each time a character is received, the receiver calculates the parity of the received data bits, in accordance with
the field PAR in DBGU_MR. It then compares the result with the received parity bit. If different, the parity error bit
PARE in DBGU_SR is set at the same time the RXRDY is set. The parity bit is cleared when the control register
DBGU_CR is written with the bit RSTSTA (Reset Status) at 1. If a new character is received before the reset status
command is written, the PARE bit remains at 1.
Figure 26-8. Parity Error
DRXD
S
D0
D1
D2
D3
D4
D5
D6
D7
P
stop
RXRDY
PARE
Wrong Parity Bit
RSTSTA
26.4.2.6
Receiver Framing Error
When a start bit is detected, it generates a character reception when all the data bits have been sampled. The stop
bit is also sampled and when it is detected at 0, the FRAME (Framing Error) bit in DBGU_SR is set at the same
time the RXRDY bit is set. The bit FRAME remains high until the control register DBGU_CR is written with the bit
RSTSTA at 1.
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Figure 26-9. Receiver Framing Error
DRXD
S
D0
D1
D2
D3
D4
D5
D6
D7
P
stop
RXRDY
FRAME
Stop Bit
Detected at 0
26.4.3
RSTSTA
Transmitter
26.4.3.1
Transmitter Reset, Enable and Disable
After device reset, the Debug Unit transmitter is disabled and it must be enabled before being used. The transmitter is enabled by writing the control register DBGU_CR with the bit TXEN at 1. From this command, the transmitter
waits for a character to be written in the Transmit Holding Register DBGU_THR before actually starting the
transmission.
The programmer can disable the transmitter by writing DBGU_CR with the bit TXDIS at 1. If the transmitter is not
operating, it is immediately stopped. However, if a character is being processed into the Shift Register and/or a
character has been written in the Transmit Holding Register, the characters are completed before the transmitter is
actually stopped.
The programmer can also put the transmitter in its reset state by writing the DBGU_CR with the bit RSTTX at 1.
This immediately stops the transmitter, whether or not it is processing characters.
26.4.3.2
Transmit Format
The Debug Unit transmitter drives the pin DTXD at the baud rate clock speed. The line is driven depending on the
format defined in the Mode Register and the data stored in the Shift Register. One start bit at level 0, then the 8
data bits, from the lowest to the highest bit, one optional parity bit and one stop bit at 1 are consecutively shifted out
as shown on the following figure. The field PARE in the mode register DBGU_MR defines whether or not a parity
bit is shifted out. When a parity bit is enabled, it can be selected between an odd parity, an even parity, or a fixed
space or mark bit.
Figure 26-10. Character Transmission
Example: Parity enabled
Baud Rate
Clock
DTXD
Start
Bit
D0
D1
D2
D3
D4
D5
D6
D7
Parity
Bit
Stop
Bit
26.4.3.3
Transmitter Control
When the transmitter is enabled, the bit TXRDY (Transmitter Ready) is set in the status register DBGU_SR. The
transmission starts when the programmer writes in the Transmit Holding Register DBGU_THR, and after the written character is transferred from DBGU_THR to the Shift Register. The bit TXRDY remains high until a second
character is written in DBGU_THR. As soon as the first character is completed, the last character written in
DBGU_THR is transferred into the shift register and TXRDY rises again, showing that the holding register is empty.
When both the Shift Register and the DBGU_THR are empty, i.e., all the characters written in DBGU_THR have
been processed, the bit TXEMPTY rises after the last stop bit has been completed.
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Figure 26-11. Transmitter Control
DBGU_THR
Data 0
Data 1
Shift Register
DTXD
Data 0
S
Data 0
Data 1
P
stop
S
Data 1
P
stop
TXRDY
TXEMPTY
Write Data 0
in DBGU_THR
26.4.4
Write Data 1
in DBGU_THR
Peripheral Data Controller
Both the receiver and the transmitter of the Debug Unit's UART are generally connected to a Peripheral Data Controller (PDC) channel.
The peripheral data controller channels are programmed via registers that are mapped within the Debug Unit user
interface from the offset 0x100. The status bits are reported in the Debug Unit status register DBGU_SR and can
generate an interrupt.
The RXRDY bit triggers the PDC channel data transfer of the receiver. This results in a read of the data in
DBGU_RHR. The TXRDY bit triggers the PDC channel data transfer of the transmitter. This results in a write of a
data in DBGU_THR.
26.4.5
Test Modes
The Debug Unit supports three tests modes. These modes of operation are programmed by using the field
CHMODE (Channel Mode) in the mode register DBGU_MR.
The Automatic Echo mode allows bit-by-bit retransmission. When a bit is received on the DRXD line, it is sent to
the DTXD line. The transmitter operates normally, but has no effect on the DTXD line.
The Local Loopback mode allows the transmitted characters to be received. DTXD and DRXD pins are not used
and the output of the transmitter is internally connected to the input of the receiver. The DRXD pin level has no
effect and the DTXD line is held high, as in idle state.
The Remote Loopback mode directly connects the DRXD pin to the DTXD line. The transmitter and the receiver
are disabled and have no effect. This mode allows a bit-by-bit retransmission.
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Figure 26-12. Test Modes
Automatic Echo
RXD
Receiver
Transmitter
Disabled
TXD
Local Loopback
Disabled
Receiver
RXD
VDD
Disabled
Transmitter
Remote Loopback
Receiver
Transmitter
26.4.6
TXD
VDD
Disabled
Disabled
RXD
TXD
Debug Communication Channel Support
The Debug Unit handles the signals COMMRX and COMMTX that come from the Debug Communication Channel
of the ARM Processor and are driven by the In-circuit Emulator.
The Debug Communication Channel contains two registers that are accessible through the ICE Breaker on the
JTAG side and through the coprocessor 0 on the ARM Processor side.
As a reminder, the following instructions are used to read and write the Debug Communication Channel:
MRC
p14, 0, Rd, c1, c0, 0
Returns the debug communication data read register into Rd
MCR
p14, 0, Rd, c1, c0, 0
Writes the value in Rd to the debug communication data write register.
The bits COMMRX and COMMTX, which indicate, respectively, that the read register has been written by the
debugger but not yet read by the processor, and that the write register has been written by the processor and not
yet read by the debugger, are wired on the two highest bits of the status register DBGU_SR. These bits can generate an interrupt. This feature permits handling under interrupt a debug link between a debug monitor running on the
target system and a debugger.
26.4.7
Chip Identifier
The Debug Unit features two chip identifier registers, DBGU_CIDR (Chip ID Register) and DBGU_EXID (Extension
ID). Both registers contain a hard-wired value that is read-only. The first register contains the following fields:
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• EXT - shows the use of the extension identifier register
• NVPTYP and NVPSIZ - identifies the type of embedded non-volatile memory and its size
• ARCH - identifies the set of embedded peripherals
• SRAMSIZ - indicates the size of the embedded SRAM
• EPROC - indicates the embedded ARM processor
• VERSION - gives the revision of the silicon
The second register is device-dependent and reads 0 if the bit EXT is 0.
26.4.8
ICE Access Prevention
The Debug Unit allows blockage of access to the system through the ARM processor's ICE interface. This feature
is implemented via the register Force NTRST (DBGU_FNR), that allows assertion of the NTRST signal of the ICE
Interface. Writing the bit FNTRST (Force NTRST) to 1 in this register prevents any activity on the TAP controller.
On standard devices, the bit FNTRST resets to 0 and thus does not prevent ICE access.
This feature is especially useful on custom ROM devices for customers who do not want their on-chip code to be
visible.
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26.5
Debug Unit (DBGU) User Interface
Table 26-2.
Register Mapping
Offset
Register
Name
Access
Reset
0x0000
Control Register
DBGU_CR
Write-only
–
0x0004
Mode Register
DBGU_MR
Read-write
0x0
0x0008
Interrupt Enable Register
DBGU_IER
Write-only
–
0x000C
Interrupt Disable Register
DBGU_IDR
Write-only
–
0x0010
Interrupt Mask Register
DBGU_IMR
Read-only
0x0
0x0014
Status Register
DBGU_SR
Read-only
–
0x0018
Receive Holding Register
DBGU_RHR
Read-only
0x0
0x001C
Transmit Holding Register
DBGU_THR
Write-only
–
0x0020
Baud Rate Generator Register
DBGU_BRGR
Read-write
0x0
–
–
–
0x0024 - 0x003C
Reserved
0x0040
Chip ID Register
DBGU_CIDR
Read-only
–
0x0044
Chip ID Extension Register
DBGU_EXID
Read-only
–
0x0048
Force NTRST Register
DBGU_FNR
Read-write
0x0
–
–
–
0x0100 - 0x0124
PDC Area
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26.5.1
Name:
Debug Unit Control Register
DBGU_CR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
RSTSTA
7
6
5
4
3
2
1
0
TXDIS
TXEN
RXDIS
RXEN
RSTTX
RSTRX
–
–
• RSTRX: Reset Receiver
0 = No effect.
1 = The receiver logic is reset and disabled. If a character is being received, the reception is aborted.
• RSTTX: Reset Transmitter
0 = No effect.
1 = The transmitter logic is reset and disabled. If a character is being transmitted, the transmission is aborted.
• RXEN: Receiver Enable
0 = No effect.
1 = The receiver is enabled if RXDIS is 0.
• RXDIS: Receiver Disable
0 = No effect.
1 = The receiver is disabled. If a character is being processed and RSTRX is not set, the character is completed before the
receiver is stopped.
• TXEN: Transmitter Enable
0 = No effect.
1 = The transmitter is enabled if TXDIS is 0.
• TXDIS: Transmitter Disable
0 = No effect.
1 = The transmitter is disabled. If a character is being processed and a character has been written the DBGU_THR and
RSTTX is not set, both characters are completed before the transmitter is stopped.
• RSTSTA: Reset Status Bits
0 = No effect.
1 = Resets the status bits PARE, FRAME and OVRE in the DBGU_SR.
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26.5.2
Name:
Debug Unit Mode Register
DBGU_MR
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
14
13
12
11
10
9
–
–
15
CHMODE
8
–
PAR
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
–
• PAR: Parity Type
PAR
Parity Type
0
0
0
Even parity
0
0
1
Odd parity
0
1
0
Space: parity forced to 0
0
1
1
Mark: parity forced to 1
1
x
x
No parity
• CHMODE: Channel Mode
CHMODE
Mode Description
0
0
Normal Mode
0
1
Automatic Echo
1
0
Local Loopback
1
1
Remote Loopback
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26.5.3
Name:
Debug Unit Interrupt Enable Register
DBGU_IER
Access Type:
Write-only
31
30
29
28
27
26
25
24
COMMRX
COMMTX
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
RXBUFF
TXBUFE
–
TXEMPTY
–
7
6
5
4
3
2
1
0
PARE
FRAME
OVRE
ENDTX
ENDRX
–
TXRDY
RXRDY
• RXRDY: Enable RXRDY Interrupt
• TXRDY: Enable TXRDY Interrupt
• ENDRX: Enable End of Receive Transfer Interrupt
• ENDTX: Enable End of Transmit Interrupt
• OVRE: Enable Overrun Error Interrupt
• FRAME: Enable Framing Error Interrupt
• PARE: Enable Parity Error Interrupt
• TXEMPTY: Enable TXEMPTY Interrupt
• TXBUFE: Enable Buffer Empty Interrupt
• RXBUFF: Enable Buffer Full Interrupt
• COMMTX: Enable COMMTX (from ARM) Interrupt
• COMMRX: Enable COMMRX (from ARM) Interrupt
0 = No effect.
1 = Enables the corresponding interrupt.
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26.5.4
Name:
Debug Unit Interrupt Disable Register
DBGU_IDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
COMMRX
COMMTX
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
RXBUFF
TXBUFE
–
TXEMPTY
–
7
6
5
4
3
2
1
0
PARE
FRAME
OVRE
ENDTX
ENDRX
–
TXRDY
RXRDY
• RXRDY: Disable RXRDY Interrupt
• TXRDY: Disable TXRDY Interrupt
• ENDRX: Disable End of Receive Transfer Interrupt
• ENDTX: Disable End of Transmit Interrupt
• OVRE: Disable Overrun Error Interrupt
• FRAME: Disable Framing Error Interrupt
• PARE: Disable Parity Error Interrupt
• TXEMPTY: Disable TXEMPTY Interrupt
• TXBUFE: Disable Buffer Empty Interrupt
• RXBUFF: Disable Buffer Full Interrupt
• COMMTX: Disable COMMTX (from ARM) Interrupt
• COMMRX: Disable COMMRX (from ARM) Interrupt
0 = No effect.
1 = Disables the corresponding interrupt.
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26.5.5
Name:
Debug Unit Interrupt Mask Register
DBGU_IMR
Access Type:
Read-only
31
30
29
28
27
26
25
24
COMMRX
COMMTX
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
RXBUFF
TXBUFE
–
TXEMPTY
–
7
6
5
4
3
2
1
0
PARE
FRAME
OVRE
ENDTX
ENDRX
–
TXRDY
RXRDY
• RXRDY: Mask RXRDY Interrupt
• TXRDY: Disable TXRDY Interrupt
• ENDRX: Mask End of Receive Transfer Interrupt
• ENDTX: Mask End of Transmit Interrupt
• OVRE: Mask Overrun Error Interrupt
• FRAME: Mask Framing Error Interrupt
• PARE: Mask Parity Error Interrupt
• TXEMPTY: Mask TXEMPTY Interrupt
• TXBUFE: Mask TXBUFE Interrupt
• RXBUFF: Mask RXBUFF Interrupt
• COMMTX: Mask COMMTX Interrupt
• COMMRX: Mask COMMRX Interrupt
0 = The corresponding interrupt is disabled.
1 = The corresponding interrupt is enabled.
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26.5.6
Name:
Debug Unit Status Register
DBGU_SR
Access Type:
Read-only
31
30
29
28
27
26
25
24
COMMRX
COMMTX
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
RXBUFF
TXBUFE
–
TXEMPTY
–
7
6
5
4
3
2
1
0
PARE
FRAME
OVRE
ENDTX
ENDRX
–
TXRDY
RXRDY
• RXRDY: Receiver Ready
0 = No character has been received since the last read of the DBGU_RHR or the receiver is disabled.
1 = At least one complete character has been received, transferred to DBGU_RHR and not yet read.
• TXRDY: Transmitter Ready
0 = A character has been written to DBGU_THR and not yet transferred to the Shift Register, or the transmitter is disabled.
1 = There is no character written to DBGU_THR not yet transferred to the Shift Register.
• ENDRX: End of Receiver Transfer
0 = The End of Transfer signal from the receiver Peripheral Data Controller channel is inactive.
1 = The End of Transfer signal from the receiver Peripheral Data Controller channel is active.
• ENDTX: End of Transmitter Transfer
0 = The End of Transfer signal from the transmitter Peripheral Data Controller channel is inactive.
1 = The End of Transfer signal from the transmitter Peripheral Data Controller channel is active.
• OVRE: Overrun Error
0 = No overrun error has occurred since the last RSTSTA.
1 = At least one overrun error has occurred since the last RSTSTA.
• FRAME: Framing Error
0 = No framing error has occurred since the last RSTSTA.
1 = At least one framing error has occurred since the last RSTSTA.
• PARE: Parity Error
0 = No parity error has occurred since the last RSTSTA.
1 = At least one parity error has occurred since the last RSTSTA.
• TXEMPTY: Transmitter Empty
0 = There are characters in DBGU_THR, or characters being processed by the transmitter, or the transmitter is disabled.
1 = There are no characters in DBGU_THR and there are no characters being processed by the transmitter.
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• TXBUFE: Transmission Buffer Empty
0 = The buffer empty signal from the transmitter PDC channel is inactive.
1 = The buffer empty signal from the transmitter PDC channel is active.
• RXBUFF: Receive Buffer Full
0 = The buffer full signal from the receiver PDC channel is inactive.
1 = The buffer full signal from the receiver PDC channel is active.
• COMMTX: Debug Communication Channel Write Status
0 = COMMTX from the ARM processor is inactive.
1 = COMMTX from the ARM processor is active.
• COMMRX: Debug Communication Channel Read Status
0 = COMMRX from the ARM processor is inactive.
1 = COMMRX from the ARM processor is active.
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26.5.7
Name:
Debug Unit Receiver Holding Register
DBGU_RHR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
RXCHR
• RXCHR: Received Character
Last received character if RXRDY is set.
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26.5.8
Name:
Debug Unit Transmit Holding Register
DBGU_THR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
TXCHR
• TXCHR: Character to be Transmitted
Next character to be transmitted after the current character if TXRDY is not set.
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26.5.9
Name:
Debug Unit Baud Rate Generator Register
DBGU_BRGR
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
3
2
1
0
CD
7
6
5
4
CD
• CD: Clock Divisor
CD
Baud Rate Clock
0
Disabled
1
MCK
2 to 65535
MCK / (CD x 16)
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26.5.10
Name:
Debug Unit Chip ID Register
DBGU_CIDR
Access Type:
31
Read-only
30
29
EXT
23
28
27
26
NVPTYP
22
21
20
19
18
ARCH
15
14
13
6
24
17
16
9
8
1
0
SRAMSIZ
12
11
10
NVPSIZ2
7
25
ARCH
NVPSIZ
5
4
3
EPROC
2
VERSION
• VERSION: Version of the Device
Current version of the device.
• EPROC: Embedded Processor
EPROC
Processor
0
0
1
ARM946ES
0
1
0
ARM7TDMI
1
0
0
ARM920T
1
0
1
ARM926EJS
• NVPSIZ: Nonvolatile Program Memory Size
NVPSIZ
Size
0
0
0
0
None
0
0
0
1
8K bytes
0
0
1
0
16K bytes
0
0
1
1
32K bytes
0
1
0
0
Reserved
0
1
0
1
64K bytes
0
1
1
0
Reserved
0
1
1
1
128K bytes
1
0
0
0
Reserved
1
0
0
1
256K bytes
1
0
1
0
512K bytes
1
0
1
1
Reserved
1
1
0
0
1024K bytes
1
1
0
1
Reserved
1
1
1
0
2048K bytes
1
1
1
1
Reserved
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• NVPSIZ2 Second Nonvolatile Program Memory Size
NVPSIZ2
Size
0
0
0
0
None
0
0
0
1
8K bytes
0
0
1
0
16K bytes
0
0
1
1
32K bytes
0
1
0
0
Reserved
0
1
0
1
64K bytes
0
1
1
0
Reserved
0
1
1
1
128K bytes
1
0
0
0
Reserved
1
0
0
1
256K bytes
1
0
1
0
512K bytes
1
0
1
1
Reserved
1
1
0
0
1024K bytes
1
1
0
1
Reserved
1
1
1
0
2048K bytes
1
1
1
1
Reserved
• SRAMSIZ: Internal SRAM Size
SRAMSIZ
Size
0
0
0
0
Reserved
0
0
0
1
1K bytes
0
0
1
0
2K bytes
0
0
1
1
6K bytes
0
1
0
0
112K bytes
0
1
0
1
4K bytes
0
1
1
0
80K bytes
0
1
1
1
160K bytes
1
0
0
0
8K bytes
1
0
0
1
16K bytes
1
0
1
0
32K bytes
1
0
1
1
64K bytes
1
1
0
0
128K bytes
1
1
0
1
256K bytes
1
1
1
0
96K bytes
1
1
1
1
512K bytes
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• ARCH: Architecture Identifier
ARCH
Hex
Bin
Architecture
0x19
0001 1001
AT91SAM9xx Series
0x29
0010 1001
AT91SAM9XExx Series
0x34
0011 0100
AT91x34 Series
0x37
0011 0111
CAP7 Series
0x39
0011 1001
CAP9 Series
0x3B
0011 1011
CAP11 Series
0x40
0100 0000
AT91x40 Series
0x42
0100 0010
AT91x42 Series
0x55
0101 0101
AT91x55 Series
0x60
0110 0000
AT91SAM7Axx Series
0x61
0110 0001
AT91SAM7AQxx Series
0x63
0110 0011
AT91x63 Series
0x70
0111 0000
AT91SAM7Sxx Series
0x71
0111 0001
AT91SAM7XCxx Series
0x72
0111 0010
AT91SAM7SExx Series
0x73
0111 0011
AT91SAM7Lxx Series
0x75
0111 0101
AT91SAM7Xxx Series
0x92
1001 0010
AT91x92 Series
0xF0
1111 0000
AT75Cxx Series
• NVPTYP: Nonvolatile Program Memory Type
NVPTYP
Memory
0
0
0
ROM
0
0
1
ROMless or on-chip Flash
1
0
0
SRAM emulating ROM
0
1
0
Embedded Flash Memory
0
1
1
ROM and Embedded Flash Memory
NVPSIZ is ROM size
NVPSIZ2 is Flash size
• EXT: Extension Flag
0 = Chip ID has a single register definition without extension
1 = An extended Chip ID exists.
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26.5.11
Name:
Debug Unit Chip ID Extension Register
DBGU_EXID
Access Type:
31
Read-only
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
EXID
23
22
21
20
EXID
15
14
13
12
EXID
7
6
5
4
EXID
• EXID: Chip ID Extension
Reads 0 if the bit EXT in DBGU_CIDR is 0.
26.5.12
Name:
Debug Unit Force NTRST Register
DBGU_FNR
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
FNTRST
• FNTRST: Force NTRST
0 = NTRST of the ARM processor’s TAP controller is driven by the power_on_reset signal.
1 = NTRST of the ARM processor’s TAP controller is held low.
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27. Parallel Input Output Controller (PIO)
27.1
Overview
The Parallel Input/Output Controller (PIO) manages up to 32 fully programmable input/output lines. Each I/O line
may be dedicated as a general-purpose I/O or be assigned to a function of an embedded peripheral. This assures
effective optimization of the pins of a product.
Each I/O line is associated with a bit number in all of the 32-bit registers of the 32-bit wide User Interface.
Each I/O line of the PIO Controller features:
• An input change interrupt enabling level change detection on any I/O line.
• A glitch filter providing rejection of pulses lower than one-half of clock cycle.
• Multi-drive capability similar to an open drain I/O line.
• Control of the the pull-up of the I/O line.
• Input visibility and output control.
The PIO Controller also features a synchronous output providing up to 32 bits of data output in a single write
operation.
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27.2
Block Diagram
Figure 27-1. Block Diagram
PIO Controller
AIC
PMC
PIO Interrupt
PIO Clock
Data, Enable
Up to 32
peripheral IOs
Embedded
Peripheral
PIN 0
Data, Enable
PIN 1
Up to 32 pins
Embedded
Peripheral
Up to 32
peripheral IOs
PIN 31
APB
Figure 27-2. Application Block Diagram
On-Chip Peripheral Drivers
Keyboard Driver
Control & Command
Driver
On-Chip Peripherals
PIO Controller
Keyboard Driver
General Purpose I/Os
External Devices
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27.3
Product Dependencies
27.3.1
Pin Multiplexing
Each pin is configurable, according to product definition as either a general-purpose I/O line only, or as an I/O line
multiplexed with one or two peripheral I/Os. As the multiplexing is hardware-defined and thus product-dependent,
the hardware designer and programmer must carefully determine the configuration of the PIO controllers required
by their application. When an I/O line is general-purpose only, i.e. not multiplexed with any peripheral I/O, programming of the PIO Controller regarding the assignment to a peripheral has no effect and only the PIO Controller can
control how the pin is driven by the product.
27.3.2
External Interrupt Lines
The interrupt signals FIQ and IRQ0 to IRQn are most generally multiplexed through the PIO Controllers. However,
it is not necessary to assign the I/O line to the interrupt function as the PIO Controller has no effect on inputs and
the interrupt lines (FIQ or IRQs) are used only as inputs.
27.3.3
Power Management
The Power Management Controller controls the PIO Controller clock in order to save power. Writing any of the registers of the user interface does not require the PIO Controller clock to be enabled. This means that the
configuration of the I/O lines does not require the PIO Controller clock to be enabled.
However, when the clock is disabled, not all of the features of the PIO Controller are available. Note that the Input
Change Interrupt and the read of the pin level require the clock to be validated.
After a hardware reset, the PIO clock is disabled by default.
The user must configure the Power Management Controller before any access to the input line information.
27.3.4
Interrupt Generation
For interrupt handling, the PIO Controllers are considered as user peripherals. This means that the PIO Controller
interrupt lines are connected among the interrupt sources 2 to 31. Refer to the PIO Controller peripheral identifier in
the product description to identify the interrupt sources dedicated to the PIO Controllers.
The PIO Controller interrupt can be generated only if the PIO Controller clock is enabled.
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27.4
Functional Description
The PIO Controller features up to 32 fully-programmable I/O lines. Most of the control logic associated to each I/O
is represented in Figure 27-3. In this description each signal shown represents but one of up to 32 possible
indexes.
Figure 27-3. I/O Line Control Logic
PIO_OER[0]
PIO_OSR[0]
PIO_PUER[0]
PIO_ODR[0]
PIO_PUSR[0]
PIO_PUDR[0]
1
Peripheral A
Output Enable
0
0
Peripheral B
Output Enable
0
1
PIO_PER[0]
PIO_ASR[0]
1
PIO_PSR[0]
PIO_ABSR[0]
PIO_PDR[0]
PIO_BSR[0]
Peripheral A
Output
0
Peripheral B
Output
1
PIO_MDER[0]
PIO_MDSR[0]
PIO_MDDR[0]
0
0
PIO_SODR[0]
PIO_ODSR[0]
1
Pad
PIO_CODR[0]
1
Peripheral A
Input
PIO_PDSR[0]
PIO_ISR[0]
0
Edge
Detector
Glitch
Filter
Peripheral B
Input
(Up to 32 possible inputs)
PIO Interrupt
1
PIO_IFER[0]
PIO_IFSR[0]
PIO_IFDR[0]
PIO_IER[0]
PIO_IMR[0]
PIO_IDR[0]
PIO_ISR[31]
PIO_IER[31]
PIO_IMR[31]
PIO_IDR[31]
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27.4.1
Pull-up Resistor Control
Each I/O line is designed with an embedded pull-up resistor. The pull-up resistor can be enabled or disabled by
writing respectively PIO_PUER (Pull-up Enable Register) and PIO_PUDR (Pull-up Disable Resistor). Writing in
these registers results in setting or clearing the corresponding bit in PIO_PUSR (Pull-up Status Register). Reading
a 1 in PIO_PUSR means the pull-up is disabled and reading a 0 means the pull-up is enabled.
Control of the pull-up resistor is possible regardless of the configuration of the I/O line.
After reset, all of the pull-ups are enabled, i.e. PIO_PUSR resets at the value 0x0.
27.4.2
I/O Line or Peripheral Function Selection
When a pin is multiplexed with one or two peripheral functions, the selection is controlled with the registers
PIO_PER (PIO Enable Register) and PIO_PDR (PIO Disable Register). The register PIO_PSR (PIO Status Register) is the result of the set and clear registers and indicates whether the pin is controlled by the corresponding
peripheral or by the PIO Controller. A value of 0 indicates that the pin is controlled by the corresponding on-chip
peripheral selected in the PIO_ABSR (AB Select Status Register). A value of 1 indicates the pin is controlled by the
PIO controller.
If a pin is used as a general purpose I/O line (not multiplexed with an on-chip peripheral), PIO_PER and PIO_PDR
have no effect and PIO_PSR returns 1 for the corresponding bit.
After reset, most generally, the I/O lines are controlled by the PIO controller, i.e. PIO_PSR resets at 1. However, in
some events, it is important that PIO lines are controlled by the peripheral (as in the case of memory chip select
lines that must be driven inactive after reset or for address lines that must be driven low for booting out of an external memory). Thus, the reset value of PIO_PSR is defined at the product level, depending on the multiplexing of
the device.
27.4.3
Peripheral A or B Selection
The PIO Controller provides multiplexing of up to two peripheral functions on a single pin. The selection is performed by writing PIO_ASR (A Select Register) and PIO_BSR (Select B Register). PIO_ABSR (AB Select Status
Register) indicates which peripheral line is currently selected. For each pin, the corresponding bit at level 0 means
peripheral A is selected whereas the corresponding bit at level 1 indicates that peripheral B is selected.
Note that multiplexing of peripheral lines A and B only affects the output line. The peripheral input lines are always
connected to the pin input.
After reset, PIO_ABSR is 0, thus indicating that all the PIO lines are configured on peripheral A. However, peripheral A generally does not drive the pin as the PIO Controller resets in I/O line mode.
Writing in PIO_ASR and PIO_BSR manages PIO_ABSR regardless of the configuration of the pin. However,
assignment of a pin to a peripheral function requires a write in the corresponding peripheral selection register
(PIO_ASR or PIO_BSR) in addition to a write in PIO_PDR.
27.4.4
Output Control
When the I/0 line is assigned to a peripheral function, i.e. the corresponding bit in PIO_PSR is at 0, the drive of the
I/O line is controlled by the peripheral. Peripheral A or B, depending on the value in PIO_ABSR, determines
whether the pin is driven or not.
When the I/O line is controlled by the PIO controller, the pin can be configured to be driven. This is done by writing
PIO_OER (Output Enable Register) and PIO_ODR (Output Disable Register). The results of these write operations
are detected in PIO_OSR (Output Status Register). When a bit in this register is at 0, the corresponding I/O line is
used as an input only. When the bit is at 1, the corresponding I/O line is driven by the PIO controller.
The level driven on an I/O line can be determined by writing in PIO_SODR (Set Output Data Register) and
PIO_CODR (Clear Output Data Register). These write operations respectively set and clear PIO_ODSR (Output
Data Status Register), which represents the data driven on the I/O lines. Writing in PIO_OER and PIO_ODR manSAM7L128/64 [DATASHEET]
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ages PIO_OSR whether the pin is configured to be controlled by the PIO controller or assigned to a peripheral
function. This enables configuration of the I/O line prior to setting it to be managed by the PIO Controller.
Similarly, writing in PIO_SODR and PIO_CODR effects PIO_ODSR. This is important as it defines the first level
driven on the I/O line.
27.4.5
Synchronous Data Output
Controlling all parallel busses using several PIOs requires two successive write operations in the PIO_SODR and
PIO_CODR registers. This may lead to unexpected transient values. The PIO controller offers a direct control of
PIO outputs by single write access to PIO_ODSR (Output Data Status Register). Only bits unmasked by
PIO_OWSR (Output Write Status Register) are written. The mask bits in the PIO_OWSR are set by writing to
PIO_OWER (Output Write Enable Register) and cleared by writing to PIO_OWDR (Output Write Disable Register).
After reset, the synchronous data output is disabled on all the I/O lines as PIO_OWSR resets at 0x0.
27.4.6
Multi Drive Control (Open Drain)
Each I/O can be independently programmed in Open Drain by using the Multi Drive feature. This feature permits
several drivers to be connected on the I/O line which is driven low only by each device. An external pull-up resistor
(or enabling of the internal one) is generally required to guarantee a high level on the line.
The Multi Drive feature is controlled by PIO_MDER (Multi-driver Enable Register) and PIO_MDDR (Multi-driver
Disable Register). The Multi Drive can be selected whether the I/O line is controlled by the PIO controller or
assigned to a peripheral function. PIO_MDSR (Multi-driver Status Register) indicates the pins that are configured
to support external drivers.
After reset, the Multi Drive feature is disabled on all pins, i.e. PIO_MDSR resets at value 0x0.
27.4.7
Output Line Timings
Figure 27-4 shows how the outputs are driven either by writing PIO_SODR or PIO_CODR, or by directly writing
PIO_ODSR. This last case is valid only if the corresponding bit in PIO_OWSR is set. Figure 27-4 also shows when
the feedback in PIO_PDSR is available.
Figure 27-4. Output Line Timings
MCK
Write PIO_SODR
Write PIO_ODSR at 1
APB Access
Write PIO_CODR
Write PIO_ODSR at 0
APB Access
PIO_ODSR
2 cycles
2 cycles
PIO_PDSR
27.4.8
Inputs
The level on each I/O line can be read through PIO_PDSR (Pin Data Status Register). This register indicates the
level of the I/O lines regardless of their configuration, whether uniquely as an input or driven by the PIO controller
or driven by a peripheral.
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Reading the I/O line levels requires the clock of the PIO controller to be enabled, otherwise PIO_PDSR reads the
levels present on the I/O line at the time the clock was disabled.
27.4.9
Input Glitch Filtering
Optional input glitch filters are independently programmable on each I/O line. When the glitch filter is enabled, a
glitch with a duration of less than 1/2 Master Clock (MCK) cycle is automatically rejected, while a pulse with a duration of 1 Master Clock cycle or more is accepted. For pulse durations between 1/2 Master Clock cycle and 1 Master
Clock cycle the pulse may or may not be taken into account, depending on the precise timing of its occurrence.
Thus for a pulse to be visible it must exceed 1 Master Clock cycle, whereas for a glitch to be reliably filtered out, its
duration must not exceed 1/2 Master Clock cycle. The filter introduces one Master Clock cycle latency if the pin
level change occurs before a rising edge. However, this latency does not appear if the pin level change occurs
before a falling edge. This is illustrated in Figure 27-5.
The glitch filters are controlled by the register set; PIO_IFER (Input Filter Enable Register), PIO_IFDR (Input Filter
Disable Register) and PIO_IFSR (Input Filter Status Register). Writing PIO_IFER and PIO_IFDR respectively sets
and clears bits in PIO_IFSR. This last register enables the glitch filter on the I/O lines.
When the glitch filter is enabled, it does not modify the behavior of the inputs on the peripherals. It acts only on the
value read in PIO_PDSR and on the input change interrupt detection. The glitch filters require that the PIO Controller clock is enabled.
Figure 27-5. Input Glitch Filter Timing
MCK
up to 1.5 cycles
Pin Level
1 cycle
1 cycle
1 cycle
1 cycle
PIO_PDSR
if PIO_IFSR = 0
2 cycles
PIO_PDSR
if PIO_IFSR = 1
27.4.10
up to 2.5 cycles
1 cycle
up to 2 cycles
Input Change Interrupt
The PIO Controller can be programmed to generate an interrupt when it detects an input change on an I/O line.
The Input Change Interrupt is controlled by writing PIO_IER (Interrupt Enable Register) and PIO_IDR (Interrupt
Disable Register), which respectively enable and disable the input change interrupt by setting and clearing the corresponding bit in PIO_IMR (Interrupt Mask Register). As Input change detection is possible only by comparing two
successive samplings of the input of the I/O line, the PIO Controller clock must be enabled. The Input Change
Interrupt is available, regardless of the configuration of the I/O line, i.e. configured as an input only, controlled by
the PIO Controller or assigned to a peripheral function.
When an input change is detected on an I/O line, the corresponding bit in PIO_ISR (Interrupt Status Register) is
set. If the corresponding bit in PIO_IMR is set, the PIO Controller interrupt line is asserted. The interrupt signals of
the thirty-two channels are ORed-wired together to generate a single interrupt signal to the Advanced Interrupt
Controller.
When the software reads PIO_ISR, all the interrupts are automatically cleared. This signifies that all the interrupts
that are pending when PIO_ISR is read must be handled.
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Figure 27-6. Input Change Interrupt Timings
MCK
Pin Level
PIO_ISR
Read PIO_ISR
APB Access
APB Access
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27.5
I/O Lines Programming Example
The programing example as shown in Table 27-1 below is used to define the following configuration.
• 4-bit output port on I/O lines 0 to 3, (should be written in a single write operation), open-drain, with pull-up
resistor
• Four output signals on I/O lines 4 to 7 (to drive LEDs for example), driven high and low, no pull-up resistor
• Four input signals on I/O lines 8 to 11 (to read push-button states for example), with pull-up resistors, glitch
filters and input change interrupts
• Four input signals on I/O line 12 to 15 to read an external device status (polled, thus no input change interrupt),
no pull-up resistor, no glitch filter
• I/O lines 16 to 19 assigned to peripheral A functions with pull-up resistor
• I/O lines 20 to 23 assigned to peripheral B functions, no pull-up resistor
• I/O line 24 to 27 assigned to peripheral A with Input Change Interrupt and pull-up resistor
Table 27-1.
Programming Example
Register
Value to be Written
PIO_PER
0x0000 FFFF
PIO_PDR
0x0FFF 0000
PIO_OER
0x0000 00FF
PIO_ODR
0x0FFF FF00
PIO_IFER
0x0000 0F00
PIO_IFDR
0x0FFF F0FF
PIO_SODR
0x0000 0000
PIO_CODR
0x0FFF FFFF
PIO_IER
0x0F00 0F00
PIO_IDR
0x00FF F0FF
PIO_MDER
0x0000 000F
PIO_MDDR
0x0FFF FFF0
PIO_PUDR
0x00F0 00F0
PIO_PUER
0x0F0F FF0F
PIO_ASR
0x0F0F 0000
PIO_BSR
0x00F0 0000
PIO_OWER
0x0000 000F
PIO_OWDR
0x0FFF FFF0
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27.6
Parallel Input/Output Controller (PIO) User Interface
Each I/O line controlled by the PIO Controller is associated with a bit in each of the PIO Controller User Interface
registers. Each register is 32 bits wide. If a parallel I/O line is not defined, writing to the corresponding bits has no
effect. Undefined bits read zero. If the I/O line is not multiplexed with any peripheral, the I/O line is controlled by the
PIO Controller and PIO_PSR returns 1 systematically.
Table 27-2.
Register Mapping
Offset
Register
Name
Access
Reset
0x0000
PIO Enable Register
PIO_PER
Write-only
–
0x0004
PIO Disable Register
PIO_PDR
Write-only
–
PIO_PSR
Read-only
(1)
0x0008
PIO Status Register
0x000C
Reserved
0x0010
Output Enable Register
PIO_OER
Write-only
–
0x0014
Output Disable Register
PIO_ODR
Write-only
–
0x0018
Output Status Register
PIO_OSR
Read-only
0x0000 0000
0x001C
Reserved
0x0020
Glitch Input Filter Enable Register
PIO_IFER
Write-only
–
0x0024
Glitch Input Filter Disable Register
PIO_IFDR
Write-only
–
0x0028
Glitch Input Filter Status Register
PIO_IFSR
Read-only
0x0000 0000
0x002C
Reserved
0x0030
Set Output Data Register
PIO_SODR
Write-only
–
0x0034
Clear Output Data Register
PIO_CODR
Write-only
0x0038
Output Data Status Register
PIO_ODSR
Read-only
or(2)
Read-write
–
0x003C
Pin Data Status Register
PIO_PDSR
Read-only
(3)
0x0040
Interrupt Enable Register
PIO_IER
Write-only
–
0x0044
Interrupt Disable Register
PIO_IDR
Write-only
–
0x0048
Interrupt Mask Register
PIO_IMR
Read-only
0x00000000
0x004C
Interrupt Status Register(4)
PIO_ISR
Read-only
0x00000000
0x0050
Multi-driver Enable Register
PIO_MDER
Write-only
–
0x0054
Multi-driver Disable Register
PIO_MDDR
Write-only
–
0x0058
Multi-driver Status Register
PIO_MDSR
Read-only
0x00000000
0x005C
Reserved
0x0060
Pull-up Disable Register
PIO_PUDR
Write-only
–
0x0064
Pull-up Enable Register
PIO_PUER
Write-only
–
0x0068
Pad Pull-up Status Register
PIO_PUSR
Read-only
0x00000000
0x006C
Reserved
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Table 27-2.
Offset
Register Mapping (Continued)
Register
0x0070
Name
(5)
(5)
Peripheral A Select Register
Access
Reset
PIO_ASR
Write-only
–
0x0074
Peripheral B Select Register
PIO_BSR
Write-only
–
0x0078
AB Status Register(5)
PIO_ABSR
Read-only
0x00000000
0x007C
to
0x009C
Reserved
0x00A0
Output Write Enable
PIO_OWER
Write-only
–
0x00A4
Output Write Disable
PIO_OWDR
Write-only
–
0x00A8
Output Write Status Register
PIO_OWSR
Read-only
0x00000000
0x00AC
Reserved
Notes:
1. Reset value of PIO_PSR depends on the product implementation.
2. PIO_ODSR is Read-only or Read/Write depending on PIO_OWSR I/O lines.
3. Reset value of PIO_PDSR depends on the level of the I/O lines. Reading the I/O line levels requires the clock of the PIO
Controller to be enabled, otherwise PIO_PDSR reads the levels present on the I/O line at the time the clock was disabled.
4. PIO_ISR is reset at 0x0. However, the first read of the register may read a different value as input changes may have
occurred.
5. Only this set of registers clears the status by writing 1 in the first register and sets the status by writing 1 in the second
register.
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27.6.1
Name:
PIO Controller PIO Enable Register
PIO_PER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: PIO Enable
0 = No effect.
1 = Enables the PIO to control the corresponding pin (disables peripheral control of the pin).
27.6.2
Name:
PIO Controller PIO Disable Register
PIO_PDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: PIO Disable
0 = No effect.
1 = Disables the PIO from controlling the corresponding pin (enables peripheral control of the pin).
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27.6.3
Name:
PIO Controller PIO Status Register
PIO_PSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: PIO Status
0 = PIO is inactive on the corresponding I/O line (peripheral is active).
1 = PIO is active on the corresponding I/O line (peripheral is inactive).
27.6.4
Name:
PIO Controller Output Enable Register
PIO_OER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Enable
0 = No effect.
1 = Enables the output on the I/O line.
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27.6.5
Name:
PIO Controller Output Disable Register
PIO_ODR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Disable
0 = No effect.
1 = Disables the output on the I/O line.
27.6.6
Name:
PIO Controller Output Status Register
PIO_OSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Status
0 = The I/O line is a pure input.
1 = The I/O line is enabled in output.
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27.6.7
Name:
PIO Controller Input Filter Enable Register
PIO_IFER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Filter Enable
0 = No effect.
1 = Enables the input glitch filter on the I/O line.
27.6.8
Name:
PIO Controller Input Filter Disable Register
PIO_IFDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Filter Disable
0 = No effect.
1 = Disables the input glitch filter on the I/O line.
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27.6.9
Name:
PIO Controller Input Filter Status Register
PIO_IFSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Filer Status
0 = The input glitch filter is disabled on the I/O line.
1 = The input glitch filter is enabled on the I/O line.
27.6.10
Name:
PIO Controller Set Output Data Register
PIO_SODR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Set Output Data
0 = No effect.
1 = Sets the data to be driven on the I/O line.
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27.6.11
Name:
PIO Controller Clear Output Data Register
PIO_CODR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Set Output Data
0 = No effect.
1 = Clears the data to be driven on the I/O line.
27.6.12
Name:
PIO Controller Output Data Status Register
PIO_ODSR
Access Type:
Read-only or Read-write
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Data Status
0 = The data to be driven on the I/O line is 0.
1 = The data to be driven on the I/O line is 1.
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27.6.13
Name:
PIO Controller Pin Data Status Register
PIO_PDSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Data Status
0 = The I/O line is at level 0.
1 = The I/O line is at level 1.
27.6.14
Name:
PIO Controller Interrupt Enable Register
PIO_IER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Change Interrupt Enable
0 = No effect.
1 = Enables the Input Change Interrupt on the I/O line.
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27.6.15
Name:
PIO Controller Interrupt Disable Register
PIO_IDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Change Interrupt Disable
0 = No effect.
1 = Disables the Input Change Interrupt on the I/O line.
27.6.16
Name:
PIO Controller Interrupt Mask Register
PIO_IMR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Change Interrupt Mask
0 = Input Change Interrupt is disabled on the I/O line.
1 = Input Change Interrupt is enabled on the I/O line.
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27.6.17
Name:
PIO Controller Interrupt Status Register
PIO_ISR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Input Change Interrupt Status
0 = No Input Change has been detected on the I/O line since PIO_ISR was last read or since reset.
1 = At least one Input Change has been detected on the I/O line since PIO_ISR was last read or since reset.
27.6.18
Name:
PIO Multi-driver Enable Register
PIO_MDER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Multi Drive Enable.
0 = No effect.
1 = Enables Multi Drive on the I/O line.
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27.6.19
Name:
PIO Multi-driver Disable Register
PIO_MDDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Multi Drive Disable.
0 = No effect.
1 = Disables Multi Drive on the I/O line.
27.6.20
Name:
PIO Multi-driver Status Register
PIO_MDSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Multi Drive Status.
0 = The Multi Drive is disabled on the I/O line. The pin is driven at high and low level.
1 = The Multi Drive is enabled on the I/O line. The pin is driven at low level only.
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27.6.21
Name:
PIO Pull Up Disable Register
PIO_PUDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Pull Up Disable.
0 = No effect.
1 = Disables the pull up resistor on the I/O line.
27.6.22
Name:
PIO Pull Up Enable Register
PIO_PUER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Pull Up Enable.
0 = No effect.
1 = Enables the pull up resistor on the I/O line.
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27.6.23
Name:
PIO Pull Up Status Register
PIO_PUSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Pull Up Status.
0 = Pull Up resistor is enabled on the I/O line.
1 = Pull Up resistor is disabled on the I/O line.
27.6.24
Name:
PIO Peripheral A Select Register
PIO_ASR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Peripheral A Select.
0 = No effect.
1 = Assigns the I/O line to the Peripheral A function.
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27.6.25
Name:
PIO Peripheral B Select Register
PIO_BSR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Peripheral B Select.
0 = No effect.
1 = Assigns the I/O line to the peripheral B function.
27.6.26
Name:
PIO Peripheral A B Status Register
PIO_ABSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Peripheral A B Status.
0 = The I/O line is assigned to the Peripheral A.
1 = The I/O line is assigned to the Peripheral B.
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27.6.27
Name:
PIO Output Write Enable Register
PIO_OWER
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Write Enable.
0 = No effect.
1 = Enables writing PIO_ODSR for the I/O line.
27.6.28
Name:
PIO Output Write Disable Register
PIO_OWDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Write Disable.
0 = No effect.
1 = Disables writing PIO_ODSR for the I/O line.
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27.6.29
Name:
PIO Output Write Status Register
PIO_OWSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
P31
P30
P29
P28
P27
P26
P25
P24
23
22
21
20
19
18
17
16
P23
P22
P21
P20
P19
P18
P17
P16
15
14
13
12
11
10
9
8
P15
P14
P13
P12
P11
P10
P9
P8
7
6
5
4
3
2
1
0
P7
P6
P5
P4
P3
P2
P1
P0
• P0-P31: Output Write Status.
0 = Writing PIO_ODSR does not affect the I/O line.
1 = Writing PIO_ODSR affects the I/O line.
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28. Serial Peripheral Interface (SPI)
28.1
Overview
The Serial Peripheral Interface (SPI) circuit is a synchronous serial data link that provides communication with
external devices in Master or Slave Mode. It also enables communication between processors if an external processor is connected to the system.
The Serial Peripheral Interface is essentially a shift register that serially transmits data bits to other SPIs. During a
data transfer, one SPI system acts as the “master”' which controls the data flow, while the other devices act as
“slaves'' which have data shifted into and out by the master. Different CPUs can take turn being masters (Multiple
Master Protocol opposite to Single Master Protocol where one CPU is always the master while all of the others are
always slaves) and one master may simultaneously shift data into multiple slaves. However, only one slave may
drive its output to write data back to the master at any given time.
A slave device is selected when the master asserts its NSS signal. If multiple slave devices exist, the master generates a separate slave select signal for each slave (NPCS).
The SPI system consists of two data lines and two control lines:
• Master Out Slave In (MOSI): This data line supplies the output data from the master shifted into the input(s) of
the slave(s).
• Master In Slave Out (MISO): This data line supplies the output data from a slave to the input of the master.
There may be no more than one slave transmitting data during any particular transfer.
• Serial Clock (SPCK): This control line is driven by the master and regulates the flow of the data bits. The master
may transmit data at a variety of baud rates; the SPCK line cycles once for each bit that is transmitted.
• Slave Select (NSS): This control line allows slaves to be turned on and off by hardware.
28.2
Block Diagram
Figure 28-1. Block Diagram
PDC
APB
SPCK
MISO
PMC
MOSI
MCK
SPI Interface
PIO
NPCS0/NSS
NPCS1
NPCS2
Interrupt Control
NPCS3
SPI Interrupt
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28.3
Application Block Diagram
Figure 28-2. Application Block Diagram: Single Master/Multiple Slave Implementation
SPI Master
SPCK
SPCK
MISO
MISO
MOSI
MOSI
NPCS0
NSS
Slave 0
SPCK
NPCS1
NPCS2
NC
NPCS3
MISO
Slave 1
MOSI
NSS
SPCK
MISO
Slave 2
MOSI
NSS
28.4
Signal Description
Table 28-1.
Signal Description
Type
Pin Name
Pin Description
Master
Slave
MISO
Master In Slave Out
Input
Output
MOSI
Master Out Slave In
Output
Input
SPCK
Serial Clock
Output
Input
NPCS1-NPCS3
Peripheral Chip Selects
Output
Unused
NPCS0/NSS
Peripheral Chip Select/Slave Select
Output
Input
28.5
Product Dependencies
28.5.1
I/O Lines
The pins used for interfacing the compliant external devices may be multiplexed with PIO lines. The programmer
must first program the PIO controllers to assign the SPI pins to their peripheral functions.
28.5.2
Power Management
The SPI may be clocked through the Power Management Controller (PMC), thus the programmer must first configure the PMC to enable the SPI clock.
28.5.3
Interrupt
The SPI interface has an interrupt line connected to the Advanced Interrupt Controller (AIC). Handling the SPI
interrupt requires programming the AIC before configuring the SPI.
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28.6
Functional Description
28.6.1
Modes of Operation
The SPI operates in Master Mode or in Slave Mode.
Operation in Master Mode is programmed by writing at 1 the MSTR bit in the Mode Register. The pins NPCS0 to
NPCS3 are all configured as outputs, the SPCK pin is driven, the MISO line is wired on the receiver input and the
MOSI line driven as an output by the transmitter.
If the MSTR bit is written at 0, the SPI operates in Slave Mode. The MISO line is driven by the transmitter output,
the MOSI line is wired on the receiver input, the SPCK pin is driven by the transmitter to synchronize the receiver.
The NPCS0 pin becomes an input, and is used as a Slave Select signal (NSS). The pins NPCS1 to NPCS3 are not
driven and can be used for other purposes.
The data transfers are identically programmable for both modes of operations. The baud rate generator is activated
only in Master Mode.
28.6.2
Data Transfer
Four combinations of polarity and phase are available for data transfers. The clock polarity is programmed with the
CPOL bit in the Chip Select Register. The clock phase is programmed with the NCPHA bit. These two parameters
determine the edges of the clock signal on which data is driven and sampled. Each of the two parameters has two
possible states, resulting in four possible combinations that are incompatible with one another. Thus, a master/slave pair must use the same parameter pair values to communicate. If multiple slaves are used and fixed in
different configurations, the master must reconfigure itself each time it needs to communicate with a different slave.
Table 28-2 shows the four modes and corresponding parameter settings.
Table 28-2.
SPI Bus Protocol Mode
SPI Mode
CPOL
NCPHA
0
0
1
1
0
0
2
1
1
3
1
0
Figure 28-3 and Figure 28-4 show examples of data transfers.
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Figure 28-3. SPI Transfer Format (NCPHA = 1, 8 bits per transfer)
1
SPCK cycle (for reference)
2
3
4
6
5
7
8
SPCK
(CPOL = 0)
SPCK
(CPOL = 1)
MOSI
(from master)
MSB
MISO
(from slave)
MSB
6
5
4
3
2
1
LSB
6
5
4
3
2
1
LSB
*
NSS
(to slave)
* Not defined, but normally MSB of previous character received.
Figure 28-4. SPI Transfer Format (NCPHA = 0, 8 bits per transfer)
1
SPCK cycle (for reference)
2
3
4
5
8
7
6
SPCK
(CPOL = 0)
SPCK
(CPOL = 1)
MOSI
(from master)
MISO
(from slave)
*
MSB
6
5
4
3
2
1
MSB
6
5
4
3
2
1
LSB
LSB
NSS
(to slave)
* Not defined but normally LSB of previous character transmitted.
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28.6.3
Master Mode Operations
When configured in Master Mode, the SPI operates on the clock generated by the internal programmable baud
rate generator. It fully controls the data transfers to and from the slave(s) connected to the SPI bus. The SPI drives
the chip select line to the slave and the serial clock signal (SPCK).
The SPI features two holding registers, the Transmit Data Register and the Receive Data Register, and a single
Shift Register. The holding registers maintain the data flow at a constant rate.
After enabling the SPI, a data transfer begins when the processor writes to the SPI_TDR (Transmit Data Register).
The written data is immediately transferred in the Shift Register and transfer on the SPI bus starts. While the data
in the Shift Register is shifted on the MOSI line, the MISO line is sampled and shifted in the Shift Register. Transmission cannot occur without reception.
Before writting the TDR, the PCS field must be set in order to select a slave.
If new data is written in SPI_TDR during the transfer, it stays in it until the current transfer is completed. Then, the
received data is transferred from the Shift Register to SPI_RDR, the data in SPI_TDR is loaded in the Shift Register and a new transfer starts.
The transfer of a data written in SPI_TDR in the Shift Register is indicated by the TDRE bit (Transmit Data Register
Empty) in the Status Register (SPI_SR). When new data is written in SPI_TDR, this bit is cleared. The TDRE bit is
used to trigger the Transmit PDC channel.
The end of transfer is indicated by the TXEMPTY flag in the SPI_SR register. If a transfer delay (DLYBCT) is
greater than 0 for the last transfer, TXEMPTY is set after the completion of said delay. The master clock (MCK) can
be switched off at this time.
The transfer of received data from the Shift Register in SPI_RDR is indicated by the RDRF bit (Receive Data Register Full) in the Status Register (SPI_SR). When the received data is read, the RDRF bit is cleared.
If the SPI_RDR (Receive Data Register) has not been read before new data is received, the Overrun Error bit
(OVRES) in SPI_SR is set. As long as this flag is set, data is loaded in SPI_RDR. The user has to read the status
register to clear the OVRES bit.
Figure 28-5 on page 292 shows a block diagram of the SPI when operating in Master Mode. Figure 28-6 on page
293 shows a flow chart describing how transfers are handled.
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28.6.3.1
Master Mode Block Diagram
Figure 28-5. Master Mode Block Diagram
SPI_CSR0..3
SCBR
Baud Rate Generator
MCK
SPCK
SPI
Clock
SPI_CSR0..3
BITS
NCPHA
CPOL
LSB
MISO
SPI_RDR
RDRF
OVRES
RD
MSB
Shift Register
MOSI
SPI_TDR
TDRE
TD
SPI_CSR0..3
SPI_RDR
CSAAT
PCS
PS
NPCS3
PCSDEC
SPI_MR
PCS
0
NPCS2
Current
Peripheral
NPCS1
SPI_TDR
NPCS0
PCS
1
MSTR
MODF
NPCS0
MODFDIS
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28.6.3.2
Master Mode Flow Diagram
Figure 28-6. Master Mode Flow Diagram
SPI Enable
- NPCS defines the current Chip Select
- CSAAT, DLYBS, DLYBCT refer to the fields of the
Chip Select Register corresponding to the Current Chip Select
- When NPCS is 0xF, CSAAT is 0.
1
TDRE ?
0
PS ?
1
0
0
Fixed
peripheral
PS ?
1
Fixed
peripheral
0
1
CSAAT ?
Variable
peripheral
Variable
peripheral
SPI_TDR(PCS)
= NPCS ?
no
NPCS = SPI_TDR(PCS)
NPCS = SPI_MR(PCS)
yes
SPI_MR(PCS)
= NPCS ?
no
NPCS = 0xF
NPCS = 0xF
Delay DLYBCS
Delay DLYBCS
NPCS = SPI_TDR(PCS)
NPCS = SPI_MR(PCS),
SPI_TDR(PCS)
Delay DLYBS
Serializer = SPI_TDR(TD)
TDRE = 1
Data Transfer
SPI_RDR(RD) = Serializer
RDRF = 1
Delay DLYBCT
0
TDRE ?
1
1
CSAAT ?
0
NPCS = 0xF
Delay DLYBCS
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28.6.3.3
Clock Generation
The SPI Baud rate clock is generated by dividing the Master Clock (MCK) , by a value between 1 and 255.
This allows a maximum operating baud rate at up to Master Clock and a minimum operating baud rate of MCK
divided by 255.
Programming the SCBR field at 0 is forbidden. Triggering a transfer while SCBR is at 0 can lead to unpredictable
results.
At reset, SCBR is 0 and the user has to program it at a valid value before performing the first transfer.
The divisor can be defined independently for each chip select, as it has to be programmed in the SCBR field of the
Chip Select Registers. This allows the SPI to automatically adapt the baud rate for each interfaced peripheral without reprogramming.
28.6.3.4
Transfer Delays
Figure 28-7 shows a chip select transfer change and consecutive transfers on the same chip select. Three delays
can be programmed to modify the transfer waveforms:
• The delay between chip selects, programmable only once for all the chip selects by writing the DLYBCS field in
the Mode Register. Allows insertion of a delay between release of one chip select and before assertion of a new
one.
• The delay before SPCK, independently programmable for each chip select by writing the field DLYBS. Allows
the start of SPCK to be delayed after the chip select has been asserted.
• The delay between consecutive transfers, independently programmable for each chip select by writing the
DLYBCT field. Allows insertion of a delay between two transfers occurring on the same chip select
These delays allow the SPI to be adapted to the interfaced peripherals and their speed and bus release time.
Figure 28-7. Programmable Delays
Chip Select 1
Chip Select 2
SPCK
DLYBCS
DLYBS
DLYBCT
DLYBCT
28.6.3.5
Peripheral Selection
The serial peripherals are selected through the assertion of the NPCS0 to NPCS3 signals. By default, all the NPCS
signals are high before and after each transfer.
The peripheral selection can be performed in two different ways:
• Fixed Peripheral Select: SPI exchanges data with only one peripheral
• Variable Peripheral Select: Data can be exchanged with more than one peripheral
Fixed Peripheral Select is activated by writing the PS bit to zero in SPI_MR (Mode Register). In this case, the current peripheral is defined by the PCS field in SPI_MR and the PCS field in the SPI_TDR has no effect.
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Variable Peripheral Select is activated by setting PS bit to one. The PCS field in SPI_TDR is used to select the current peripheral. This means that the peripheral selection can be defined for each new data.
The Fixed Peripheral Selection allows buffer transfers with a single peripheral. Using the PDC is an optimal means,
as the size of the data transfer between the memory and the SPI is either 8 bits or 16 bits. However, changing the
peripheral selection requires the Mode Register to be reprogrammed.
The Variable Peripheral Selection allows buffer transfers with multiple peripherals without reprogramming the
Mode Register. Data written in SPI_TDR is 32 bits wide and defines the real data to be transmitted and the peripheral it is destined to. Using the PDC in this mode requires 32-bit wide buffers, with the data in the LSBs and the
PCS and LASTXFER fields in the MSBs, however the SPI still controls the number of bits (8 to16) to be transferred
through MISO and MOSI lines with the chip select configuration registers. This is not the optimal means in term of
memory size for the buffers, but it provides a very effective means to exchange data with several peripherals without any intervention of the processor.
28.6.3.6
Peripheral Chip Select Decoding
The user can program the SPI to operate with up to 15 peripherals by decoding the four Chip Select lines, NPCS0
to NPCS3 with an external logic. This can be enabled by writing the PCSDEC bit at 1 in the Mode Register
(SPI_MR).
When operating without decoding, the SPI makes sure that in any case only one chip select line is activated, i.e.
driven low at a time. If two bits are defined low in a PCS field, only the lowest numbered chip select is driven low.
When operating with decoding, the SPI directly outputs the value defined by the PCS field of either the Mode Register or the Transmit Data Register (depending on PS).
As the SPI sets a default value of 0xF on the chip select lines (i.e. all chip select lines at 1) when not processing
any transfer, only 15 peripherals can be decoded.
The SPI has only four Chip Select Registers, not 15. As a result, when decoding is activated, each chip select
defines the characteristics of up to four peripherals. As an example, SPI_CRS0 defines the characteristics of the
externally decoded peripherals 0 to 3, corresponding to the PCS values 0x0 to 0x3. Thus, the user has to make
sure to connect compatible peripherals on the decoded chip select lines 0 to 3, 4 to 7, 8 to 11 and 12 to 14.
28.6.3.7
Peripheral Deselection
When operating normally, as soon as the transfer of the last data written in SPI_TDR is completed, the NPCS lines
all rise. This might lead to runtime error if the processor is too long in responding to an interrupt, and thus might
lead to difficulties for interfacing with some serial peripherals requiring the chip select line to remain active during a
full set of transfers.
To facilitate interfacing with such devices, the Chip Select Register can be programmed with the CSAAT bit (Chip
Select Active After Transfer) at 1. This allows the chip select lines to remain in their current state (low = active) until
transfer to another peripheral is required.
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Figure 28-8. Peripheral Deselection
CSAAT = 0 and CSNAAT = 0
TDRE
NPCS[0..3]
CSAAT = 1 and CSNAAT= 0 / 1
DLYBCT
DLYBCT
A
A
A
A
DLYBCS
A
DLYBCS
PCS = A
PCS = A
Write SPI_TDR
TDRE
NPCS[0..3]
DLYBCT
DLYBCT
A
A
A
A
DLYBCS
A
DLYBCS
PCS=A
PCS = A
Write SPI_TDR
TDRE
NPCS[0..3]
DLYBCT
DLYBCT
A
B
A
B
DLYBCS
DLYBCS
PCS = B
PCS = B
Write SPI_TDR
28.6.3.8
Mode Fault Detection
A mode fault is detected when the SPI is programmed in Master Mode and a low level is driven by an external master on the NPCS0/NSS signal. NPCS0, MOSI, MISO and SPCK must be configured in open drain through the PIO
controller, so that external pull up resistors are needed to guarantee high level.
When a mode fault is detected, the MODF bit in the SPI_SR is set until the SPI_SR is read and the SPI is automatically disabled until re-enabled by writing the SPIEN bit in the SPI_CR (Control Register) at 1.
By default, the Mode Fault detection circuitry is enabled. The user can disable Mode Fault detection by setting the
MODFDIS bit in the SPI Mode Register (SPI_MR).
28.6.4
SPI Slave Mode
When operating in Slave Mode, the SPI processes data bits on the clock provided on the SPI clock pin (SPCK).
The SPI waits for NSS to go active before receiving the serial clock from an external master. When NSS falls, the
clock is validated on the serializer, which processes the number of bits defined by the BITS field of the Chip Select
Register 0 (SPI_CSR0). These bits are processed following a phase and a polarity defined respectively by the
NCPHA and CPOL bits of the SPI_CSR0. Note that BITS, CPOL and NCPHA of the other Chip Select Registers
have no effect when the SPI is programmed in Slave Mode.
The bits are shifted out on the MISO line and sampled on the MOSI line.
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When all the bits are processed, the received data is transferred in the Receive Data Register and the RDRF bit
rises. If the SPI_RDR (Receive Data Register) has not been read before new data is received, the Overrun Error
bit (OVRES) in SPI_SR is set. As long as this flag is set, data is loaded in SPI_RDR. The user has to read the status register to clear the OVRES bit.
When a transfer starts, the data shifted out is the data present in the Shift Register. If no data has been written in
the Transmit Data Register (SPI_TDR), the last data received is transferred. If no data has been received since the
last reset, all bits are transmitted low, as the Shift Register resets at 0.
When a first data is written in SPI_TDR, it is transferred immediately in the Shift Register and the TDRE bit rises. If
new data is written, it remains in SPI_TDR until a transfer occurs, i.e. NSS falls and there is a valid clock on the
SPCK pin. When the transfer occurs, the last data written in SPI_TDR is transferred in the Shift Register and the
TDRE bit rises. This enables frequent updates of critical variables with single transfers.
Then, a new data is loaded in the Shift Register from the Transmit Data Register. In case no character is ready to
be transmitted, i.e. no character has been written in SPI_TDR since the last load from SPI_TDR to the Shift Register, the Shift Register is not modified and the last received character is retransmitted.
Figure 28-9 shows a block diagram of the SPI when operating in Slave Mode.
Figure 28-9. Slave Mode Functional Block Diagram
SPCK
NSS
SPI
Clock
SPIEN
SPIENS
SPIDIS
SPI_CSR0
BITS
NCPHA
CPOL
MOSI
LSB
SPI_RDR
RDRF
OVRES
RD
MSB
Shift Register
MISO
SPI_TDR
TD
TDRE
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28.7
Serial Peripheral Interface (SPI) User Interface
Table 28-3.
Register Mapping
Offset
Register
Name
Access
Reset
0x00
Control Register
SPI_CR
Write-only
---
0x04
Mode Register
SPI_MR
Read-write
0x0
0x08
Receive Data Register
SPI_RDR
Read-only
0x0
0x0C
Transmit Data Register
SPI_TDR
Write-only
---
0x10
Status Register
SPI_SR
Read-only
0x000000F0
0x14
Interrupt Enable Register
SPI_IER
Write-only
---
0x18
Interrupt Disable Register
SPI_IDR
Write-only
---
0x1C
Interrupt Mask Register
SPI_IMR
Read-only
0x0
0x20 - 0x2C
Reserved
0x30
Chip Select Register 0
SPI_CSR0
Read-write
0x0
0x34
Chip Select Register 1
SPI_CSR1
Read-write
0x0
0x38
Chip Select Register 2
SPI_CSR2
Read-write
0x0
0x3C
Chip Select Register 3
SPI_CSR3
Read-write
0x0
–
–
–
0x004C - 0x00F8
0x100 - 0x124
Reserved
Reserved for the PDC
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28.7.1
Name:
SPI Control Register
SPI_CR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
LASTXFER
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
SWRST
–
–
–
–
–
SPIDIS
SPIEN
• SPIEN: SPI Enable
0 = No effect.
1 = Enables the SPI to transfer and receive data.
• SPIDIS: SPI Disable
0 = No effect.
1 = Disables the SPI.
As soon as SPIDIS is set, SPI finishes its tranfer.
All pins are set in input mode and no data is received or transmitted.
If a transfer is in progress, the transfer is finished before the SPI is disabled.
If both SPIEN and SPIDIS are equal to one when the control register is written, the SPI is disabled.
• SWRST: SPI Software Reset
0 = No effect.
1 = Reset the SPI. A software-triggered hardware reset of the SPI interface is performed.
The SPI is in slave mode after software reset.
PDC channels are not affected by software reset.
• LASTXFER: Last Transfer
0 = No effect.
1 = The current NPCS will be deasserted after the character written in TD has been transferred. When CSAAT is set, this
allows to close the communication with the current serial peripheral by raising the corresponding NPCS line as soon as TD
transfer has completed.
28.7.2
Name:
SPI Mode Register
SPI_MR
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Access Type:
31
Read/Write
30
29
28
27
26
19
18
25
24
17
16
DLYBCS
23
22
21
20
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
LLB
–
–
MODFDIS
PCSDEC
PS
MSTR
PCS
• MSTR: Master/Slave Mode
0 = SPI is in Slave mode.
1 = SPI is in Master mode.
• PS: Peripheral Select
0 = Fixed Peripheral Select.
1 = Variable Peripheral Select.
• PCSDEC: Chip Select Decode
0 = The chip selects are directly connected to a peripheral device.
1 = The four chip select lines are connected to a 4- to 16-bit decoder.
When PCSDEC equals one, up to 15 Chip Select signals can be generated with the four lines using an external 4- to 16-bit
decoder. The Chip Select Registers define the characteristics of the 15 chip selects according to the following rules:
SPI_CSR0 defines peripheral chip select signals 0 to 3.
SPI_CSR1 defines peripheral chip select signals 4 to 7.
SPI_CSR2 defines peripheral chip select signals 8 to 11.
SPI_CSR3 defines peripheral chip select signals 12 to 14.
• MODFDIS: Mode Fault Detection
0 = Mode fault detection is enabled.
1 = Mode fault detection is disabled.
• LLB: Local Loopback Enable
0 = Local loopback path disabled.
1 = Local loopback path enabled (
LLB controls the local loopback on the data serializer for testing in Master Mode only. (MISO is internally connected on
MOSI.)
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• PCS: Peripheral Chip Select
This field is only used if Fixed Peripheral Select is active (PS = 0).
If PCSDEC = 0:
PCS = xxx0
NPCS[3:0] = 1110
PCS = xx01
NPCS[3:0] = 1101
PCS = x011
NPCS[3:0] = 1011
PCS = 0111
NPCS[3:0] = 0111
PCS = 1111
forbidden (no peripheral is selected)
(x = don’t care)
If PCSDEC = 1:
NPCS[3:0] output signals = PCS.
• DLYBCS: Delay Between Chip Selects
This field defines the delay from NPCS inactive to the activation of another NPCS. The DLYBCS time guarantees non-overlapping chip selects and solves bus contentions in case of peripherals having long data float times.
If DLYBCS is less than or equal to six, six MCK periods will be inserted by default.
Otherwise, the following equation determines the delay:
Delay Between Chip Selects = DLYBCS
----------------------MCK
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28.7.3
Name:
SPI Receive Data Register
SPI_RDR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
15
14
13
12
PCS
11
10
9
8
3
2
1
0
RD
7
6
5
4
RD
• RD: Receive Data
Data received by the SPI Interface is stored in this register right-justified. Unused bits read zero.
• PCS: Peripheral Chip Select
In Master Mode only, these bits indicate the value on the NPCS pins at the end of a transfer. Otherwise, these bits read
zero.
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28.7.4
Name:
SPI Transmit Data Register
SPI_TDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
LASTXFER
23
22
21
20
19
18
17
16
–
–
–
–
15
14
13
12
PCS
11
10
9
8
3
2
1
0
TD
7
6
5
4
TD
• TD: Transmit Data
Data to be transmitted by the SPI Interface is stored in this register. Information to be transmitted must be written to the
transmit data register in a right-justified format.
• PCS: Peripheral Chip Select
This field is only used if Variable Peripheral Select is active (PS = 1).
If PCSDEC = 0:
PCS = xxx0
NPCS[3:0] = 1110
PCS = xx01
NPCS[3:0] = 1101
PCS = x011
NPCS[3:0] = 1011
PCS = 0111
NPCS[3:0] = 0111
PCS = 1111
forbidden (no peripheral is selected)
(x = don’t care)
If PCSDEC = 1:
NPCS[3:0] output signals = PCS
• LASTXFER: Last Transfer
0 = No effect.
1 = The current NPCS will be deasserted after the character written in TD has been transferred. When CSAAT is set, this
allows to close the communication with the current serial peripheral by raising the corresponding NPCS line as soon as TD
transfer has completed.
This field is only used if Variable Peripheral Select is active (PS = 1).
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28.7.5
Name:
SPI Status Register
SPI_SR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
SPIENS
15
14
13
12
11
10
9
8
–
–
–
–
–
-
TXEMPTY
NSSR
7
6
5
4
3
2
1
0
TXBUFE
RXBUFF
ENDTX
ENDRX
OVRES
MODF
TDRE
RDRF
• RDRF: Receive Data Register Full
0 = No data has been received since the last read of SPI_RDR
1 = Data has been received and the received data has been transferred from the serializer to SPI_RDR since the last read
of SPI_RDR.
• TDRE: Transmit Data Register Empty
0 = Data has been written to SPI_TDR and not yet transferred to the serializer.
1 = The last data written in the Transmit Data Register has been transferred to the serializer.
TDRE equals zero when the SPI is disabled or at reset. The SPI enable command sets this bit to one.
• MODF: Mode Fault Error
0 = No Mode Fault has been detected since the last read of SPI_SR.
1 = A Mode Fault occurred since the last read of the SPI_SR.
• OVRES: Overrun Error Status
0 = No overrun has been detected since the last read of SPI_SR.
1 = An overrun has occurred since the last read of SPI_SR.
An overrun occurs when SPI_RDR is loaded at least twice from the serializer since the last read of the SPI_RDR.
• ENDRX: End of RX buffer
0 = The Receive Counter Register has not reached 0 since the last write in SPI_RCR(1) or SPI_RNCR(1).
1 = The Receive Counter Register has reached 0 since the last write in SPI_RCR(1) or SPI_RNCR(1).
• ENDTX: End of TX buffer
0 = The Transmit Counter Register has not reached 0 since the last write in SPI_TCR(1) or SPI_TNCR(1).
1 = The Transmit Counter Register has reached 0 since the last write in SPI_TCR(1) or SPI_TNCR(1).
• RXBUFF: RX Buffer Full
0 = SPI_RCR(1) or SPI_RNCR(1) has a value other than 0.
1 = Both SPI_RCR(1) and SPI_RNCR(1) have a value of 0.
• TXBUFE: TX Buffer Empty
0 = SPI_TCR(1) or SPI_TNCR(1) has a value other than 0.
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1 = Both SPI_TCR(1) and SPI_TNCR(1) have a value of 0.
• NSSR: NSS Rising
0 = No rising edge detected on NSS pin since last read.
1 = A rising edge occurred on NSS pin since last read.
• TXEMPTY: Transmission Registers Empty
0 = As soon as data is written in SPI_TDR.
1 = SPI_TDR and internal shifter are empty. If a transfer delay has been defined, TXEMPTY is set after the completion of
such delay.
• SPIENS: SPI Enable Status
0 = SPI is disabled.
1 = SPI is enabled.
Note:
1. SPI_RCR, SPI_RNCR, SPI_TCR, SPI_TNCR are physically located in the PDC.
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28.7.6
Name:
SPI Interrupt Enable Register
SPI_IER
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
-
TXEMPTY
NSSR
7
6
5
4
3
2
1
0
TXBUFE
RXBUFF
ENDTX
ENDRX
OVRES
MODF
TDRE
RDRF
• RDRF: Receive Data Register Full Interrupt Enable
• TDRE: SPI Transmit Data Register Empty Interrupt Enable
• MODF: Mode Fault Error Interrupt Enable
• OVRES: Overrun Error Interrupt Enable
• ENDRX: End of Receive Buffer Interrupt Enable
• ENDTX: End of Transmit Buffer Interrupt Enable
• RXBUFF: Receive Buffer Full Interrupt Enable
• TXBUFE: Transmit Buffer Empty Interrupt Enable
• NSSR: NSS Rising Interrupt Enable
0 = No effect.
1 = Enables the corresponding interrupt.
• TXEMPTY: Transmission Registers Empty Enable
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28.7.7
Name:
SPI Interrupt Disable Register
SPI_IDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
-
TXEMPTY
NSSR
7
6
5
4
3
2
1
0
TXBUFE
RXBUFF
ENDTX
ENDRX
OVRES
MODF
TDRE
RDRF
• RDRF: Receive Data Register Full Interrupt Disable
• TDRE: SPI Transmit Data Register Empty Interrupt Disable
• MODF: Mode Fault Error Interrupt Disable
• OVRES: Overrun Error Interrupt Disable
• ENDRX: End of Receive Buffer Interrupt Disable
• ENDTX: End of Transmit Buffer Interrupt Disable
• RXBUFF: Receive Buffer Full Interrupt Disable
• TXBUFE: Transmit Buffer Empty Interrupt Disable
• NSSR: NSS Rising Interrupt Disable
0 = No effect.
1 = Disables the corresponding interrupt.
• TXEMPTY: Transmission Registers Empty Disable
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28.7.8
Name:
SPI Interrupt Mask Register
SPI_IMR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
-
TXEMPTY
NSSR
7
6
5
4
3
2
1
0
TXBUFE
RXBUFF
ENDTX
ENDRX
OVRES
MODF
TDRE
RDRF
• RDRF: Receive Data Register Full Interrupt Mask
• TDRE: SPI Transmit Data Register Empty Interrupt Mask
• MODF: Mode Fault Error Interrupt Mask
• OVRES: Overrun Error Interrupt Mask
• ENDRX: End of Receive Buffer Interrupt Mask
• ENDTX: End of Transmit Buffer Interrupt Mask
• RXBUFF: Receive Buffer Full Interrupt Mask
• TXBUFE: Transmit Buffer Empty Interrupt Mask
• NSSR: NSS Rising Interrupt Mask
0 = The corresponding interrupt is not enabled.
1 = The corresponding interrupt is enabled.
• TXEMPTY: Transmission Registers Empty Mask
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28.7.9
Name:
SPI Chip Select Register
SPI_CSR0... SPI_CSR3
Access Type:
31
Read/Write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
DLYBCT
23
22
21
20
DLYBS
15
14
13
12
SCBR
7
6
5
4
BITS
3
2
1
0
CSAAT
–
NCPHA
CPOL
• CPOL: Clock Polarity
0 = The inactive state value of SPCK is logic level zero.
1 = The inactive state value of SPCK is logic level one.
CPOL is used to determine the inactive state value of the serial clock (SPCK). It is used with NCPHA to produce the
required clock/data relationship between master and slave devices.
• NCPHA: Clock Phase
0 = Data is changed on the leading edge of SPCK and captured on the following edge of SPCK.
1 = Data is captured on the leading edge of SPCK and changed on the following edge of SPCK.
NCPHA determines which edge of SPCK causes data to change and which edge causes data to be captured. NCPHA is
used with CPOL to produce the required clock/data relationship between master and slave devices.
• CSAAT: Chip Select Active After Transfer
0 = The Peripheral Chip Select Line rises as soon as the last transfer is achieved.
1 = The Peripheral Chip Select does not rise after the last transfer is achieved. It remains active until a new transfer is
requested on a different chip select.
• BITS: Bits Per Transfer
The BITS field determines the number of data bits transferred. Reserved values should not be used.
BITS
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
Bits Per Transfer
8
9
10
11
12
13
14
15
16
Reserved
Reserved
Reserved
Reserved
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BITS
1101
1110
1111
Bits Per Transfer
Reserved
Reserved
Reserved
• SCBR: Serial Clock Baud Rate
In Master Mode, the SPI Interface uses a modulus counter to derive the SPCK baud rate from the Master Clock MCK. The
Baud rate is selected by writing a value from 1 to 255 in the SCBR field. The following equations determine the SPCK baud
rate:
MCKSPCK Baudrate = -------------SCBR
Programming the SCBR field at 0 is forbidden. Triggering a transfer while SCBR is at 0 can lead to unpredictable results.
At reset, SCBR is 0 and the user has to program it at a valid value before performing the first transfer.
• DLYBS: Delay Before SPCK
This field defines the delay from NPCS valid to the first valid SPCK transition.
When DLYBS equals zero, the NPCS valid to SPCK transition is 1/2 the SPCK clock period.
Otherwise, the following equations determine the delay:
DLYBS
Delay Before SPCK = ------------------MCK
• DLYBCT: Delay Between Consecutive Transfers
This field defines the delay between two consecutive transfers with the same peripheral without removing the chip select.
The delay is always inserted after each transfer and before removing the chip select if needed.
When DLYBCT equals zero, no delay between consecutive transfers is inserted and the clock keeps its duty cycle over the
character transfers.
Otherwise, the following equation determines the delay:
32 × DLYBCT
Delay Between Consecutive Transfers = ------------------------------------MCK
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29. Two Wire Interface (TWI)
29.1
Overview
The Atmel Two-wire Interface (TWI) interconnects components on a unique two-wire bus, made up of one clock
line and one data line with speeds of up to 400 Kbits per second, based on a byte-oriented transfer format. It can
be used with any Atmel Two-wire Interface bus Serial EEPROM and I²C compatible device such as Real Time
Clock (RTC), Dot Matrix/Graphic LCD Controllers and Temperature Sensor, to name but a few. The TWI is programmable as a master or a slave with sequential or single-byte access. Multiple master capability is supported.
Arbitration of the bus is performed internally and puts the TWI in slave mode automatically if the bus arbitration is
lost.
A configurable baud rate generator permits the output data rate to be adapted to a wide range of core clock
frequencies.
Below, Table 29-1 lists the compatibility level of the Atmel Two-wire Interface in Master Mode and a full I2C compatible device.
Table 29-1.
Atmel TWI compatibility with i2C Standard
I2C Standard
Atmel TWI
Standard Mode Speed (100 KHz)
Supported
Fast Mode Speed (400 KHz)
Supported
7 or 10 bits Slave Addressing
Supported
(1)
START BYTE
Not Supported
Repeated Start (Sr) Condition
Supported
ACK and NACK Management
Supported
Slope control and input filtering (Fast mode)
Not Supported
Clock stretching
Supported
Note:
29.2
1. START + b000000001 + Ack + Sr
List of Abbreviations
Table 29-2.
Abbreviations
Abbreviation
Description
TWI
Two-wire Interface
A
Acknowledge
NA
Non Acknowledge
P
Stop
S
Start
Sr
Repeated Start
SADR
Slave Address
ADR
Any address except SADR
R
Read
W
Write
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29.3
Block Diagram
Figure 29-1. Block Diagram
APB Bridge
TWCK
PIO
PMC
MCK
TWD
Two-wire
Interface
TWI
Interrupt
29.4
AIC
Application Block Diagram
Figure 29-2. Application Block Diagram
VDD
Rp
Host with
TWI
Interface
Rp
TWD
TWCK
Atmel TWI
Serial EEPROM
Slave 1
I²C RTC
I²C LCD
Controller
I²C Temp.
Sensor
Slave 2
Slave 3
Slave 4
Rp: Pull up value as given by the I²C Standard
29.4.1
I/O Lines Description
Table 29-3.
I/O Lines Description
Pin Name
Pin Description
Type
TWD
Two-wire Serial Data
Input/Output
TWCK
Two-wire Serial Clock
Input/Output
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29.5
Product Dependencies
29.5.1
I/O Lines
Both TWD and TWCK are bidirectional lines, connected to a positive supply voltage via a current source or pull-up
resistor (see Figure 29-2 on page 312). When the bus is free, both lines are high. The output stages of devices
connected to the bus must have an open-drain or open-collector to perform the wired-AND function.
TWD and TWCK pins may be multiplexed with PIO lines. To enable the TWI, the programmer must perform the following step:
• Program the PIO controller to:
– Dedicate TWD and TWCK as peripheral lines.
29.5.2
Power Management
• Enable the peripheral clock.
The TWI interface may be clocked through the Power Management Controller (PMC), thus the programmer must
first configure the PMC to enable the TWI clock.
29.5.3
Interrupt
The TWI interface has an interrupt line connected to the Advanced Interrupt Controller (AIC). In order to handle
interrupts, the AIC must be programmed before configuring the TWI.
29.6
Functional Description
29.6.1
Transfer Format
The data put on the TWD line must be 8 bits long. Data is transferred MSB first; each byte must be followed by an
acknowledgement. The number of bytes per transfer is unlimited (see Figure 29-4).
Each transfer begins with a START condition and terminates with a STOP condition (see Figure 29-3).
• A high-to-low transition on the TWD line while TWCK is high defines the START condition.
• A low-to-high transition on the TWD line while TWCK is high defines a STOP condition.
Figure 29-3.
START and STOP Conditions
TWD
TWCK
Start
Stop
Figure 29-4. Transfer Format
TWD
TWCK
Start
Address
R/W
Ack
Data
Ack
Data
Ack
Stop
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29.6.2
Modes of Operation
The TWI has six modes of operation:
• Master transmitter mode
• Master receiver mode
• Multi-master transmitter mode
• Multi-master receiver mode
• Slave transmitter mode
• Slave receiver mode
These modes are described in the following chapters.
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29.7
Master Mode
29.7.1
Definition
The Master is the device that starts a transfer, generates a clock and stops it.
29.7.2
Application Block Diagram
Figure 29-5. Master Mode Typical Application Block Diagram
VDD
Rp
Host with
TWI
Interface
Rp
TWD
TWCK
Atmel TWI
Serial EEPROM
Slave 1
I²C RTC
I²C LCD
Controller
I²C Temp.
Sensor
Slave 2
Slave 3
Slave 4
Rp: Pull up value as given by the I²C Standard
29.7.3
Programming Master Mode
The following registers have to be programmed before entering Master mode:
1. DADR (+ IADRSZ + IADR if a 10 bit device is addressed): The device address is used to access slave
devices in read or write mode.
2. CKDIV + CHDIV + CLDIV: Clock Waveform.
3. SVDIS: Disable the slave mode.
4. MSEN: Enable the master mode.
29.7.4
Master Transmitter Mode
After the master initiates a Start condition when writing into the Transmit Holding Register, TWI_THR, it sends a 7bit slave address, configured in the Master Mode register (DADR in TWI_MMR), to notify the slave device. The bit
following the slave address indicates the transfer direction, 0 in this case (MREAD = 0 in TWI_MMR).
The TWI transfers require the slave to acknowledge each received byte. During the acknowledge clock pulse (9th
pulse), the master releases the data line (HIGH), enabling the slave to pull it down in order to generate the
acknowledge. The master polls the data line during this clock pulse and sets the Not Acknowledge bit (NACK) in
the status register if the slave does not acknowledge the byte. As with the other status bits, an interrupt can be
generated if enabled in the interrupt enable register (TWI_IER). If the slave acknowledges the byte, the data written in the TWI_THR, is then shifted in the internal shifter and transferred. When an acknowledge is detected, the
TXRDY bit is set until a new write in the TWI_THR.
When no more data is written into the TWI_THR, the master generates a stop condition to end the transfer. The
end of the complete transfer is marked by the TWI_TXCOMP bit set to one. See Figure 29-6, Figure 29-7, and Figure 29-8.
TXRDY is used as Transmit Ready for the PDC transmit channel.
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Figure 29-6. Master Write with One Data Byte
S
TWD
DADR
W
A
DATA
A
P
TXCOMP
TXRDY
STOP sent automaticaly
(ACK received and TXRDY = 1)
Write THR (DATA)
Figure 29-7. Master Write with Multiple Data Byte
S
TWD
DADR
W
A
DATA n
A
DATA n+5
A
DATA n+x
A
P
TXCOMP
TXRDY
Write THR (Data n)
Write THR (Data n+1)
Write THR (Data n+x)
Last data sent
STOP sent automaticaly
(ACK received and TXRDY = 1)
Figure 29-8. Master Write with One Byte Internal Address and Multiple Data Bytes
TWD S
DADR
W
A
IADR(7:0)
A
DATA n
A
DATA n+5
A
DATA n+x
A
P
TXCOMP
TXRDY
Write THR (Data n)
29.7.5
Write THR (Data n+1)
Write THR (Data n+x) STOP sent automaticaly
Last data sent (ACK received and TXRDY = 1)
Master Receiver Mode
The read sequence begins by setting the START bit. After the start condition has been sent, the master sends a 7bit slave address to notify the slave device. The bit following the slave address indicates the transfer direction, 1 in
this case (MREAD = 1 in TWI_MMR). During the acknowledge clock pulse (9th pulse), the master releases the
data line (HIGH), enabling the slave to pull it down in order to generate the acknowledge. The master polls the data
line during this clock pulse and sets the NACK bit in the status register if the slave does not acknowledge the byte.
If an acknowledge is received, the master is then ready to receive data from the slave. After data has been
received, the master sends an acknowledge condition to notify the slave that the data has been received except for
the last data, after the stop condition. See Figure 29-9. When the RXRDY bit is set in the status register, a character has been received in the receive-holding register (TWI_RHR). The RXRDY bit is reset when reading the
TWI_RHR.
When a single data byte read is performed, with or without internal address (IADR), the START and STOP bits
must be set at the same time. See Figure 29-9. When a multiple data byte read is performed, with or without interSAM7L128/64 [DATASHEET]
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nal address (IADR), the STOP bit must be set after the next-to-last data received. See Figure 29-10. For Internal
Address usage see Section 29.7.6.
Figure 29-9. Master Read with One Data Byte
TWD
S
DADR
R
A
DATA
N
P
TXCOMP
Write START &
STOP Bit
RXRDY
Read RHR
Figure 29-10. Master Read with Multiple Data Bytes
TWD
S
DADR
R
A
DATA n
A
DATA (n+1)
A
DATA (n+m)-1
A
DATA (n+m)
N
P
TXCOMP
Write START Bit
RXRDY
Read RHR
DATA n
Read RHR
DATA (n+1)
Read RHR
DATA (n+m)-1
Read RHR
DATA (n+m)
Write STOP Bit
after next-to-last data read
RXRDY is used as Receive Ready for the PDC receive channel.
29.7.6
Internal Address
The TWI interface can perform various transfer formats: Transfers with 7-bit slave address devices and 10-bit slave
address devices.
29.7.6.1
7-bit Slave Addressing
When Addressing 7-bit slave devices, the internal address bytes are used to perform random address (read or
write) accesses to reach one or more data bytes, within a memory page location in a serial memory, for example.
When performing read operations with an internal address, the TWI performs a write operation to set the internal
address into the slave device, and then switch to Master Receiver mode. Note that the second start condition (after
sending the IADR) is sometimes called “repeated start” (Sr) in I2C fully-compatible devices. See Figure 29-12. See
Figure 29-11 and Figure 29-13 for Master Write operation with internal address.
The three internal address bytes are configurable through the Master Mode register (TWI_MMR).
If the slave device supports only a 7-bit address, i.e. no internal address, IADRSZ must be set to 0.
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In the figures below the following abbreviations are used:
•S
Start
• Sr
Repeated Start
•P
Stop
•W
Write
•R
Read
•A
Acknowledge
•N
Not Acknowledge
• DADR
Device Address
• IADR
Internal Address
Figure 29-11. Master Write with One, Two or Three Bytes Internal Address and One Data Byte
Three bytes internal address
S
TWD
DADR
W
A
IADR(23:16)
A
IADR(15:8)
A
IADR(7:0)
A
W
A
IADR(15:8)
A
IADR(7:0)
A
DATA
A
W
A
IADR(7:0)
A
DATA
A
DATA
A
P
Two bytes internal address
S
TWD
DADR
P
One byte internal address
S
TWD
DADR
P
Figure 29-12. Master Read with One, Two or Three Bytes Internal Address and One Data Byte
Three bytes internal address
TWD
S
DADR
W
A
IADR(23:16)
A
IADR(15:8)
A
IADR(7:0)
A
Sr
DADR
R
A
DATA
N
P
Two bytes internal address
TWD
S
DADR
W
A
IADR(15:8)
A
IADR(7:0)
A
Sr
W
A
IADR(7:0)
A
Sr
R
A
DADR
R
A
DATA
N
P
One byte internal address
TWD
S
DADR
DADR
DATA
N
P
29.7.6.2
10-bit Slave Addressing
For a slave address higher than 7 bits, the user must configure the address size (IADRSZ) and set the other slave
address bits in the internal address register (TWI_IADR). The two remaining Internal address bytes, IADR[15:8]
and IADR[23:16] can be used the same as in 7-bit Slave Addressing.
Example: Address a 10-bit device (10-bit device address is b1 b2 b3 b4 b5 b6 b7 b8 b9 b10)
1. Program IADRSZ = 1,
2. Program DADR with 1 1 1 1 0 b1 b2 (b1 is the MSB of the 10-bit address, b2, etc.)
3. Program TWI_IADR with b3 b4 b5 b6 b7 b8 b9 b10 (b10 is the LSB of the 10-bit address)
Figure 29-13 below shows a byte write to an Atmel AT24LC512 EEPROM. This demonstrates the use of internal
addresses to access the device.
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Figure 29-13. Internal Address Usage
S
T
A
R
T
Device
Address
W
R
I
T
E
FIRST
WORD ADDRESS
SECOND
WORD ADDRESS
S
T
O
P
DATA
0
M
S
B
29.7.7
LR A
S / C
BW K
M
S
B
A
C
K
LA
SC
BK
A
C
K
Using the Peripheral DMA Controller (PDC)
The use of the PDC significantly reduces the CPU load.
To assure correct implementation, respect the following programming sequences:
29.7.7.1
1.
2.
3.
4.
5.
29.7.7.2
1.
2.
3.
4.
5.
29.7.8
Data Transmit with the PDC
Initialize the transmit PDC (memory pointers, size, etc.).
Configure the master mode (DADR, CKDIV, etc.).
Start the transfer by setting the PDC TXTEN bit.
Wait for the PDC end TX flag.
Disable the PDC by setting the PDC TXDIS bit.
Data Receive with the PDC
Initialize the receive PDC (memory pointers, size - 1, etc.).
Configure the master mode (DADR, CKDIV, etc.).
Start the transfer by setting the PDC RXTEN bit.
Wait for the PDC end RX flag.
Disable the PDC by setting the PDC RXDIS bit.
Read-write Flowcharts
The following flowcharts shown in Figure 29-15 on page 321, Figure 29-16 on page 322, Figure 29-17 on page
323, Figure 29-18 on page 324 and Figure 29-19 on page 325 give examples for read and write operations. A polling or interrupt method can be used to check the status bits. The interrupt method requires that the interrupt enable
register (TWI_IER) be configured first.
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Figure 29-14. TWI Write Operation with Single Data Byte without Internal Address
BEGIN
Set TWI clock
(CLDIV, CHDIV, CKDIV) in TWI_CWGR
(Needed only once)
Set the Control register:
- Master enable
TWI_CR = MSEN + SVDIS
Set the Master Mode register:
- Device slave address (DADR)
- Transfer direction bit
Write ==> bit MREAD = 0
Load Transmit register
TWI_THR = Data to send
Read Status register
No
TXRDY = 1?
Yes
Read Status register
No
TXCOMP = 1?
Yes
Transfer finished
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Figure 29-15. TWI Write Operation with Single Data Byte and Internal Address
BEGIN
Set TWI clock
(CLDIV, CHDIV, CKDIV) in TWI_CWGR
(Needed only once)
Set the Control register:
- Master enable
TWI_CR = MSEN + SVDIS
Set the Master Mode register:
- Device slave address (DADR)
- Internal address size (IADRSZ)
- Transfer direction bit
Write ==> bit MREAD = 0
Set the internal address
TWI_IADR = address
Load transmit register
TWI_THR = Data to send
Read Status register
No
TXRDY = 1?
Yes
Read Status register
TXCOMP = 1?
No
Yes
Transfer finished
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Figure 29-16. TWI Write Operation with Multiple Data Bytes with or without Internal Address
BEGIN
Set TWI clock
(CLDIV, CHDIV, CKDIV) in TWI_CWGR
(Needed only once)
Set the Control register:
- Master enable
TWI_CR = MSEN + SVDIS
Set the Master Mode register:
- Device slave address
- Internal address size (if IADR used)
- Transfer direction bit
Write ==> bit MREAD = 0
No
Internal address size = 0?
Set the internal address
TWI_IADR = address
Yes
Load Transmit register
TWI_THR = Data to send
Read Status register
TWI_THR = data to send
No
TXRDY = 1?
Yes
Data to send?
Yes
Read Status register
Yes
No
TXCOMP = 1?
END
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Figure 29-17. TWI Read Operation with Single Data Byte without Internal Address
BEGIN
Set TWI clock
(CLDIV, CHDIV, CKDIV) in TWI_CWGR
(Needed only once)
Set the Control register:
- Master enable
TWI_CR = MSEN + SVDIS
Set the Master Mode register:
- Device slave address
- Transfer direction bit
Read ==> bit MREAD = 1
Start the transfer
TWI_CR = START | STOP
Read status register
RXRDY = 1?
No
Yes
Read Receive Holding Register
Read Status register
No
TXCOMP = 1?
Yes
END
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Figure 29-18. TWI Read Operation with Single Data Byte and Internal Address
BEGIN
Set TWI clock
(CLDIV, CHDIV, CKDIV) in TWI_CWGR
(Needed only once)
Set the Control register:
- Master enable
TWI_CR = MSEN + SVDIS
Set the Master Mode register:
- Device slave address
- Internal address size (IADRSZ)
- Transfer direction bit
Read ==> bit MREAD = 1
Set the internal address
TWI_IADR = address
Start the transfer
TWI_CR = START | STOP
Read Status register
No
RXRDY = 1?
Yes
Read Receive Holding register
Read Status register
No
TXCOMP = 1?
Yes
END
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Figure 29-19. TWI Read Operation with Multiple Data Bytes with or without Internal Address
BEGIN
Set TWI clock
(CLDIV, CHDIV, CKDIV) in TWI_CWGR
(Needed only once)
Set the Control register:
- Master enable
TWI_CR = MSEN + SVDIS
Set the Master Mode register:
- Device slave address
- Internal address size (if IADR used)
- Transfer direction bit
Read ==> bit MREAD = 1
Internal address size = 0?
Set the internal address
TWI_IADR = address
Yes
Start the transfer
TWI_CR = START
Read Status register
RXRDY = 1?
No
Yes
Read Receive Holding register (TWI_RHR)
No
Last data to read
but one?
Yes
Stop the transfer
TWI_CR = STOP
Read Status register
No
RXRDY = 1?
Yes
Read Receive Holding register (TWI_RHR)
Read status register
TXCOMP = 1?
No
Yes
END
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29.8
Multi-master Mode
29.8.1
Definition
More than one master may handle the bus at the same time without data corruption by using arbitration.
Arbitration starts as soon as two or more masters place information on the bus at the same time, and stops (arbitration is lost) for the master that intends to send a logical one while the other master sends a logical zero.
As soon as arbitration is lost by a master, it stops sending data and listens to the bus in order to detect a stop.
When the stop is detected, the master who has lost arbitration may put its data on the bus by respecting arbitration.
Arbitration is illustrated in Figure 29-21 on page 327.
29.8.2
Different Multi-master Modes
Two multi-master modes may be distinguished:
1. TWI is considered as a Master only and will never be addressed.
2. TWI may be either a Master or a Slave and may be addressed.
Note:
In both Multi-master modes arbitration is supported.
29.8.2.1
TW
I as Master Only
In this mode, TWI is considered as a Master only (MSEN is always at one) and must be driven like a Master with
the ARBLST (ARBitration Lost) flag in addition.
If arbitration is lost (ARBLST = 1), the programmer must reinitiate the data transfer.
If the user starts a transfer (ex.: DADR + START + W + Write in THR) and if the bus is busy, the TWI automatically
waits for a STOP condition on the bus to initiate the transfer (see Figure 29-20 on page 327).
Note:
The state of the bus (busy or free) is not indicated in the user interface.
29.8.2.2
TW
I as Master or Slave
The automatic reversal from Master to Slave is not supported in case of a lost arbitration.
Then, in the case where TWI may be either a Master or a Slave, the programmer must manage the pseudo Multimaster mode described in the steps below.
1. Program TWI in Slave mode (SADR + MSDIS + SVEN) and perform Slave Access (if TWI is addressed).
2. If TWI has to be set in Master mode, wait until TXCOMP flag is at 1.
3. Program Master mode (DADR + SVDIS + MSEN) and start the transfer (ex: START + Write in THR).
4. As soon as the Master mode is enabled, TWI scans the bus in order to detect if it is busy or free. When the
bus is considered as free, TWI initiates the transfer.
5. As soon as the transfer is initiated and until a STOP condition is sent, the arbitration becomes relevant
and the user must monitor the ARBLST flag.
6. If the arbitration is lost (ARBLST is set to 1), the user must program the TWI in Slave mode in the case
where the Master that won the arbitration wanted to access the TWI.
7. If TWI has to be set in Slave mode, wait until TXCOMP flag is at 1 and then program the Slave mode.
Note:
In the case where the arbitration is lost and TWI is addressed, TWI will not acknowledge even if it is programmed in
Slave mode as soon as ARBLST is set to 1. Then, the Master must repeat SADR.
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Figure 29-20. Programmer Sends Data While the Bus is Busy
TWCK
START sent by the TWI
STOP sent by the master
DATA sent by a master
TWD
DATA sent by the TWI
Bus is busy
Bus is free
Transfer is kept
TWI DATA transfer
A transfer is programmed
(DADR + W + START + Write THR)
Bus is considered as free
Transfer is initiated
Figure 29-21. Arbitration Cases
TWCK
TWD
TWCK
Data from a Master
S
1
0
0 1 1
Data from TWI
S
1
0
1
TWD
S
1
0
0
P
Arbitration is lost
TWI stops sending data
1 1
Data from the master
P
Arbitration is lost
S
1
0
1
S
1
0
0 1
1
S
1
0
0 1
1
The master stops sending data
Data from the TWI
ARBLST
Bus is busy
Transfer is kept
TWI DATA transfer
A transfer is programmed
(DADR + W + START + Write THR)
Bus is free
Transfer is stopped
Transfer is programmed again
(DADR + W + START + Write THR)
Bus is considered as free
Transfer is initiated
The flowchart shown in Figure 29-22 on page 328 gives an example of read and write operations in Multi-master
mode.
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Figure 29-22. Multi-master Flowchart
START
Programm the SLAVE mode:
SADR + MSDIS + SVEN
Read Status Register
SVACC = 1 ?
Yes
GACC = 1 ?
No
No
No
SVREAD = 0 ?
No
EOSACC = 1 ?
TXRDY= 1 ?
Yes
Yes
Yes
No
Write in TWI_THR
TXCOMP = 1 ?
No
RXRDY= 0 ?
Yes
No
No
Yes
Read TWI_RHR
Need to perform
a master access ?
GENERAL CALL TREATMENT
Yes
Decoding of the
programming sequence
No
Prog seq
OK ?
Change SADR
Program the Master mode
DADR + SVDIS + MSEN + CLK + R / W
Read Status Register
Yes
No
ARBLST = 1 ?
Yes
Yes
MREAD = 1 ?
RXRDY= 0 ?
No
TXRDY= 0 ?
No
Read TWI_RHR
Yes
Yes
No
Data to read?
Data to send ?
No
Yes
Write in TWI_THR
No
Stop transfer
Read Status Register
Yes
TXCOMP = 0 ?
No
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29.9
Slave Mode
29.9.1
Definition
The Slave Mode is defined as a mode where the device receives the clock and the address from another device
called the master.
In this mode, the device never initiates and never completes the transmission (START, REPEATED_START and
STOP conditions are always provided by the master).
29.9.2
Application Block Diagram
Figure 29-23. Slave Mode Typical Application Block Diagram
VDD
R
Master
Host with
TWI
Interface
29.9.3
R
TWD
TWCK
Host with TWI
Interface
Host with TWI
Interface
LCD Controller
Slave 1
Slave 2
Slave 3
Programming Slave Mode
The following fields must be programmed before entering Slave mode:
1. SADR (TWI_SMR): The slave device address is used in order to be accessed by master devices in read
or write mode.
2. MSDIS (TWI_CR): Disable the master mode.
3. SVEN (TWI_CR): Enable the slave mode.
As the device receives the clock, values written in TWI_CWGR are not taken into account.
29.9.4
Receiving Data
After a Start or Repeated Start condition is detected and if the address sent by the Master matches with the Slave
address programmed in the SADR (Slave ADdress) field, SVACC (Slave ACCess) flag is set and SVREAD (Slave
READ) indicates the direction of the transfer.
SVACC remains high until a STOP condition or a repeated START is detected. When such a condition is detected,
EOSACC (End Of Slave ACCess) flag is set.
29.9.4.1
Read Sequence
In the case of a Read sequence (SVREAD is high), TWI transfers data written in the TWI_THR (TWI Transmit
Holding Register) until a STOP condition or a REPEATED_START + an address different from SADR is detected.
Note that at the end of the read sequence TXCOMP (Transmission Complete) flag is set and SVACC reset.
As soon as data is written in the TWI_THR, TXRDY (Transmit Holding Register Ready) flag is reset, and it is set
when the shift register is empty and the sent data acknowledged or not. If the data is not acknowledged, the NACK
flag is set.
Note that a STOP or a repeated START always follows a NACK.
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See Figure 29-24 on page 331.
29.9.4.2
W
rite Sequence
In the case of a Write sequence (SVREAD is low), the RXRDY (Receive Holding Register Ready) flag is set as
soon as a character has been received in the TWI_RHR (TWI Receive Holding Register). RXRDY is reset when
reading the TWI_RHR.
TWI continues receiving data until a STOP condition or a REPEATED_START + an address different from SADR
is detected. Note that at the end of the write sequence TXCOMP flag is set and SVACC reset.
See Figure 29-25 on page 331.
29.9.4.3
Clock Synchronization Sequence
In the case where TWI_THR or TWI_RHR is not written/read in time, TWI performs a clock synchronization.
Clock stretching information is given by the SCLWS (Clock Wait state) bit.
See Figure 29-27 on page 333 and Figure 29-28 on page 334.
29.9.4.4
General Call
In the case where a GENERAL CALL is performed, GACC (General Call ACCess) flag is set.
After GACC is set, it is up to the programmer to interpret the meaning of the GENERAL CALL and to decode the
new address programming sequence.
See Figure 29-26 on page 332.
29.9.4.5
PDC
As it is impossible to know the exact number of data to receive/send, the use of PDC is NOT recommended in
SLAVE mode.
29.9.5
Data Transfer
29.9.5.1
Read Operation
The read mode is defined as a data requirement from the master.
After a START or a REPEATED START condition is detected, the decoding of the address starts. If the slave
address (SADR) is decoded, SVACC is set and SVREAD indicates the direction of the transfer.
Until a STOP or REPEATED START condition is detected, TWI continues sending data loaded in the TWI_THR
register.
If a STOP condition or a REPEATED START + an address different from SADR is detected, SVACC is reset.
Figure 29-24 on page 331 describes the write operation.
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Figure 29-24. Read Access Ordered by a MASTER
SADR matches,
TWI answers with an ACK
SADR does not match,
TWI answers with a NACK
TWD
S
ADR
R
NA
DATA
NA
P/S/Sr
SADR R
A
DATA
A
ACK/NACK from the Master
A
DATA
NA
S/Sr
TXRDY
Read RHR
Write THR
NACK
SVACC
SVREAD
SVREAD has to be taken into account only while SVACC is active
EOSVACC
Notes:
1. When SVACC is low, the state of SVREAD becomes irrelevant.
2. TXRDY is reset when data has been transmitted from TWI_THR to the shift register and set when this data has been
acknowledged or non acknowledged.
29.9.5.2
W
rite Operation
The write mode is defined as a data transmission from the master.
After a START or a REPEATED START, the decoding of the address starts. If the slave address is decoded,
SVACC is set and SVREAD indicates the direction of the transfer (SVREAD is low in this case).
Until a STOP or REPEATED START condition is detected, TWI stores the received data in the TWI_RHR register.
If a STOP condition or a REPEATED START + an address different from SADR is detected, SVACC is reset.
Figure 29-25 on page 331 describes the Write operation.
Figure 29-25. Write Access Ordered by a Master
SADR does not match,
TWI answers with a NACK
TWD
S
ADR
W
NA
DATA
NA
SADR matches,
TWI answers with an ACK
P/S/Sr
SADR W
A
DATA
A
Read RHR
A
DATA
NA
S/Sr
RXRDY
SVACC
SVREAD
SVREAD has to be taken into account only while SVACC is active
EOSVACC
Notes:
1. When SVACC is low, the state of SVREAD becomes irrelevant.
2. RXRDY is set when data has been transmitted from the shift register to the TWI_RHR and reset when this data is read.
29.9.5.3
General Call
The general call is performed in order to change the address of the slave.
If a GENERAL CALL is detected, GACC is set.
After the detection of General Call, it is up to the programmer to decode the commands which come afterwards.
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In case of a WRITE command, the programmer has to decode the programming sequence and program a new
SADR if the programming sequence matches.
Figure 29-26 on page 332 describes the General Call access.
Figure 29-26. Master Performs a General Call
0000000 + W
TXD
S
GENERAL CALL
RESET command = 00000110X
WRITE command = 00000100X
A
Reset or write DADD
A
DATA1
A
DATA2
A
New SADR
A
P
New SADR
Programming sequence
GCACC
Reset after read
SVACC
Note:
This method allows the user to create an own programming sequence by choosing the programming bytes and the
number of them. The programming sequence has to be provided to the master.
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29.9.5.4
Clock Synchronization
In both read and write modes, it may happen that TWI_THR/TWI_RHR buffer is not filled /emptied before the emission/reception of a new character. In this case, to avoid sending/receiving undesired data, a clock stretching
mechanism is implemented.
29.9.5.5
Clock Synchronization in Read Mode
The clock is tied low if the shift register is empty and if a STOP or REPEATED START condition was not detected.
It is tied low until the shift register is loaded.
Figure 29-27 on page 333 describes the clock synchronization in Read mode.
Figure 29-27. Clock Synchronization in Read Mode
TWI_THR
S
SADR
R
DATA1
1
DATA0
A
DATA0
A
DATA1
DATA2
A
DATA2
XXXXXXX
NA
S
2
TWCK
Write THR
CLOCK is tied low by the TWI
as long as THR is empty
SCLWS
TXRDY
SVACC
SVREAD
As soon as a START is detected
TXCOMP
Ack or Nack from the master
TWI_THR is transmitted to the shift register
Notes:
1
The data is memorized in TWI_THR until a new value is written
2
The clock is stretched after the ACK, the state of TWD is undefined during clock stretching
1. TXRDY is reset when data has been written in the TWI_THR to the shift register and set when this data has been acknowledged or non acknowledged.
2. At the end of the read sequence, TXCOMP is set after a STOP or after a REPEATED_START + an address different from
SADR.
3. SCLWS is automatically set when the clock synchronization mechanism is started.
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29.9.5.6
Clock Synchronization in W
rite Mode
The clock is tied low if the shift register and the TWI_RHR is full. If a STOP or REPEATED_START condition was
not detected, it is tied low until TWI_RHR is read.
Figure 29-28 on page 334 describes the clock synchronization in Read mode.
Figure 29-28. Clock Synchronization in Write Mode
TWCK
CLOCK is tied low by the TWI as long as RHR is full
TWD
S
SADR
W
A
DATA0
TWI_RHR
A
DATA1
A
DATA0 is not read in the RHR
DATA2
DATA1
NA
S
ADR
DATA2
SCLWS
SCL is stretched on the last bit of DATA1
RXRDY
Rd DATA0
Rd DATA1
Rd DATA2
SVACC
SVREAD
TXCOMP
Notes:
As soon as a START is detected
1. At the end of the read sequence, TXCOMP is set after a STOP or after a REPEATED_START + an address different from
SADR.
2. SCLWS is automatically set when the clock synchronization mechanism is started and automatically reset when the mechanism is finished.
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29.9.5.7
Reversal after a Repeated Start
29.9.5.8
Reversal of Read to W
rite
The master initiates the communication by a read command and finishes it by a write command.
Figure 29-29 on page 335 describes the repeated start + reversal from Read to Write mode.
Figure 29-29. Repeated Start + Reversal from Read to Write Mode
TWI_THR
TWD
DATA0
S
SADR
R
A
DATA0
DATA1
A
DATA1
NA
Sr
SADR
W
A
DATA2
TWI_RHR
A
DATA3
DATA2
A
P
DATA3
SVACC
SVREAD
TXRDY
RXRDY
EOSACC
Cleared after read
As soon as a START is detected
TXCOMP
1. TXCOMP is only set at the end of the transmission because after the repeated start, SADR is detected again.
29.9.5.9
Reversal of W
rite to Read
The master initiates the communication by a write command and finishes it by a read command.Figure 29-30 on
page 335 describes the repeated start + reversal from Write to Read mode.
Figure 29-30. Repeated Start + Reversal from Write to Read Mode
DATA2
TWI_THR
TWD
S
SADR
W
A
DATA0
TWI_RHR
A
DATA1
DATA0
A
Sr
SADR
R
A
DATA3
DATA2
A
DATA3
NA
P
DATA1
SVACC
SVREAD
TXRDY
RXRDY
EOSACC
TXCOMP
Notes:
Read TWI_RHR
Cleared after read
As soon as a START is detected
1. In this case, if TWI_THR has not been written at the end of the read command, the clock is automatically stretched before
the ACK.
2. TXCOMP is only set at the end of the transmission because after the repeated start, SADR is detected again.
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29.9.6
Read Write Flowcharts
The flowchart shown in Figure 29-31 on page 336 gives an example of read and write operations in Slave mode. A
polling or interrupt method can be used to check the status bits. The interrupt method requires that the interrupt
enable register (TWI_IER) be configured first.
Figure 29-31. Read Write Flowchart in Slave Mode
Set the SLAVE mode:
SADR + MSDIS + SVEN
Read Status Register
SVACC = 1 ?
No
No
EOSACC = 1 ?
GACC = 1 ?
No
SVREAD = 0 ?
TXRDY= 1 ?
No
No
Write in TWI_THR
No
TXCOMP = 1 ?
RXRDY= 0 ?
No
END
Read TWI_RHR
GENERAL CALL TREATMENT
Decoding of the
programming sequence
Prog seq
OK ?
No
Change SADR
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29.10 Two-wire Interface (TWI) User Interface
Table 29-4.
Register Mapping
Offset
Register
Name
Access
Reset
0x00
Control Register
TWI_CR
Write-only
N/A
0x04
Master Mode Register
TWI_MMR
Read-write
0x00000000
0x08
Slave Mode Register
TWI_SMR
Read-write
0x00000000
0x0C
Internal Address Register
TWI_IADR
Read-write
0x00000000
0x10
Clock Waveform Generator Register
TWI_CWGR
Read-write
0x00000000
0x20
Status Register
TWI_SR
Read-only
0x0000F009
0x24
Interrupt Enable Register
TWI_IER
Write-only
N/A
0x28
Interrupt Disable Register
TWI_IDR
Write-only
N/A
0x2C
Interrupt Mask Register
TWI_IMR
Read-only
0x00000000
0x30
Receive Holding Register
TWI_RHR
Read-only
0x00000000
0x34
Transmit Holding Register
TWI_THR
Write-only
0x00000000
0x38 - 0xFC
Reserved
–
–
–
0x100 - 0x124
Reserved for the PDC
–
–
–
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29.10.1
Name:
TWI Control Register
TWI_CR
Access:
Write-only
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
SWRST
6
–
5
SVDIS
4
SVEN
3
MSDIS
2
MSEN
1
STOP
0
START
• START: Send a START Condition
0 = No effect.
1 = A frame beginning with a START bit is transmitted according to the features defined in the mode register.
This action is necessary when the TWI peripheral wants to read data from a slave. When configured in Master Mode with a
write operation, a frame is sent as soon as the user writes a character in the Transmit Holding Register (TWI_THR).
• STOP: Send a STOP Condition
0 = No effect.
1 = STOP Condition is sent just after completing the current byte transmission in master read mode.
– In single data byte master read, the START and STOP must both be set.
– In multiple data bytes master read, the STOP must be set after the last data received but one.
– In master read mode, if a NACK bit is received, the STOP is automatically performed.
– In multiple data write operation, when both THR and shift register are empty, a STOP condition is automatically
sent.
• MSEN: TWI Master Mode Enabled
0 = No effect.
1 = If MSDIS = 0, the master mode is enabled.
Note:
Switching from Slave to Master mode is only permitted when TXCOMP = 1.
• MSDIS: TWI Master Mode Disabled
0 = No effect.
1 = The master mode is disabled, all pending data is transmitted. The shifter and holding characters (if it contains data) are
transmitted in case of write operation. In read operation, the character being transferred must be completely received
before disabling.
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• SVEN: TWI Slave Mode Enabled
0 = No effect.
1 = If SVDIS = 0, the slave mode is enabled.
Note:
Switching from Master to Slave mode is only permitted when TXCOMP = 1.
• SVDIS: TWI Slave Mode Disabled
0 = No effect.
1 = The slave mode is disabled. The shifter and holding characters (if it contains data) are transmitted in case of read operation. In write operation, the character being transferred must be completely received before disabling.
• SWRST: Software Reset
0 = No effect.
1 = Equivalent to a system reset.
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29.10.2
Name:
TWI Master Mode Register
TWI_MMR
Access:
Read-write
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
21
20
19
DADR
18
17
16
15
–
14
–
13
–
12
MREAD
11
–
10
–
9
8
7
–
6
–
5
–
4
–
3
–
2
–
1
–
IADRSZ
0
–
• IADRSZ: Internal Device Address Size
IADRSZ[9:8]
0
0
No internal device address
0
1
One-byte internal device address
1
0
Two-byte internal device address
1
1
Three-byte internal device address
• MREAD: Master Read Direction
0 = Master write direction.
1 = Master read direction.
• DADR: Device Address
The device address is used to access slave devices in read or write mode. Those bits are only used in Master mode.
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29.10.3
Name:
Access:
TWI Slave Mode Register
TWI_SMR
Read-write
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
21
20
19
SADR
18
17
16
15
–
14
–
13
–
12
–
11
–
10
–
9
8
7
–
6
–
5
–
4
–
3
–
2
–
1
–
0
–
• SADR: Slave Address
The slave device address is used in Slave mode in order to be accessed by master devices in read or write mode.
SADR must be programmed before enabling the Slave mode or after a general call. Writes at other times have no effect.
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29.10.4
Name:
Access:
TWI Internal Address Register
TWI_IADR
Read-write
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
23
22
21
20
27
–
26
–
25
–
24
–
19
18
17
16
11
10
9
8
3
2
1
0
IADR
15
14
13
12
IADR
7
6
5
4
IADR
• IADR: Internal Address
0, 1, 2 or 3 bytes depending on IADRSZ.
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29.10.5
Name:
Access:
TWI Clock Waveform Generator Register
TWI_CWGR
Read-write
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
22
21
20
19
18
17
CKDIV
16
15
14
13
12
11
10
9
8
3
2
1
0
CHDIV
7
6
5
4
CLDIV
TWI_CWGR is only used in Master mode.
• CLDIV: Clock Low Divider
The SCL low period is defined as follows:
T low = ( ( CLDIV × 2
CKDIV
) + 4 ) × T MCK
• CHDIV: Clock High Divider
The SCL high period is defined as follows:
T high = ( ( CHDIV × 2
CKDIV
) + 4 ) × T MCK
• CKDIV: Clock Divider
The CKDIV is used to increase both SCL high and low periods.
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29.10.6
Name:
TWI Status Register
TWI_SR
Access:
Read-only
Reset Value: 0x0000F009
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
TXBUFE
14
RXBUFF
13
ENDTX
12
ENDRX
11
EOSACC
10
SCLWS
9
ARBLST
8
NACK
7
–
6
OVRE
5
GACC
4
SVACC
3
SVREAD
2
TXRDY
1
RXRDY
0
TXCOMP
• TXCOMP: Transmission Completed (automatically set / reset)
TXCOMP used in Master mode:
0 = During the length of the current frame.
1 = When both holding and shifter registers are empty and STOP condition has been sent.
TXCOMP behavior in Master mode can be seen in Figure 29-8 on page 316 and in Figure 29-10 on page 317.
TXCOMP used in Slave mode:
0 = As soon as a Start is detected.
1 = After a Stop or a Repeated Start + an address different from SADR is detected.
TXCOMP behavior in Slave mode can be seen in Figure 29-27 on page 333, Figure 29-28 on page 334, Figure 29-29 on
page 335 and Figure 29-30 on page 335.
• RXRDY: Receive Holding Register Ready (automatically set / reset)
0 = No character has been received since the last TWI_RHR read operation.
1 = A byte has been received in the TWI_RHR since the last read.
RXRDY behavior in Master mode can be seen in Figure 29-10 on page 317.
RXRDY behavior in Slave mode can be seen in Figure 29-25 on page 331, Figure 29-28 on page 334, Figure 29-29 on
page 335 and Figure 29-30 on page 335.
• TXRDY: Transmit Holding Register Ready (automatically set / reset)
TXRDY used in Master mode:
0 = The transmit holding register has not been transferred into shift register. Set to 0 when writing into TWI_THR register.
1 = As soon as a data byte is transferred from TWI_THR to internal shifter or if a NACK error is detected, TXRDY is set at
the same time as TXCOMP and NACK. TXRDY is also set when MSEN is set (enable TWI).
TXRDY behavior in Master mode can be seen in Figure 29-8 on page 316.
TXRDY used in Slave mode:
0 = As soon as data is written in the TWI_THR, until this data has been transmitted and acknowledged (ACK or NACK).
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1 = It indicates that the TWI_THR is empty and that data has been transmitted and acknowledged.
If TXRDY is high and if a NACK has been detected, the transmission will be stopped. Thus when TRDY = NACK = 1, the
programmer must not fill TWI_THR to avoid losing it.
TXRDY behavior in Slave mode can be seen in Figure 29-24 on page 331, Figure 29-27 on page 333, Figure 29-29 on
page 335 and Figure 29-30 on page 335.
• SVREAD: Slave Read (automatically set / reset)
This bit is only used in Slave mode. When SVACC is low (no Slave access has been detected) SVREAD is irrelevant.
0 = Indicates that a write access is performed by a Master.
1 = Indicates that a read access is performed by a Master.
SVREAD behavior can be seen in Figure 29-24 on page 331, Figure 29-25 on page 331, Figure 29-29 on page 335 and
Figure 29-30 on page 335.
• SVACC: Slave Access (automatically set / reset)
This bit is only used in Slave mode.
0 = TWI is not addressed. SVACC is automatically cleared after a NACK or a STOP condition is detected.
1 = Indicates that the address decoding sequence has matched (A Master has sent SADR). SVACC remains high until a
NACK or a STOP condition is detected.
SVACC behavior can be seen in Figure 29-24 on page 331, Figure 29-25 on page 331, Figure 29-29 on page 335 and Figure 29-30 on page 335.
• GACC: General Call Access (clear on read)
This bit is only used in Slave mode.
0 = No General Call has been detected.
1 = A General Call has been detected. After the detection of General Call, the programmer decoded the commands that follow and the programming sequence.
GACC behavior can be seen in Figure 29-26 on page 332.
• OVRE: Overrun Error (clear on read)
This bit is only used in Master mode.
0 = TWI_RHR has not been loaded while RXRDY was set
1 = TWI_RHR has been loaded while RXRDY was set. Reset by read in TWI_SR when TXCOMP is set.
• NACK: Not Acknowledged (clear on read)
NACK used in Master mode:
0 = Each data byte has been correctly received by the far-end side TWI slave component.
1 = A data byte has not been acknowledged by the slave component. Set at the same time as TXCOMP.
NACK used in Slave Read mode:
0 = Each data byte has been correctly received by the Master.
1 = In read mode, a data byte has not been acknowledged by the Master. When NACK is set the programmer must not fill
TWI_THR even if TXRDY is set, because it means that the Master will stop the data transfer or re initiate it.
Note that in Slave Write mode all data are acknowledged by the TWI.
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• ARBLST: Arbitration Lost (clear on read)
This bit is only used in Master mode.
0: Arbitration won.
1: Arbitration lost. Another master of the TWI bus has won the multi-master arbitration. TXCOMP is set at the same time.
• SCLWS: Clock Wait State (automatically set / reset)
This bit is only used in Slave mode.
0 = The clock is not stretched.
1 = The clock is stretched. TWI_THR / TWI_RHR buffer is not filled / emptied before the emission / reception of a new
character.
SCLW
S behavior can be seen in Figure 29-27 on page 333 and Figure 29-28 on page 334.
• EOSACC: End Of Slave Access (clear on read)
This bit is only used in Slave mode.
0 = A slave access is being performing.
1 = The Slave Access is finished. End Of Slave Access is automatically set as soon as SVACC is reset.
EOSACC behavior can be seen in Figure 29-29 on page 335 and Figure 29-30 on page 335
• ENDRX: End of RX buffer
This bit is only used in Master mode.
0 = The Receive Counter Register has not reached 0 since the last write in TWI_RCR or TWI_RNCR.
1 = The Receive Counter Register has reached 0 since the last write in TWI_RCR or TWI_RNCR.
• ENDTX: End of TX buffer
This bit is only used in Master mode.
0 = The Transmit Counter Register has not reached 0 since the last write in TWI_TCR or TWI_TNCR.
1 = The Transmit Counter Register has reached 0 since the last write in TWI_TCR or TWI_TNCR.
• RXBUFF: RX Buffer Full
This bit is only used in Master mode.
0 = TWI_RCR or TWI_RNCR have a value other than 0.
1 = Both TWI_RCR and TWI_RNCR have a value of 0.
• TXBUFE: TX Buffer Empty
This bit is only used in Master mode.
0 = TWI_TCR or TWI_TNCR have a value other than 0.
1 = Both TWI_TCR and TWI_TNCR have a value of 0.
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29.10.7
Name:
TWI Interrupt Enable Register
TWI_IER
Access:
Write-only
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
TXBUFE
14
RXBUFF
13
ENDTX
12
ENDRX
11
EOSACC
10
SCL_WS
9
ARBLST
8
NACK
7
–
6
OVRE
5
GACC
4
SVACC
3
–
2
TXRDY
1
RXRDY
0
TXCOMP
• TXCOMP: Transmission Completed Interrupt Enable
• RXRDY: Receive Holding Register Ready Interrupt Enable
• TXRDY: Transmit Holding Register Ready Interrupt Enable
• SVACC: Slave Access Interrupt Enable
• GACC: General Call Access Interrupt Enable
• OVRE: Overrun Error Interrupt Enable
• NACK: Not Acknowledge Interrupt Enable
• ARBLST: Arbitration Lost Interrupt Enable
• SCL_WS: Clock Wait State Interrupt Enable
• EOSACC: End Of Slave Access Interrupt Enable
• ENDRX: End of Receive Buffer Interrupt Enable
• ENDTX: End of Transmit Buffer Interrupt Enable
• RXBUFF: Receive Buffer Full Interrupt Enable
• TXBUFE: Transmit Buffer Empty Interrupt Enable
0 = No effect.
1 = Enables the corresponding interrupt.
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29.10.8
Name:
TWI Interrupt Disable Register
TWI_IDR
Access:
Write-only
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
TXBUFE
14
RXBUFF
13
ENDTX
12
ENDRX
11
EOSACC
10
SCL_WS
9
ARBLST
8
NACK
7
–
6
OVRE
5
GACC
4
SVACC
3
–
2
TXRDY
1
RXRDY
0
TXCOMP
• TXCOMP: Transmission Completed Interrupt Disable
• RXRDY: Receive Holding Register Ready Interrupt Disable
• TXRDY: Transmit Holding Register Ready Interrupt Disable
• SVACC: Slave Access Interrupt Disable
• GACC: General Call Access Interrupt Disable
• OVRE: Overrun Error Interrupt Disable
• NACK: Not Acknowledge Interrupt Disable
• ARBLST: Arbitration Lost Interrupt Disable
• SCL_WS: Clock Wait State Interrupt Disable
• EOSACC: End Of Slave Access Interrupt Disable
• ENDRX: End of Receive Buffer Interrupt Disable
• ENDTX: End of Transmit Buffer Interrupt Disable
• RXBUFF: Receive Buffer Full Interrupt Disable
• TXBUFE: Transmit Buffer Empty Interrupt Disable
0 = No effect.
1 = Disables the corresponding interrupt.
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29.10.9
Name:
TWI Interrupt Mask Register
TWI_IMR
Access:
Read-only
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
TXBUFE
14
RXBUFF
13
ENDTX
12
ENDRX
11
EOSACC
10
SCL_WS
9
ARBLST
8
NACK
7
–
6
OVRE
5
GACC
4
SVACC
3
–
2
TXRDY
1
RXRDY
0
TXCOMP
• TXCOMP: Transmission Completed Interrupt Mask
• RXRDY: Receive Holding Register Ready Interrupt Mask
• TXRDY: Transmit Holding Register Ready Interrupt Mask
• SVACC: Slave Access Interrupt Mask
• GACC: General Call Access Interrupt Mask
• OVRE: Overrun Error Interrupt Mask
• NACK: Not Acknowledge Interrupt Mask
• ARBLST: Arbitration Lost Interrupt Mask
• SCL_WS: Clock Wait State Interrupt Mask
• EOSACC: End Of Slave Access Interrupt Mask
• ENDRX: End of Receive Buffer Interrupt Mask
• ENDTX: End of Transmit Buffer Interrupt Mask
• RXBUFF: Receive Buffer Full Interrupt Mask
• TXBUFE: Transmit Buffer Empty Interrupt Mask
0 = The corresponding interrupt is disabled.
1 = The corresponding interrupt is enabled.
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29.10.10 TWI Receive Holding Register
Name:
TWI_RHR
Access:
Read-only
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
6
5
4
3
2
1
0
RXDATA
• RXDATA: Master or Slave Receive Holding Data
29.10.11 TWI Transmit Holding Register
Name:
TWI_THR
Access:
Read-write
Reset Value: 0x00000000
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
6
5
4
3
2
1
0
TXDATA
• TXDATA: Master or Slave Transmit Holding Data
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30. Universal Synchronous Asynchronous Receiver Transceiver (USART)
30.1
Overview
The Universal Synchronous Asynchronous Receiver Transceiver (USART) provides one full duplex universal synchronous asynchronous serial link. Data frame format is widely programmable (data length, parity, number of stop
bits) to support a maximum of standards. The receiver implements parity error, framing error and overrun error
detection. The receiver time-out enables handling variable-length frames and the transmitter timeguard facilitates
communications with slow remote devices. Multidrop communications are also supported through address bit handling in reception and transmission.
The USART features three test modes: remote loopback, local loopback and automatic echo.
The USART supports specific operating modes providing interfaces on RS485 buses, with ISO7816 T = 0 or T = 1
smart card slots, infrared transceivers and connection to modem ports. The hardware handshaking feature enables
an out-of-band flow control by automatic management of the pins RTS and CTS.
The USART supports the connection to the Peripheral DMA Controller, which enables data transfers to the transmitter and from the receiver. The PDC provides chained buffer management without any intervention of the
processor.
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30.2
Block Diagram
Figure 30-1. USART Block Diagram
Peripheral DMA
Controller
Channel
Channel
PIO
Controller
USART
RXD
Receiver
RTS
AIC
USART
Interrupt
TXD
Transmitter
CTS
DTR
PMC
Modem
Signals
Control
MCK
DIV
DSR
DCD
MCK/DIV
RI
SLCK
Baud Rate
Generator
SCK
User Interface
APB
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30.3
Application Block Diagram
Figure 30-2. Application Block Diagram
IrLAP
PPP
Modem
Driver
Serial
Driver
Field Bus
Driver
EMV
Driver
IrDA
Driver
USART
RS232
Drivers
RS232
Drivers
RS485
Drivers
Serial
Port
Differential
Bus
Smart
Card
Slot
IrDA
Transceivers
Modem
PSTN
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30.4
I/O Lines Description
Table 30-1.
I/O Line Description
Name
Description
Type
Active Level
SCK
Serial Clock
I/O
TXD
Transmit Serial Data
I/O
RXD
Receive Serial Data
Input
RI
Ring Indicator
Input
Low
DSR
Data Set Ready
Input
Low
DCD
Data Carrier Detect
Input
Low
DTR
Data Terminal Ready
Output
Low
CTS
Clear to Send
Input
Low
RTS
Request to Send
Output
Low
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30.5
Product Dependencies
30.5.1
I/O Lines
The pins used for interfacing the USART may be multiplexed with the PIO lines. The programmer must first program the PIO controller to assign the desired USART pins to their peripheral function. If I/O lines of the USART are
not used by the application, they can be used for other purposes by the PIO Controller.
To prevent the TXD line from falling when the USART is disabled, the use of an internal pull up is mandatory. If the
hardware handshaking feature or Modem mode is used, the internal pull up on TXD must also be enabled.
All the pins of the modems may or may not be implemented on the USART. Only USART1 fully equipped with all
the modem signals. On USARTs not equipped with the corresponding pin, the associated control bits and statuses
have no effect on the behavior of the USART.
30.5.2
Power Management
The USART is not continuously clocked. The programmer must first enable the USART Clock in the Power Management Controller (PMC) before using the USART. However, if the application does not require USART
operations, the USART clock can be stopped when not needed and be restarted later. In this case, the USART will
resume its operations where it left off.
Configuring the USART does not require the USART clock to be enabled.
30.5.3
Interrupt
The USART interrupt line is connected on one of the internal sources of the Advanced Interrupt Controller. Using
the USART interrupt requires the AIC to be programmed first. Note that it is not recommended to use the USART
interrupt line in edge sensitive mode.
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30.6
Functional Description
The USART is capable of managing several types of serial synchronous or asynchronous communications.
It supports the following communication modes:
• 5- to 9-bit full-duplex asynchronous serial communication
– MSB- or LSB-first
– 1, 1.5 or 2 stop bits
– Parity even, odd, marked, space or none
– By 8 or by 16 over-sampling receiver frequency
– Optional hardware handshaking
– Optional modem signals management
– Optional break management
– Optional multidrop serial communication
• High-speed 5- to 9-bit full-duplex synchronous serial communication
– MSB- or LSB-first
– 1 or 2 stop bits
– Parity even, odd, marked, space or none
– By 8 or by 16 over-sampling frequency
– Optional hardware handshaking
– Optional modem signals management
– Optional break management
– Optional multidrop serial communication
• RS485 with driver control signal
• ISO7816, T0 or T1 protocols for interfacing with smart cards
– NACK handling, error counter with repetition and iteration limit
• InfraRed IrDA Modulation and Demodulation
• Test modes
– Remote loopback, local loopback, automatic echo
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30.6.1
Baud Rate Generator
The Baud Rate Generator provides the bit period clock named the Baud Rate Clock to both the receiver and the
transmitter.
The Baud Rate Generator clock source can be selected by setting the USCLKS field in the Mode Register
(US_MR) between:
• the Master Clock MCK
• a division of the Master Clock, the divider being product dependent, but generally set to 8
• the external clock, available on the SCK pin
The Baud Rate Generator is based upon a 16-bit divider, which is programmed with the CD field of the Baud Rate
Generator Register (US_BRGR). If CD is programmed at 0, the Baud Rate Generator does not generate any clock.
If CD is programmed at 1, the divider is bypassed and becomes inactive.
If the external SCK clock is selected, the duration of the low and high levels of the signal provided on the SCK pin
must be longer than a Master Clock (MCK) period. The frequency of the signal provided on SCK must be at least
4.5 times lower than MCK.
Figure 30-3. Baud Rate Generator
USCLKS
MCK
MCK/DIV
SCK
Reserved
CD
CD
SCK
0
1
2
16-bit Counter
FIDI
>1
3
1
0
0
0
SYNC
OVER
Sampling
Divider
0
Baud Rate
Clock
1
1
SYNC
USCLKS = 3
Sampling
Clock
30.6.1.1
Baud Rate in Asynchronous Mode
If the USART is programmed to operate in asynchronous mode, the selected clock is first divided by CD, which is
field programmed in the Baud Rate Generator Register (US_BRGR). The resulting clock is provided to the receiver
as a sampling clock and then divided by 16 or 8, depending on the programming of the OVER bit in US_MR.
If OVER is set to 1, the receiver sampling is 8 times higher than the baud rate clock. If OVER is cleared, the sampling is performed at 16 times the baud rate clock.
The following formula performs the calculation of the Baud Rate.
SelectedClock
Baudrate = -------------------------------------------( 8 ( 2 – Over )CD )
This gives a maximum baud rate of MCK divided by 8, assuming that MCK is the highest possible clock and that
OVER is programmed at 1.
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30.6.1.2
Baud Rate Calculation Example
Table 30-2 shows calculations of CD to obtain a baud rate at 38400 bauds for different source clock frequencies.
This table also shows the actual resulting baud rate and the error.
Table 30-2.
Baud Rate Example (OVER = 0)
Source Clock
Expected Baud
Rate
MHz
Bit/s
3 686 400
38 400
6.00
6
38 400.00
0.00%
4 915 200
38 400
8.00
8
38 400.00
0.00%
5 000 000
38 400
8.14
8
39 062.50
1.70%
7 372 800
38 400
12.00
12
38 400.00
0.00%
8 000 000
38 400
13.02
13
38 461.54
0.16%
12 000 000
38 400
19.53
20
37 500.00
2.40%
12 288 000
38 400
20.00
20
38 400.00
0.00%
14 318 180
38 400
23.30
23
38 908.10
1.31%
14 745 600
38 400
24.00
24
38 400.00
0.00%
18 432 000
38 400
30.00
30
38 400.00
0.00%
24 000 000
38 400
39.06
39
38 461.54
0.16%
24 576 000
38 400
40.00
40
38 400.00
0.00%
25 000 000
38 400
40.69
40
38 109.76
0.76%
32 000 000
38 400
52.08
52
38 461.54
0.16%
32 768 000
38 400
53.33
53
38 641.51
0.63%
33 000 000
38 400
53.71
54
38 194.44
0.54%
40 000 000
38 400
65.10
65
38 461.54
0.16%
50 000 000
38 400
81.38
81
38 580.25
0.47%
Calculation Result
CD
Actual Baud Rate
Error
Bit/s
The baud rate is calculated with the following formula:
BaudRate = MCK ⁄ CD × 16
The baud rate error is calculated with the following formula. It is not recommended to work with an error higher than
5%.
ExpectedBaudRate
Error = 1 – ⎛ ---------------------------------------------------⎞
⎝ ActualBaudRate ⎠
30.6.1.3
Fractional Baud Rate in Asynchronous Mode
The Baud Rate generator previously defined is subject to the following limitation: the output frequency changes by
only integer multiples of the reference frequency. An approach to this problem is to integrate a fractional N clock
generator that has a high resolution. The generator architecture is modified to obtain Baud Rate changes by a fraction of the reference source clock. This fractional part is programmed with the FP field in the Baud Rate Generator
Register (US_BRGR). If FP is not 0, the fractional part is activated. The resolution is one eighth of the clock divider.
This feature is only available when using USART normal mode. The fractional Baud Rate is calculated using the
following formula:
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SelectedClock
Baudrate = ---------------------------------------------------------------⎛ 8 ( 2 – Over ) ⎛ CD + FP
-------⎞ ⎞
⎝
⎝
8 ⎠⎠
The modified architecture is presented below:
Figure 30-4. Fractional Baud Rate Generator
FP
USCLKS
CD
Modulus
Control
FP
MCK
MCK/DIV
SCK
Reserved
CD
SCK
0
1
2
16-bit Counter
3
glitch-free
logic
1
0
FIDI
>1
0
0
SYNC
OVER
Sampling
Divider
0
Baud Rate
Clock
1
1
SYNC
USCLKS = 3
Sampling
Clock
30.6.1.4
Baud Rate in Synchronous Mode
If the USART is programmed to operate in synchronous mode, the selected clock is simply divided by the field CD
in US_BRGR.
BaudRate = SelectedClock
-------------------------------------CD
In synchronous mode, if the external clock is selected (USCLKS = 3), the clock is provided directly by the signal on
the USART SCK pin. No division is active. The value written in US_BRGR has no effect. The external clock frequency must be at least 4.5 times lower than the system clock.
When either the external clock SCK or the internal clock divided (MCK/DIV) is selected, the value programmed in
CD must be even if the user has to ensure a 50:50 mark/space ratio on the SCK pin. If the internal clock MCK is
selected, the Baud Rate Generator ensures a 50:50 duty cycle on the SCK pin, even if the value programmed in
CD is odd.
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30.6.1.5
Baud Rate in ISO 7816 Mode
The ISO7816 specification defines the bit rate with the following formula:
Di
B = ------ × f
Fi
where:
• B is the bit rate
• Di is the bit-rate adjustment factor
• Fi is the clock frequency division factor
• f is the ISO7816 clock frequency (Hz)
Di is a binary value encoded on a 4-bit field, named DI, as represented in Table 30-3.
Table 30-3.
Binary and Decimal Values for Di
DI field
0001
0010
0011
0100
0101
0110
1000
1001
1
2
4
8
16
32
12
20
Di (decimal)
Fi is a binary value encoded on a 4-bit field, named FI, as represented in Table 30-4.
Table 30-4.
Binary and Decimal Values for Fi
FI field
0000
0001
0010
0011
0100
0101
0110
1001
1010
1011
1100
1101
Fi (decimal
372
372
558
744
1116
1488
1860
512
768
1024
1536
2048
Table 30-5 shows the resulting Fi/Di Ratio, which is the ratio between the ISO7816 clock and the baud rate clock.
Table 30-5.
Possible Values for the Fi/Di Ratio
Fi/Di
372
558
774
1116
1488
1806
512
768
1024
1536
2048
1
372
558
744
1116
1488
1860
512
768
1024
1536
2048
2
186
279
372
558
744
930
256
384
512
768
1024
4
93
139.5
186
279
372
465
128
192
256
384
512
8
46.5
69.75
93
139.5
186
232.5
64
96
128
192
256
16
23.25
34.87
46.5
69.75
93
116.2
32
48
64
96
128
32
11.62
17.43
23.25
34.87
46.5
58.13
16
24
32
48
64
12
31
46.5
62
93
124
155
42.66
64
85.33
128
170.6
20
18.6
27.9
37.2
55.8
74.4
93
25.6
38.4
51.2
76.8
102.4
If the USART is configured in ISO7816 Mode, the clock selected by the USCLKS field in the Mode Register
(US_MR) is first divided by the value programmed in the field CD in the Baud Rate Generator Register
(US_BRGR). The resulting clock can be provided to the SCK pin to feed the smart card clock inputs. This means
that the CLKO bit can be set in US_MR.
This clock is then divided by the value programmed in the FI_DI_RATIO field in the FI_DI_Ratio register
(US_FIDI). This is performed by the Sampling Divider, which performs a division by up to 2047 in ISO7816 Mode.
The non-integer values of the Fi/Di Ratio are not supported and the user must program the FI_DI_RATIO field to a
value as close as possible to the expected value.
The FI_DI_RATIO field resets to the value 0x174 (372 in decimal) and is the most common divider between the
ISO7816 clock and the bit rate (Fi = 372, Di = 1).
Figure 30-5 shows the relation between the Elementary Time Unit, corresponding to a bit time, and the ISO 7816
clock.
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Figure 30-5. Elementary Time Unit (ETU)
FI_DI_RATIO
ISO7816 Clock Cycles
ISO7816 Clock
on SCK
ISO7816 I/O Line
on TXD
1 ETU
30.6.2
Receiver and Transmitter Control
After reset, the receiver is disabled. The user must enable the receiver by setting the RXEN bit in the Control Register (US_CR). However, the receiver registers can be programmed before the receiver clock is enabled.
After reset, the transmitter is disabled. The user must enable it by setting the TXEN bit in the Control Register
(US_CR). However, the transmitter registers can be programmed before being enabled.
The Receiver and the Transmitter can be enabled together or independently.
At any time, the software can perform a reset on the receiver or the transmitter of the USART by setting the corresponding bit, RSTRX and RSTTX respectively, in the Control Register (US_CR). The software resets clear the
status flag and reset internal state machines but the user interface configuration registers hold the value configured
prior to software reset. Regardless of what the receiver or the transmitter is performing, the communication is
immediately stopped.
The user can also independently disable the receiver or the transmitter by setting RXDIS and TXDIS respectively
in US_CR. If the receiver is disabled during a character reception, the USART waits until the end of reception of the
current character, then the reception is stopped. If the transmitter is disabled while it is operating, the USART waits
the end of transmission of both the current character and character being stored in the Transmit Holding Register
(US_THR). If a timeguard is programmed, it is handled normally.
30.6.3
Synchronous and Asynchronous Modes
30.6.3.1
Transmitter Operations
The transmitter performs the same in both synchronous and asynchronous operating modes (SYNC = 0 or SYNC
= 1). One start bit, up to 9 data bits, one optional parity bit and up to two stop bits are successively shifted out on
the TXD pin at each falling edge of the programmed serial clock.
The number of data bits is selected by the CHRL field and the MODE 9 bit in the Mode Register (US_MR). Nine
bits are selected by setting the MODE 9 bit regardless of the CHRL field. The parity bit is set according to the PAR
field in US_MR. The even, odd, space, marked or none parity bit can be configured. The MSBF field in US_MR
configures which data bit is sent first. If written at 1, the most significant bit is sent first. At 0, the less significant bit
is sent first. The number of stop bits is selected by the NBSTOP field in US_MR. The 1.5 stop bit is supported in
asynchronous mode only.
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Figure 30-6. Character Transmit
Example: 8-bit, Parity Enabled One Stop
Baud Rate
Clock
TXD
D0
Start
Bit
D1
D2
D3
D4
D5
D6
D7
Parity
Bit
Stop
Bit
The characters are sent by writing in the Transmit Holding Register (US_THR). The transmitter reports two status
bits in the Channel Status Register (US_CSR): TXRDY (Transmitter Ready), which indicates that US_THR is
empty and TXEMPTY, which indicates that all the characters written in US_THR have been processed. When the
current character processing is completed, the last character written in US_THR is transferred into the Shift Register of the transmitter and US_THR becomes empty, thus TXRDY rises.
Both TXRDY and TXEMPTY bits are low when the transmitter is disabled. Writing a character in US_THR while
TXRDY is low has no effect and the written character is lost.
Figure 30-7. Transmitter Status
Baud Rate
Clock
TXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop Start
D0
Bit Bit Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
Write
US_THR
TXRDY
TXEMPTY
30.6.3.2
Manchester Encoder
When the Manchester encoder is in use, characters transmitted through the USART are encoded based on
biphase Manchester II format. To enable this mode, set the MAN field in the US_MR register to 1. Depending on
polarity configuration, a logic level (zero or one), is transmitted as a coded signal one-to-zero or zero-to-one. Thus,
a transition always occurs at the midpoint of each bit time. It consumes more bandwidth than the original NRZ signal (2x) but the receiver has more error control since the expected input must show a change at the center of a bit
cell. An example of Manchester encoded sequence is: the byte 0xB1 or 10110001 encodes to 10 01 10 10 01 01
01 10, assuming the default polarity of the encoder. Figure 30-8 illustrates this coding scheme.
Figure 30-8. NRZ to Manchester Encoding
NRZ
encoded
data
Manchester
encoded
data
1
0
1
1
0
0
0
1
Txd
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The Manchester encoded character can also be encapsulated by adding both a configurable preamble and a start
frame delimiter pattern. Depending on the configuration, the preamble is a training sequence, composed of a predefined pattern with a programmable length from 1 to 15 bit times. If the preamble length is set to 0, the preamble
waveform is not generated prior to any character. The preamble pattern is chosen among the following sequences:
ALL_ONE, ALL_ZERO, ONE_ZERO or ZERO_ONE, writing the field TX_PP in the US_MAN register, the field
TX_PL is used to configure the preamble length. Figure 30-9 illustrates and defines the valid patterns. To improve
flexibility, the encoding scheme can be configured using the TX_MPOL field in the US_MAN register. If the
TX_MPOL field is set to zero (default), a logic zero is encoded with a zero-to-one transition and a logic one is
encoded with a one-to-zero transition. If the TX_MPOL field is set to one, a logic one is encoded with a one-to-zero
transition and a logic zero is encoded with a zero-to-one transition.
Figure 30-9. Preamble Patterns, Default Polarity Assumed
Manchester
encoded
data
Txd
SFD
DATA
SFD
DATA
SFD
DATA
SFD
DATA
8 bit width "ALL_ONE" Preamble
Manchester
encoded
data
Txd
8 bit width "ALL_ZERO" Preamble
Manchester
encoded
data
Txd
8 bit width "ZERO_ONE" Preamble
Manchester
encoded
data
Txd
8 bit width "ONE_ZERO" Preamble
A start frame delimiter is to be configured using the ONEBIT field in the US_MR register. It consists of a userdefined pattern that indicates the beginning of a valid data. Figure 30-10 illustrates these patterns. If the start frame
delimiter, also known as start bit, is one bit, (ONEBIT at 1), a logic zero is Manchester encoded and indicates that
a new character is being sent serially on the line. If the start frame delimiter is a synchronization pattern also
referred to as sync (ONEBIT at 0), a sequence of 3 bit times is sent serially on the line to indicate the start of a new
character. The sync waveform is in itself an invalid Manchester waveform as the transition occurs at the middle of
the second bit time. Two distinct sync patterns are used: the command sync and the data sync. The command
sync has a logic one level for one and a half bit times, then a transition to logic zero for the second one and a half
bit times. If the MODSYNC field in the US_MR register is set to 1, the next character is a command. If it is set to 0,
the next character is a data. When direct memory access is used, the MODSYNC field can be immediately updated
with a modified character located in memory. To enable this mode, VAR_SYNC field in US_MR register must be
set to 1. In this case, the MODSYNC field in US_MR is bypassed and the sync configuration is held in the TXSYNH
in the US_THR register. The USART character format is modified and includes sync information.
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Figure 30-10. Start Frame Delimiter
Preamble Length
is set to 0
SFD
Manchester
encoded
data
DATA
Txd
One bit start frame delimiter
SFD
Manchester
encoded
data
DATA
Txd
Command Sync
start frame delimiter
SFD
Manchester
encoded
data
DATA
Txd
Data Sync
start frame delimiter
30.6.3.3
Drift Compensation
Drift compensation is available only in 16X oversampling mode. An hardware recovery system allows a larger clock
drift. To enable the hardware system, the bit in the USART_MAN register must be set. If the RXD edge is one 16X
clock cycle from the expected edge, this is considered as normal jitter and no corrective actions is taken. If the
RXD event is between 4 and 2 clock cycles before the expected edge, then the current period is shortened by one
clock cycle. If the RXD event is between 2 and 3 clock cycles after the expected edge, then the current period is
lengthened by one clock cycle. These intervals are considered to be drift and so corrective actions are automatically taken.
Figure 30-11. Bit Resynchronization
Oversampling
16x Clock
RXD
Sampling
point
Expected edge
Synchro.
Error
Synchro.
Jump
Tolerance
Sync
Jump
Synchro.
Error
30.6.3.4
Asynchronous Receiver
If the USART is programmed in asynchronous operating mode (SYNC = 0), the receiver oversamples the RXD
input line. The oversampling is either 16 or 8 times the Baud Rate clock, depending on the OVER bit in the Mode
Register (US_MR).
The receiver samples the RXD line. If the line is sampled during one half of a bit time at 0, a start bit is detected
and data, parity and stop bits are successively sampled on the bit rate clock.
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If the oversampling is 16, (OVER at 0), a start is detected at the eighth sample at 0. Then, data bits, parity bit and
stop bit are sampled on each 16 sampling clock cycle. If the oversampling is 8 (OVER at 1), a start bit is detected
at the fourth sample at 0. Then, data bits, parity bit and stop bit are sampled on each 8 sampling clock cycle.
The number of data bits, first bit sent and parity mode are selected by the same fields and bits as the transmitter,
i.e. respectively CHRL, MODE9, MSBF and PAR. For the synchronization mechanism only, the number of stop
bits has no effect on the receiver as it considers only one stop bit, regardless of the field NBSTOP, so that resynchronization between the receiver and the transmitter can occur. Moreover, as soon as the stop bit is sampled, the
receiver starts looking for a new start bit so that resynchronization can also be accomplished when the transmitter
is operating with one stop bit.
Figure 30-12 and Figure 30-13 illustrate start detection and character reception when USART operates in asynchronous mode.
Figure 30-12. Asynchronous Start Detection
Baud Rate
Clock
Sampling
Clock (x16)
RXD
Sampling
1
2
3
4
5
6
7
8
1
2
3
4
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16
D0
Sampling
Start
Detection
RXD
Sampling
1
2
3
4
5
6
7
0 1
Start
Rejection
Figure 30-13. Asynchronous Character Reception
Example: 8-bit, Parity Enabled
Baud Rate
Clock
RXD
Start
Detection
16
16
16
16
16
16
16
16
16
16
samples samples samples samples samples samples samples samples samples samples
D0
D1
D2
D3
D4
D5
D6
D7
Parity
Bit
Stop
Bit
30.6.3.5
Manchester Decoder
When the MAN field in US_MR register is set to 1, the Manchester decoder is enabled. The decoder performs both
preamble and start frame delimiter detection. One input line is dedicated to Manchester encoded input data.
An optional preamble sequence can be defined, its length is user-defined and totally independent of the emitter
side. Use RX_PL in US_MAN register to configure the length of the preamble sequence. If the length is set to 0, no
preamble is detected and the function is disabled. In addition, the polarity of the input stream is programmable with
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RX_MPOL field in US_MAN register. Depending on the desired application the preamble pattern matching is to be
defined via the RX_PP field in US_MAN. See Figure 30-9 for available preamble patterns.
Unlike preamble, the start frame delimiter is shared between Manchester Encoder and Decoder. So, if ONEBIT
field is set to 1, only a zero encoded Manchester can be detected as a valid start frame delimiter. If ONEBIT is set
to 0, only a sync pattern is detected as a valid start frame delimiter. Decoder operates by detecting transition on
incoming stream. If RXD is sampled during one quarter of a bit time at zero, a start bit is detected. See Figure 3014.. The sample pulse rejection mechanism applies.
Figure 30-14. Asynchronous Start Bit Detection
Sampling
Clock
(16 x)
Manchester
encoded
data
Txd
Start
Detection
1
2
3
4
The receiver is activated and starts Preamble and Frame Delimiter detection, sampling the data at one quarter and
then three quarters. If a valid preamble pattern or start frame delimiter is detected, the receiver continues decoding
with the same synchronization. If the stream does not match a valid pattern or a valid start frame delimiter, the
receiver re-synchronizes on the next valid edge.The minimum time threshold to estimate the bit value is three quarters of a bit time.
If a valid preamble (if used) followed with a valid start frame delimiter is detected, the incoming stream is decoded
into NRZ data and passed to USART for processing. Figure 30-15 illustrates Manchester pattern mismatch. When
incoming data stream is passed to the USART, the receiver is also able to detect Manchester code violation. A
code violation is a lack of transition in the middle of a bit cell. In this case, MANE flag in US_CSR register is raised.
It is cleared by writing the Control Register (US_CR) with the RSTSTA bit at 1. See Figure 30-16 for an example of
Manchester error detection during data phase.
Figure 30-15. Preamble Pattern Mismatch
Preamble Mismatch
Manchester coding error
Manchester
encoded
data
Preamble Mismatch
invalid pattern
SFD
Txd
DATA
Preamble Length is set to 8
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Figure 30-16. Manchester Error Flag
Preamble Length
is set to 4
Elementary character bit time
SFD
Manchester
encoded
data
Txd
Entering USART character area
sampling points
Preamble subpacket
and Start Frame Delimiter
were successfully
decoded
Manchester
Coding Error
detected
When the start frame delimiter is a sync pattern (ONEBIT field at 0), both command and data delimiter are supported. If a valid sync is detected, the received character is written as RXCHR field in the US_RHR register and the
RXSYNH is updated. RXCHR is set to 1 when the received character is a command, and it is set to 0 if the
received character is a data. This mechanism alleviates and simplifies the direct memory access as the character
contains its own sync field in the same register.
As the decoder is setup to be used in unipolar mode, the first bit of the frame has to be a zero-to-one transition.
30.6.3.6
Radio Interface: Manchester Encoded USART Application
This section describes low data rate RF transmission systems and their integration with a Manchester encoded
USART. These systems are based on transmitter and receiver ICs that support ASK and FSK modulation
schemes.
The goal is to perform full duplex radio transmission of characters using two different frequency carriers. See the
configuration in Figure 30-17.
Figure 30-17. Manchester Encoded Characters RF Transmission
Fup frequency Carrier
ASK/FSK
Upstream Receiver
Upstream
Emitter
LNA
VCO
RF filter
Demod
Serial
Configuration
Interface
control
Fdown frequency Carrier
bi-dir
line
Manchester
decoder
USART
Receiver
Manchester
encoder
USART
Emitter
ASK/FSK
downstream transmitter
Downstream
Receiver
PA
RF filter
Mod
VCO
control
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The USART module is configured as a Manchester encoder/decoder. Looking at the downstream communication
channel, Manchester encoded characters are serially sent to the RF emitter. This may also include a user defined
preamble and a start frame delimiter. Mostly, preamble is used in the RF receiver to distinguish between a valid
data from a transmitter and signals due to noise. The Manchester stream is then modulated. See Figure 30-18 for
an example of ASK modulation scheme. When a logic one is sent to the ASK modulator, the power amplifier,
referred to as PA, is enabled and transmits an RF signal at downstream frequency. When a logic zero is transmitted, the RF signal is turned off. If the FSK modulator is activated, two different frequencies are used to transmit
data. When a logic 1 is sent, the modulator outputs an RF signal at frequency F0 and switches to F1 if the data
sent is a 0. See Figure 30-19.
From the receiver side, another carrier frequency is used. The RF receiver performs a bit check operation examining demodulated data stream. If a valid pattern is detected, the receiver switches to receiving mode. The
demodulated stream is sent to the Manchester decoder. Because of bit checking inside RF IC, the data transferred
to the microcontroller is reduced by a user-defined number of bits. The Manchester preamble length is to be
defined in accordance with the RF IC configuration.
Figure 30-18. ASK Modulator Output
1
0
0
1
0
0
1
NRZ stream
Manchester
encoded
data
default polarity
unipolar output
Txd
ASK Modulator
Output
Uptstream Frequency F0
Figure 30-19. FSK Modulator Output
1
NRZ stream
Manchester
encoded
data
default polarity
unipolar output
Txd
FSK Modulator
Output
Uptstream Frequencies
[F0, F0+offset]
30.6.3.7
Synchronous Receiver
In synchronous mode (SYNC = 1), the receiver samples the RXD signal on each rising edge of the Baud Rate
Clock. If a low level is detected, it is considered as a start. All data bits, the parity bit and the stop bits are sampled
and the receiver waits for the next start bit. Synchronous mode operations provide a high speed transfer capability.
Configuration fields and bits are the same as in asynchronous mode.
Figure 30-20 illustrates a character reception in synchronous mode.
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Figure 30-20. Synchronous Mode Character Reception
Example: 8-bit, Parity Enabled 1 Stop
Baud Rate
Clock
RXD
Sampling
Start
D0
D1
D2
D3
D4
D5
D6
D7
Stop Bit
Parity Bit
30.6.3.8
Receiver Operations
When a character reception is completed, it is transferred to the Receive Holding Register (US_RHR) and the
RXRDY bit in the Status Register (US_CSR) rises. If a character is completed while the RXRDY is set, the OVRE
(Overrun Error) bit is set. The last character is transferred into US_RHR and overwrites the previous one. The
OVRE bit is cleared by writing the Control Register (US_CR) with the RSTSTA (Reset Status) bit at 1.
Figure 30-21. Receiver Status
Baud Rate
Clock
RXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop Start
D0
Bit Bit Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
RSTSTA = 1
Write
US_CR
Read
US_RHR
RXRDY
OVRE
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30.6.3.9
Parity
The USART supports five parity modes selected by programming the PAR field in the Mode Register (US_MR).
The PAR field also enables the Multidrop mode, see “Multidrop Mode” on page 371. Even and odd parity bit generation and error detection are supported.
If even parity is selected, the parity generator of the transmitter drives the parity bit at 0 if a number of 1s in the
character data bit is even, and at 1 if the number of 1s is odd. Accordingly, the receiver parity checker counts the
number of received 1s and reports a parity error if the sampled parity bit does not correspond. If odd parity is
selected, the parity generator of the transmitter drives the parity bit at 1 if a number of 1s in the character data bit is
even, and at 0 if the number of 1s is odd. Accordingly, the receiver parity checker counts the number of received 1s
and reports a parity error if the sampled parity bit does not correspond. If the mark parity is used, the parity generator of the transmitter drives the parity bit at 1 for all characters. The receiver parity checker reports an error if the
parity bit is sampled at 0. If the space parity is used, the parity generator of the transmitter drives the parity bit at 0
for all characters. The receiver parity checker reports an error if the parity bit is sampled at 1. If parity is disabled,
the transmitter does not generate any parity bit and the receiver does not report any parity error.
Table 30-6 shows an example of the parity bit for the character 0x41 (character ASCII “A”) depending on the configuration of the USART. Because there are two bits at 1, 1 bit is added when a parity is odd, or 0 is added when a
parity is even.
Table 30-6.
Parity Bit Examples
Character
Hexa
Binary
Parity Bit
Parity Mode
A
0x41
0100 0001
1
Odd
A
0x41
0100 0001
0
Even
A
0x41
0100 0001
1
Mark
A
0x41
0100 0001
0
Space
A
0x41
0100 0001
None
None
When the receiver detects a parity error, it sets the PARE (Parity Error) bit in the Channel Status Register
(US_CSR). The PARE bit can be cleared by writing the Control Register (US_CR) with the RSTSTA bit at 1. Figure
30-22 illustrates the parity bit status setting and clearing.
Figure 30-22. Parity Error
Baud Rate
Clock
RXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Bad Stop
Parity Bit
Bit
RSTSTA = 1
Write
US_CR
PARE
RXRDY
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30.6.3.10
Multidrop Mode
If the PAR field in the Mode Register (US_MR) is programmed to the value 0x6 or 0x07, the USART runs in Multidrop Mode. This mode differentiates the data characters and the address characters. Data is transmitted with the
parity bit at 0 and addresses are transmitted with the parity bit at 1.
If the USART is configured in multidrop mode, the receiver sets the PARE parity error bit when the parity bit is high
and the transmitter is able to send a character with the parity bit high when the Control Register is written with the
SENDA bit at 1.
To handle parity error, the PARE bit is cleared when the Control Register is written with the bit RSTSTA at 1.
The transmitter sends an address byte (parity bit set) when SENDA is written to US_CR. In this case, the next byte
written to US_THR is transmitted as an address. Any character written in US_THR without having written the command SENDA is transmitted normally with the parity at 0.
30.6.3.11
Transmitter Timeguard
The timeguard feature enables the USART interface with slow remote devices.
The timeguard function enables the transmitter to insert an idle state on the TXD line between two characters. This
idle state actually acts as a long stop bit.
The duration of the idle state is programmed in the TG field of the Transmitter Timeguard Register (US_TTGR).
When this field is programmed at zero no timeguard is generated. Otherwise, the transmitter holds a high level on
TXD after each transmitted byte during the number of bit periods programmed in TG in addition to the number of
stop bits.
As illustrated in Figure 30-23, the behavior of TXRDY and TXEMPTY status bits is modified by the programming of
a timeguard. TXRDY rises only when the start bit of the next character is sent, and thus remains at 0 during the
timeguard transmission if a character has been written in US_THR. TXEMPTY remains low until the timeguard
transmission is completed as the timeguard is part of the current character being transmitted.
Figure 30-23. Timeguard Operations
TG = 4
TG = 4
Baud Rate
Clock
TXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
Write
US_THR
TXRDY
TXEMPTY
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Table 30-7 indicates the maximum length of a timeguard period that the transmitter can handle in relation to the
function of the Baud Rate.
Table 30-7.
Maximum Timeguard Length Depending on Baud Rate
Baud Rate
Bit time
Timeguard
Bit/sec
µs
ms
1 200
833
212.50
9 600
104
26.56
14400
69.4
17.71
19200
52.1
13.28
28800
34.7
8.85
33400
29.9
7.63
56000
17.9
4.55
57600
17.4
4.43
115200
8.7
2.21
30.6.3.12
Receiver Time-out
The Receiver Time-out provides support in handling variable-length frames. This feature detects an idle condition
on the RXD line. When a time-out is detected, the bit TIMEOUT in the Channel Status Register (US_CSR) rises
and can generate an interrupt, thus indicating to the driver an end of frame.
The time-out delay period (during which the receiver waits for a new character) is programmed in the TO field of
the Receiver Time-out Register (US_RTOR). If the TO field is programmed at 0, the Receiver Time-out is disabled
and no time-out is detected. The TIMEOUT bit in US_CSR remains at 0. Otherwise, the receiver loads a 16-bit
counter with the value programmed in TO. This counter is decremented at each bit period and reloaded each time
a new character is received. If the counter reaches 0, the TIMEOUT bit in the Status Register rises. Then, the user
can either:
• Stop the counter clock until a new character is received. This is performed by writing the Control Register
(US_CR) with the STTTO (Start Time-out) bit at 1. In this case, the idle state on RXD before a new character is
received will not provide a time-out. This prevents having to handle an interrupt before a character is received
and allows waiting for the next idle state on RXD after a frame is received.
• Obtain an interrupt while no character is received. This is performed by writing US_CR with the RETTO (Reload
and Start Time-out) bit at 1. If RETTO is performed, the counter starts counting down immediately from the
value TO. This enables generation of a periodic interrupt so that a user time-out can be handled, for example
when no key is pressed on a keyboard.
If STTTO is performed, the counter clock is stopped until a first character is received. The idle state on RXD before
the start of the frame does not provide a time-out. This prevents having to obtain a periodic interrupt and enables a
wait of the end of frame when the idle state on RXD is detected.
If RETTO is performed, the counter starts counting down immediately from the value TO. This enables generation
of a periodic interrupt so that a user time-out can be handled, for example when no key is pressed on a keyboard.
Figure 30-24 shows the block diagram of the Receiver Time-out feature.
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Figure 30-24. Receiver Time-out Block Diagram
TO
Baud Rate
Clock
1
D
Clock
Q
16-bit Time-out
Counter
16-bit
Value
=
STTTO
Character
Received
Load
Clear
TIMEOUT
0
RETTO
Table 30-8 gives the maximum time-out period for some standard baud rates.
Table 30-8.
Maximum Time-out Period
Baud Rate
Bit Time
Time-out
bit/sec
µs
ms
600
1 667
109 225
1 200
833
54 613
2 400
417
27 306
4 800
208
13 653
9 600
104
6 827
14400
69
4 551
19200
52
3 413
28800
35
2 276
33400
30
1 962
56000
18
1 170
57600
17
1 138
200000
5
328
30.6.3.13
Framing Error
The receiver is capable of detecting framing errors. A framing error happens when the stop bit of a received character is detected at level 0. This can occur if the receiver and the transmitter are fully desynchronized.
A framing error is reported on the FRAME bit of the Channel Status Register (US_CSR). The FRAME bit is
asserted in the middle of the stop bit as soon as the framing error is detected. It is cleared by writing the Control
Register (US_CR) with the RSTSTA bit at 1.
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Figure 30-25. Framing Error Status
Baud Rate
Clock
RXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
RSTSTA = 1
Write
US_CR
FRAME
RXRDY
30.6.3.14
Transmit Break
The user can request the transmitter to generate a break condition on the TXD line. A break condition drives the
TXD line low during at least one complete character. It appears the same as a 0x00 character sent with the parity
and the stop bits at 0. However, the transmitter holds the TXD line at least during one character until the user
requests the break condition to be removed.
A break is transmitted by writing the Control Register (US_CR) with the STTBRK bit at 1. This can be performed at
any time, either while the transmitter is empty (no character in either the Shift Register or in US_THR) or when a
character is being transmitted. If a break is requested while a character is being shifted out, the character is first
completed before the TXD line is held low.
Once STTBRK command is requested further STTBRK commands are ignored until the end of the break is
completed.
The break condition is removed by writing US_CR with the STPBRK bit at 1. If the STPBRK is requested before the
end of the minimum break duration (one character, including start, data, parity and stop bits), the transmitter
ensures that the break condition completes.
The transmitter considers the break as though it is a character, i.e. the STTBRK and STPBRK commands are
taken into account only if the TXRDY bit in US_CSR is at 1 and the start of the break condition clears the TXRDY
and TXEMPTY bits as if a character is processed.
Writing US_CR with the both STTBRK and STPBRK bits at 1 can lead to an unpredictable result. All STPBRK
commands requested without a previous STTBRK command are ignored. A byte written into the Transmit Holding
Register while a break is pending, but not started, is ignored.
After the break condition, the transmitter returns the TXD line to 1 for a minimum of 12 bit times. Thus, the transmitter ensures that the remote receiver detects correctly the end of break and the start of the next character. If the
timeguard is programmed with a value higher than 12, the TXD line is held high for the timeguard period.
After holding the TXD line for this period, the transmitter resumes normal operations.
Figure 30-26 illustrates the effect of both the Start Break (STTBRK) and Stop Break (STPBRK) commands on the
TXD line.
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Figure 30-26. Break Transmission
Baud Rate
Clock
TXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
STTBRK = 1
Break Transmission
End of Break
STPBRK = 1
Write
US_CR
TXRDY
TXEMPTY
30.6.3.15
Receive Break
The receiver detects a break condition when all data, parity and stop bits are low. This corresponds to detecting a
framing error with data at 0x00, but FRAME remains low.
When the low stop bit is detected, the receiver asserts the RXBRK bit in US_CSR. This bit may be cleared by writing the Control Register (US_CR) with the bit RSTSTA at 1.
An end of receive break is detected by a high level for at least 2/16 of a bit period in asynchronous operating mode
or one sample at high level in synchronous operating mode. The end of break detection also asserts the RXBRK
bit.
30.6.3.16
Hardware Handshaking
The USART features a hardware handshaking out-of-band flow control. The RTS and CTS pins are used to connect with the remote device, as shown in Figure 30-27.
Figure 30-27. Connection with a Remote Device for Hardware Handshaking
USART
Remote
Device
TXD
RXD
RXD
TXD
CTS
RTS
RTS
CTS
Setting the USART to operate with hardware handshaking is performed by writing the USART_MODE field in the
Mode Register (US_MR) to the value 0x2.
The USART behavior when hardware handshaking is enabled is the same as the behavior in standard synchronous or asynchronous mode, except that the receiver drives the RTS pin as described below and the level on the
CTS pin modifies the behavior of the transmitter as described below. Using this mode requires using the PDC
channel for reception. The transmitter can handle hardware handshaking in any case.
Figure 30-28 shows how the receiver operates if hardware handshaking is enabled. The RTS pin is driven high if
the receiver is disabled and if the status RXBUFF (Receive Buffer Full) coming from the PDC channel is high. Normally, the remote device does not start transmitting while its CTS pin (driven by RTS) is high. As soon as the
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Receiver is enabled, the RTS falls, indicating to the remote device that it can start transmitting. Defining a new buffer to the PDC clears the status bit RXBUFF and, as a result, asserts the pin RTS low.
Figure 30-28. Receiver Behavior when Operating with Hardware Handshaking
RXD
RXEN = 1
RXDIS = 1
Write
US_CR
RTS
RXBUFF
Figure 30-29 shows how the transmitter operates if hardware handshaking is enabled. The CTS pin disables the
transmitter. If a character is being processing, the transmitter is disabled only after the completion of the current
character and transmission of the next character happens as soon as the pin CTS falls.
Figure 30-29. Transmitter Behavior when Operating with Hardware Handshaking
CTS
TXD
30.6.4
ISO7816 Mode
The USART features an ISO7816-compatible operating mode. This mode permits interfacing with smart cards and
Security Access Modules (SAM) communicating through an ISO7816 link. Both T = 0 and T = 1 protocols defined
by the ISO7816 specification are supported.
Setting the USART in ISO7816 mode is performed by writing the USART_MODE field in the Mode Register
(US_MR) to the value 0x4 for protocol T = 0 and to the value 0x5 for protocol T = 1.
30.6.4.1
ISO7816 Mode Overview
The ISO7816 is a half duplex communication on only one bidirectional line. The baud rate is determined by a division of the clock provided to the remote device (see “Baud Rate Generator” on page 357).
The USART connects to a smart card as shown in Figure 30-30. The TXD line becomes bidirectional and the Baud
Rate Generator feeds the ISO7816 clock on the SCK pin. As the TXD pin becomes bidirectional, its output remains
driven by the output of the transmitter but only when the transmitter is active while its input is directed to the input
of the receiver. The USART is considered as the master of the communication as it generates the clock.
Figure 30-30. Connection of a Smart Card to the USART
USART
SCK
TXD
CLK
I/O
Smart
Card
When operating in ISO7816, either in T = 0 or T = 1 modes, the character format is fixed. The configuration is 8
data bits, even parity and 1 or 2 stop bits, regardless of the values programmed in the CHRL, MODE9, PAR and
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CHMODE fields. MSBF can be used to transmit LSB or MSB first. Parity Bit (PAR) can be used to transmit in normal or inverse mode. Refer to “USART Mode Register” on page 388 and “PAR: Parity Type” on page 389.
The USART cannot operate concurrently in both receiver and transmitter modes as the communication is unidirectional at a time. It has to be configured according to the required mode by enabling or disabling either the receiver
or the transmitter as desired. Enabling both the receiver and the transmitter at the same time in ISO7816 mode
may lead to unpredictable results.
The ISO7816 specification defines an inverse transmission format. Data bits of the character must be transmitted
on the I/O line at their negative value. The USART does not support this format and the user has to perform an
exclusive OR on the data before writing it in the Transmit Holding Register (US_THR) or after reading it in the
Receive Holding Register (US_RHR).
30.6.4.2
Protocol T = 0
In T = 0 protocol, a character is made up of one start bit, eight data bits, one parity bit and one guard time, which
lasts two bit times. The transmitter shifts out the bits and does not drive the I/O line during the guard time.
If no parity error is detected, the I/O line remains at 1 during the guard time and the transmitter can continue with
the transmission of the next character, as shown in Figure 30-31.
If a parity error is detected by the receiver, it drives the I/O line at 0 during the guard time, as shown in Figure 3032. This error bit is also named NACK, for Non Acknowledge. In this case, the character lasts 1 bit time more, as
the guard time length is the same and is added to the error bit time which lasts 1 bit time.
When the USART is the receiver and it detects an error, it does not load the erroneous character in the Receive
Holding Register (US_RHR). It appropriately sets the PARE bit in the Status Register (US_SR) so that the software
can handle the error.
Figure 30-31. T = 0 Protocol without Parity Error
Baud Rate
Clock
RXD
Start
Bit
D0
D2
D1
D4
D3
D5
D6
D7
Parity Guard Guard Next
Bit Time 1 Time 2 Start
Bit
Figure 30-32. T = 0 Protocol with Parity Error
Baud Rate
Clock
Error
I/O
Start
Bit
D0
D1
D2
D3
D4
D5
D6
D7
Parity Guard
Bit Time 1
Guard Start
Time 2 Bit
D0
D1
Repetition
30.6.4.3
Receive Error Counter
The USART receiver also records the total number of errors. This can be read in the Number of Error (US_NER)
register. The NB_ERRORS field can record up to 255 errors. Reading US_NER automatically clears the
NB_ERRORS field.
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30.6.4.4
Receive NACK Inhibit
The USART can also be configured to inhibit an error. This can be achieved by setting the INACK bit in the Mode
Register (US_MR). If INACK is at 1, no error signal is driven on the I/O line even if a parity bit is detected, but the
INACK bit is set in the Status Register (US_SR). The INACK bit can be cleared by writing the Control Register
(US_CR) with the RSTNACK bit at 1.
Moreover, if INACK is set, the erroneous received character is stored in the Receive Holding Register, as if no
error occurred. However, the RXRDY bit does not raise.
30.6.4.5
Transmit Character Repetition
When the USART is transmitting a character and gets a NACK, it can automatically repeat the character before
moving on to the next one. Repetition is enabled by writing the MAX_ITERATION field in the Mode Register
(US_MR) at a value higher than 0. Each character can be transmitted up to eight times; the first transmission plus
seven repetitions.
If MAX_ITERATION does not equal zero, the USART repeats the character as many times as the value loaded in
MAX_ITERATION.
When the USART repetition number reaches MAX_ITERATION, the ITERATION bit is set in the Channel Status
Register (US_CSR). If the repetition of the character is acknowledged by the receiver, the repetitions are stopped
and the iteration counter is cleared.
The ITERATION bit in US_CSR can be cleared by writing the Control Register with the RSIT bit at 1.
30.6.4.6
Disable Successive Receive NACK
The receiver can limit the number of successive NACKs sent back to the remote transmitter. This is programmed
by setting the bit DSNACK in the Mode Register (US_MR). The maximum number of NACK transmitted is programmed in the MAX_ITERATION field. As soon as MAX_ITERATION is reached, the character is considered as
correct, an acknowledge is sent on the line and the ITERATION bit in the Channel Status Register is set.
30.6.4.7
Protocol T = 1
When operating in ISO7816 protocol T = 1, the transmission is similar to an asynchronous format with only one
stop bit. The parity is generated when transmitting and checked when receiving. Parity error detection sets the
PARE bit in the Channel Status Register (US_CSR).
30.6.5
IrDA Mode
The USART features an IrDA mode supplying half-duplex point-to-point wireless communication. It embeds the
modulator and demodulator which allows a glueless connection to the infrared transceivers, as shown in Figure 3033. The modulator and demodulator are compliant with the IrDA specification version 1.1 and support data transfer
speeds ranging from 2.4 Kb/s to 115.2 Kb/s.
The USART IrDA mode is enabled by setting the USART_MODE field in the Mode Register (US_MR) to the value
0x8. The IrDA Filter Register (US_IF) allows configuring the demodulator filter. The USART transmitter and
receiver operate in a normal asynchronous mode and all parameters are accessible. Note that the modulator and
the demodulator are activated.
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Figure 30-33. Connection to IrDA Transceivers
USART
IrDA
Transceivers
Receiver
Demodulator
Transmitter
Modulator
RXD
RX
TX
TXD
The receiver and the transmitter must be enabled or disabled according to the direction of the transmission to be
managed.
To receive IrDA signals, the following needs to be done:
• Disable TX and Enable RX
• Configure the TXD pin as PIO and set it as an output at 0 (to avoid LED emission). Disable the internal pull-up
(better for power consumption).
• Receive data
30.6.5.1
IrDA Modulation
For baud rates up to and including 115.2 Kbits/sec, the RZI modulation scheme is used. “0” is represented by a
light pulse of 3/16th of a bit time. Some examples of signal pulse duration are shown in Table 30-9.
Table 30-9.
IrDA Pulse Duration
Baud Rate
Pulse Duration (3/16)
2.4 Kb/s
78.13 µs
9.6 Kb/s
19.53 µs
19.2 Kb/s
9.77 µs
38.4 Kb/s
4.88 µs
57.6 Kb/s
3.26 µs
115.2 Kb/s
1.63 µs
Figure 30-34 shows an example of character transmission.
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Figure 30-34. IrDA Modulation
Start
Bit
Transmitter
Output
0
Stop
Bit
Data Bits
0
1
1
0
0
1
1
0
1
TXD
3
16 Bit Period
Bit Period
30.6.5.2
IrDA Baud Rate
Table 30-10 gives some examples of CD values, baud rate error and pulse duration. Note that the requirement on
the maximum acceptable error of ±1.87% must be met.
Table 30-10. IrDA Baud Rate Error
Peripheral Clock
Baud Rate
CD
Baud Rate Error
Pulse Time
3 686 400
115 200
2
0.00%
1.63
20 000 000
115 200
11
1.38%
1.63
32 768 000
115 200
18
1.25%
1.63
40 000 000
115 200
22
1.38%
1.63
3 686 400
57 600
4
0.00%
3.26
20 000 000
57 600
22
1.38%
3.26
32 768 000
57 600
36
1.25%
3.26
40 000 000
57 600
43
0.93%
3.26
3 686 400
38 400
6
0.00%
4.88
20 000 000
38 400
33
1.38%
4.88
32 768 000
38 400
53
0.63%
4.88
40 000 000
38 400
65
0.16%
4.88
3 686 400
19 200
12
0.00%
9.77
20 000 000
19 200
65
0.16%
9.77
32 768 000
19 200
107
0.31%
9.77
40 000 000
19 200
130
0.16%
9.77
3 686 400
9 600
24
0.00%
19.53
20 000 000
9 600
130
0.16%
19.53
32 768 000
9 600
213
0.16%
19.53
40 000 000
9 600
260
0.16%
19.53
3 686 400
2 400
96
0.00%
78.13
20 000 000
2 400
521
0.03%
78.13
32 768 000
2 400
853
0.04%
78.13
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30.6.5.3
IrDA Demodulator
The demodulator is based on the IrDA Receive filter comprised of an 8-bit down counter which is loaded with the
value programmed in US_IF. When a falling edge is detected on the RXD pin, the Filter Counter starts counting
down at the Master Clock (MCK) speed. If a rising edge is detected on the RXD pin, the counter stops and is
reloaded with US_IF. If no rising edge is detected when the counter reaches 0, the input of the receiver is driven
low during one bit time.
Figure 30-35 illustrates the operations of the IrDA demodulator.
Figure 30-35. IrDA Demodulator Operations
MCK
RXD
Counter
Value
Receiver
Input
6
5
4 3
Pulse
Rejected
2
6
6
5
4
3
2
1
0
Pulse
Accepted
As the IrDA mode uses the same logic as the ISO7816, note that the FI_DI_RATIO field in US_FIDI must be set to
a value higher than 0 in order to assure IrDA communications operate correctly.
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30.6.6
RS485 Mode
The USART features the RS485 mode to enable line driver control. While operating in RS485 mode, the USART
behaves as though in asynchronous or synchronous mode and configuration of all the parameters is possible. The
difference is that the RTS pin is driven high when the transmitter is operating. The behavior of the RTS pin is controlled by the TXEMPTY bit. A typical connection of the USART to a RS485 bus is shown in Figure 30-36.
Figure 30-36. Typical Connection to a RS485 Bus
USART
RXD
Differential
Bus
TXD
RTS
The USART is set in RS485 mode by programming the USART_MODE field in the Mode Register (US_MR) to the
value 0x1.
The RTS pin is at a level inverse to the TXEMPTY bit. Significantly, the RTS pin remains high when a timeguard is
programmed so that the line can remain driven after the last character completion. Figure 30-37 gives an example
of the RTS waveform during a character transmission when the timeguard is enabled.
Figure 30-37. Example of RTS Drive with Timeguard
TG = 4
Baud Rate
Clock
TXD
Start
D0
Bit
D1
D2
D3
D4
D5
D6
D7
Parity Stop
Bit Bit
Write
US_THR
TXRDY
TXEMPTY
RTS
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30.6.7
Modem Mode
The USART features modem mode, which enables control of the signals: DTR (Data Terminal Ready), DSR (Data
Set Ready), RTS (Request to Send), CTS (Clear to Send), DCD (Data Carrier Detect) and RI (Ring Indicator).
While operating in modem mode, the USART behaves as a DTE (Data Terminal Equipment) as it drives DTR and
RTS and can detect level change on DSR, DCD, CTS and RI.
Setting the USART in modem mode is performed by writing the USART_MODE field in the Mode Register
(US_MR) to the value 0x3. While operating in modem mode the USART behaves as though in asynchronous mode
and all the parameter configurations are available.
Table 30-11 gives the correspondence of the USART signals with modem connection standards.
Table 30-11. Circuit References
USART Pin
V24
CCITT
Direction
TXD
2
103
From terminal to modem
RTS
4
105
From terminal to modem
DTR
20
108.2
From terminal to modem
RXD
3
104
From modem to terminal
CTS
5
106
From terminal to modem
DSR
6
107
From terminal to modem
DCD
8
109
From terminal to modem
RI
22
125
From terminal to modem
The control of the DTR output pin is performed by writing the Control Register (US_CR) with the DTRDIS and
DTREN bits respectively at 1. The disable command forces the corresponding pin to its inactive level, i.e. high. The
enable command forces the corresponding pin to its active level, i.e. low. RTS output pin is automatically controlled
in this mode
The level changes are detected on the RI, DSR, DCD and CTS pins. If an input change is detected, the RIIC,
DSRIC, DCDIC and CTSIC bits in the Channel Status Register (US_CSR) are set respectively and can trigger an
interrupt. The status is automatically cleared when US_CSR is read. Furthermore, the CTS automatically disables
the transmitter when it is detected at its inactive state. If a character is being transmitted when the CTS rises, the
character transmission is completed before the transmitter is actually disabled.
30.6.8
Test Modes
The USART can be programmed to operate in three different test modes. The internal loopback capability allows
on-board diagnostics. In the loopback mode the USART interface pins are disconnected or not and reconfigured
for loopback internally or externally.
30.6.8.1
Normal Mode
Normal mode connects the RXD pin on the receiver input and the transmitter output on the TXD pin.
Figure 30-38. Normal Mode Configuration
RXD
Receiver
TXD
Transmitter
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30.6.8.2
Automatic Echo Mode
Automatic echo mode allows bit-by-bit retransmission. When a bit is received on the RXD pin, it is sent to the TXD
pin, as shown in Figure 30-39. Programming the transmitter has no effect on the TXD pin. The RXD pin is still connected to the receiver input, thus the receiver remains active.
Figure 30-39. Automatic Echo Mode Configuration
RXD
Receiver
TXD
Transmitter
30.6.8.3
Local Loopback Mode
Local loopback mode connects the output of the transmitter directly to the input of the receiver, as shown in Figure
30-40. The TXD and RXD pins are not used. The RXD pin has no effect on the receiver and the TXD pin is continuously driven high, as in idle state.
Figure 30-40. Local Loopback Mode Configuration
RXD
Receiver
1
Transmitter
TXD
30.6.8.4
Remote Loopback Mode
Remote loopback mode directly connects the RXD pin to the TXD pin, as shown in Figure 30-41. The transmitter
and the receiver are disabled and have no effect. This mode allows bit-by-bit retransmission.
Figure 30-41. Remote Loopback Mode Configuration
Receiver
1
RXD
TXD
Transmitter
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30.7
Universal Synchronous Asynchronous Receiver Transmitter (USART) User Interface
Table 30-12.
Register Mapping
Offset
Register
Name
Access
Reset
0x0000
Control Register
US_CR
Write-only
–
0x0004
Mode Register
US_MR
Read-write
–
0x0008
Interrupt Enable Register
US_IER
Write-only
–
0x000C
Interrupt Disable Register
US_IDR
Write-only
–
0x0010
Interrupt Mask Register
US_IMR
Read-only
0x0
0x0014
Channel Status Register
US_CSR
Read-only
–
0x0018
Receiver Holding Register
US_RHR
Read-only
0x0
0x001C
Transmitter Holding Register
US_THR
Write-only
–
0x0020
Baud Rate Generator Register
US_BRGR
Read-write
0x0
0x0024
Receiver Time-out Register
US_RTOR
Read-write
0x0
0x0028
Transmitter Timeguard Register
US_TTGR
Read-write
0x0
–
–
–
0x2C - 0x3C
Reserved
0x0040
FI DI Ratio Register
US_FIDI
Read-write
0x174
0x0044
Number of Errors Register
US_NER
Read-only
–
0x0048
Reserved
–
–
–
0x004C
IrDA Filter Register
US_IF
Read-write
0x0
0x0050
Manchester Encoder Decoder Register
US_MAN
Read-write
0x30011004
–
–
–
0x100 - 0x128
Reserved for PDC Registers
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30.7.1
Name:
USART Control Register
US_CR
Access Type:
Write-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
RTSDIS
18
RTSEN
17
DTRDIS
16
DTREN
15
RETTO
14
RSTNACK
13
RSTIT
12
SENDA
11
STTTO
10
STPBRK
9
STTBRK
8
RSTSTA
7
TXDIS
6
TXEN
5
RXDIS
4
RXEN
3
RSTTX
2
RSTRX
1
–
0
–
• RSTRX: Reset Receiver
0: No effect.
1: Resets the receiver.
• RSTTX: Reset Transmitter
0: No effect.
1: Resets the transmitter.
• RXEN: Receiver Enable
0: No effect.
1: Enables the receiver, if RXDIS is 0.
• RXDIS: Receiver Disable
0: No effect.
1: Disables the receiver.
• TXEN: Transmitter Enable
0: No effect.
1: Enables the transmitter if TXDIS is 0.
• TXDIS: Transmitter Disable
0: No effect.
1: Disables the transmitter.
• RSTSTA: Reset Status Bits
0: No effect.
1: Resets the status bits PARE, FRAME, OVRE, MANERR and RXBRK in US_CSR.
• STTBRK: Start Break
0: No effect.
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1: Starts transmission of a break after the characters present in US_THR and the Transmit Shift Register have been transmitted. No effect if a break is already being transmitted.
• STPBRK: Stop Break
0: No effect.
1: Stops transmission of the break after a minimum of one character length and transmits a high level during 12-bit periods.
No effect if no break is being transmitted.
• STTTO: Start Time-out
0: No effect.
1: Starts waiting for a character before clocking the time-out counter. Resets the status bit TIMEOUT in US_CSR.
• SENDA: Send Address
0: No effect.
1: In Multidrop Mode only, the next character written to the US_THR is sent with the address bit set.
• RSTIT: Reset Iterations
0: No effect.
1: Resets ITERATION in US_CSR. No effect if the ISO7816 is not enabled.
• RSTNACK: Reset Non Acknowledge
0: No effect
1: Resets NACK in US_CSR.
• RETTO: Rearm Time-out
0: No effect
1: Restart Time-out
• DTREN: Data Terminal Ready Enable
0: No effect.
1: Drives the pin DTR at 0.
• DTRDIS: Data Terminal Ready Disable
0: No effect.
1: Drives the pin DTR to 1.
• RTSEN: Request to Send Enable
0: No effect.
1: Drives the pin RTS to 0.
• RTSDIS: Request to Send Disable
0: No effect.
1: Drives the pin RTS to 1.
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30.7.2
Name:
USART Mode Register
US_MR
Access Type:
Read-write
31
ONEBIT
30
MODSYNC–
29
MAN
28
FILTER
27
–
26
25
MAX_ITERATION
24
23
–
22
VAR_SYNC
21
DSNACK
20
INACK
19
OVER
18
CLKO
17
MODE9
16
MSBF
14
13
12
11
10
PAR
9
8
SYNC
4
3
2
1
0
15
CHMODE
7
NBSTOP
6
5
CHRL
USCLKS
USART_MODE
• USART_MODE
USART_MODE
Mode of the USART
0
0
0
0
Normal
0
0
0
1
RS485
0
0
1
0
Hardware Handshaking
0
0
1
1
Modem
0
1
0
0
IS07816 Protocol: T = 0
0
1
1
0
IS07816 Protocol: T = 1
1
0
0
0
IrDA
Others
Reserved
• USCLKS: Clock Selection
USCLKS
Selected Clock
0
0
MCK
0
1
MCK/DIV (DIV = 8)
1
0
Reserved
1
1
SCK
• CHRL: Character Length.
CHRL
Character Length
0
0
5 bits
0
1
6 bits
1
0
7 bits
1
1
8 bits
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• SYNC: Synchronous Mode Select
0: USART operates in Asynchronous Mode.
1: USART operates in Synchronous Mode.
• PAR: Parity Type
PAR
Parity Type
0
0
0
Even parity
0
0
1
Odd parity
0
1
0
Parity forced to 0 (Space)
0
1
1
Parity forced to 1 (Mark)
1
0
x
No parity
1
1
x
Multidrop mode
• NBSTOP: Number of Stop Bits
NBSTOP
Asynchronous (SYNC = 0)
Synchronous (SYNC = 1)
0
0
1 stop bit
1 stop bit
0
1
1.5 stop bits
Reserved
1
0
2 stop bits
2 stop bits
1
1
Reserved
Reserved
• CHMODE: Channel Mode
CHMODE
Mode Description
0
0
Normal Mode
0
1
Automatic Echo. Receiver input is connected to the TXD pin.
1
0
Local Loopback. Transmitter output is connected to the Receiver Input..
1
1
Remote Loopback. RXD pin is internally connected to the TXD pin.
• MSBF: Bit Order
0: Least Significant Bit is sent/received first.
1: Most Significant Bit is sent/received first.
• MODE9: 9-bit Character Length
0: CHRL defines character length.
1: 9-bit character length.
• CLKO: Clock Output Select
0: The USART does not drive the SCK pin.
1: The USART drives the SCK pin if USCLKS does not select the external clock SCK.
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• OVER: Oversampling Mode
0: 16x Oversampling.
1: 8x Oversampling.
• INACK: Inhibit Non Acknowledge
0: The NACK is generated.
1: The NACK is not generated.
• DSNACK: Disable Successive NACK
0: NACK is sent on the ISO line as soon as a parity error occurs in the received character (unless INACK is set).
1: Successive parity errors are counted up to the value specified in the MAX_ITERATION field. These parity errors generate a NACK on the ISO line. As soon as this value is reached, no additional NACK is sent on the ISO line. The flag
ITERATION is asserted.
• VAR_SYNC: Variable Synchronization of Command/Data Sync Start Frame Delimiter
0: User defined configuration of command or data sync field depending on SYNC value.
1: The sync field is updated when a character is written into US_THR register.
• MAX_ITERATION
Defines the maximum number of iterations in mode ISO7816, protocol T= 0.
• FILTER: Infrared Receive Line Filter
0: The USART does not filter the receive line.
1: The USART filters the receive line using a three-sample filter (1/16-bit clock) (2 over 3 majority).
• MAN: Manchester Encoder/Decoder Enable
0: Manchester Encoder/Decoder are disabled.
1: Manchester Encoder/Decoder are enabled.
• MODSYNC: Manchester Synchronization Mode
0:The Manchester Start bit is a 0 to 1 transition
1: The Manchester Start bit is a 1 to 0 transition.
• ONEBIT: Start Frame Delimiter Selector
0: Start Frame delimiter is COMMAND or DATA SYNC.
1: Start Frame delimiter is One Bit.
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30.7.3
Name:
USART Interrupt Enable Register
US_IER
Access Type:
Write-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
MANE
19
CTSIC
18
DCDIC
17
DSRIC
16
RIIC
15
–
14
–
13
NACK
12
RXBUFF
11
TXBUFE
10
ITER
9
TXEMPTY
8
TIMEOUT
7
PARE
6
FRAME
5
OVRE
4
ENDTX
3
ENDRX
2
RXBRK
1
TXRDY
0
RXRDY
• RXRDY: RXRDY Interrupt Enable
• TXRDY: TXRDY Interrupt Enable
• RXBRK: Receiver Break Interrupt Enable
• ENDRX: End of Receive Transfer Interrupt Enable
• ENDTX: End of Transmit Interrupt Enable
• OVRE: Overrun Error Interrupt Enable
• FRAME: Framing Error Interrupt Enable
• PARE: Parity Error Interrupt Enable
• TIMEOUT: Time-out Interrupt Enable
• TXEMPTY: TXEMPTY Interrupt Enable
• ITER: Iteration Interrupt Enable
• TXBUFE: Buffer Empty Interrupt Enable
• RXBUFF: Buffer Full Interrupt Enable
• NACK: Non Acknowledge Interrupt Enable
• RIIC: Ring Indicator Input Change Enable
• DSRIC: Data Set Ready Input Change Enable
• DCDIC: Data Carrier Detect Input Change Interrupt Enable
• CTSIC: Clear to Send Input Change Interrupt Enable
• MANE: Manchester Error Interrupt Enable
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30.7.4
Name:
USART Interrupt Disable Register
US_IDR
Access Type:
Write-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
MANE
19
CTSIC
18
DCDIC
17
DSRIC
16
RIIC
15
–
14
–
13
NACK
12
RXBUFF
11
TXBUFE
10
ITER
9
TXEMPTY
8
TIMEOUT
7
PARE
6
FRAME
5
OVRE
4
ENDTX
3
ENDRX
2
RXBRK
1
TXRDY
0
RXRDY
• RXRDY: RXRDY Interrupt Disable
• TXRDY: TXRDY Interrupt Disable
• RXBRK: Receiver Break Interrupt Disable
• ENDRX: End of Receive Transfer Interrupt Disable
• ENDTX: End of Transmit Interrupt Disable
• OVRE: Overrun Error Interrupt Disable
• FRAME: Framing Error Interrupt Disable
• PARE: Parity Error Interrupt Disable
• TIMEOUT: Time-out Interrupt Disable
• TXEMPTY: TXEMPTY Interrupt Disable
• ITER: Iteration Interrupt Enable
• TXBUFE: Buffer Empty Interrupt Disable
• RXBUFF: Buffer Full Interrupt Disable
• NACK: Non Acknowledge Interrupt Disable
• RIIC: Ring Indicator Input Change Disable
• DSRIC: Data Set Ready Input Change Disable
• DCDIC: Data Carrier Detect Input Change Interrupt Disable
• CTSIC: Clear to Send Input Change Interrupt Disable
• MANE: Manchester Error Interrupt Disable
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30.7.5
Name:
USART Interrupt Mask Register
US_IMR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
MANE
19
CTSIC
18
DCDIC
17
DSRIC
16
RIIC
15
–
14
–
13
NACK
12
RXBUFF
11
TXBUFE
10
ITER
9
TXEMPTY
8
TIMEOUT
7
PARE
6
FRAME
5
OVRE
4
ENDTX
3
ENDRX
2
RXBRK
1
TXRDY
0
RXRDY
• RXRDY: RXRDY Interrupt Mask
• TXRDY: TXRDY Interrupt Mask
• RXBRK: Receiver Break Interrupt Mask
• ENDRX: End of Receive Transfer Interrupt Mask
• ENDTX: End of Transmit Interrupt Mask
• OVRE: Overrun Error Interrupt Mask
• FRAME: Framing Error Interrupt Mask
• PARE: Parity Error Interrupt Mask
• TIMEOUT: Time-out Interrupt Mask
• TXEMPTY: TXEMPTY Interrupt Mask
• ITER: Iteration Interrupt Enable
• TXBUFE: Buffer Empty Interrupt Mask
• RXBUFF: Buffer Full Interrupt Mask
• NACK: Non Acknowledge Interrupt Mask
• RIIC: Ring Indicator Input Change Mask
• DSRIC: Data Set Ready Input Change Mask
• DCDIC: Data Carrier Detect Input Change Interrupt Mask
• CTSIC: Clear to Send Input Change Interrupt Mask
• MANE: Manchester Error Interrupt Mask
SAM7L128/64 [DATASHEET]
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30.7.6
Name:
USART Channel Status Register
US_CSR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
MANERR
23
CTS
22
DCD
21
DSR
20
RI
19
CTSIC
18
DCDIC
17
DSRIC
16
RIIC
15
–
14
–
13
NACK
12
RXBUFF
11
TXBUFE
10
ITER
9
TXEMPTY
8
TIMEOUT
7
PARE
6
FRAME
5
OVRE
4
ENDTX
3
ENDRX
2
RXBRK
1
TXRDY
0
RXRDY
• RXRDY: Receiver Ready
0: No complete character has been received since the last read of US_RHR or the receiver is disabled. If characters were
being received when the receiver was disabled, RXRDY changes to 1 when the receiver is enabled.
1: At least one complete character has been received and US_RHR has not yet been read.
• TXRDY: Transmitter Ready
0: A character is in the US_THR waiting to be transferred to the Transmit Shift Register, or an STTBRK command has been
requested, or the transmitter is disabled. As soon as the transmitter is enabled, TXRDY becomes 1.
1: There is no character in the US_THR.
• RXBRK: Break Received/End of Break
0: No Break received or End of Break detected since the last RSTSTA.
1: Break Received or End of Break detected since the last RSTSTA.
• ENDRX: End of Receiver Transfer
0: The End of Transfer signal from the Receive PDC channel is inactive.
1: The End of Transfer signal from the Receive PDC channel is active.
• ENDTX: End of Transmitter Transfer
0: The End of Transfer signal from the Transmit PDC channel is inactive.
1: The End of Transfer signal from the Transmit PDC channel is active.
• OVRE: Overrun Error
0: No overrun error has occurred since the last RSTSTA.
1: At least one overrun error has occurred since the last RSTSTA.
• FRAME: Framing Error
0: No stop bit has been detected low since the last RSTSTA.
1: At least one stop bit has been detected low since the last RSTSTA.
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• PARE: Parity Error
0: No parity error has been detected since the last RSTSTA.
1: At least one parity error has been detected since the last RSTSTA.
• TIMEOUT: Receiver Time-out
0: There has not been a time-out since the last Start Time-out command (STTTO in US_CR) or the Time-out Register is 0.
1: There has been a time-out since the last Start Time-out command (STTTO in US_CR).
• TXEMPTY: Transmitter Empty
0: There are characters in either US_THR or the Transmit Shift Register, or the transmitter is disabled.
1: There are no characters in US_THR, nor in the Transmit Shift Register.
• ITER: Max number of Repetitions Reached
0: Maximum number of repetitions has not been reached since the last RSTSTA.
1: Maximum number of repetitions has been reached since the last RSTSTA.
• TXBUFE: Transmission Buffer Empty
0: The signal Buffer Empty from the Transmit PDC channel is inactive.
1: The signal Buffer Empty from the Transmit PDC channel is active.
• RXBUFF: Reception Buffer Full
0: The signal Buffer Full from the Receive PDC channel is inactive.
1: The signal Buffer Full from the Receive PDC channel is active.
• NACK: Non Acknowledge
0: No Non Acknowledge has not been detected since the last RSTNACK.
1: At least one Non Acknowledge has been detected since the last RSTNACK.
• RIIC: Ring Indicator Input Change Flag
0: No input change has been detected on the RI pin since the last read of US_CSR.
1: At least one input change has been detected on the RI pin since the last read of US_CSR.
• DSRIC: Data Set Ready Input Change Flag
0: No input change has been detected on the DSR pin since the last read of US_CSR.
1: At least one input change has been detected on the DSR pin since the last read of US_CSR.
• DCDIC: Data Carrier Detect Input Change Flag
0: No input change has been detected on the DCD pin since the last read of US_CSR.
1: At least one input change has been detected on the DCD pin since the last read of US_CSR.
• CTSIC: Clear to Send Input Change Flag
0: No input change has been detected on the CTS pin since the last read of US_CSR.
1: At least one input change has been detected on the CTS pin since the last read of US_CSR.
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• RI: Image of RI Input
0: RI is at 0.
1: RI is at 1.
• DSR: Image of DSR Input
0: DSR is at 0
1: DSR is at 1.
• DCD: Image of DCD Input
0: DCD is at 0.
1: DCD is at 1.
• CTS: Image of CTS Input
0: CTS is at 0.
1: CTS is at 1.
• MANERR: Manchester Error
0: No Manchester error has been detected since the last RSTSTA.
1: At least one Manchester error has been detected since the last RSTSTA.
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30.7.7
Name:
USART Receive Holding Register
US_RHR
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
RXSYNH
14
–
13
–
12
–
11
–
10
–
9
–
8
RXCHR
7
6
5
4
3
2
1
0
RXCHR
• RXCHR: Received Character
Last character received if RXRDY is set.
• RXSYNH: Received Sync
0: Last Character received is a Data.
1: Last Character received is a Command.
SAM7L128/64 [DATASHEET]
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30.7.8
Name:
USART Transmit Holding Register
US_THR
Access Type:
Write-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
TXSYNH
14
–
13
–
12
–
11
–
10
–
9
–
8
TXCHR
7
6
5
4
3
2
1
0
TXCHR
• TXCHR: Character to be Transmitted
Next character to be transmitted after the current character if TXRDY is not set.
• TXSYNH: Sync Field to be transmitted
0: The next character sent is encoded as a data. Start Frame Delimiter is DATA SYNC.
1: The next character sent is encoded as a command. Start Frame Delimiter is COMMAND SYNC.
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30.7.9
Name:
USART Baud Rate Generator Register
US_BRGR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
17
FP–
16
15
14
13
12
11
10
9
8
3
2
1
0
CD
7
6
5
4
CD
• CD: Clock Divider
USART_MODE ≠ ISO7816
SYNC = 0
CD
OVER = 0
0
1 to 65535
SYNC = 1
OVER = 1
USART_MODE =
ISO7816
Baud Rate Clock Disabled
Baud Rate =
Selected Clock/16/CD
Baud Rate =
Selected Clock/8/CD
Baud Rate =
Selected Clock /CD
Baud Rate = Selected
Clock/CD/FI_DI_RATIO
• FP: Fractional Part
0: Fractional divider is disabled.
1 - 7: Baudrate resolution, defined by FP x 1/8.
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30.7.10
Name:
USART Receiver Time-out Register
US_RTOR
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
14
13
12
11
10
9
8
3
2
1
0
TO
7
6
5
4
TO
• TO: Time-out Value
0: The Receiver Time-out is disabled.
1 - 65535: The Receiver Time-out is enabled and the Time-out delay is TO x Bit Period.
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30.7.11
Name:
USART Transmitter Timeguard Register
US_TTGR
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
6
5
4
3
2
1
0
TG
• TG: Timeguard Value
0: The Transmitter Timeguard is disabled.
1 - 255: The Transmitter timeguard is enabled and the timeguard delay is TG x Bit Period.
SAM7L128/64 [DATASHEET]
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30.7.12
Name:
USART FI DI RATIO Register
US_FIDI
Access Type:
Read-write
Reset Value:
0x174
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
9
FI_DI_RATIO
8
7
6
5
4
3
2
1
0
FI_DI_RATIO
• FI_DI_RATIO: FI Over DI Ratio Value
0: If ISO7816 mode is selected, the Baud Rate Generator generates no signal.
1 - 2047: If ISO7816 mode is selected, the Baud Rate is the clock provided on SCK divided by FI_DI_RATIO.
SAM7L128/64 [DATASHEET]
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30.7.13
Name:
USART Number of Errors Register
US_NER
Access Type:
Read-only
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
6
5
4
3
2
1
0
NB_ERRORS
• NB_ERRORS: Number of Errors
Total number of errors that occurred during an ISO7816 transfer. This register automatically clears when read.
SAM7L128/64 [DATASHEET]
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30.7.14
Name:
USART IrDA FILTER Register
US_IF
Access Type:
Read-write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
–
9
–
8
–
7
6
5
4
3
2
1
0
IRDA_FILTER
• IRDA_FILTER: IrDA Filter
Sets the filter of the IrDA demodulator.
SAM7L128/64 [DATASHEET]
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30.7.15
Name:
USART Manchester Configuration Register
US_MAN
Access Type:
Read-write
31
–
30
DRIFT
29
1
28
RX_MPOL
27
–
26
–
25
23
–
22
–
21
–
20
–
19
18
15
–
14
–
13
–
12
TX_MPOL
11
–
10
–
9
7
–
6
–
5
–
4
–
3
2
1
24
RX_PP
17
16
RX_PL
8
TX_PP
0
TX_PL
• TX_PL: Transmitter Preamble Length
0: The Transmitter Preamble pattern generation is disabled
1 - 15: The Preamble Length is TX_PL x Bit Period
• TX_PP: Transmitter Preamble Pattern
TX_PP
Preamble Pattern default polarity assumed (TX_MPOL field not set)
0
0
ALL_ONE
0
1
ALL_ZERO
1
0
ZERO_ONE
1
1
ONE_ZERO
• TX_MPOL: Transmitter Manchester Polarity
0: Logic Zero is coded as a zero-to-one transition, Logic One is coded as a one-to-zero transition.
1: Logic Zero is coded as a one-to-zero transition, Logic One is coded as a zero-to-one transition.
• RX_PL: Receiver Preamble Length
0: The receiver preamble pattern detection is disabled
1 - 15: The detected preamble length is RX_PL x Bit Period
• RX_PP: Receiver Preamble Pattern Detected
RX_PP
Preamble Pattern default polarity assumed (RX_MPOL field not set)
0
0
ALL_ONE
0
1
ALL_ZERO
1
0
ZERO_ONE
1
1
ONE_ZERO
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• RX_MPOL: Receiver Manchester Polarity
0: Logic Zero is coded as a zero-to-one transition, Logic One is coded as a one-to-zero transition.
1: Logic Zero is coded as a one-to-zero transition, Logic One is coded as a zero-to-one transition.
• DRIFT: Drift Compensation
0: The USART can not recover from an important clock drift
1: The USART can recover from clock drift. The 16X clock mode must be enabled.
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31. Timer Counter (TC)
31.1
Overview
The Timer Counter (TC) includes three identical 16-bit Timer Counter channels.
Each channel can be independently programmed to perform a wide range of functions including frequency measurement, event counting, interval measurement, pulse generation, delay timing and pulse width modulation.
Each channel has three external clock inputs, five internal clock inputs and two multi-purpose input/output signals
which can be configured by the user. Each channel drives an internal interrupt signal which can be programmed to
generate processor interrupts.
The Timer Counter block has two global registers which act upon all three TC channels.
The Block Control Register allows the three channels to be started simultaneously with the same instruction.
The Block Mode Register defines the external clock inputs for each channel, allowing them to be chained.
Table 31-1 gives the assignment of the device Timer Counter clock inputs common to Timer Counter 0 to 2
Table 31-1.
Timer Counter Clock Assignment
Name
Definition
TIMER_CLOCK1
Timerclock1
TIMER_CLOCK2
Timercock2
TIMER_CLOCK3
Timerclock3
TIMER_CLOCK4
Timerclock4
TIMER_CLOCK5
Timerclock5
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31.2
Block Diagram
Figure 31-1. Timer Counter Block Diagram
Parallel I/O
Controller
TIMER_CLOCK1
TCLK0
TIMER_CLOCK2
TIOA1
TIOA2
TIMER_CLOCK3
TIMER_CLOCK4
XC0
TCLK1
XC1
TCLK2
XC2
Timer/Counter
Channel 0
TIOA
TIOA0
TIOB0
TIOA0
TIOB
TIMER_CLOCK5
TC0XC0S
TIOB0
SYNC
TCLK0
TCLK1
TCLK2
INT0
TCLK0
TCLK1
XC0
TIOA0
XC1
Timer/Counter
Channel 1
TIOA
TIOA1
TIOB1
TIOA1
TIOB
TIOA2
TCLK2
TIOB1
XC2
TC1XC1S
TCLK0
XC0
TCLK1
XC1
SYNC
Timer/Counter
Channel 2
INT1
TIOA
TIOA2
TIOB2
TIOA2
TIOB
TCLK2
XC2
TIOA0
TIOA1
TC2XC2S
TIOB2
SYNC
INT2
Timer Counter
Advanced
Interrupt
Controller
Table 31-2.
Signal Name Description
Block/Channel
Signal Name
XC0, XC1, XC2
Channel Signal
Description
External Clock Inputs
TIOA
Capture Mode: Timer Counter Input
Waveform Mode: Timer Counter Output
TIOB
Capture Mode: Timer Counter Input
Waveform Mode: Timer Counter Input/Output
INT
SYNC
Interrupt Signal Output
Synchronization Input Signal
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31.3
Pin Name List
Table 31-3.
TC pin list
Pin Name
Description
Type
TCLK0-TCLK2
External Clock Input
Input
TIOA0-TIOA2
I/O Line A
I/O
TIOB0-TIOB2
I/O Line B
I/O
31.4
Product Dependencies
31.4.1
I/O Lines
The pins used for interfacing the compliant external devices may be multiplexed with PIO lines. The programmer
must first program the PIO controllers to assign the TC pins to their peripheral functions.
31.4.2
Power Management
The TC is clocked through the Power Management Controller (PMC), thus the programmer must first configure the
PMC to enable the Timer Counter clock.
31.4.3
Interrupt
The TC has an interrupt line connected to the Advanced Interrupt Controller (AIC). Handling the TC interrupt
requires programming the AIC before configuring the TC.
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31.5
Functional Description
31.5.1
TC Description
The three channels of the Timer Counter are independent and identical in operation. The registers for channel programming are listed in Table 31-4 on page 422.
31.5.2
16-bit Counter
Each channel is organized around a 16-bit counter. The value of the counter is incremented at each positive edge
of the selected clock. When the counter has reached the value 0xFFFF and passes to 0x0000, an overflow occurs
and the COVFS bit in TC_SR (Status Register) is set.
The current value of the counter is accessible in real time by reading the Counter Value Register, TC_CV. The
counter can be reset by a trigger. In this case, the counter value passes to 0x0000 on the next valid edge of the
selected clock.
31.5.3
Clock Selection
At block level, input clock signals of each channel can either be connected to the external inputs TCLK0, TCLK1 or
TCLK2, or be connected to the internal I/O signals TIOA0, TIOA1 or TIOA2 for chaining by programming the
TC_BMR (Block Mode). See Figure 31-2 on page 411.
Each channel can independently select an internal or external clock source for its counter:
•
Internal clock signals: TIMER_CLOCK1, TIMER_CLOCK2, TIMER_CLOCK3, TIMER_CLOCK4,
TIMER_CLOCK5
•
External clock signals: XC0, XC1 or XC2
This selection is made by the TCCLKS bits in the TC Channel Mode Register.
The selected clock can be inverted with the CLKI bit in TC_CMR. This allows counting on the opposite edges of the
clock.
The burst function allows the clock to be validated when an external signal is high. The BURST parameter in the
Mode Register defines this signal (none, XC0, XC1, XC2). See Figure 31-3 on page 411
Note:
In all cases, if an external clock is used, the duration of each of its levels must be longer than the master clock period.
The external clock frequency must be at least 2.5 times lower than the master clock
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Figure 31-2. Clock Chaining Selection
TC0XC0S
Timer/Counter
Channel 0
TCLK0
TIOA1
XC0
TIOA2
TIOA0
XC1 = TCLK1
XC2 = TCLK2
TIOB0
SYNC
TC1XC1S
Timer/Counter
Channel 1
TCLK1
XC0 = TCLK2
TIOA0
TIOA1
XC1
TIOA2
XC2 = TCLK2
TIOB1
SYNC
Timer/Counter
Channel 2
TC2XC2S
XC0 = TCLK0
TCLK2
TIOA2
XC1 = TCLK1
TIOA0
XC2
TIOB2
TIOA1
SYNC
Figure 31-3. Clock Selection
TCCLKS
TIMER_CLOCK1
TIMER_CLOCK2
CLKI
TIMER_CLOCK3
TIMER_CLOCK4
TIMER_CLOCK5
Selected
Clock
XC0
XC1
XC2
BURST
1
SAM7L128/64 [DATASHEET]
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31.5.4
Clock Control
The clock of each counter can be controlled in two different ways: it can be enabled/disabled and started/stopped.
See Figure 31-4.
•
The clock can be enabled or disabled by the user with the CLKEN and the CLKDIS commands in the Control
Register. In Capture Mode it can be disabled by an RB load event if LDBDIS is set to 1 in TC_CMR. In
Waveform Mode, it can be disabled by an RC Compare event if CPCDIS is set to 1 in TC_CMR. When
disabled, the start or the stop actions have no effect: only a CLKEN command in the Control Register can reenable the clock. When the clock is enabled, the CLKSTA bit is set in the Status Register.
•
The clock can also be started or stopped: a trigger (software, synchro, external or compare) always starts the
clock. The clock can be stopped by an RB load event in Capture Mode (LDBSTOP = 1 in TC_CMR) or a RC
compare event in Waveform Mode (CPCSTOP = 1 in TC_CMR). The start and the stop commands have effect
only if the clock is enabled.
Figure 31-4. Clock Control
Selected
Clock
Trigger
CLKSTA
Q
Q
S
CLKEN
CLKDIS
S
R
R
Counter
Clock
31.5.5
Stop
Event
Disable
Event
TC Operating Modes
Each channel can independently operate in two different modes:
•
Capture Mode provides measurement on signals.
•
Waveform Mode provides wave generation.
The TC Operating Mode is programmed with the WAVE bit in the TC Channel Mode Register.
In Capture Mode, TIOA and TIOB are configured as inputs.
In Waveform Mode, TIOA is always configured to be an output and TIOB is an output if it is not selected to be the
external trigger.
31.5.6
Trigger
A trigger resets the counter and starts the counter clock. Three types of triggers are common to both modes, and a
fourth external trigger is available to each mode.
The following triggers are common to both modes:
•
Software Trigger: Each channel has a software trigger, available by setting SWTRG in TC_CCR.
SAM7L128/64 [DATASHEET]
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•
SYNC: Each channel has a synchronization signal SYNC. When asserted, this signal has the same effect as a
software trigger. The SYNC signals of all channels are asserted simultaneously by writing TC_BCR (Block
Control) with SYNC set.
•
Compare RC Trigger: RC is implemented in each channel and can provide a trigger when the counter value
matches the RC value if CPCTRG is set in TC_CMR.
The channel can also be configured to have an external trigger. In Capture Mode, the external trigger signal can be
selected between TIOA and TIOB. In Waveform Mode, an external event can be programmed on one of the following signals: TIOB, XC0, XC1 or XC2. This external event can then be programmed to perform a trigger by setting
ENETRG in TC_CMR.
If an external trigger is used, the duration of the pulses must be longer than the master clock period in order to be
detected.
Regardless of the trigger used, it will be taken into account at the following active edge of the selected clock. This
means that the counter value can be read differently from zero just after a trigger, especially when a low frequency
signal is selected as the clock.
31.5.7
Capture Operating Mode
This mode is entered by clearing the WAVE parameter in TC_CMR (Channel Mode Register).
Capture Mode allows the TC channel to perform measurements such as pulse timing, frequency, period, duty cycle
and phase on TIOA and TIOB signals which are considered as inputs.
Figure 31-5 shows the configuration of the TC channel when programmed in Capture Mode.
31.5.8
Capture Registers A and B
Registers A and B (RA and RB) are used as capture registers. This means that they can be loaded with the counter
value when a programmable event occurs on the signal TIOA.
The LDRA parameter in TC_CMR defines the TIOA edge for the loading of register A, and the LDRB parameter
defines the TIOA edge for the loading of Register B.
RA is loaded only if it has not been loaded since the last trigger or if RB has been loaded since the last loading of
RA.
RB is loaded only if RA has been loaded since the last trigger or the last loading of RB.
Loading RA or RB before the read of the last value loaded sets the Overrun Error Flag (LOVRS) in TC_SR (Status
Register). In this case, the old value is overwritten.
31.5.9
Trigger Conditions
In addition to the SYNC signal, the software trigger and the RC compare trigger, an external trigger can be defined.
The ABETRG bit in TC_CMR selects TIOA or TIOB input signal as an external trigger. The ETRGEDG parameter
defines the edge (rising, falling or both) detected to generate an external trigger. If ETRGEDG = 0 (none), the
external trigger is disabled.
SAM7L128/64 [DATASHEET]
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MTIOA
MTIOB
1
If RA is not loaded
or RB is Loaded
Edge
Detector
ETRGEDG
SWTRG
Timer/Counter Channel
ABETRG
BURST
CLKI
R
S
OVF
LDRB
Edge
Detector
Edge
Detector
Capture
Register A
LDBSTOP
R
S
CLKEN
LDRA
If RA is Loaded
CPCTRG
16-bit Counter
RESET
Trig
CLK
Q
Q
CLKSTA
LDBDIS
Capture
Register B
CLKDIS
TC1_SR
TIOA
TIOB
SYNC
XC2
XC1
XC0
TIMER_CLOCK5
TIMER_CLOCK4
TIMER_CLOCK3
TIMER_CLOCK2
TIMER_CLOCK1
TCCLKS
Compare RC =
Register C
COVFS
INT
Figure 31-5. Capture Mode
LOVRS
CPCS
LDRBS
LDRAS
ETRGS
TC1_IMR
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31.5.10
Waveform Operating Mode
Waveform operating mode is entered by setting the WAVE parameter in TC_CMR (Channel Mode Register).
In Waveform Operating Mode the TC channel generates 1 or 2 PWM signals with the same frequency and independently programmable duty cycles, or generates different types of one-shot or repetitive pulses.
In this mode, TIOA is configured as an output and TIOB is defined as an output if it is not used as an external event
(EEVT parameter in TC_CMR).
Figure 31-6 shows the configuration of the TC channel when programmed in Waveform Operating Mode.
31.5.11
Waveform Selection
Depending on the WAVSEL parameter in TC_CMR (Channel Mode Register), the behavior of TC_CV varies.
With any selection, RA, RB and RC can all be used as compare registers.
RA Compare is used to control the TIOA output, RB Compare is used to control the TIOB output (if correctly configured) and RC Compare is used to control TIOA and/or TIOB outputs.
SAM7L128/64 [DATASHEET]
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TIOB
SYNC
XC2
XC1
XC0
TIMER_CLOCK5
TIMER_CLOCK4
TIMER_CLOCK3
TIMER_CLOCK2
TIMER_CLOCK1
1
EEVT
BURST
Timer/Counter Channel
Edge
Detector
EEVTEDG
SWTRG
ENETRG
CLKI
Trig
CLK
R
S
OVF
WAVSEL
RESET
16-bit Counter
WAVSEL
Q
Compare RA =
Register A
Q
CLKSTA
Compare RC =
Compare RB =
CPCSTOP
CPCDIS
Register C
CLKDIS
Register B
R
S
CLKEN
CPAS
INT
BSWTRG
BEEVT
BCPB
BCPC
ASWTRG
AEEVT
ACPA
ACPC
Output Controller
Output Controller
TCCLKS
TIOB
MTIOB
TIOA
MTIOA
Figure 31-6. Waveform Mode
CPCS
CPBS
COVFS
TC1_SR
ETRGS
TC1_IMR
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31.5.11.1
W
AVSEL = 00
When WAVSEL = 00, the value of TC_CV is incremented from 0 to 0xFFFF. Once 0xFFFF has been reached, the
value of TC_CV is reset. Incrementation of TC_CV starts again and the cycle continues. See Figure 31-7.
An external event trigger or a software trigger can reset the value of TC_CV. It is important to note that the trigger
may occur at any time. See Figure 31-8.
RC Compare cannot be programmed to generate a trigger in this configuration. At the same time, RC Compare
can stop the counter clock (CPCSTOP = 1 in TC_CMR) and/or disable the counter clock (CPCDIS = 1 in
TC_CMR).
Figure 31-7. WAVSEL= 00 without trigger
Counter Value
Counter cleared by compare match with 0xFFFF
0xFFFF
RC
RB
RA
Time
Waveform Examples
TIOB
TIOA
Figure 31-8. WAVSEL= 00 with trigger
Counter Value
Counter cleared by compare match with 0xFFFF
0xFFFF
RC
Counter cleared by trigger
RB
RA
Waveform Examples
Time
TIOB
TIOA
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31.5.11.2
W
AVSEL = 10
When WAVSEL = 10, the value of TC_CV is incremented from 0 to the value of RC, then automatically reset on a
RC Compare. Once the value of TC_CV has been reset, it is then incremented and so on. See Figure 31-9.
It is important to note that TC_CV can be reset at any time by an external event or a software trigger if both are programmed correctly. See Figure 31-10.
In addition, RC Compare can stop the counter clock (CPCSTOP = 1 in TC_CMR) and/or disable the counter clock
(CPCDIS = 1 in TC_CMR).
Figure 31-9. WAVSEL = 10 Without Trigger
Counter Value
0xFFFF
Counter cleared by compare match with RC
RC
RB
RA
Waveform Examples
Time
TIOB
TIOA
Figure 31-10. WAVSEL = 10 With Trigger
Counter Value
0xFFFF
Counter cleared by compare match with RC
Counter cleared by trigger
RC
RB
RA
Waveform Examples
Time
TIOB
TIOA
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31.5.11.3
W
AVSEL = 01
When WAVSEL = 01, the value of TC_CV is incremented from 0 to 0xFFFF. Once 0xFFFF is reached, the value of
TC_CV is decremented to 0, then re-incremented to 0xFFFF and so on. See Figure 31-11.
A trigger such as an external event or a software trigger can modify TC_CV at any time. If a trigger occurs while
TC_CV is incrementing, TC_CV then decrements. If a trigger is received while TC_CV is decrementing, TC_CV
then increments. See Figure 31-12.
RC Compare cannot be programmed to generate a trigger in this configuration.
At the same time, RC Compare can stop the counter clock (CPCSTOP = 1) and/or disable the counter clock (CPCDIS = 1).
Figure 31-11. WAVSEL = 01 Without Trigger
Counter Value
Counter decremented by compare match with 0xFFFF
0xFFFF
RC
RB
RA
Time
Waveform Examples
TIOB
TIOA
Figure 31-12. WAVSEL = 01 With Trigger
Counter Value
Counter decremented by compare match with 0xFFFF
0xFFFF
Counter decremented
by trigger
RC
RB
Counter incremented
by trigger
RA
Waveform Examples
Time
TIOB
TIOA
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31.5.11.4
W
AVSEL = 11
When WAVSEL = 11, the value of TC_CV is incremented from 0 to RC. Once RC is reached, the value of TC_CV
is decremented to 0, then re-incremented to RC and so on. See Figure 31-13.
A trigger such as an external event or a software trigger can modify TC_CV at any time. If a trigger occurs while
TC_CV is incrementing, TC_CV then decrements. If a trigger is received while TC_CV is decrementing, TC_CV
then increments. See Figure 31-14.
RC Compare can stop the counter clock (CPCSTOP = 1) and/or disable the counter clock (CPCDIS = 1).
Figure 31-13. WAVSEL = 11 Without Trigger
Counter Value
0xFFFF
Counter decremented by compare match with RC
RC
RB
RA
Time
Waveform Examples
TIOB
TIOA
Figure 31-14. WAVSEL = 11 With Trigger
Counter Value
0xFFFF
Counter decremented by compare match with RC
RC
RB
Counter decremented
by trigger
Counter incremented
by trigger
RA
Waveform Examples
Time
TIOB
TIOA
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31.5.12
External Event/Trigger Conditions
An external event can be programmed to be detected on one of the clock sources (XC0, XC1, XC2) or TIOB. The
external event selected can then be used as a trigger.
The EEVT parameter in TC_CMR selects the external trigger. The EEVTEDG parameter defines the trigger edge
for each of the possible external triggers (rising, falling or both). If EEVTEDG is cleared (none), no external event is
defined.
If TIOB is defined as an external event signal (EEVT = 0), TIOB is no longer used as an output and the compare
register B is not used to generate waveforms and subsequently no IRQs. In this case the TC channel can only generate a waveform on TIOA.
When an external event is defined, it can be used as a trigger by setting bit ENETRG in TC_CMR.
As in Capture Mode, the SYNC signal and the software trigger are also available as triggers. RC Compare can also
be used as a trigger depending on the parameter WAVSEL.
31.5.13
Output Controller
The output controller defines the output level changes on TIOA and TIOB following an event. TIOB control is used
only if TIOB is defined as output (not as an external event).
The following events control TIOA and TIOB: software trigger, external event and RC compare. RA compare controls TIOA and RB compare controls TIOB. Each of these events can be programmed to set, clear or toggle the
output as defined in the corresponding parameter in TC_CMR.
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31.6
Timer Counter (TC) User Interface
Table 31-4.
Register Mapping
Offset(1)
Register
Name
Access
Reset
0x00 + channel * 0x40 + 0x00
Channel Control Register
TC_CCR
Write-only
–
0x00 + channel * 0x40 + 0x04
Channel Mode Register
TC_CMR
Read-write
0
0x00 + channel * 0x40 + 0x08
Reserved
0x00 + channel * 0x40 + 0x0C
Reserved
0x00 + channel * 0x40 + 0x10
Counter Value
TC_CV
Read-only
0
(2)
0x00 + channel * 0x40 + 0x14
Register A
TC_RA
Read-write
0
0x00 + channel * 0x40 + 0x18
Register B
TC_RB
Read-write(2)
0
0x00 + channel * 0x40 + 0x1C
Register C
TC_RC
Read-write
0
0x00 + channel * 0x40 + 0x20
Status Register
TC_SR
Read-only
0
0x00 + channel * 0x40 + 0x24
Interrupt Enable Register
TC_IER
Write-only
–
0x00 + channel * 0x40 + 0x28
Interrupt Disable Register
TC_IDR
Write-only
–
0x00 + channel * 0x40 + 0x2C
Interrupt Mask Register
TC_IMR
Read-only
0
0xC0
Block Control Register
TC_BCR
Write-only
–
0xC4
Block Mode Register
TC_BMR
Read-write
0
0xFC
Reserved
–
–
–
Notes:
1. Channel index ranges from 0 to 2.
2. Read-only if WAVE = 0
SAM7L128/64 [DATASHEET]
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31.6.1
TC Block Control Register
Register Name:
TC_BCR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
SYNC
• SYNC: Synchro Command
0 = No effect.
1 = Asserts the SYNC signal which generates a software trigger simultaneously for each of the channels.
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31.6.2
TC Block Mode Register
Register Name:
TC_BMR
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
–
–
TC2XC2S
TC1XC1S
0
TC0XC0S
• TC0XC0S: External Clock Signal 0 Selection
TC0XC0S
Signal Connected to XC0
0
0
TCLK0
0
1
none
1
0
TIOA1
1
1
TIOA2
• TC1XC1S: External Clock Signal 1 Selection
TC1XC1S
Signal Connected to XC1
0
0
TCLK1
0
1
none
1
0
TIOA0
1
1
TIOA2
• TC2XC2S: External Clock Signal 2 Selection
TC2XC2S
Signal Connected to XC2
0
0
TCLK2
0
1
none
1
0
TIOA0
1
1
TIOA1
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31.6.3
TC Channel Control Register
Register Name:
TC_CCRx [x=0..2]
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
SWTRG
CLKDIS
CLKEN
• CLKEN: Counter Clock Enable Command
0 = No effect.
1 = Enables the clock if CLKDIS is not 1.
• CLKDIS: Counter Clock Disable Command
0 = No effect.
1 = Disables the clock.
• SWTRG: Software Trigger Command
0 = No effect.
1 = A software trigger is performed: the counter is reset and the clock is started.
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31.6.4
TC Channel Mode Register: Capture Mode
Register Name:
TC_CMRx [x=0..2] (WAVE = 0)
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
–
–
–
–
15
14
13
12
11
10
WAVE
CPCTRG
–
–
–
ABETRG
7
6
5
3
2
LDBDIS
LDBSTOP
16
LDRB
4
BURST
CLKI
LDRA
9
8
ETRGEDG
1
0
TCCLKS
• TCCLKS: Clock Selection
TCCLKS
Clock Selected
0
0
0
TIMER_CLOCK1
0
0
1
TIMER_CLOCK2
0
1
0
TIMER_CLOCK3
0
1
1
TIMER_CLOCK4
1
0
0
TIMER_CLOCK5
1
0
1
XC0
1
1
0
XC1
1
1
1
XC2
• CLKI: Clock Invert
0 = Counter is incremented on rising edge of the clock.
1 = Counter is incremented on falling edge of the clock.
• BURST: Burst Signal Selection
BURST
0
0
The clock is not gated by an external signal.
0
1
XC0 is ANDed with the selected clock.
1
0
XC1 is ANDed with the selected clock.
1
1
XC2 is ANDed with the selected clock.
• LDBSTOP: Counter Clock Stopped with RB Loading
0 = Counter clock is not stopped when RB loading occurs.
1 = Counter clock is stopped when RB loading occurs.
• LDBDIS: Counter Clock Disable with RB Loading
0 = Counter clock is not disabled when RB loading occurs.
1 = Counter clock is disabled when RB loading occurs.
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• ETRGEDG: External Trigger Edge Selection
ETRGEDG
Edge
0
0
none
0
1
rising edge
1
0
falling edge
1
1
each edge
• ABETRG: TIOA or TIOB External Trigger Selection
0 = TIOB is used as an external trigger.
1 = TIOA is used as an external trigger.
• CPCTRG: RC Compare Trigger Enable
0 = RC Compare has no effect on the counter and its clock.
1 = RC Compare resets the counter and starts the counter clock.
• WAVE
0 = Capture Mode is enabled.
1 = Capture Mode is disabled (Waveform Mode is enabled).
• LDRA: RA Loading Selection
LDRA
Edge
0
0
none
0
1
rising edge of TIOA
1
0
falling edge of TIOA
1
1
each edge of TIOA
• LDRB: RB Loading Selection
LDRB
Edge
0
0
none
0
1
rising edge of TIOA
1
0
falling edge of TIOA
1
1
each edge of TIOA
SAM7L128/64 [DATASHEET]
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31.6.5
TC Channel Mode Register: Waveform Mode
Register Name:
TC_CMRx [x=0..2] (WAVE = 1)
Access Type:
Read-write
31
30
29
BSWTRG
23
22
21
ASWTRG
15
28
27
BEEVT
20
19
AEEVT
14
WAVE
13
7
6
CPCDIS
CPCSTOP
24
BCPB
18
11
ENETRG
5
25
17
16
ACPC
12
WAVSEL
26
BCPC
ACPA
10
9
EEVT
4
3
BURST
CLKI
8
EEVTEDG
2
1
0
TCCLKS
• TCCLKS: Clock Selection
TCCLKS
Clock Selected
0
0
0
TIMER_CLOCK1
0
0
1
TIMER_CLOCK2
0
1
0
TIMER_CLOCK3
0
1
1
TIMER_CLOCK4
1
0
0
TIMER_CLOCK5
1
0
1
XC0
1
1
0
XC1
1
1
1
XC2
• CLKI: Clock Invert
0 = Counter is incremented on rising edge of the clock.
1 = Counter is incremented on falling edge of the clock.
• BURST: Burst Signal Selection
BURST
0
0
The clock is not gated by an external signal.
0
1
XC0 is ANDed with the selected clock.
1
0
XC1 is ANDed with the selected clock.
1
1
XC2 is ANDed with the selected clock.
• CPCSTOP: Counter Clock Stopped with RC Compare
0 = Counter clock is not stopped when counter reaches RC.
1 = Counter clock is stopped when counter reaches RC.
• CPCDIS: Counter Clock Disable with RC Compare
0 = Counter clock is not disabled when counter reaches RC.
1 = Counter clock is disabled when counter reaches RC.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
428
• EEVTEDG: External Event Edge Selection
EEVTEDG
Edge
0
0
none
0
1
rising edge
1
0
falling edge
1
1
each edge
• EEVT: External Event Selection
EEVT
Signal selected as external event
TIOB Direction
0
0
TIOB
input (1)
0
1
XC0
output
1
0
XC1
output
1
1
XC2
output
1. If TIOB is chosen as the external event signal, it is configured as an input and no longer generates waveforms and subsequently no IRQs.
Note:
• ENETRG: External Event Trigger Enable
0 = The external event has no effect on the counter and its clock. In this case, the selected external event only controls the
TIOA output.
1 = The external event resets the counter and starts the counter clock.
• WAVSEL: Waveform Selection
WAVSEL
Effect
0
0
UP mode without automatic trigger on RC Compare
1
0
UP mode with automatic trigger on RC Compare
0
1
UPDOWN mode without automatic trigger on RC Compare
1
1
UPDOWN mode with automatic trigger on RC Compare
• WAVE
0 = Waveform Mode is disabled (Capture Mode is enabled).
1 = Waveform Mode is enabled.
• ACPA: RA Compare Effect on TIOA
ACPA
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
429
• ACPC: RC Compare Effect on TIOA
ACPC
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
• AEEVT: External Event Effect on TIOA
AEEVT
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
• ASWTRG: Software Trigger Effect on TIOA
ASWTRG
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
• BCPB: RB Compare Effect on TIOB
BCPB
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
• BCPC: RC Compare Effect on TIOB
BCPC
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
430
• BEEVT: External Event Effect on TIOB
BEEVT
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
• BSWTRG: Software Trigger Effect on TIOB
BSWTRG
Effect
0
0
none
0
1
set
1
0
clear
1
1
toggle
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
431
31.6.6
TC Counter Value Register
Register Name:
TC_CVx [x=0..2]
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
3
2
1
0
CV
7
6
5
4
CV
• CV: Counter Value
CV contains the counter value in real time.
31.6.7
TC Register A
Register Name:
TC_RAx [x=0..2]
Access Type:
Read-only if WAVE = 0, Read-write if WAVE = 1
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
3
2
1
0
RA
7
6
5
4
RA
• RA: Register A
RA contains the Register A value in real time.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
432
31.6.8
TC Register B
Register Name:
TC_RBx [x=0..2]
Access Type:
Read-only if WAVE = 0, Read-write if WAVE = 1
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
3
2
1
0
RB
7
6
5
4
RB
• RB: Register B
RB contains the Register B value in real time.
31.6.9
TC Register C
Register Name:
TC_RCx [x=0..2]
Access Type:
Read-write
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
3
2
1
0
RC
7
6
5
4
RC
• RC: Register C
RC contains the Register C value in real time.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
433
31.6.10 TC Status Register
Register Name:
TC_SRx [x=0..2]
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
MTIOB
MTIOA
CLKSTA
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
ETRGS
LDRBS
LDRAS
CPCS
CPBS
CPAS
LOVRS
COVFS
• COVFS: Counter Overflow Status
0 = No counter overflow has occurred since the last read of the Status Register.
1 = A counter overflow has occurred since the last read of the Status Register.
• LOVRS: Load Overrun Status
0 = Load overrun has not occurred since the last read of the Status Register or WAVE = 1.
1 = RA or RB have been loaded at least twice without any read of the corresponding register since the last read of the Status Register, if WAVE = 0.
• CPAS: RA Compare Status
0 = RA Compare has not occurred since the last read of the Status Register or WAVE = 0.
1 = RA Compare has occurred since the last read of the Status Register, if WAVE = 1.
• CPBS: RB Compare Status
0 = RB Compare has not occurred since the last read of the Status Register or WAVE = 0.
1 = RB Compare has occurred since the last read of the Status Register, if WAVE = 1.
• CPCS: RC Compare Status
0 = RC Compare has not occurred since the last read of the Status Register.
1 = RC Compare has occurred since the last read of the Status Register.
• LDRAS: RA Loading Status
0 = RA Load has not occurred since the last read of the Status Register or WAVE = 1.
1 = RA Load has occurred since the last read of the Status Register, if WAVE = 0.
• LDRBS: RB Loading Status
0 = RB Load has not occurred since the last read of the Status Register or WAVE = 1.
1 = RB Load has occurred since the last read of the Status Register, if WAVE = 0.
• ETRGS: External Trigger Status
0 = External trigger has not occurred since the last read of the Status Register.
1 = External trigger has occurred since the last read of the Status Register.
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• CLKSTA: Clock Enabling Status
0 = Clock is disabled.
1 = Clock is enabled.
• MTIOA: TIOA Mirror
0 = TIOA is low. If WAVE = 0, this means that TIOA pin is low. If WAVE = 1, this means that TIOA is driven low.
1 = TIOA is high. If WAVE = 0, this means that TIOA pin is high. If WAVE = 1, this means that TIOA is driven high.
• MTIOB: TIOB Mirror
0 = TIOB is low. If WAVE = 0, this means that TIOB pin is low. If WAVE = 1, this means that TIOB is driven low.
1 = TIOB is high. If WAVE = 0, this means that TIOB pin is high. If WAVE = 1, this means that TIOB is driven high.
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31.6.11 TC Interrupt Enable Register
Register Name:
TC_IERx [x=0..2]
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
ETRGS
LDRBS
LDRAS
CPCS
CPBS
CPAS
LOVRS
COVFS
• COVFS: Counter Overflow
0 = No effect.
1 = Enables the Counter Overflow Interrupt.
• LOVRS: Load Overrun
0 = No effect.
1 = Enables the Load Overrun Interrupt.
• CPAS: RA Compare
0 = No effect.
1 = Enables the RA Compare Interrupt.
• CPBS: RB Compare
0 = No effect.
1 = Enables the RB Compare Interrupt.
• CPCS: RC Compare
0 = No effect.
1 = Enables the RC Compare Interrupt.
• LDRAS: RA Loading
0 = No effect.
1 = Enables the RA Load Interrupt.
• LDRBS: RB Loading
0 = No effect.
1 = Enables the RB Load Interrupt.
• ETRGS: External Trigger
0 = No effect.
1 = Enables the External Trigger Interrupt.
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31.6.12 TC Interrupt Disable Register
Register Name:
TC_IDRx [x=0..2]
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
ETRGS
LDRBS
LDRAS
CPCS
CPBS
CPAS
LOVRS
COVFS
• COVFS: Counter Overflow
0 = No effect.
1 = Disables the Counter Overflow Interrupt.
• LOVRS: Load Overrun
0 = No effect.
1 = Disables the Load Overrun Interrupt (if WAVE = 0).
• CPAS: RA Compare
0 = No effect.
1 = Disables the RA Compare Interrupt (if WAVE = 1).
• CPBS: RB Compare
0 = No effect.
1 = Disables the RB Compare Interrupt (if WAVE = 1).
• CPCS: RC Compare
0 = No effect.
1 = Disables the RC Compare Interrupt.
• LDRAS: RA Loading
0 = No effect.
1 = Disables the RA Load Interrupt (if WAVE = 0).
• LDRBS: RB Loading
0 = No effect.
1 = Disables the RB Load Interrupt (if WAVE = 0).
• ETRGS: External Trigger
0 = No effect.
1 = Disables the External Trigger Interrupt.
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31.6.13 TC Interrupt Mask Register
Register Name:
TC_IMRx [x=0..2]
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
ETRGS
LDRBS
LDRAS
CPCS
CPBS
CPAS
LOVRS
COVFS
• COVFS: Counter Overflow
0 = The Counter Overflow Interrupt is disabled.
1 = The Counter Overflow Interrupt is enabled.
• LOVRS: Load Overrun
0 = The Load Overrun Interrupt is disabled.
1 = The Load Overrun Interrupt is enabled.
• CPAS: RA Compare
0 = The RA Compare Interrupt is disabled.
1 = The RA Compare Interrupt is enabled.
• CPBS: RB Compare
0 = The RB Compare Interrupt is disabled.
1 = The RB Compare Interrupt is enabled.
• CPCS: RC Compare
0 = The RC Compare Interrupt is disabled.
1 = The RC Compare Interrupt is enabled.
• LDRAS: RA Loading
0 = The Load RA Interrupt is disabled.
1 = The Load RA Interrupt is enabled.
• LDRBS: RB Loading
0 = The Load RB Interrupt is disabled.
1 = The Load RB Interrupt is enabled.
• ETRGS: External Trigger
0 = The External Trigger Interrupt is disabled.
1 = The External Trigger Interrupt is enabled.
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32. Pulse Width Modulation Controller (PWM)
32.1
Overview
The PWM macrocell controls several channels independently. Each channel controls one square output waveform.
Characteristics of the output waveform such as period, duty-cycle and polarity are configurable through the user
interface. Each channel selects and uses one of the clocks provided by the clock generator. The clock generator
provides several clocks resulting from the division of the PWM macrocell master clock.
All PWM macrocell accesses are made through APB mapped registers.
Channels can be synchronized, to generate non overlapped waveforms. All channels integrate a double buffering
system in order to prevent an unexpected output waveform while modifying the period or the duty-cycle.
32.2
Block Diagram
Figure 32-1. Pulse Width Modulation Controller Block Diagram
PWM
Controller
PWMx
Channel
Period
PWMx
Update
Duty Cycle
Clock
Selector
Comparator
PWMx
Counter
PIO
PWM0
Channel
Period
PWM0
Update
Duty Cycle
Clock
Selector
PMC
MCK
Clock Generator
Comparator
PWM0
Counter
APB Interface
Interrupt Generator
AIC
APB
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32.3
I/O Lines Description
Each channel outputs one waveform on one external I/O line.
Table 32-1.
I/O Line Description
Name
Description
Type
PWMx
PWM Waveform Output for channel x
Output
32.4
Product Dependencies
32.4.1
I/O Lines
The pins used for interfacing the PWM may be multiplexed with PIO lines. The programmer must first program the
PIO controller to assign the desired PWM pins to their peripheral function. If I/O lines of the PWM are not used by
the application, they can be used for other purposes by the PIO controller.
All of the PWM outputs may or may not be enabled. If an application requires only four channels, then only four
PIO lines will be assigned to PWM outputs.
32.4.2
Power Management
The PWM is not continuously clocked. The programmer must first enable the PWM clock in the Power Management Controller (PMC) before using the PWM. However, if the application does not require PWM operations, the
PWM clock can be stopped when not needed and be restarted later. In this case, the PWM will resume its operations where it left off.
Configuring the PWM does not require the PWM clock to be enabled.
32.4.3
Interrupt Sources
The PWM interrupt line is connected on one of the internal sources of the Advanced Interrupt Controller. Using the
PWM interrupt requires the AIC to be programmed first. Note that it is not recommended to use the PWM interrupt
line in edge sensitive mode.
32.5
Functional Description
The PWM macrocell is primarily composed of a clock generator module and 4 channels.
– Clocked by the system clock, MCK, the clock generator module provides 13 clocks.
– Each channel can independently choose one of the clock generator outputs.
– Each channel generates an output waveform with attributes that can be defined independently for each
channel through the user interface registers.
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32.5.1
PWM Clock Generator
Figure 32-2. Functional View of the Clock Generator Block Diagram
MCK
modulo n counter
MCK
MCK/2
MCK/4
MCK/8
MCK/16
MCK/32
MCK/64
MCK/128
MCK/256
MCK/512
MCK/1024
Divider A
PREA
clkA
DIVA
PWM_MR
Divider B
PREB
clkB
DIVB
PWM_MR
Caution: Before using the PWM macrocell, the programmer must first enable the PWM clock in the Power Management Controller (PMC).
The PWM macrocell master clock, MCK, is divided in the clock generator module to provide different clocks available for all channels. Each channel can independently select one of the divided clocks.
The clock generator is divided in three blocks:
– a modulo n counter which provides 11 clocks: FMCK, FMCK/2, FMCK/4, FMCK/8, FMCK/16, FMCK/32,
FMCK/64, FMCK/128, FMCK/256, FMCK/512, FMCK/1024
– two linear dividers (1, 1/2, 1/3, ... 1/255) that provide two separate clocks: clkA and clkB
Each linear divider can independently divide one of the clocks of the modulo n counter. The selection of the clock
to be divided is made according to the PREA (PREB) field of the PWM Mode register (PWM_MR). The resulting
clock clkA (clkB) is the clock selected divided by DIVA (DIVB) field value in the PWM Mode register (PWM_MR).
After a reset of the PWM controller, DIVA (DIVB) and PREA (PREB) in the PWM Mode register are set to 0. This
implies that after reset clkA (clkB) are turned off.
At reset, all clocks provided by the modulo n counter are turned off except clock “clk”. This situation is also true
when the PWM master clock is turned off through the Power Management Controller.
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32.5.2
PWM Channel
32.5.2.1
Block Diagram
Figure 32-3. Functional View of the Channel Block Diagram
inputs
from clock
generator
Channel
Clock
Selector
Internal
Counter
Comparator
PWMx output waveform
inputs from
APB bus
Each of the 4 channels is composed of three blocks:
• A clock selector which selects one of the clocks provided by the clock generator described in Section 32.5.1
“PWM Clock Generator” on page 441.
• An internal counter clocked by the output of the clock selector. This internal counter is incremented or
decremented according to the channel configuration and comparators events. The size of the internal counter is
16 bits.
• A comparator used to generate events according to the internal counter value. It also computes the PWMx
output waveform according to the configuration.
32.5.2.2
W
aveform Properties
The different properties of output waveforms are:
• the internal clock selection. The internal channel counter is clocked by one of the clocks provided by the clock
generator described in the previous section. This channel parameter is defined in the CPRE field of the
PWM_CMRx register. This field is reset at 0.
• the waveform period. This channel parameter is defined in the CPRD field of the PWM_CPRDx register.
- If the waveform is left aligned, then the output waveform period depends on the counter source clock and can
be calculated:
By using the Master Clock (MCK) divided by an X given prescaler value
(with X being 1, 2, 4, 8, 16, 32, 64, 128, 256, 512, or 1024), the resulting period formula will be:
(------------------------------X × CPRD -)
MCK
By using a Master Clock divided by one of both DIVA or DIVB divider, the formula becomes, respectively:
( CRPD × DIVA )
( CRPD × DIVAB )
------------------------------------------- or ----------------------------------------------MCK
MCK
If the waveform is center aligned then the output waveform period depends on the counter source clock and can
be calculated:
By using the Master Clock (MCK) divided by an X given prescaler value
(with X being 1, 2, 4, 8, 16, 32, 64, 128, 256, 512, or 1024). The resulting period formula will be:
(-----------------------------------------2 × X × CPRD )MCK
By using a Master Clock divided by one of both DIVA or DIVB divider, the formula becomes, respectively:
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( 2 × CPRD × DIVA )
( 2 × CPRD × DIVB )
------------------------------------------------------ or -----------------------------------------------------MCK
MCK
• the waveform duty cycle. This channel parameter is defined in the CDTY field of the PWM_CDTYx register.
If the waveform is left aligned then:
( period – 1 ⁄ fchannel_x_clock × CDTY )
duty cycle = -----------------------------------------------------------------------------------------------------------period
If the waveform is center aligned, then:
( period ⁄ 2 ) – 1 ⁄ fchannel_x_clock × CDTY ) )duty cycle = (----------------------------------------------------------------------------------------------------------------------------( period ⁄ 2 )
• the waveform polarity. At the beginning of the period, the signal can be at high or low level. This property is
defined in the CPOL field of the PWM_CMRx register. By default the signal starts by a low level.
• the waveform alignment. The output waveform can be left or center aligned. Center aligned waveforms can be
used to generate non overlapped waveforms. This property is defined in the CALG field of the PWM_CMRx
register. The default mode is left aligned.
Figure 32-4. Non Overlapped Center Aligned Waveforms
No overlap
PWM0
PWM1
Period
Note:
1. See Figure 32-5 on page 444 for a detailed description of center aligned waveforms.
When center aligned, the internal channel counter increases up to CPRD and.decreases down to 0. This ends the
period.
When left aligned, the internal channel counter increases up to CPRD and is reset. This ends the period.
Thus, for the same CPRD value, the period for a center aligned channel is twice the period for a left aligned
channel.
Waveforms are fixed at 0 when:
• CDTY = CPRD and CPOL = 0
• CDTY = 0 and CPOL = 1
Waveforms are fixed at 1 (once the channel is enabled) when:
• CDTY = 0 and CPOL = 0
• CDTY = CPRD and CPOL = 1
The waveform polarity must be set before enabling the channel. This immediately affects the channel output level.
Changes on channel polarity are not taken into account while the channel is enabled.
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Figure 32-5. Waveform Properties
PWM_MCKx
CHIDx(PWM_SR)
CHIDx(PWM_ENA)
CHIDx(PWM_DIS)
Center Aligned
CALG(PWM_CMRx) = 1
PWM_CCNTx
CPRD(PWM_CPRDx)
CDTY(PWM_CDTYx)
Period
Output Waveform PWMx
CPOL(PWM_CMRx) = 0
Output Waveform PWMx
CPOL(PWM_CMRx) = 1
CHIDx(PWM_ISR)
Left Aligned
CALG(PWM_CMRx) = 0
PWM_CCNTx
CPRD(PWM_CPRDx)
CDTY(PWM_CDTYx)
Period
Output Waveform PWMx
CPOL(PWM_CMRx) = 0
Output Waveform PWMx
CPOL(PWM_CMRx) = 1
CHIDx(PWM_ISR)
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32.5.3
PWM Controller Operations
32.5.3.1
Initialization
Before enabling the output channel, this channel must have been configured by the software application:
• Configuration of the clock generator if DIVA and DIVB are required
• Selection of the clock for each channel (CPRE field in the PWM_CMRx register)
• Configuration of the waveform alignment for each channel (CALG field in the PWM_CMRx register)
• Configuration of the period for each channel (CPRD in the PWM_CPRDx register). Writing in PWM_CPRDx
Register is possible while the channel is disabled. After validation of the channel, the user must use
PWM_CUPDx Register to update PWM_CPRDx as explained below.
• Configuration of the duty cycle for each channel (CDTY in the PWM_CDTYx register). Writing in PWM_CDTYx
Register is possible while the channel is disabled. After validation of the channel, the user must use
PWM_CUPDx Register to update PWM_CDTYx as explained below.
• Configuration of the output waveform polarity for each channel (CPOL in the PWM_CMRx register)
• Enable Interrupts (Writing CHIDx in the PWM_IER register)
• Enable the PWM channel (Writing CHIDx in the PWM_ENA register)
It is possible to synchronize different channels by enabling them at the same time by means of writing simultaneously several CHIDx bits in the PWM_ENA register.
• In such a situation, all channels may have the same clock selector configuration and the same period specified.
32.5.3.2
Source Clock Selection Criteria
The large number of source clocks can make selection difficult. The relationship between the value in the Period
Register (PWM_CPRDx) and the Duty Cycle Register (PWM_CDTYx) can help the user in choosing. The event
number written in the Period Register gives the PWM accuracy. The Duty Cycle quantum cannot be lower than
1/PW
M_CPRDx value. The higher the value of PWM_CPRDx, the greater the PWM accuracy.
For example, if the user sets 15 (in decimal) in PWM_CPRDx, the user is able to set a value between 1 up to 14 in
PWM_CDTYx Register. The resulting duty cycle quantum cannot be lower than 1/15 of the PWM period.
32.5.3.3
Changing the Duty Cycle or the Period
It is possible to modulate the output waveform duty cycle or period.
To prevent unexpected output waveform, the user must use the update register (PWM_CUPDx) to change waveform parameters while the channel is still enabled. The user can write a new period value or duty cycle value in the
update register (PWM_CUPDx). This register holds the new value until the end of the current cycle and updates
the value for the next cycle. Depending on the CPD field in the PWM_CMRx register, PWM_CUPDx either updates
PWM_CPRDx or PWM_CDTYx. Note that even if the update register is used, the period must not be smaller than
the duty cycle.
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Figure 32-6. Synchronized Period or Duty Cycle Update
User's Writing
PWM_CUPDx Value
0
1
PWM_CPRDx
PWM_CMRx. CPD
PWM_CDTYx
End of Cycle
To prevent overwriting the PWM_CUPDx by software, the user can use status events in order to synchronize his
software. Two methods are possible. In both, the user must enable the dedicated interrupt in PWM_IER at PWM
Controller level.
The first method (polling method) consists of reading the relevant status bit in PWM_ISR Register according to the
enabled channel(s). See Figure 32-7.
The second method uses an Interrupt Service Routine associated with the PWM channel.
Note:
Reading the PWM_ISR register automatically clears CHIDx flags.
Figure 32-7. Polling Method
PWM_ISR Read
Acknowledgement and clear previous register state
Writing in CPD field
Update of the Period or Duty Cycle
CHIDx = 1
YES
Writing in PWM_CUPDx
The last write has been taken into account
Note:
Polarity and alignment can be modified only when the channel is disabled.
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32.5.3.4
Interrupts
Depending on the interrupt mask in the PWM_IMR register, an interrupt is generated at the end of the corresponding channel period. The interrupt remains active until a read operation in the PWM_ISR register occurs.
A channel interrupt is enabled by setting the corresponding bit in the PWM_IER register. A channel interrupt is disabled by setting the corresponding bit in the PWM_IDR register.
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32.6
Pulse Width Modulation Controller (PWM) User Interface
Table 32-2.
Register Mapping(2)
Offset
Register
Name
Access
Reset
0x00
PWM Mode Register
PWM_MR
Read-write
0
0x04
PWM Enable Register
PWM_ENA
Write-only
-
0x08
PWM Disable Register
PWM_DIS
Write-only
-
0x0C
PWM Status Register
PWM_SR
Read-only
0
0x10
PWM Interrupt Enable Register
PWM_IER
Write-only
-
0x14
PWM Interrupt Disable Register
PWM_IDR
Write-only
-
0x18
PWM Interrupt Mask Register
PWM_IMR
Read-only
0
0x1C
PWM Interrupt Status Register
PWM_ISR
Read-only
0
0x100 - 0x1FC
Reserved
0x200 + ch_num * 0x20 + 0x00
PWM Channel Mode Register
PWM_CMR
Read-write
0x0
0x200 + ch_num * 0x20 + 0x04
PWM Channel Duty Cycle Register
PWM_CDTY
Read-write
0x0
0x200 + ch_num * 0x20 + 0x08
PWM Channel Period Register
PWM_CPRD
Read-write
0x0
0x200 + ch_num * 0x20 + 0x0C
PWM Channel Counter Register
PWM_CCNT
Read-only
0x0
0x200 + ch_num * 0x20 + 0x10
PWM Channel Update Register
PWM_CUPD
Write-only
-
2. Some registers are indexed with “ch_num” index ranging from 0 to 3.
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32.6.1
PWM Mode Register
Register Name:
PWM_MR
Access Type:
Read/Write
31
–
30
–
29
–
28
–
23
22
21
20
27
26
25
24
17
16
9
8
1
0
PREB
19
18
10
DIVB
15
–
14
–
13
–
12
–
11
7
6
5
4
3
PREA
2
DIVA
• DIVA, DIVB: CLKA, CLKB Divide Factor
DIVA, DIVB
CLKA, CLKB
0
CLKA, CLKB clock is turned off
1
CLKA, CLKB clock is clock selected by PREA, PREB
2-255
CLKA, CLKB clock is clock selected by PREA, PREB divided by DIVA, DIVB factor.
• PREA, PREB
PREA, PREB
Divider Input Clock
0
0
0
0
MCK.
0
0
0
1
MCK/2
0
0
1
0
MCK/4
0
0
1
1
MCK/8
0
1
0
0
MCK/16
0
1
0
1
MCK/32
0
1
1
0
MCK/64
0
1
1
1
MCK/128
1
0
0
0
MCK/256
1
0
0
1
MCK/512
1
0
1
0
MCK/1024
Other
Reserved
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32.6.2
PWM Enable Register
Register Name:
PWM_ENA
Access Type:
Write-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID
0 = No effect.
1 = Enable PWM output for channel x.
32.6.3
PWM Disable Register
Register Name:
PWM_DIS
Access Type:
Write-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID
0 = No effect.
1 = Disable PWM output for channel x.
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32.6.4
PWM Status Register
Register Name:
PWM_SR
Access Type:
Read-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID
0 = PWM output for channel x is disabled.
1 = PWM output for channel x is enabled.
32.6.5
PWM Interrupt Enable Register
Register Name:
PWM_IER
Access Type:
Write-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID.
0 = No effect.
1 = Enable interrupt for PWM channel x.
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32.6.6
PWM Interrupt Disable Register
Register Name:
PWM_IDR
Access Type:
Write-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID.
0 = No effect.
1 = Disable interrupt for PWM channel x.
32.6.7
PWM Interrupt Mask Register
Register Name:
PWM_IMR
Access Type:
Read-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID.
0 = Interrupt for PWM channel x is disabled.
1 = Interrupt for PWM channel x is enabled.
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32.6.8
PWM Interrupt Status Register
Register Name:
PWM_ISR
Access Type:
Read-only
31
-
30
-
29
-
28
-
27
-
26
-
25
-
24
-
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
-
4
-
3
CHID3
2
CHID2
1
CHID1
0
CHID0
• CHIDx: Channel ID
0 = No new channel period has been achieved since the last read of the PWM_ISR register.
1 = At least one new channel period has been achieved since the last read of the PWM_ISR register.
Note: Reading PWM_ISR automatically clears CHIDx flags.
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32.6.9
PWM Channel Mode Register
Register Name:
PWM_CMR[0..3]
Access Type:
Read/Write
31
–
30
–
29
–
28
–
27
–
26
–
25
–
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
12
–
11
–
10
CPD
9
CPOL
8
CALG
7
–
6
–
5
–
4
–
3
2
1
0
CPRE
• CPRE: Channel Pre-scaler
CPRE
Channel Pre-scaler
0
0
0
0
MCK
0
0
0
1
MCK/2
0
0
1
0
MCK/4
0
0
1
1
MCK/8
0
1
0
0
MCK/16
0
1
0
1
MCK/32
0
1
1
0
MCK/64
0
1
1
1
MCK/128
1
0
0
0
MCK/256
1
0
0
1
MCK/512
1
0
1
0
MCK/1024
1
0
1
1
CLKA
1
1
0
0
CLKB
Other
Reserved
• CALG: Channel Alignment
0 = The period is left aligned.
1 = The period is center aligned.
• CPOL: Channel Polarity
0 = The output waveform starts at a low level.
1 = The output waveform starts at a high level.
• CPD: Channel Update Period
0 = Writing to the PWM_CUPDx will modify the duty cycle at the next period start event.
1 = Writing to the PWM_CUPDx will modify the period at the next period start event.
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32.6.10 PWM Channel Duty Cycle Register
Register Name:
PWM_CDTY[0..3]
Access Type:
31
Read/Write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
CDTY
23
22
21
20
CDTY
15
14
13
12
CDTY
7
6
5
4
CDTY
Only the first 16 bits (internal channel counter size) are significant.
• CDTY: Channel Duty Cycle
Defines the waveform duty cycle. This value must be defined between 0 and CPRD (PWM_CPRx).
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32.6.11 PWM Channel Period Register
Register Name:
PWM_CPRD[0..3]
Access Type:
31
Read/Write
30
29
28
27
26
25
24
19
18
17
16
11
10
9
8
3
2
1
0
CPRD
23
22
21
20
CPRD
15
14
13
12
CPRD
7
6
5
4
CPRD
Only the first 16 bits (internal channel counter size) are significant.
• CPRD: Channel Period
If the waveform is left-aligned, then the output waveform period depends on the counter source clock and can be
calculated:
– By using the Master Clock (MCK) divided by an X given prescaler value (with X being 1, 2, 4, 8, 16, 32, 64, 128,
256, 512, or 1024). The resulting period formula will be:
( X × CPRD )
-------------------------------MCK
– By using a Master Clock divided by one of both DIVA or DIVB divider, the formula becomes, respectively:
( CRPD × DIVA )
( CRPD × DIVAB )
------------------------------------------- or ----------------------------------------------MCK
MCK
If the waveform is center-aligned, then the output waveform period depends on the counter source clock and can be
calculated:
– By using the Master Clock (MCK) divided by an X given prescaler value (with X being 1, 2, 4, 8, 16, 32, 64, 128,
256, 512, or 1024). The resulting period formula will be:
(-----------------------------------------2 × X × CPRD )MCK
– By using a Master Clock divided by one of both DIVA or DIVB divider, the formula becomes, respectively:
( 2 × CPRD × DIVA )
( 2 × CPRD × DIVB )
------------------------------------------------------ or -----------------------------------------------------MCK
MCK
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33. Analog-to-Digital Converter (ADC)
33.1
Overview
The ADC is based on a Successive Approximation Register (SAR) 10-bit Analog-to-Digital Converter (ADC). It also
integrates a 4-to-1 analog multiplexer, making possible the analog-to-digital conversions of 4 analog lines. The
conversions extend from 0V to ADVREF.
The ADC supports an 8-bit or 10-bit resolution mode, and conversion results are reported in a common register for
all channels, as well as in a channel-dedicated register. Software trigger, external trigger on rising edge of the
ADTRG pin or internal triggers from Timer Counter output(s) are configurable.
The ADC also integrates a Sleep Mode and a conversion sequencer and connects with a PDC channel. These features reduce both power consumption and processor intervention.
Finally, the user can configure ADC timings, such as Startup Time and Sample & Hold Time.
33.2
Block Diagram
Figure 33-1. Analog-to-Digital Converter Block Diagram
Timer
Counter
Channels
ADC
ADTRG
Trigger
Selection
Control
Logic
ADC Interrupt
AIC
ADVREF
ASB
PDC
AD-
Dedicated
Analog
Inputs
AD-
Successive
Approximation
Register
Analog-to-Digital
Converter
User
Interface
Peripheral Bridge
ADAPB
GND
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33.3
Signal Description
Table 33-1.
ADC Pin Description
Pin Name
Description
ADVREF
Reference voltage
AD0 - AD3
Analog input channels
ADTRG
External trigger
33.4
Product Dependencies
33.4.1
Power Management
The ADC is automatically clocked after the first conversion in Normal Mode. In Sleep Mode, the ADC clock is automatically stopped after each conversion. As the logic is small and the ADC cell can be put into Sleep Mode, the
Power Management Controller has no effect on the ADC behavior.
33.4.2
Interrupt Sources
The ADC interrupt line is connected on one of the internal sources of the Advanced Interrupt Controller. Using the
ADC interrupt requires the AIC to be programmed first.
33.4.3
Analog Inputs
The analog input pins can be multiplexed with PIO lines. In this case, the assignment of the ADC input is automatically done as soon as the corresponding channel is enabled by writing the register ADC_CHER. By default, after
reset, the PIO line is configured as input with its pull-up enabled and the ADC input is connected to the GND.
33.4.4
I/O Lines
The pin ADTRG may be shared with other peripheral functions through the PIO Controller. In this case, the PIO
Controller should be set accordingly to assign the pin ADTRG to the ADC function.
33.4.5
Timer Triggers
Timer Counters may or may not be used as hardware triggers depending on user requirements. Thus, some or all
of the timer counters may be non-connected.
33.4.6
Conversion Performances
For performance and electrical characteristics of the ADC, see the DC Characteristics section.
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33.5
Functional Description
33.5.1
Analog-to-digital Conversion
The ADC uses the ADC Clock to perform conversions. Converting a single analog value to a 10-bit digital data
requires Sample and Hold Clock cycles as defined in the field SHTIM of the “ADC Mode Register” on page 466 and
10 ADC Clock cycles. The ADC Clock frequency is selected in the PRESCAL field of the Mode Register
(ADC_MR).
The ADC clock range is between MCK/2, if PRESCAL is 0, and MCK/128, if PRESCAL is set to 63 (0x3F). PRESCAL must be programmed in order to provide an ADC clock frequency according to the parameters given in the
Product definition section.
33.5.2
Conversion Reference
The conversion is performed on a full range between 0V and the reference voltage pin ADVREF.Analog inputs
between these voltages convert to values based on a linear conversion.
33.5.3
Conversion Resolution
The ADC supports 8-bit or 10-bit resolutions. The 8-bit selection is performed by setting the bit LOWRES in the
ADC Mode Register (ADC_MR). By default, after a reset, the resolution is the highest and the DATA field in the
data registers is fully used. By setting the bit LOWRES, the ADC switches in the lowest resolution and the conversion results can be read in the eight lowest significant bits of the data registers. The two highest bits of the DATA
field in the corresponding ADC_CDR register and of the LDATA field in the ADC_LCDR register read 0.
Moreover, when a PDC channel is connected to the ADC, 10-bit resolution sets the transfer request sizes to 16-bit.
Setting the bit LOWRES automatically switches to 8-bit data transfers. In this case, the destination buffers are
optimized.
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33.5.4
Conversion Results
When a conversion is completed, the resulting 10-bit digital value is stored in the Channel Data Register
(ADC_CDR) of the current channel and in the ADC Last Converted Data Register (ADC_LCDR).
The channel EOC bit in the Status Register (ADC_SR) is set and the DRDY is set. In the case of a connected PDC
channel, DRDY rising triggers a data transfer request. In any case, either EOC and DRDY can trigger an interrupt.
Reading one of the ADC_CDR registers clears the corresponding EOC bit. Reading ADC_LCDR clears the DRDY
bit and the EOC bit corresponding to the last converted channel.
Figure 33-2. EOCx and DRDY Flag Behavior
Write the ADC_CR
with START = 1
Read the ADC_CDRx
Write the ADC_CR
with START = 1
Read the ADC_LCDR
CHx
(ADC_CHSR)
EOCx
(ADC_SR)
Conversion Time
Conversion Time
DRDY
(ADC_SR)
If the ADC_CDR is not read before further incoming data is converted, the corresponding Overrun Error (OVRE)
flag is set in the Status Register (ADC_SR).
In the same way, new data converted when DRDY is high sets the bit GOVRE (General Overrun Error) in
ADC_SR.
The OVRE and GOVRE flags are automatically cleared when ADC_SR is read.
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Figure 33-3. GOVRE and OVREx Flag Behavior
Read ADC_SR
ADTRG
CH0
(ADC_CHSR)
CH1
(ADC_CHSR)
ADC_LCDR
Undefined Data
ADC_CDR0
Undefined Data
ADC_CDR1
EOC0
(ADC_SR)
EOC1
(ADC_SR)
Data B
Data A
Data C
Data A
Data C
Undefined Data
Data B
Conversion
Conversion
Conversion
Read ADC_CDR0
Read ADC_CDR1
GOVRE
(ADC_SR)
DRDY
(ADC_SR)
OVRE0
(ADC_SR)
Warning: If the corresponding channel is disabled during a conversion or if it is disabled and then reenabled during
a conversion, its associated data and its corresponding EOC and OVRE flags in ADC_SR are unpredictable.
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33.5.5
Conversion Triggers
Conversions of the active analog channels are started with a software or a hardware trigger. The software trigger is
provided by writing the Control Register (ADC_CR) with the bit START at 1.
The hardware trigger can be one of the TIOA outputs of the Timer Counter channels, or the external trigger input of
the ADC (ADTRG). The hardware trigger is selected with the field TRGSEL in the Mode Register (ADC_MR). The
selected hardware trigger is enabled with the bit TRGEN in the Mode Register (ADC_MR).
If a hardware trigger is selected, the start of a conversion is detected at each rising edge of the selected signal. If
one of the TIOA outputs is selected, the corresponding Timer Counter channel must be programmed in Waveform
Mode.
Only one start command is necessary to initiate a conversion sequence on all the channels. The ADC hardware
logic automatically performs the conversions on the active channels, then waits for a new request. The Channel
Enable (ADC_CHER) and Channel Disable (ADC_CHDR) Registers enable the analog channels to be enabled or
disabled independently.
If the ADC is used with a PDC, only the transfers of converted data from enabled channels are performed and the
resulting data buffers should be interpreted accordingly.
Warning: Enabling hardware triggers does not disable the software trigger functionality. Thus, if a hardware trigger
is selected, the start of a conversion can be initiated either by the hardware or the software trigger.
33.5.6
Sleep Mode and Conversion Sequencer
The ADC Sleep Mode maximizes power saving by automatically deactivating the ADC when it is not being used for
conversions. Sleep Mode is selected by setting the bit SLEEP in the Mode Register ADC_MR.
The SLEEP mode is automatically managed by a conversion sequencer, which can automatically process the conversions of all channels at lowest power consumption.
When a start conversion request occurs, the ADC is automatically activated. As the analog cell requires a start-up
time, the logic waits during this time and starts the conversion on the enabled channels. When all conversions are
complete, the ADC is deactivated until the next trigger. Triggers occurring during the sequence are not taken into
account.
The conversion sequencer allows automatic processing with minimum processor intervention and optimized power
consumption. Conversion sequences can be performed periodically using a Timer/Counter output. The periodic
acquisition of several samples can be processed automatically without any intervention of the processor thanks to
the PDC.
Note:
The reference voltage pins always remain connected in normal mode as in sleep mode.
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33.5.7
ADC Timings
Each ADC has its own minimal Startup Time that is programmed through the field STARTUP in the Mode Register
ADC_MR.
In the same way, a minimal Sample and Hold Time is necessary for the ADC to guarantee the best converted final
value between two channels selection. This time has to be programmed through the SHTIM bitfield in the Mode
Register ADC_MR.
Warning: No input buffer amplifier to isolate the source is included in the ADC. This must be taken into consideration to program a precise value in the SHTIM field. See the section ADC Characteristics in the product datasheet.
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33.6
Analog-to-Digital Converter (ADC) User Interface
Table 33-2.
Offset
Register Mapping
Register
Name
Access
Reset
0x00
Control Register
ADC_CR
Write-only
–
0x04
Mode Register
ADC_MR
Read-write
0x00000000
0x08
Reserved
–
–
–
0x0C
Reserved
–
–
–
0x10
Channel Enable Register
ADC_CHER
Write-only
–
0x14
Channel Disable Register
ADC_CHDR
Write-only
–
0x18
Channel Status Register
ADC_CHSR
Read-only
0x00000000
0x1C
Status Register
ADC_SR
Read-only
0x000C0000
0x20
Last Converted Data Register
ADC_LCDR
Read-only
0x00000000
0x24
Interrupt Enable Register
ADC_IER
Write-only
–
0x28
Interrupt Disable Register
ADC_IDR
Write-only
–
0x2C
Interrupt Mask Register
ADC_IMR
Read-only
0x00000000
0x30
Channel Data Register 0
ADC_CDR0
Read-only
0x00000000
0x34
Channel Data Register 1
ADC_CDR1
Read-only
0x00000000
...
...
...
ADC_CDR3
Read-only
0x00000000
–
–
–
...
0x4C
0x50 - 0xFC
...
Channel Data Register 3
Reserved
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33.6.1
ADC Control Register
Register Name:
ADC_CR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
START
SWRST
• SWRST: Software Reset
0 = No effect.
1 = Resets the ADC simulating a hardware reset.
• START: Start Conversion
0 = No effect.
1 = Begins analog-to-digital conversion.
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33.6.2
ADC Mode Register
Register Name:
ADC_MR
Access Type:
Read-write
31
30
29
28
–
–
–
–
23
22
21
20
27
25
24
18
17
16
10
9
8
2
1
SHTIM
19
–
15
26
STARTUP
14
13
12
11
PRESCAL
7
6
5
4
–
–
SLEEP
LOWRES
3
TRGSEL
0
TRGEN
• TRGEN: Trigger Enable
TRGEN
Selected TRGEN
0
Hardware triggers are disabled. Starting a conversion is only possible by software.
1
Hardware trigger selected by TRGSEL field is enabled.
• TRGSEL: Trigger Selection
TRGSEL
Selected TRGSEL
0
0
0
TIOA Ouput of the Timer Counter Channel 0
0
0
1
TIOA Ouput of the Timer Counter Channel 1
0
1
0
TIOA Ouput of the Timer Counter Channel 2
0
1
1
Reserved
1
0
0
Reserved
1
0
1
Reserved
1
1
0
External trigger
1
1
1
Reserved
• LOWRES: Resolution
LOWRES
Selected Resolution
0
10-bit resolution
1
8-bit resolution
• SLEEP: Sleep Mode
SLEEP
Selected Mode
0
Normal Mode
1
Sleep Mode
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• PRESCAL: Prescaler Rate Selection
ADCClock = MCK / ( (PRESCAL+1) * 2 )
• STARTUP: Start Up Time
Startup Time = (STARTUP+1) * 8 / ADCClock
• SHTIM: Sample & Hold Time
Sample & Hold Time = (SHTIM+1) / ADCClock
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33.6.3
ADC Channel Enable Register
Register Name:
ADC_CHER
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
—
—
—
—
CH3
CH2
CH1
CH0
• CHx: Channel x Enable
0 = No effect.
1 = Enables the corresponding channel.
33.6.4
ADC Channel Disable Register
Register Name:
ADC_CHDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
—
—
—
—
CH3
CH2
CH1
CH0
• CHx: Channel x Disable
0 = No effect.
1 = Disables the corresponding channel.
Warning: If the corresponding channel is disabled during a conversion or if it is disabled then reenabled during a conversion, its associated data and its corresponding EOC and OVRE flags in ADC_SR are unpredictable.
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33.6.5
ADC Channel Status Register
Register Name:
ADC_CHSR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
—
—
—
—
CH3
CH2
CH1
CH0
• CHx: Channel x Status
0 = Corresponding channel is disabled.
1 = Corresponding channel is enabled.
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33.6.6
ADC Status Register
Register Name:
ADC_SR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
RXBUFF
ENDRX
GOVRE
DRDY
15
14
13
12
11
10
9
8
—
—
—
—
OVRE3
OVRE2
OVRE1
OVRE0
7
6
5
4
3
2
1
0
—
—
—
—
EOC3
EOC2
EOC1
EOC0
• EOCx: End of Conversion x
0 = Corresponding analog channel is disabled, or the conversion is not finished.
1 = Corresponding analog channel is enabled and conversion is complete.
• OVREx: Overrun Error x
0 = No overrun error on the corresponding channel since the last read of ADC_SR.
1 = There has been an overrun error on the corresponding channel since the last read of ADC_SR.
• DRDY: Data Ready
0 = No data has been converted since the last read of ADC_LCDR.
1 = At least one data has been converted and is available in ADC_LCDR.
• GOVRE: General Overrun Error
0 = No General Overrun Error occurred since the last read of ADC_SR.
1 = At least one General Overrun Error has occurred since the last read of ADC_SR.
• ENDRX: End of RX Buffer
0 = The Receive Counter Register has not reached 0 since the last write in ADC_RCR or ADC_RNCR.
1 = The Receive Counter Register has reached 0 since the last write in ADC_RCR or ADC_RNCR.
• RXBUFF: RX Buffer Full
0 = ADC_RCR or ADC_RNCR have a value other than 0.
1 = Both ADC_RCR and ADC_RNCR have a value of 0.
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33.6.7
ADC Last Converted Data Register
Register Name:
ADC_LCDR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
–
–
–
–
–
–
7
6
5
4
3
2
8
LDATA
1
0
LDATA
• LDATA: Last Data Converted
The analog-to-digital conversion data is placed into this register at the end of a conversion and remains until a new conversion is completed.
33.6.8
ADC Interrupt Enable Register
Register Name:
ADC_IER
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
RXBUFF
ENDRX
GOVRE
DRDY
15
14
13
12
11
10
9
8
—
—
—
—
OVRE3
OVRE2
OVRE1
OVRE0
7
6
5
4
3
2
1
0
—
—
—
—
EOC3
EOC2
EOC1
EOC0
• EOCx: End of Conversion Interrupt Enable x
• OVREx: Overrun Error Interrupt Enable x
• DRDY: Data Ready Interrupt Enable
• GOVRE: General Overrun Error Interrupt Enable
• ENDRX: End of Receive Buffer Interrupt Enable
• RXBUFF: Receive Buffer Full Interrupt Enable
0 = No effect.
1 = Enables the corresponding interrupt.
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33.6.9
ADC Interrupt Disable Register
Register Name:
ADC_IDR
Access Type:
Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
RXBUFF
ENDRX
GOVRE
DRDY
15
14
13
12
11
10
9
8
—
—
—
—
OVRE3
OVRE2
OVRE1
OVRE0
7
6
5
4
3
2
1
0
—
—
—
—
EOC3
EOC2
EOC1
EOC0
• EOCx: End of Conversion Interrupt Disable x
• OVREx: Overrun Error Interrupt Disable x
• DRDY: Data Ready Interrupt Disable
• GOVRE: General Overrun Error Interrupt Disable
• ENDRX: End of Receive Buffer Interrupt Disable
• RXBUFF: Receive Buffer Full Interrupt Disable
0 = No effect.
1 = Disables the corresponding interrupt.
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33.6.10 ADC Interrupt Mask Register
Register Name:
ADC_IMR
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
RXBUFF
ENDRX
GOVRE
DRDY
15
14
13
12
11
10
9
8
—
—
—
—
OVRE3
OVRE2
OVRE1
OVRE0
7
6
5
4
3
2
1
0
—
—
—
—
EOC3
EOC2
EOC1
EOC0
• EOCx: End of Conversion Interrupt Mask x
• OVREx: Overrun Error Interrupt Mask x
• DRDY: Data Ready Interrupt Mask
• GOVRE: General Overrun Error Interrupt Mask
• ENDRX: End of Receive Buffer Interrupt Mask
• RXBUFF: Receive Buffer Full Interrupt Mask
0 = The corresponding interrupt is disabled.
1 = The corresponding interrupt is enabled.
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33.6.11 ADC Channel Data Register
Register Name:
ADC_CDRx
Access Type:
Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
–
–
–
–
–
–
7
6
5
4
3
2
8
DATA
1
0
DATA
• DATA: Converted Data
The analog-to-digital conversion data is placed into this register at the end of a conversion and remains until a new conversion is completed. The Convert Data Register (CDR) is only loaded if the corresponding analog channel is enabled.
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34. Segment LCD Controller (SLCDC)
34.1
Overview
An LCD consists of several segments (pixels or complete symbols) which can be visible or invisible. A segment
has two electrodes with liquid crystal between them. When a voltage above a threshold voltage is applied across
the liquid crystal, the segment becomes visible.
The voltage must alternate to avoid an electrophoresis effect in the liquid crystal, which degrades the display.
Hence the waveform across a segment must not have a DC component.
The SLCDC controller is intended for monochrome passive liquid crystal display (LCD) with up to 10 common terminals and up to 40 segment terminals.
The SLCDC is programmable to support many different requirements such as:
• Adjusting the driving time of the LCD pads in order to save power and increase the controllability of the DC
offset
• Driving smaller LCD (down to 1 common by 1 segment)
• Adjusting the SLCDC frequency in order to obtain the best compromise between frequency and consumption
and adapt it to the LCD driver
.
Table 34-1.
List of Terms
Term
Description
LCD
A passive display panel with terminals leading directly to a segment
Segment
The least viewing element (pixel) which can be on or off
Common(s)
Denotes how many segments are connected to a segment terminal
Duty
1/(Number of common terminals on an actual LCD display)
Bias
1/(Number of voltage levels used driving a LCD display -1)
Frame Rate
Number of times the LCD segments are energized per second.
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34.2
Block Diagram
Figure 34-1. LCD Macrocell Block Diagram
SCLK
Prescaler
SCLK/1024
SCLK/ 8
Clock
Multiplexer
PRESC
SLCDC_FRR
SEG0
SEG1
SEG2
Com./Rate Uniformizer
SEG3
/2
/16
SEG4
SEG5
COMSEL
DIV
Divide by 1 to 8
clkslcdc
COMSEL, LPMODE, BIAS
BUFFTIME, LCDBLKFREQ
ENDFRAME
Timing Generation
Buffer_on
User Frame Buffer
Display Frame
Buffer
A
P
B
Analog
Switch
Array
LCD COM
Waveform
Generator
SLCDC_MEM 0-1
Output
Decoder
40 x
10:1
MUX
B
U
S
LCD SEG
Waveform
Generator
SEG35
SEG36
BIAS
DISPMODE, SEGSEL
SLCDC_MEM 18-19
SEG37
SEG38
SEG39
SLCDC_DR
LCDBLKFREQ, DISPMODE
COM0
COM1
SLCDC_IER
SLCDC_IDR
SLCDC_IMR
IT
Generation
DISABLE
1/4 VLCD
Analog
Buffers
ENDFRAME
Buffer_on
SLCDC_ISR
SLCDC_CR
SLCDC_MR
on
ENABLE, DISABLE, SWRST
1/3 VLCD
COM8
1/2 VLCD
COM9
2/3 VLCD
2/3 1/3
3/4 VLCD
3/4 1/2 1/4
COMSEL, SEGSEL
BIAS,BUFFTIME, LPMODE
SLCDC_SR
ENA
VLCD
R
R
R
GND
On-chip resistor ladder for 1/3 bias
VLCD
R
R
R
R
GND
On-chip resistor ladder for 1/4 and 1/2 bias
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34.3
I/O Lines Description
Table 34-2.
I/O Lines Description
Name
Description
Type
SEG [39:0]
Segments control signals
Output
COM [9:0]
Commons control signals
Output
34.4
Product Dependencies
34.4.1
I/O Lines
The pins used for interfacing the SLCD Controller may be multiplexed with PIO lines. Please refer to product block
diagram.
In this case, the assignment of the segment controls and commons are automatically done depending on COMSEL
and SEGSEL in SLCDC_MR. If I/O lines of the SLCD Controller are not used by the application, they can be used
for other purposes by the PIO Controller.
34.4.2
Power Management
The SLCD Controller is clocked by the slow clock (SCLK). All the timings are based upon a typical value of 32 kHz
for SCLK. The power management of the SLCD controller is handled by the Shutdown Controller.
The SLCD Controller is supplied by 3V domain.
34.4.3
Interrupt Sources
The SLCD Controller interrupt line is connected to one of the internal sources of the Advanced Interrupt Controller.
Using the SLCD Controller interrupt requires prior programming of the AIC.
34.4.4
Number of Segments and Commons
The product, embeds 40 segments and 10 Commons.
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34.5
Functional Description
After the initialization sequence the SLCDCC is ready to be enabled in order to enter the display phase (where it is
possible to do more than display data written in the SLCDC memory) up to the disable sequence.
• Initialization Sequence:
1. Select the LCD supply source in the shutdown controller
– Internal: The on chip charge pump is selected,
– External: the external supply source has to be between 2 and 3.4 V
2. Select the clock division (SLDCD_FRR) to use a proper frame rate
3. Enter the number of common and segments terminals (SLDCD_MR)
4. Select the bias in compliance with the LCD manufacturer data sheet
5. Enter buffer driving time
• During the Display Phase:
1. Data may be written at any time in the SLCDC memory, they are automatically latched and displayed at
the next LCD frame
2. It is possible to:
– Adjust contrast
– Adjust the frame frequency
– Adjust buffer driving time
– Reduce the SLCDC consumption by entering in low-power waveform at any time
– Use the large set of display features such as blinking, inverted blink, etc.
• Disable Sequence:
There are two ways to disable the SLCDC
1. By using the LCDDIS (LCD Disable) bit. (In this case, SLCDC configuration and memory content are
kept.)
2. Or by using the SWRST (Software Reset) bit.
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34.5.1
Clock Generation
34.5.1.1
Block Diagram
Figure 34-2. Clock Generation Block Diagram
Com./Rate Uniformizer
Prescaler SCLK/8
Clock
Mux
SCLK
/2
Divider (1 to 8)
clkSLCDC
SCLK/1024
/16
PRESC
SLCDC_FRR
clkSLCDC
SLCDC_MR
COMSEL
DIV
Timing Generation
ENDFRAME
LPMODE
COMSEL
COM + SEG Waveform Generator
SEGSEL
LCD COM
Waveform
Generator
LCD SEG
Waveform
Generator
Buffer driving time management
BUFFTIME
Buffer_on
Blinking generator
SLCDC_DR
LCDBLKFREQ
Blink period
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34.5.2
Waveform Generation
34.5.2.1
Static Duty and Bias
This kind of display is driven with the waveform shown in Figure 34-3. SEG0 - COM0 is the voltage across a segment that is on, and SEG1 - COM0 is the voltage across a segment that is off.
Figure 34-3. Driving an LCD with One Common Terminal
VLCD
VLCD
SEG0
GND
SEG1
GND
VLCD
VLCD
COM0
GND
COM0
GND
VLCD
SEG0 - COM0
GND
GND
SEG1 - COM0
-VLCD
Frame Frame
34.5.2.2
Frame Frame
1/2 Duty and 1/2 Bias
For an LCD with two common terminals (1/2 duty) a more complex waveform must be used to control segments
individually. Although 1/3 bias can be selected, 1/2 bias is most common for these displays. In the waveform
shown in Figure 34-4, SEG0 - COM0 is the voltage across a segment that is on, and SEG0 - COM1 is the voltage
across a segment that is off.
Figure 34-4. Driving an LCD with Two Common Terminals
VLCD
VLCD
SEG0
SEG0
GND
1/
GND
VLCD
V
2 LCD
GND
COM0
VLCD
V
2 LCD
GND
-1/ V
2 LCD
-VLCD
1/
VLCD
V
2 LCD
GND
COM1
VLCD
V
2 LCD
GND
-1/ V
2 LCD
-VLCD
1/
SEG0 - COM0
Frame Frame
34.5.2.3
1/
SEG0 - COM1
Frame Frame
1/3 Duty and 1/3 Bias
1/3 bias is usually recommended for an LCD with three common terminals (1/3 duty). In the waveform shown in
Figure 34-5, SEG0 - COM0 is the voltage across a segment that is on and SEG0-COM1 is the voltage across a
segment that is off.
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Figure 34-5. Driving an LCD with Three Common Terminals
VLCD
3VLCD
1/ V
3 LCD
GND
2/
SEG0
VLCD
3VLCD
1/ V
3 LCD
GND
2/
VLCD
V
3 LCD
1/ V
3 LCD
GND
1
- /3VLCD
-2/3VLCD
-VLCD
VLCD
V
3 LCD
1/ V
3 LCD
GND
2/
SEG0
VLCD
3VLCD
1/ V
3 LCD
GND
2/
COM0
2/
VLCD
V
3 LCD
1/ V
3 LCD
GND
1
- /3VLCD
-2/3VLCD
-VLCD
COM1
2/
SEG0 - COM0
Frame
Frame
SEG0 - COM1
Frame
Frame
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34.5.2.4
1/4 Duty and 1/3 Bias
1/3 bias is optimal for LCD displays with four common terminals (1/4 duty). In the waveform shown in Figure 34-6,
SEG0 - COM0 is the voltage across a segment that is on and SEG0 - COM1 is the voltage across a segment that
is off.
Figure 34-6. Driving an LCD with Four Common Terminals
VLCD
3VLCD
1/ V
3 LCD
GND
2/
SEG0
VLCD
V
3 LCD
1/ V
3 LCD
GND
2/
VLCD
3VLCD
1/ V
3 LCD
GND
-1/3VLCD
-2/3VLCD
-VLCD
VLCD
3VLCD
1/ V
3 LCD
GND
2/
SEG0
VLCD
V
3 LCD
1/ V
3 LCD
GND
2/
COM0
2/
VLCD
3VLCD
1/ V
3 LCD
GND
-1/3VLCD
-2/3VLCD
-VLCD
COM1
2/
SEG0 - COM0
Frame
Frame
SEG0 - COM1
Frame
Frame
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34.5.2.5
Low Power W
aveform
To reduce toggle activity and hence power consumption, a low power waveform can be selected by writing
LPMODE to one. The default and low power waveform is shown in Figure 34-7 for 1/3 duty and 1/3 bias. For other
selections of duty and bias, the effect is similar.
Figure 34-7.
Default and Low Power Waveform
VLCD
3VLCD
1/ V
3 LCD
GND
VLCD
3VLCD
1/ V
3 LCD
GND
2/
2/
SEG0
VLCD
V
3 LCD
1/ V
3 LCD
GND
2/
VLCD
V
3 LCD
1/ V
3 LCD
GND
2/
COM0
VLCD
3VLCD
1/ V
3 LCD
GND
-1/3VLCD
-2/3VLCD
-VLCD
2/
COM0
VLCD
3VLCD
1/ V
3 LCD
GND
-1/3VLCD
-2/3VLCD
-VLCD
2/
SEG0 - COM0
Frame
Note:
SEG0
Frame
SEG0 - COM0
Frame
Frame
Refer to the LCD specification to verify that low power waveforms are supported.
34.5.2.6
Frame Rate
The Frame Rate register (SLCDC_FRR) enables the generation of the frequency used by the SLCD Controller. It is
done by a prescaler (division by 8, 16, 32, 64, 128, 256, 512 and 1024) followed by a finer divider (division by 1, 2,
3, 4, 5, 6, 7 or 8).
To calculate the proper frame frequency needed, the equation below must be taken into account:
fSCLK
f frame = --------------------------------------------------------------( PRES ⋅ DIV ⋅ NCOM )
Where:
fSCLK = slow clock frequency
fframe = frame frequency
PRES = prescaler value (8, 16, 32, 64, 128, 256, 512 or 1024)
DIV = divider value (1, 2, 3, 4, 5, 6, 7, or 8)
NCOM = depends of number of commons and is defined in Table 34-3 below:
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Table 34-3.
NCOM
Number of Commons
NCOM
1
16
2
16
3
15
4
16
5
15
6
18
7
14
8
16
9
18
10
20
34.5.2.7
Buffer Driving Time
Intermediate voltage levels are generated from buffer drivers. The buffers are active the amount of time specified
by BUFTIME[3:0] in SLCDC_MR, then buffers are bypassed.
Shortening the drive time will reduce power consumption, but displays with high internal resistance or capacitance
may need longer drive time to achieve sufficient contrast.
Example for bias = 1/3.
Figure 34-8. Buffer Driving
SLCDC_MR
BUFFTIME
VLCD
R
2/3 VLCD
R
1/3 FLCD
R
34.5.3
Number of Commons, Segments and Bias
It is important to note that the selection of the number of commons, segments and the bias is only taken into
account when the SLCDC is disabled.
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34.5.4
SLCDC memory
Figure 34-9. Memory Management
COM0 time slot
COM1 time slot
COM2 time slot
COM0
Display data previously
loaded from the usr buff
to the disp buff
COM1
Load data from the
usr buff to the disp buff
Display data previously
loaded from the usr buff
to the disp buff
COM2
Load data from the
usr buff to the disp buff
Display data previously
loaded from the usr buff
to the disp reg
Load data from the
usr buff to the disp buff
usr buff = user buffer
disp buf = display buffer
When a bit in the display memory (SLDC_MEM) is written to one, the corresponding segment is energized (on),
and non-energized when a bit in the display memory is written to zero.
At the beginning of each common, the display buffer is updated. The value of the previous common is latched in
the display memory (it’s value is transferred from the user buffer to the frame buffer).
The advantages of this solution are:
• Ability to access the user buffer at any time in the frame, in any display mode and even in low power waveform
• Ability to change only one pixel without reloading the picture
34.5.5
Display Features
In order to improve the flexibility of SLCDC the following set of display modes are embedded:
1. Force Mode Off: All pixels are turned off and the memory content is kept.
2. Force Mode On: All pixels are turned on and the memory content is kept.
3. Inverted Mode: All pixels are set in the inverted state as defined in SLCDC memory and the memory content is kept.
4. Two Blinking Modes:
– Standard Blinking Mode: All pixels are alternately turned off to the predefined state in SLCDC memory
at LCDBLKFREQ frequency.
– Inverted Blinking Mode: All pixels are alternately turned off to the predefined opposite state in SLCDC
memory at LCDBLKFREQ frequency.
5. Buffer Swap Mode: All pixels are alternatively assigned to the state defined in the user buffer then to the
state defined in the display buffer.
34.5.6
Buffer Swap Mode
This mode allows to assign all pixels to two states alternatively without reloading the user buffer at each change.
The means to alternatively display two states is as follows:
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1. Initially, the SLCDC must be in normal mode or in a standard blinking mode.
2. Data corresponding to the first pixel state is written in the user buffer (through the SLCDC_MEM
registers).
3. Wait two ENDFRAME events (to be sure that the user buffer is entirely transferred in the display buffer).
4. SLCDC_DR must be programmed with DISPMODE = 6 (User Buffer Only Load Mode). This mode blocks
the automatic transfer from the user buffer to the display buffer.
5. Wait ENDFRAME event. (The display mode is internally updated at the beginning of each frame.)
6. Data corresponding to the second pixel state is written in the user buffer (through the SLCDC_MEM registers). So, now the first pixel state is in the display buffer and the second pixel state is in the user buffer.
7. SLCDC_DR must be programmed with DISPMODE = 7 (buffer swap mode) and LCDBLKFREQ must be
programmed with the wanted blinking frequency (if not previously done).
Now, each state is alternatively displayed at LCDBLKFREQ frequency.
Except for the phase dealing with the storage of the two display states, the management of the Buffer Swap Mode
is the same as the standard blinking mode.
34.5.7
Disable Sequence
There are two ways to disable the SLCDC:
1. By using the disable bit. (In this case, register configuration and SLCDC memory are kept.)
2. Or by using the software reset bit that acts like a hardware reset.
In both cases, no DC voltage should be left across any segment.
34.5.7.1
Disable Bit
When the LCD Disable Command is activated during a frame, the next frame will be generated in “All Ground”
Mode (whereby all commons and segments will be tied to ground).
At the end of this ‘All Ground” frame, the disable bit is reset and the disable interrupt is asserted. This indicates that
the SLCDC is really disabled and that the LCD can be switched off.
Figure 34-10. Disabling Sequence
Disable Example for Three Commons
End of Frame Interrupt
Common
VLCD
The common is tied to ground
1/3
GND
-1/3
-VLCD
Disable Command
The disable command is activated
The command is taken into account
ENA bit
Disable Interrupt
The SLCDC is really disabled
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34.5.7.2
Software Reset
When the LCD software reset command is activated during a frame it is immediately taken into account and all
commons and segments are tied to ground.
Note that in the case of a software reset, the disable interrupt is not asserted.
Figure 34-11. Software Reset
SW Reset Example for Three Commons
End Of Frame Interrupt
Common
VLCD
The common is immediatly tied to ground
1/3
GND
-1/3
-VLCD
SW Reset Command
The SW reset command is activated
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34.5.8
Flowchart
Figure 34-12. SLCDC Flow Chart
START
INITIALIZATION
Supply source (internal or external)
Number of com (COMSEL in SLCDC_MR)
Number of seg (SEGSEL in SLCDC_MR)
Frame rate ((PRESC + DIV) in SLCDC_FRR)
Buff on time (BUFTIME in SLCDC_MR)
Bias (BIAS in SLCDC_MR)
ENABLES THE SLCDC
LCDEN in SLCDC_MR
ENA = 1?
ENA in SLCDC_SR
No
Update the displayed data?
Write the new data in the SLCDC_MEM
No
Update/Change
the display mode?
No
Change/Update the display mode (DISPMODE in SLCDC_DR)
No
Blink?
- Normal mode
- Force off
- Force on
- Inverted mode
Change/Update the blinking frequency (LCDBLKFREQ in SLCDC_DR)
Change/Update the display mode (DISPMODE in SLCDC_DR)
- Blinking mode
- Inverted Blinking mode
Change the power
comsumption ?
No
Enter/Exit from
low-power wave form?
No
Change the frame rate ?
LPMODE in SLCDC_MR
PRESC + DIV in SLCDC_FRR
Disable the SLCDC ?
No
BUFTIME in SLCDC_MR
No
SW reset ?
LCDDIS in SLCDC_CR
Disable interrupt?
DIS in SLCDC_ISR
No
ENA bit = 0?
ENA in SLCDC_SR
No
No
SWRST in SLCDC_CR
END
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34.6
Waveform Specifications
34.6.1
DC Characteristics
Refer to the DC Characteristics section of the product datasheet.
34.6.2
LCD Contrast
The peak value (VLCD) on the output waveform determines the LCD Contrast. VLCD is controlled by software in 16
steps of 62 mV each from 2.4V to 3.4V independent of VDDIN.
This is a function of the supply controller.
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34.7
Segment LCD Controller (SLCDC) User Interface
Table 34-4.
Offset
Register Mapping
Register
Name
Access
Reset
0x0
SLCDC Control Register
SLCDC_CR
Write-only
-
0x4
SLCDC Mode Register
SLCDC_MR
Read-write
0x0
0x8
SLCDC Frame Rate Register
SLCDC_FRR
Read-write
0x0
OxC
SLCDC Display Register
SLCDC_DR
Read-write
0x0
0x10
SLCDC Status Register
SLCDC_SR
Read-only
0x0
0x20
SLCDC Interrupt Enable Register
SLCDC_IER
Write-only
-
0x24
SLCDC Interrupt Disable Register
SLCDC_IDR
Write-only
-
0x28
SLCDC Interrupt Mask Register
SLCDC_IMR
Write-only
-
0x2C
SLCDC Interrupt Status Register
SLCDC_ISR
Read-only
0x0
0x200
SLCDC Memory Register
SLCDC_MEM
Read-write
0x0
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
490
34.7.1
SLCDC Control Register
SLCDC_CR
Name:
Access:
Write-only
Reset Value: 0x00000000
31
23
15
7
-
30
22
14
6
-
29
21
13
5
-
28
20
12
4
-
27
19
11
3
SWRST
26
18
10
2
-
25
17
9
1
LCDDIS
24
16
8
0
LCDEN
• LCDEN: Enable the LCDC
0 = No effect.
1 = The SLCDC is enabled
• LCDDIS: Disable LCDC
0 = No effect.
1 = The SLCDC is disabled.
Note: LCDDIS is taken into account at the beginning of the next frame.
• SWRST: Software Reset
0 = No effect.
1 = Equivalent to a power-up reset. When this command is performed, the SLCDC1 immediately ties all segments end
commons lines to values corresponding to a “ground voltage”.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
491
34.7.2
SLCDC Mode Register
SLCDC_MR
Name:
Access:
Read-write
Reset Value: 0x00000000
31
23
15
7
-
30
22
14
6
-
29
21
28
20
27
19
26
18
25
17
24
LPMODE
16
12
11
10
9
8
2
1
0
BIAS
BUFTIME
13
SEGSEL
5
-
4
-
3
COMSEL
• COMSEL: Selection of the Number of Commons
(Taken into account when the SLCDC is disabled.)
COMSEL3
COMSEL2
COMSEL1
COMSEL0
COM Pin
I/O Port Pin
0
0
0
0
COM0
COM1:9
0
0
0
1
COM0:1
COM2:9
0
0
1
0
COM0:2
COM3:9
0
0
1
1
COM0:3
COM4:9
0
1
0
0
COM0:4
COM5:9
0
1
0
1
COM0:5
COM6:9
0
1
1
0
COM0:6
COM7:9
0
1
1
1
COM0:7
COM8:9
1
0
0
0
COM0:8
COM9
1
0
0
1
COM0:9
None
• SEGSEL: Selection of the Number of Segments
(Taken into account when the SLCDC is disabled.)
Maximum
Number of
Segments
SEGSEL5
SEGSEL4
SEGSEL3
SEGSEL2
SEGSEL1
SEGSEL0
I/O Port in Use as
Segment Driver
0
0
0
0
0
0
SEG0
1
0
0
0
0
0
1
SEG0
2
0
0
0
0
1
0
SEG0:1
3
...
...
...
...
...
...
...
...
1
0
0
1
0
1
SEG0:37
38
1
0
0
1
1
0
SEG0:38
39
1
0
0
1
1
1
SEG0:39
40
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
492
• BUFTIME: Buffer On-Time
(Taken into account from the next begin of frame.)
BUFTIME3
BUFTIME2
BUFTIME1
BUFTIME0
Nominal Drive Time
0
0
0
0
0%
0
0
0
1
2 x tSCLK
0
0
1
0
4 x tSCLK
0
0
1
1
8 x tSCLK
0
1
0
0
16 x tSCLK
0
1
0
1
32 x tSCLK
0
1
1
0
64 x tSCLK
0
1
1
1
128 x tSCLK
1
0
0
0
50%
1
0
0
1
100%
• BIAS: LCD Display Configuration
(Taken into account when the SLCDC is disabled.)
Note:
BIAS1
BIAS0
Ratio
0
0
1
0
1
1/2
1
0
1/3
1
1
1/4
BIAS is only taken into account when the SLCDC is disabled.
• LPMODE: Low Power Mode (Taken into account from the next begin of frame.)
0 = Normal Mode.
1 = Low Power Waveform is enabled.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
493
34.7.3
SLCDC Frame Rate Register
SLCDC_FRR
Name:
Access:
Read-write
Reset Value: 0x00000000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
8
7
6
5
4
3
2
9
DIV
1
PRESC
0
• PRES: Clock Prescaler
(Taken into account from the next begin of frame.)
PRESC2
PRESC1
PRESC0
Output from Prescaler
0
0
0
SCLK/8
0
0
1
SCLK/16
0
1
0
SCLK/32
0
1
1
SCLK/64
1
0
0
SCLK/128
1
0
1
SCLK/256
1
1
0
SCLK/512
1
1
1
SCLK/1024
• DIV: Clock Division
(Taken into account from the next begin of frame.)
DIV2
DIV1
DIV0
Output from Prescaler Divided by:
0
0
0
1
0
0
1
2
0
1
0
3
0
1
1
4
1
0
0
5
1
0
1
6
1
1
0
7
1
1
1
8
SAM7L128/64 [DATASHEET]
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494
34.7.4
SLCDC Memory Register
SLCDC_MEM
Name:
Access:
Read / Write
Write a SLCD memory bit to one and the corresponding segment will be energized (visible). Unused SLCD Memory bits for
the actual display can be used freely as storage.
SEG0
--
SEG31
SLCDC_MEM19
SLCDC_MEM18
COM9
COM9
X
--
X
SLCDC_MEM17
SLCDC_MEM16
COM8
COM8
X
--
X
SLCDC_MEM15
SLCDC_MEM14
COM7
COM7
X
--
X
SLCDC_MEM13
SLCDC_MEM12
COM6
COM6
X
--
X
SLCDC_MEM11
SLCDC_MEM10
COM5
COM5
X
--
X
SLCDC_MEM9
SLCDC_MEM8
COM4
COM4
X
--
X
SLCDC_MEM7
SLCDC_MEM6
COM3
COM3
X
--
X
SLCDC_MEM5
SLCDC_MEM4
COM2
COM2
X
--
X
SLCDC_MEM3
SLCDC_MEM2
COM1
COM1
X
--
X
SLCDC_MEM1
SLCDC_MEM0
COM0
COM0
X
--
X
SEG32
--
SEG39
Memory address
X
--
X
From 0x24C to 0x24F
From 0x248 to 0x24B
X
--
X
From 0x244 to 0x247
From 0x240 to 0x243
X
--
X
From 0x23C to 0x23F
From 0x238 to 0x23B
X
--
X
From 0x234 to 0x237
From 0x230 to 0x233
X
--
X
From 0x22C to 0x22F
From 0x228 to 0x22B
X
--
X
From 0x224to 0x227
From 0x220 to 0x223
X
--
X
From 0x21C to 0x21F
From 0x218 to 0x21B
X
--
X
From 0x214 to 0x217
From 0x210 to 0x213
X
--
X
From 0x20C to 0x20F
From 0x208 to 0x20B
X
--
X
From 0x204 to 0x207
From 0x200 to 0x203
SAM7L128/64 [DATASHEET]
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495
34.7.5
SLCDC Display Register
SLCDC_DR
Name:
Access:
Read-write
Reset Value: 0x00000000
31
30
29
28
27
26
25
24
–
23
–
22
–
21
–
20
–
19
–
18
–
17
–
16
–
15
–
14
–
13
–
10
–
9
–
8
7
6
5
–
–
12
11
LCDBLKFREQ
4
3
2
0
–
–
–
–
1
DISPMODE
–
• DISPMODE: Display Mode Register
(Taken into account from the next begin of frame.)
DISPMODE2
DISPMODE1
DISPMODE0
Display Mode
0
0
0
Normal Mode:
Latched data are displayed.
0
0
1
Force Off Mode:
All pixels are invisible. (The SLCDC memory is
unchanged.)
0
1
0
Force On Mode
All pixels are visible. (The SLCDC memory is unchanged.)
0
1
1
Blinking Mode:
All pixels are alternately turned off to the predefined state
in SLCDC memory at LCDBLKFREQ frequency. (The
SLCDC memory is unchanged.)
1
0
0
Inverted Mode:
All pixels are set in the inverted state as defined in SLCDC
memory. (The SLCDC memory is unchanged.)
1
0
1
Inverted Blinking Mode:
All pixels are alternately turned off to the predefined
opposite state in SLCDC memory at LCDBLKFREQ
frequency. (The SLCDC memory is unchanged.)
1
1
0
User Buffer Only Load Mode:
Blocks the automatic transfer from User Buffer to Display
Buffer.
1
Buffer Swap Mode:
All pixels are alternatively assigned to the state defined in
the User Buffer, then to the state defined in the Display
Buffer at LCDBLKFREQ frequency.
1
1
• LCDBLKFREQ: LCD Blinking Frequency Selection
(Taken into account from the next begin of frame.)
Blinking frequency = Frame Frequency/LCDBLKFREQ[7:0].
Note:
0 written in LCDBLKFREQ stops blinking.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
496
34.7.6
Name:
SLCDC Status Register
SLCDC_SR
Access Type: Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
–
–
ENA
• ENA: Enable Status (Automatically Set/Reset)
0 = The SLCDC1 is disabled.
1 = The SLCDC1 is enabled.
34.7.7
Name:
SLCDC Interrupt Enable Register
SLCDC_IER
Access Type: Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
DIS
–
ENDFRAME
• ENDFRAME: End of Frame Interrupt Enable
• DIS: Disable Interrupt Enable
0 = No effect.
1 = Enables the corresponding interrupt.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
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34.7.8
Name:
SLCDC Interrupt Disable Register
SLCDC_IDR
Access Type: Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
–
–
7
6
5
4
3
2
1
0
–
–
–
–
–
DIS
–
ENDFRAME
• ENDFRAME: End of Frame Interrupt Disable
• DIS: Disable Interrupt Disable
0 = No effect.
1 = Disables the corresponding interrupt.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
498
34.7.9
Name:
SLCDC Interrupt Mask Register
SLCDC_IMR
Access Type: Write-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
-
-
7
6
5
4
3
2
1
0
-
-
-
-
-
DIS
-
ENDFRAME
• ENDFRAME: End of Frame Interrupt Mask
• DIS: Disable Interrupt Mask
0 = The corresponding interrupt is not enabled.
1 = The corresponding interrupt is enabled.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
499
34.7.10
Name:
SLCDC Interrupt Status Register
SLCDC_ISR
Access Type: Read-only
31
30
29
28
27
26
25
24
–
–
–
–
–
–
–
–
23
22
21
20
19
18
17
16
–
–
–
–
–
–
–
–
15
14
13
12
11
10
9
8
–
–
–
–
–
–
-
-
7
6
5
4
3
2
1
0
-
-
-
-
-
DIS
-
ENDFRAME
• ENDFRAME: End of Frame Interrupt Status
0 = End of Frame Interrupt has not occurred since the last read of the Interrupt Status Register.
1 = End of Frame Interrupt has occurred since the last read of the Interrupt Status Register.
• DIS: Disable Interrupt Status
0 = Disable Interrupt has not occurred since the last read of the Interrupt Status Register
1 = Disable Interrupt has occurred since the last read of the Interrupt Status Register.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
500
35. AT91SAM7L128/64 Electrical Characteristics
35.1
Absolute Maximum Ratings
Table 35-1.
Absolute Maximum Ratings*
Operating Temperature (Industrial) ...............-40⋅ C to + 85⋅ C
Storage Temperature.....................................-60°C to + 150°C
Voltage on Input Pins
with Respect to Ground...... ..............................-0.3V to + 5.5V
*NOTICE:
Stresses beyond those listed under “Absolute Maximum
Ratings” may cause permanent damage to the device.
This is a stress rating only and functional operation of the
device at these or other conditions beyond those indicated in the operational sections of this specification is
not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Maximum Operating Voltage
(VDDCORE ).....................................................................2.0V
Maximum Operating Voltage
(VDDIO1, VDDIO2 and VDDINLCD)...................................4.0V
Total DC Output Current on all I/O lines
128-lead LQFP/144-ball LFBGA...................................100 mA
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
501
35.2
DC Characteristics
The following characteristics are applicable to the operating temperature range: TA = -40°C to 85°C, unless
otherwise specified.
Table 35-2.
DC Characteristics
Symbol
Parameter
Conditions
VDDCORE
DC Supply Core
Depends on VDDOUT (externally
connected to VDDOUT)
VVDDIO1
DC Supply I/Os
VVDDIO2
DC Supply I/Os
VVDDINLCD
VVDDLCD
VIL
VIH
VHys
VOL
VOH
IO
Min
Typ
Max
VDDOUT
Units
V
1.8
3.6
V
1.8
3.6
V
DC Supply Charge Pump
1.8
3.6
V
DC Supply LCD
Regulator
2.5
3.6
V
VVDDIO1 from 1.8V to 3.6V
PC0-PC29, NRST, NRSTB, CLKIN
-0.3
0.3 x
VVDDIO1
V
VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23
-0.3
0.3 x
VVDDIO2
V
VVDDIO1 from 1.8V to 3.6V
PC0-PC29, NRST, NRSTB, CLKIN
0.7 x
VVDDIO1
VVDDIO1
+0.3V
V
VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23
0.7 x
VVDDIO2
VVDDIO2
+0.3V
V
VVDDIO1 from 1.8V to 3.6V
PC0-PC29, NRST, NRSTB, CLKIN
0.25
0.65
V
VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23
0.25
0.7
V
IO max, VVDDIO1 from 1.8V to 3.6V
PC0-PC29, NRST
0.4
V
IO max, VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23
0.4
Adjustable
Input Low-level Voltage
Input High-level Voltage
Hysteresis Voltage
Output Low-level Voltage
IO max, VVDDIO1 from 1.8V to 3.6V
PC0-PC29, NRST
VVDDIO1 0.4
V
IO max, VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23
VVDDIO2 0.4
V
Output High-level Voltage
Output current
VVDDIO1 from 1.8V to 3.6V
PC0-PC6, PC11-PC29, NRST
VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23,
2
VVDDIO1 from 1.8V to 3.6V
PC7-PC10
4
mA
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
502
Table 35-2.
Symbol
ILEAK
RPULLUP
RPULLDOWN
CIN
Table 35-3.
DC Characteristics (Continued)
Parameter
Conditions
Input Leakage Current
Typ
Max
Units
Pull-up resistors disabled
(Typ: TA = 25°C, Max: TA = 85°C)
VVDDIO1 from 1.8V to 3.6V
PC0-PC6, PC11-PC29, NRST
VVDDIO2 from 1.8V to 3.6V
PA0-PA25, PB0-PB23
1
20
nA
Pull-up resistors disabled
(Typ: TA = 25°C, Max: TA = 85°C)
VVDDIO1 from 1.8V to 3.6V
PC70-PC10
2
40
nA
PC0-PC29,NRST
VVDDIO1 from 1.8V to 3.6V
75
100
145
kΩ
PA0-PA25, PB0-PB23,
VVDDIO2 from 1.8V to 3.6V
40
100
375
kΩ
Pull-down Resistor
TST, ERASE, JTAGSEL
VVDDIO1 from 1.8V to 3.6V
10
15
25
kΩ
Input Capacitance
Digital Inputs
4
pF
Pull-up Resistor
1.8V Voltage Regulator Characteristics
Symbol
Parameter
VVDDIO1
Supply Voltage
VACCURACY
Output Voltage Accuracy
Normal mode, ILoad = 0.1mA to 60 mA
DDROPOUT
Dropout Voltage
VVDDIN = 1.8V, ILoad = 60 mA, Normal mode,
1.8V selected (1)
Output Voltage
Normal Mode : 100mV step adjustable (2)
Deep Mode : 100mV step adjustable (2)
Standby mode
VVDDOUT
Min
Conditions
Min
Typ
Max
Units
1.8
2.7
3.6
V
3
%
150
mV
1.8
1.8
V
-3
1.55
1.55
0
Current consumption
Normal Mode
Deep mode
20
6
30
8.5
µA
TSTART
Startup Time
Standby to Normal Mode
Deep to Normal Mode
1.55V to 1.8V Normal Mode
1.55V to 1.8V Deep mode
200
200
200
200
400
400
400
400
µS
ILoad
Maximum DC Output
Current
Normal mode
Deep Mode
60
1
mA
IVDDIN
Notes:
1. This indicates that the minimum voltage on VDDOUT is: 1.80 - 0.150 = 1.65 V (when VDDIO1 = 1.8V and selected output
voltage at 1.80V).
2. Refer to Supply Controller Mode Register, VRVDD field.
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
503
Table 35-4.
Brownout Detector Characteristics
Symbol
Parameter
VVDDIO1
Supply Voltage
TACCURACY
Threshold Level Accuracy
VHYST
Hysteresis
IDD
Current Consumption
TSTART
Startup Time
Table 35-5.
Conditions
16 selectable steps of 100mV from 1.9V
to 3.4V
Normal mode
Max
Units
V
1.5
%
20
30
mV
25
48
µA
140
µS
Max
Units
Zero-Power-on Reset Characteristics
VVDDIO1
Supply Voltage
Vop
Operating voltage rising
At Startup
Vth+
Threshold voltage rising
At Startup
Vth-
Threshold voltage falling
Power-on Reset delay
Conditions
Min
Typ
VVDDIO1
(1)
1.8
3
2.0
4
V
0.6
V
2.2
V
1.8
V
6.8
mS
1. Minimum time of a voltage drop for the Power-on reset to react.
Table 35-6.
DC Flash Characteristics
Symbol
Parameter
Conditions
ISB
Standby current
ICC
-1.5
10
Parameter
Note:
Typ
VVDDIO1
Symbol
PDELAY
Min
Typ
Units
@85°C onto VDDCORE = 1.8V
@25°C onto VDDCORE = 1.8V
10
1
µA
µA
Random Read @ 25MHz
onto VDDCORE = 1.8V
12
mA
Write
onto VDDCORE = 1.8V
3.5
mA
Active current
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
504
35.3
Power Consumption
• Typical power consumption of PLLs, Slow Clock and Main Oscillator.
• Power consumption of power supply in different modes: Backup, Wait, Idle, Active and ultra Low-power.
• Power consumption by peripheral: calculated as the difference in current measurement after having enabled
then disabled the corresponding clock.
35.3.1
Power Consumption Versus Modes
The values in Table 35-7and Table 35-12 on page 516 are measured values of the power consumption with operating conditions as follows:
• VDDIO1 = VDDIO2 = 3V
• VDDOUTcc set at 1.80V
• TA = 25° C
• There is no consumption on the I/Os of the device
Figure 35-1. Measure Schematics
AMP1
VDDIO1
3V
Voltage
Regulator
VDDOUT
1.8V
VDDCORE
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
VDDLCD
AMP2
External supply
3V
VDDIO2
LCD
Voltage
Regulator
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
505
The figures shown below in Table 35-7 represent the power consumption typically measured on the power
supplies..
Table 35-7.
Power Consumption for Low Power Modes (See Figure 35-2 and Figure 35-3)
Mode
Conditions
Off Mode
(AT91SAM7L128/64)
Only the FWUP pin is supplied
Backup Mode
(AT91SAM7L128/64)
Voltage Regulator in standby mode
RTC OFF
Programmable BOD OFF
SRAM BACKUP OFF
Charge pump OFF
LCD Regulator OFF
LCD Controller OFF
Backup Mode
(AT91SAM7L128/64)
Voltage Regulator in standby mode
RTC ON
Programmable BOD OFF
SRAM BACKUP ON
Charge pump OFF
LCD Regulator OFF
LCD Controller OFF
Wait Mode
(AT91SAM7L128/64)
Voltage Regulator in Deep Mode
VDDOUT = 1.55V
RTC OFF
Programmable BOD OFF
FLASH OFF
Charge pump OFF
LCD Regulator OFF
LCD Controller OFF
PLL OFF
Idle Mode
(AT91SAM7L128/64)
Voltage regulator in Deep mode
VDDOUT = 1.55V
RTC OFF
BOD OFF
RC 2MHz OFF
Flash is in standby mode.
ARM Core in idle mode.
MCK @ 500Hz.
ADC OFF
All peripheral clocks de-activated
PLL OFF
VDDIO1
Consumption
Condition
0.1
TBD
VDDIO1 = 2.4V @25°C
VDDIO1 = 3.0V @25°C
TBD
TBD
VDDIO1 = 2.4V @85°C
VDDIO1 = 3.0V @85°C
3.2
3.9
VDDIO1 = 2.4V @25°C
VDDIO1 = 3.0V @25°C
4.31
5.34
VDDIO1 = 2.4V @85°C
VDDIO1 = 3.0V @85°C
3.3
4.14
VDDIO1 = 2.4V @25°C
VDDIO1 = 3.0V @25°C
Unit
µA
µA
µA
5.53
6.43
VDDIO1 = 2.4V @85°C
VDDIO1 = 3.0V @85°C
9.57
10.04
VDDIO1 = 2.4V @25°C
VDDIO1 = 3.0V @25°C
µA
17.42
18.34
9.76
10.6
19.46
20.77
VDDIO1 = 2.4V @85°C
VDDIO1 = 3.0V @85°C
VDDIO1 = 2.4V @25°C
VDDIO1 = 3.0V @25°C
VDDIO1 = 2.4V @85°C
VDDIO1 = 3.0V @85°C
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
µA
506
Figure 35-2. Low-power Modes Consumption @25°C
14.000
12.000
Backup mode (RTC - SRAM OFF)
10.000
Backup mode (RTC - SRAM ON)
) 8.000
A
μ
(I
6.000
Wait mode
Idle mode
4.000
2.000
0.000
2
2.5
3
3.5
4
VDDIO1 (V)
Figure 35-3. Low-power Modes Consumption @85°
25.000
20.000
Backup mode (RTC - SRAM OFF)
15.000
)
A
μ
(I
10.000
Backup mode (RTC - SRAM ON)
Wait mode
Idle mode
5.000
0.000
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
VCC (V)
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
507
35.3.2
Power Consumption for Active Mode
35.3.2.1
Table 35-8.
Low Freaquency
Low Frequency1
Mode
Active
(AT91SAM7L128/64)
(See Figure 35-4)
Active
(AT91SAM7L128/64)
(See Figure 35-5)
Conditions
Voltage regulator in Normal Mode
VDDOUT = 1.80V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC ON
All peripheral clocks activated
RC 2MHz ON
PLL OFF
Voltage regulator in Normal Mode
VDDOUT = 1.55V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC ON
All peripheral clocks activated
RC 2MHz ON
PLL OFF
VDDIO1
Consumption
Condition
1.37
0.72
0.4
0.23
0.147
0.106
0.085
VDDI01= 3V @ 25°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
1.426
0.756
0.418
0.250
0.166
0.124
0.103
VDDI01= 3V @ 85°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
1.123
0.597
0.328
0.194
0.128
0.094
0.077
VDDI01= 3V @ 25°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
1.171
0.628
0.353
0.215
0.146
0.111
0.094
VDDI01= 3V @ 85°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
Unit
mA
mA
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
508
Figure 35-4. Low-range Frequencies, Active Mode Consumption @25°C
(Peripheral Clocks On - PLL Off - RC On - VDD0I1 = 3V)
1.600
1.400
2 MHz
1.200
1 MHz
1.000
500 kHz
)
A 0.800
m
(I
0.600
250 kHz
125 kHz
64 kHz
0.400
32 kHz
0.200
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
Figure 35-5. Low-range Frequencies, Active Mode Consumption @85°C
(Peripheral Clocks On - PLL Off - RC On - VDD0I1 = 3V)
1.600
1.400
2 MHz
1.200
1 MHz
1.000
500 kHz
)
A 0.800
(m
I
0.600
250 kHz
125 kHz
64 kHz
0.400
32 kHz
0.200
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
509
Table 35-9.
Low Frequency 2 (See Charts that Follow)
Mode
Active
(AT91SAM7L128/64)
(See Figure 35-6)
Active
(AT91SAM7L128/64)
(See Figure 35-7)
Conditions
Voltage regulator in Normal Mode
VDDOUT = 1.80V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC OFF
All peripheral clocks deactivated
RC 2MHz ON
PLL OFF
Voltage regulator in Normal Mode
VDDOUT = 1.55V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC OFF
All peripheral clocks deactivated
RC 2MHz ON
PLL OFF
VDDIO1
Consumption
Condition
1.192
0.629
0.346
0.206
0.136
0.1
0.082
VDDI01= 3V @ 25°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
1.238
0.662
0.372
0.227
0.154
0.118
0.1
VDDI01= 3V @ 85°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
0.969
0.516
0.287
0.174
0.117
0.089
0.075
VDDI01= 3V @ 25°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
1.018
0.545
0.313
0.196
0.136
0.106
0.092
VDDI01= 3V @ 85°C
ARM core clock = 2 MHz
ARM core clock = 1 MHz
ARM core clock = 500 KHz
ARM core clock = 250 KHz
ARM core clock = 125 KHz
ARM core clock = 64 KHz
ARM core clock = 32 KHz
Unit
mA
mA
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
510
Figure 35-6. Low-range Frequencies, Active Mode Consumption @25°C
(Peripheral Clocks OFF - PLL Off - RC On - VDD0I1 = 3V)
1.400
1.200
2 MHz
1.000
1 MHz
500 kHz
) 0.800
A
m
(I 0.600
250 kHz
125 kHz
64 kHz
0.400
32 kHz
0.200
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
Figure 35-7. Low-range Frequencies, Active Mode Consumption @85°C
(Peripheral Clocks Off - PLL OFF - RC On -VDD0I1 = 3V)
1.400
1.200
2 MHz
1.000
1 MHz
500 kHz
) 0.800
A
(m
I 0.600
250 kHz
125 kHz
0.400
64 kHz
0.200
32 kHz
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
511
35.3.2.2
High Frequency
Table 35-10. High-range Frequencies, Active Mode (Peripheral Activated)
Mode
Active
(AT91SAM7L128/64)
(See Figure 35-8)
Active
(AT91SAM7L128/64)
(See Figure 35-9)
Conditions
Voltage regulator in Normal Mode
VDDOUT = 1.80V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC ON
All peripheral clocks activated
RC 2MHz OFF
PLL ON
Voltage regulator in Normal Mode
VDDOUT = 1.55V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC ON
All peripheral clocks activated
RC 2MHz OFF
PLL ON
VDDIO1
Consumption
Condition
3.346
5.37
10.37
11.16
12.13
14.24
19.55
22.63
VDDI01= 3V @ 25°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
3.34
5.39
10.39
11.22
12.21
14.35
19.55
22.66
VDDI01= 3V @ 85°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
2.73
4.47
8.55
9.23
10.1
11.9
16
18.6
VDDI01= 3V @ 25°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
2.76
4.52
8.62
9.33
10.21
12.04
16.07
18.75
VDDI01= 3V @ 85°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
Unit
mA
mA
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
512
Figure 35-8. High-range Frequencies, Active Mode Consumption @25°C
(Peripheral Clocks On - PLL On - RC Off -VDD0I1 = 3V)
25.000
4 MHz
20.000
8 MHz
)
A
m
(I
16 MHz
15.000
18 MHz
20 MHz
10.000
24 MHz
30 MHz
5.000
36 MHz
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
Figure 35-9. High-range Frequencies, Active Mode Consumption @85°C
(Peripheral Clocks On - PLL On - RC Off -VDD0I1 = 3V)
25.000
4 MHz
20.000
8 MHz
16 MHz
) 15.000
A
m
(I
18 MHz
20 MHz
10.000
24 MHz
30 MHz
5.000
36 MHz
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
513
Table 35-11. High-range Frequencies, Active Mode
Mode
Active
(AT91SAM7L128/64)
(See Figure 35-10)
Active
(AT91SAM7L128/64)
(See Figure 35-11)
Conditions
Voltage regulator in Normal Mode
VDDOUT = 1.80V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC OFF
All peripheral clocks deactivated
RC 2MHz OFF
PLL ON
Voltage regulator in Normal Mode
VDDOUT = 1.55V
RTC ON
Programmable BOD ON (Continuous)
Charge pump ON
LCD Regulator ON
Flash is read
ADC OFF
All peripheral clocks deactivated
RC 2MHz OFF
PLL ON
VDDIO1
Consumption
Condition
2.927
4.524
8.693
9.305
10.08
11.75
16.38
18.81
VDDI01= 3V @ 25°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
2.923
4.548
8.707
9.336
10.15
11.83
16.31
18.81
VDDI01= 3V @ 85°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
2.377
3.756
7.120
7.651
8.335
9.763
13.27
15.34
VDDI01= 3V @ 25°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
2.398
3.797
7.182
7.729
8.424
9.882
13.33
15.47
VDDI01= 3V @ 85°C
ARM core clock = 4 MHz
ARM core clock = 8 MHz
ARM core clock = 16 MHz
ARM core clock = 18 MHz
ARM core clock = 20 MHz
ARM core clock = 24 MHz
ARM core clock = 30 MHz
ARM core clock = 36 MHz
Unit
mA
mA
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
514
Figure 35-10. High-range Frequencies, Active Mode Consumption @25°C
(Peripheral Clocks Off - PLL On - RC Off - VDD0I1 = 3V)
20.000
18.000
16.000
4 MHz
14.000
8 MHz
16 MHz
12.000
)
A 10.000
(m
I
8.000
18 MHz
20 MHz
24 MHz
6.000
30 MHz
4.000
36 MHz
2.000
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
Figure 35-11. High-range Frequencies, Active Mode Consumption @85°C
(Peripheral Clocks Off - PLL On - RC Off - VDD0I1 = 3V)
20.000
18.000
4 MHz
16.000
8 MHz
14.000
16 MHz
) 12.000
A
10.000
m
(I
18 MHz
20 MHz
8.000
6.000
24 MHz
4.000
30 MHz
2.000
36 MHz
0.000
1.5
1.55
1.6
1.65
1.7
1.75
1.8
1.85
VDDOUT (V)
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
515
35.3.3
Peripheral Power Consumption in Active Mode
Table 35-12. Power Consumption on VDDCORE(1)
Peripheral
Consumption (Typ)
PIO Controller
9
USART
24
PWM
13
TWI
17
SPI
12
Timer Counter Channels
6
ADC
8
ARM7TDMI
µA/MHz
160
System Peripherals (AT91SAM7L128/64)
Note:
Unit
6
1. Note: VDDIO1= 2.4V, VDDCORE = 1.80V, TA = 25° C
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
516
35.4
Crystal Oscillators Characteristics
35.4.1
32 kHz RC Oscillator Characteristics
Table 35-13. 32 KHz RC Oscillator Characteristics
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
VVDDIO1
Supply Voltage
VDDIO1 domain
1.8
2.7
3.6
V
20
32
44
kHz
RC Oscillator Frequency
Frequency Supply Dependency
Typical @ 2.7V
-5
5
%
Frequency Temperature Dependency
Typical @ 25°C
-7
7
%
55
%
100
µs
780
nA
0.02
µA
Duty Cycle
tST
IOSC
45
Startup Time
VVDDIO1 = 1.65V
Current Consumption
After Startup Time
Temp. Range = -40°C to +85°C
Typical Consumption at 2.2V
supply and Temp = 25°C
50
370
Standby Consumption
35.4.2
2 MHz RC Oscillator Characteristics
Table 35-14. 2 MHz RC Oscillator Characteristics
Symbol
1/(tCPRC)
Parameter
Conditions
Min
Typ
Max
Unit
Supply Voltage
VDDCORE domain
1.2
1.6
1.85
V
1.35
2
2.65
MHz
RC Oscillator Frequency
Frequency Supply Dependency
VDDCORE
1.2V < 1.6V < 1.95V
1.65V < 1.8V < 1.95V
1.2V < 1.3V < 1.4V
-3
-1.5
-1.5
3
1.5
1.5
Frequency Temperature Dependency
Typical @ 25°C
-10
+10
%
55
%
5
µs
30
µA
1
µA
Duty Cycle
45
tST
Startup Time
Frequency > 1MHz
IOSC
Current Consumption
After Startup Time
Standby Consumption
50
2
18
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
%
517
35.4.3
XTAL Oscillator Characteristics
Table 35-15. XTAL Oscillator Characteristics
Symbol
Parameter
Conditions
Min
Freq
Operating Frequency
Normal mode with crystal
Supply Voltage
VDDIO1 Domain
1.8
Duty Cycle
40
Rs < 50KΩ
Startup Time
Rs < 100KΩ
(1)
Rs < 50KΩ
Current consumption
Rs < 100KΩ
(1)
IDDST
Standby Current Consumption
PON
Drive level
Rf
Internal resistor
CLEXT
Maximum external capacitor
on XIN and XOUT
CL
Internal Equivalent Load Capacitance
Notes:
Typ
50
CL = 12.5pF
CL = 6pF
CL = 12.5pF
CL = 6pF
CL = 12.5pF
CL = 6pF
CL = 12.5pF
CL = 6pF
650
450
900
650
Max
Unit
32.768
KHz
3.6
V
60
%
900
300
1200
500
ms
1400
1200
1600
1400
nA
5
nA
0.1
µW
Standby mode @ 3.6V
between XIN and XOUT
10
Integrated Load Capacitance
(XIN and XOUT in series)
2.0
2.5
MΩ
20
pF
3.0
pF
1. RS is the series resitor..
AT91SAM7L
CL
XIN
XOUT
CLEXT
CLEXT
35.4.4
Crystal Characteristics
Table 35-16. Crystal Characteristics
Symbol
Parameter
Conditions
ESR
Equivalent Series Resistor Rs
Crystal @ 32.768KHz
CM
Motional capacitance
Crystal @ 32.768KHz
CSHUNT
Shunt capacitance
Crystal @ 32.768KHz
Min
Typ
Max
Unit
50
100
KΩ
0.6
3
fF
0.6
2
pF
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
518
35.4.5
XIN Clock Characteristics
Table 35-17. XIN Clock Electrical Characteristics (In bypass mode)
Symbol
Parameter
Max
Units
XIN Clock Frequency
(1)
10
MHz
1/(tCPXIN)
XIN Clock Frequency
(2)
44
kHz
tCPXIN
XIN Clock Period
(1)
100
ns
XIN Clock Period
(2)
44
ns
XIN Clock High Half-period
(1)
22
µs
tCHXIN
XIN Clock High Half-period
(2)
11
µs
tCLXIN
XIN Clock Low Half-period
(1)
50
ns
tCLXIN
XIN Clock Low Half-period
(2)
11
µs
tCLCH
Rise Time
400
ns
tCHCL
Fall Time
400
ns
CIN
XIN Input Capacitance
RIN
XIN Pull-down Resistor
VXIN_IL
VXIN_IH
1/(tCPXIN)
tCPXIN
tCHXIN
Note:
Conditions
Min
6
pF
3
5
MΩ
VXIN Input Low-level Voltage
-0.3
0.2 x VVDDIO1
V
VXIN Input High-level Voltage
0.8 x VVDDIO1
VVDDIO1+0.3
V
1. These characteristics apply only in FFPI mode
2. These characteristics apply only when the XTAL Oscillator is in bypass mode (i.e., when MOSCEN = 0 and
OSCBYPASS = 1 in the CKGR_MOR register, see the Clock Generator Main Oscillator Register.
tCLCH
tCPXIN
tCHXIN
tCHCL
VXIN_IH
VXIN_IL
tCPXIN
tCPXIN
35.4.6
External Clock CLKIN Characteristics
Table 35-18. External Clock CLKIN Characteristics (VDDCORE set at 1.80V)
Symbol
Parameter
1/(tCPCLKIN)
CLKIN Clock Frequency
Min
Max
Units
32
MHz
SAM7L128/64 [DATASHEET]
6257B–ATARM–01-Feb-13
519
Table 35-18. External Clock CLKIN Characteristics (VDDCORE set at 1.80V)
Symbol
Parameter
Min
Max
Units
tCPCLKIN
CLKIN Clock Period
31.0
ns
tCHCLKIN
CLKIN Clock High Half-period
14.5
ns
tCLCLKIN
CLKIN Clock Low Half-period
14.3
ns
Table 35-19. External Clock CLKIN Characteristics (VDDCORE set at 1.75V)
Symbol
Parameter
Min
Max
Units
1/(tCPCLKIN)
CLKIN Clock Frequency
30.8
MHz
tCPCLKIN
CLKIN Clock Period
32.4
ns
tCHCLKIN
CLKIN Clock High Half-period
15.2
ns
tCLCLKIN
CLKIN Clock Low Half-period
15.0
ns
Table 35-20. Externa Clock CLKIN Characteristics (VDDCORE set at 1.65V)
Symbol
Parameter
Min
Max
Units
1/(tCPCLKIN)
CLKIN Clock Frequency
28
MHz
tCPCLKIN
CLKIN Clock Period
35.7
ns
tCHCLKIN
CLKIN Clock High Half-period
16.7
ns
tCLCLKIN
CLKIN Clock Low Half-period
16.5
ns
Table 35-21. External Clock CLKIN Characteristics (VDDCORE set at 1.55V)
Symbol
Parameter
1/(tCPCLKIN)
CLKIN Clock Frequency
tCPCLKIN
CLKIN Clock Period
40.0
ns
tCHCLKIN
CLKIN Clock High Half-period
18.7
ns
tCLCLKIN
CLKIN Clock Low Half-period
18.5
ns
35.5
Min
Max
Units
25
MHz
PLL Characteristics
Table 35-22. Phase Lock Loop Characteristics
Symbol
Parameter
Conditions
Min
Vdd
Supply Voltage
Supplied by VDDCORE
1.60
FOUT
Output Frequency
FIN
Input Frequency
IPLL
Current Consumption
Connected to SCLK
Active mode @ 20MHz @1.8V
Active mode @ 30MHz @1.8V
Active mode @ 40MHz @1.8V
Standby mode
Note:
Typ
Max
Unit
V
18
30
47
MHz
20
30
44
KHz
445
490
535
505
555
605
µA
0.005
0.5
µA
Startup time depends on PLL RC filter. A calculation tool is provided by Atmel.
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35.6
ADC Characteristics
Table 35-23. Channel Conversion Time and ADC Clock
Parameter
Conditions
ADC Clock Frequency
Max
Units
10-bit resolution mode
6
MHz
ADC Clock Frequency
8-bit resolution mode
10
MHz
Startup Time
Return from Idle Mode
15
µs
Track and Hold Acquisition Time
Min
Typ
500
ns
Conversion Time
ADC Clock = 6MHz
ADC Clock = 10MHz
1.67
1
µs
Throughput Rate
ADC Clock = 6MHz
ADC Clock = 10MHz
460(1)
660(2)
kSPS
Notes:
1. Corresponds to 13 clock cycles at 6 MHz: 3 clock cycles for track and hold acquisition time and 10 clock cycles for
conversion.
2. Corresponds to 15 clock cycles at 10 MHz: 5 clock cycles for track and hold acquisition time and 10 clock cycles for
conversion
Table 35-24. External Voltage Reference Input
Parameter
Conditions
ADVREF Input Voltage Range
ADVREF Average Current
Min
Typ
Max
Units
1.65
1.8
VDDCORE
V
250
µA
2.2
mA
ADC Clock = 6MHz
Current Consumption on VDDCORE
The user can drive ADC input with impedance up to:
• ZOUT ≤ (SHTIM -440) x 20 in 8-bit resolution mode
• ZOUT ≤ (SHTIM -550) x 16.6 in 10-bit resolution mode
with SHTIM (Sample and Hold Time register) expressed in ns and ZOUT expressed in ohms.
Table 35-25. Analog Inputs
Parameter
Min
Input Voltage Range
Typ
0
Units
VADVREF
Input Leakage Current
Input Capacitance
Max
±0.5
µA
6.5
8.5
pF
Typ
Max
Units
Table 35-26. Transfer Characteristics
Parameter
Conditions
Resolution
10
Integral Non-linearity
Differential Non-linearity
Min
No missing code
Bit
±2
LSB
±1
LSB
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Table 35-26. Transfer Characteristics (Continued)
Parameter
Conditions
Min
Typ
Max
Units
Offset Error
±3
LSB
Gain Error
±2
LSB
±4.2
LSB
Absolute accuracy
35.7
Regulated Charge Pump Characteristics
Table 35-27. Regulated Charge Pump Characteristics
Symbol
Parameter
VVDDINLCD
Charge Pump Supply
Voltage
VVDD3V6
Output Voltage
Conditions
Min
Typ
Max
Units
1.8
2.7
3.6
V
3.6
V
IO = 4 mA max
Active, No load, with clock,
CL = 4.7µF, ESR = 1Ω
IVDDINLCD
TSTART
Current consumption
Onto VDDIO1 = 1.8V
50
Onto VDDINLCD = 1.8V
250
Onto VDDIO1 = 3.6V
50
Onto VDDINLCD = 3.6V
65
Startup Time
4
µA
mS
External charge capacitor
Between CAPP1 and CAPM1 (Tolerance
+/- 10%)
220
nF
External charge capacitor
Between CAPP2 and CAPM2 (Tolerance
+/- 10%)
220
nF
External storage capacitor
On VDD3V6 (Tolerance +/- 10%,ESR
=<1Ω)
4.7
µF
Figure 35-12. Charge Pump Schematics
R = 10Ω
VDDIO2
VDDLCD
LCD
Voltage
Regulator
CAPP1
VDD3V6
CAPM1
Charge
Pump
CAPP2
VDDINLCD
CAPM2
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35.8
LCD Voltage Characteristic
Table 35-28. LCD Voltage Characteristics
Symbol
Parameter
VVDDLCD
Supply Voltage
Conditions
Min
2.5
Dropout Voltage
Minimum voltage difference needed
between supply voltage and external
output voltage selected
100
Output Voltage
IO = 4 mA max
2.4
IVDDLCD
Current consumption
CL=4.7µF,ESR=1Ω
No load
TSTART
LCD Startup Time
VVDDIO2
External storage capacitor
35.9
Typ
On VDDIO2
Tolerance +/- 10%, ESR=1Ω min
Max
Units
3.6
V
mV
2.9
3.4
V
30
µA
1.5
mS
4.7
µF
LCD Driver Characteristic
Table 35-29. LCD Driver Characteristics
Symbol
Parameter
VVDDIO2
Supply Voltage
IVDDLCD
Conditions
Min
Typ
2.4
Max
Units
3.4
V
Resistor Ladder @3.4V (1/4 or 1/3 or 1/2 bias)
10
17
Each output buffer @3.4V (100% of the time)
25
33
µA
Current consumption
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35.10 AC Characteristics
35.10.1
Master Clock Characteristics
Master Clock Waveform Parameters
Symbol
Parameter
Conditions
Min
Max
Units
25
30
32
MHz
28
34
36
MHz
30
36
38
MHz
30.8
37.5
39.7
MHz
VDDCORE set at 1.55V
1/(tCPMCK)
Master Clock Frequency
VDDIO1= VDDIO2 = 1.8V
VDDIO1= VDDIO2 = 2.5V
VDDIO1= VDDIO2 = 3.0V
VDDCORE set at 1.65V
1/(tCPMCK)
Master Clock Frequency
VDDIO1= VDDIO2 = 1.8V
VDDIO1= VDDIO2 = 2.5V
VDDIO1= VDDIO2 = 3.0V
VDDCORE set at 1.75V
1/(tCPMCK)
Master Clock Frequency
VDDIO1= VDDIO2 = 1.8V
VDDIO1= VDDIO2 = 2.5V
VDDIO1= VDDIO2 = 3.0V
VDDCORE set at 1.80V
1/(tCPMCK)
Master Clock Frequency
VDDIO1= VDDIO2 = 1.8V
VDDIO1= VDDIO2 = 2.5V
VDDIO1= VDDIO2 = 3.0V
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35.10.2
I/O Characteristics
Criteria used to define the maximum frequency of the I/Os:
– output duty cycle (30%-70%)
– minimum output swing: 100mV to VDDIO1 - 100 mV
– minimum output swing: 100mV to VDDIO2 - 100 mV
– Addition of rising and falling time inferior to 75% of the period
Table 35-30. I/O Characteristics
Symbol
FreqMax1
PulseminH1
PulseminL1
FreqMax2
PulseminH2
PulseminL2
Notes:
Parameter
Conditions
Min
Pin Group 1 (1) Maximum output frequency
Load: 25 pF
VDDIO1 = 1.8V
VDDIO1 = 2.5V
VDDIO1 = 3V
Pin Group 1 (1) High Level Pulse Width
Load: 25pF
VDDIO1 = 1.8V
VDDIO1 = 2.5V
VDDIO1 = 3V
25
15
13
Pin Group 1 (1) Low Level Pulse Width
Load: 25 pF
VDDIO1 = 1.8V
VDDIO1 = 2.5V
VDDIO1 = 3V
25
15
13
Pin Group 2 (2) Maximum output frequency
Load: 25 pF
VDDIO2 = 1.8V
VDDIO2 = 2.5V
VDDIO2 = 3V
Pin Group 2 (2) High Level Pulse Width
Load: 25pF
VDDIO2 = 1.8V
VDDIO2 = 2.5V
VDDIO2 = 3V
25
17
14
Pin Group 2 (2) Low Level Pulse Width
Load: 25pF
VDDIO2 = 1.8V
VDDIO2 = 2.5V
VDDIO2 = 3V
25
17
14
Max
20
33
37
Units
MHz
ns
ns
20
29
36
MHz
ns
ns
1. Pin Group 1 = PC0-PC29
2. Pin Group 2 = PA0-PA25, PB0-PB23
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35.10.3
SPI Characteristics
Figure 35-13. SPI Master Mode with (CPOL= NCPHA = 0) or (CPOL= NCPHA= 1)
SPCK
SPI0
SPI1
MISO
SPI2
MOSI
Figure 35-14. SPI Master Mode with (CPOL = 0 and NCPHA=1) or (CPOL=1 and NCPHA= 0)
SPCK
SPI3
SPI4
MISO
SPI5
MOSI
Figure 35-15. SPI Slave Mode with (CPOL=0 and NCPHA=1) or (CPOL=1 and NCPHA=0)
SPCK
SPI6
MISO
SPI7
SPI8
MOSI
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Figure 35-16. SPI Slave Mode with (CPOL = NCPHA = 0) or (CPOL= NCPHA= 1)
SPCK
SPI9
MISO
SPI10
SPI11
MOSI
Table 35-31. AT91SAM7L128/64 SPI Timings
Symbol
SPI0
SPI1
Parameter
MISO Setup time before SPCK rises (master)
MISO Hold time after SPCK rises (master)
SPI2
SPCK rising to MOSI Delay (master)
SPI3
MISO Setup time before SPCK falls (master)
SPI4
SPI5
SPI6
MISO Hold time after SPCK falls (master)
SPCK falling to MOSI Delay (master)
SPCK falling to MISO Delay (slave)
SPI7
MOSI Setup time before SPCK rises (slave)
SPI8
MOSI Hold time after SPCK rises (slave)
SPI9
SPCK rising to MISO Delay (slave)
SPI10
MOSI Setup time before SPCK falls (slave)
SPI11
MOSI Hold time after SPCK falls (slave)
Notes:
Conditions
3.3V domain
(1)
1.8V domain
(2)
Min
Max
Units
26 + (tCPMCK)/2
(3)
ns
34 + (tCPMCK)/2
(3)
ns
3.3V domain(1)
0
ns
1.8V domain
(2)
0
ns
3.3V domain
(1)
1.8V domain(2)
7
ns
10
ns
3.3V domain(1)
26 + (tCPMCK)/2(3)
ns
1.8V domain(2)
34 + (tCPMCK)/2(3)
ns
3.3V domain
(1)
0
ns
1.8V domain
(2)
0
ns
3.3V domain(1)
7
ns
1.8V domain(2)
10
ns
(1)
22.5
ns
1.8V domain(2)
30.5
ns
3.3V domain
3.3V domain
(1)
1
ns
1.8V domain(2)
2.5
ns
3.3V domain(1)
2
ns
(2)
2
1.8V domain
ns
3.3V domain(1)
23
ns
1.8V domain(2)
28
ns
(1)
1
1.8V domain(2)
1
3.3V domain(1)
2
ns
1.8V domain(2)
2
ns
3.3V domain
ns
1. 3.3V domain: VVDDIO from 3.0V to 3.6V, maximum external capacitor = 25 pF.
2. 1.8V domain: VVDDIO from 1.65V to 1.95V, maximum external capacitor = 25 pF.
3. tCPMCK: Master Clock period in ns.
Note that in SPI master mode the AT91SAM7L128/64 does not sample the data (MISO) on the opposite edge where data
clocks out (MOSI) but the same edge is used as shown in Figure 35-13 and Figure 35-14.
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35.10.4 Embedded Flash Characteristics
The maximum operating frequency is given in tables 35-32, 35-33, 35-34 and 35-35 below but is limited by the Embedded
Flash access time when the processor is fetching code out of it. The tables 35-32, 35-33, 35-34 and 35-35 below give the
device maximum operating frequency depending on the field FWS of the MC_FMR register. This field defines the number
of wait states required to access the Embedded Flash Memory.
Table 35-32. Embedded Flash Wait State (VDDCORE set at 1.80V, minimum 1.65V)
FWS
Read Operations
Maximum Operating Frequency (MHz)
0
1 cycle
17.2
1
2 cycles
30
2
3 cycles
30
3
4 cycles
39.7
Table 35-33. Embedded Flash Wait States (VDDCORE set at 1.75V, minimum 1.70V)
FWS
Read Operations
Maximum Operating Frequency (MHz)
0
1 cycle
16.5
1
2 cycles
28.6
2
3 cycles
28.6
3
4 cycles
38
Table 35-34. Embedded Flash Wait States (VDDCORE set at 1.65V, minimum 1.60V)
FWS
Read Operations
Maximum Operating Frequency (MHz)
0
1 cycle
15
1
2 cycles
26
2
3 cycles
26
3
4 cycles
36
Table 35-35. Embedded Flash Wait States (VDDCORE set at 1.55V, minimum 1.50V)
FWS
Read Operations
Maximum Operating Frequency (MHz)
0
1 cycle
13.4
1
2 cycles
23.2
2
3 cycles
23.2
3
4 cycles
32
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Table 35-36. AC Flash Characteristics
Parameter
Conditions
Typ
Max
Units
per page including auto-erase
4.4
4.6
ms
per page without auto-erase
2.2
2.3
ms
Program Cycle Time
Full Chip Erase
10
ms
Power-up delay
35.10.5
50
µs
JTAG/ICE Timings
35.10.5.1
ICE Interface Signals
Table 35-37. ICE Interface Timing Specification
Symbol
Parameter
Conditions
Min
Max
Units
51
ns
ICE0
TCK Low Half-period
(1)
ICE1
TCK High Half-period
(1)
51
ns
TCK Period
(1)
102
ns
TDI, TMS, Setup before TCK High
(1)
0
ns
ICE4
TDI, TMS, Hold after TCK High
(1)
3
ns
ICE5
TDO Hold Time
(1)
13
ns
TCK Low to TDO Valid
(1)
ICE2
ICE3
ICE6
Note:
20
ns
1. VVDDIO from 3.0V to 3.6V, maximum external capacitor = 25pF.
Figure 35-17. ICE Interface Signals
ICE2
TCK
ICE0
ICE1
TMS/TDI
ICE3
ICE4
TDO
ICE5
ICE6
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35.10.5.2
JTAG Interface Signals
Table 35-38. JTAG Interface Timing specification
Symbol
Conditions
Min
TCK Low Half-period
(1)
6.5
ns
JTAG1
TCK High Half-period
(1)
5.5
ns
JTAG2
TCK Period
(1)
12
ns
TDI, TMS Setup before TCK High
(1)
2
ns
TDI, TMS Hold after TCK High
(1)
3
ns
JTAG5
TDO Hold Time
(1)
4
ns
JTAG6
TCK Low to TDO Valid
(1)
Device Inputs Setup Time
(1)
0
ns
Device Inputs Hold Time
(1)
3
ns
JTAG9
Device Outputs Hold Time
(1)
6
ns
JTAG10
TCK to Device Outputs Valid
(1)
JTAG0
JTAG3
JTAG4
JTAG7
JTAG8
Note:
Parameter
Max
16
18
Units
ns
ns
1. VVDDIO from 3.0V to 3.6V, maximum external capacitor = 40pF.
Figure 35-18. JTAG Interface Signals
JTAG2
TCK
JTAG
JTAG1
0
TMS/TDI
JTAG3
JTAG4
JTAG7
JTAG8
TDO
JTAG5
JTAG6
Device
Inputs
Device
Outputs
JTAG9
JTAG10
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36. AT91SAM7L128/64 Mechanical Characteristics
36.1
Package Drawings
Figure 36-1. LQFP128 Package Drawing
Table 36-1.
Device and LQFP Package Maximum Weight
AT91SAM7L128/64
Table 36-2.
800
mg
Package Reference
JEDEC Drawing Reference
MS-026
JESD97 Classification
e2
Table 36-3.
LQFP Package Characteristics
Moisture Sensitivity Level
3
This package respects the recommendations of the NEMI User Group.
SAM7L128/64 [DATASHEET]
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Figure 36-2. 144-ball LFBGA Package Drawing
All dimensions are in mm
Table 36-4.
Device and LFBGA Package Maximum Weight
AT91SAM7L128/64
Table 36-5.
mg
Package Reference
JEDEC Drawing Reference
MS-026
JESD97 Classification
e1
Table 36-6.
LFBGA Package Characteristics
Moisture Sensitivity Level
3
This package respects the recommendations of the NEMI User Group.
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36.2
Soldering Profile
Table 36-7 gives the recommended soldering profile from J-STD-020C.
Table 36-7.
Soldering Profile
Profile Feature
Green Package
Average Ramp-up Rate (217°C to Peak)
3⋅ C/sec. max.
Preheat Temperature 175°C ±25°C
180 sec. max.
Temperature Maintained Above 217°C
60 sec. to 150 sec.
Time within 5⋅ C of Actual Peak Temperature
20 sec. to 40 sec.
Peak Temperature Range
260⋅ C
Ramp-down Rate
6⋅ C/sec. max.
Time 25⋅ C to Peak Temperature
8 min. max.
Note:
The package is certified to be backward compatible with Pb/Sn soldering profile.
A maximum of three reflow passes is allowed per component.
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37. AT91SAM7L128/64 Ordering Information
Table 37-1.
Ordering Information
Temperature
Operating Range
Ordering Code
Package
Package Type
AT91SAM7L128-AU
LQFP128
Green
Industrial
(-40⋅ C to 85⋅ C)
AT91SAM7L64-AU
LQFP128
Green
Industrial
(-40⋅ C to 85⋅ C)
AT91SAM7L128-CU
LFBGA144
Green
Industrial
(-40⋅ C to 85⋅ C)
AT91SAM7L64-CU
LFBGA144
Green
Industrial
(-40⋅ C to 85⋅ C)
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38. AT91SAM7L128/64 Errata
38.1
Marking
All devices are marked with the Atmel logo and the ordering code.
Additional marking has the following format:
YYWW
V
XXXXXXXXX
ARM
where
• “YY”: manufactory year
• “WW”: manufactory week
• “V”: revision
“XXXXXXXXX”: lot number
SAM7L128/64 [DATASHEET]
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38.2
AT91SAM7L128/64
Refer to Section 38.1 “Marking” on page 535.
38.2.1
Analog-to-Digital Converter (ADC)
38.2.1.1
ADC: Sleep Mode
If Sleep mode is activated while there is no activity (no conversion is being performed), it will take effect only after
a conversion occurs.
Problem Fix/Workaround
To activate sleep mode as soon as possible, it is recommended to write successively, ADC Mode Register
(SLEEP) then ADC Control Register (START bit field), in order to start an analog-todigital conversion and then put
ADC into sleep mode at the end of this conversion.
38.2.2
Pulse Width Modulation Controller (PWM)
38.2.2.1
PW
M: Counter Start Value
In left aligned mode, the first start value of the counter is 0. For the other periods, the counter starts at 1.
Problem Fix/Workaround
None.
38.2.3
Serial Peripheral Interface (SPI)
38.2.3.1
SPI: Baudrate Set to 1
When the Baudrate is set at 1 (so, the serial clock frequency equals the master clock), and when the BITS field
(number of bits to be transmitted) in SPI_CSRx equals an odd value (in this case 9, 11, 13 or 15), an additional
pulse will be generated on SPCK.
It does not occur when the BITS field is equal to 8, 10, 12, 14 or 16 and the Baudrate is equal to 1.
Problem Fix/Workaround
None.
38.2.3.2
SPI: Bad Serial Clock Generation on 2nd Chip Select
Bad Serial clock generation on the 2nd chip select when SCBR = 1, CPOL = 1 and NCPHA = 0.
This occurs using SPI with the following conditions:
• Master Mode
• CPOL = 1 and NCPHA = 0
• Multiple chip selects are used with one transfer with Baud rate (SCBR) equal to 1 (i.e., when serial clock
frequency equals the system clock frequency) and the other transfers set with SCBR are not equal to 1
• Transmitting with the slowest chip select and then with the fastest one, then an additional
on output SPCK during the second transfer.
pulse is generated
Problem Fix/Workaround
Do not use a multiple Chip Select configuration where at least one SCRx register is configured with SCBR = 1 and
the others differ from 1 if NCPHA = 0 and CPOL = 1.
If all chip selects are configured with Baudrate = 1, the issue does not appear.
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38.2.4
Two Wire Interface (TWI)
38.2.4.1
TW
I: Switching from Slave to Master Mode
When the TWI is set in slave mode and if a master write access is performed, the start event is correctly generated
but the SCL line is stuck at 1, so no transfer is possible.
Problem Fix/Workaround
Two software workarounds are possible:
1. Perform a software reset before going to master mode (TWI must be reconfigured).
2. Perform a slave read access before switching to master mode.
38.2.4.2
TW
I: Switching from Slave to Master Mode
The RXRDY Flag is not reset when a Software reset is performed.
Problem Fix/Workaround
After a Software Reset, the Register TWI_RHR must be read.
38.2.5
Universal Synchronous Asynchronous Receiver Transmitter (USART)
38.2.5.1
USART: DCD is Active High Instead of Low
DCD signal is active at “High” level in USART block (Modem Mode).
DCD should be active at “Low” level.
Problem Fix/Workaround
Add an inverter.
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Revision History
In the tables that follow, the most recent version of the document appears first.
“rfo” indicates changes requested locally or during document review and approval loop.
Doc. Rev
6257B
Doc. Rev
6257A
Comments
Change
Request
Ref.
Removed Preliminary status and moved to new Corporate format
rfo
Table 4-2“SAM7L128/64 Pinout for 144-ball LFBGA Package”, fixed signal names on pins A2, B4, D7.
6103
PMC: Section 25.7 “Programming Sequence”, sequence numbering fixed.
5399
Electrical Characteristics:
Table 35-27“Regulated Charge Pump Characteristics”, IVDDINLCD Conditions updated.
Table 35-29“LCD Driver Characteristics”, IVDDLCD Conditions, Typ, Max updated.
5462
5463
Comments
Change
Request
Ref.
First issue
SAM7L128/64 [DATASHEET]
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SAM7L128/64 [DATASHEET]
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540
Table of Contents
Description................................................................................................. 1
1
Features .................................................................................................... 2
2
Block Diagram .......................................................................................... 4
3
Signal Description .................................................................................... 5
4
Package and Pinout ................................................................................. 8
4.1128-lead LQFP Package Outline ...............................................................................8
4.2128-lead LQFP Package Pinout ................................................................................9
4.3144-ball LFBGA Package Outline ............................................................................10
4.4144-ball LFBGA Pinout ............................................................................................11
5
Power Considerations ........................................................................... 12
5.1Power Supplies ........................................................................................................12
5.2Low Power Modes ...................................................................................................12
5.3Wake-up Sources ....................................................................................................14
5.4Fast Start-Up ...........................................................................................................15
5.5Voltage Regulator ....................................................................................................15
5.6LCD Power Supply ..................................................................................................16
5.7Typical Powering Schematics ..................................................................................18
6
I/O Line Considerations ......................................................................... 19
6.1JTAG Port Pins ........................................................................................................19
6.2Test Pin ...................................................................................................................19
6.3NRST Pin .................................................................................................................19
6.4NRSTB Pin ..............................................................................................................19
6.5ERASE Pin ..............................................................................................................19
6.6PIO Controller Lines ................................................................................................19
6.7I/O Line Current Drawing .........................................................................................20
7
Processor and Architecture .................................................................. 21
7.1ARM7TDMI Processor .............................................................................................21
7.2Debug and Test Features ........................................................................................21
7.3Memory Controller ...................................................................................................21
7.4Peripheral DMA Controller .......................................................................................22
8
Memories ................................................................................................. 23
8.1Embedded Memories ..............................................................................................25
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9
System Controller .................................................................................. 28
9.1System Controller Mapping .....................................................................................28
9.2Supply Controller (SUPC) ........................................................................................30
9.3Reset Controller .......................................................................................................30
9.4Clock Generator ......................................................................................................31
9.5Power Management Controller ................................................................................31
9.6Advanced Interrupt Controller ..................................................................................32
9.7Debug Unit ...............................................................................................................33
9.8Period Interval Timer ...............................................................................................33
9.9Watchdog Timer ......................................................................................................33
9.10Real-time Clock .....................................................................................................33
9.11PIO Controllers ......................................................................................................33
10 Peripherals .............................................................................................. 34
10.1User Interface ........................................................................................................34
10.2Peripheral Identifiers ..............................................................................................34
10.3Peripheral Multiplexing on PIO Lines ....................................................................35
10.4PIO Controller A Multiplexing ................................................................................36
10.5PIO Controller B Multiplexing ................................................................................37
10.6PIO Controller C Multiplexing ................................................................................38
10.7Serial Peripheral Interface .....................................................................................39
10.8Two Wire Interface ................................................................................................39
10.9USART ..................................................................................................................39
10.10Timer Counter ......................................................................................................40
10.11PWM Controller ...................................................................................................40
10.12Analog-to-Digital Converter .................................................................................41
10.13Segment LCD Controller .....................................................................................41
11 ARM7TDMI Processor Overview ........................................................... 43
11.1Overview ................................................................................................................43
11.2ARM7TDMI Processor ...........................................................................................44
12 Debug and Test Features ...................................................................... 49
12.1Overview ................................................................................................................49
12.2Block Diagram .......................................................................................................49
12.3Application Examples ............................................................................................50
12.4Debug and Test Pin Description ............................................................................51
12.5Functional Description ...........................................................................................52
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13 Reset Controller (RSTC) ........................................................................ 55
13.1Overview ................................................................................................................55
13.2Block Diagram .......................................................................................................55
13.3Functional Description ...........................................................................................55
13.4Reset Controller (RSTC) User Interface ................................................................62
14 Real-time Clock (RTC) ............................................................................ 67
14.1Overview ................................................................................................................67
14.2Block Diagram .......................................................................................................67
14.3Product Dependencies ..........................................................................................67
14.4Functional Description ...........................................................................................68
14.5Real-time Clock (RTC) User Interface ...................................................................71
15 Periodic Interval Timer (PIT) .................................................................. 85
15.1Overview ................................................................................................................85
15.2Block Diagram .......................................................................................................85
15.3Functional Description ...........................................................................................86
15.4Periodic Interval Timer (PIT) User Interface ..........................................................87
16 Watchdog Timer (WDT) .......................................................................... 91
16.1Overview ................................................................................................................91
16.2Block Diagram .......................................................................................................91
16.3Functional Description ...........................................................................................92
16.4Watchdog Timer (WDT) User Interface .................................................................94
17 Supply Controller (SUPC) ...................................................................... 99
17.1Overview ................................................................................................................99
17.2Block Diagram .....................................................................................................100
17.3Supply Controller Functional Description ............................................................101
17.4Supply Controller (SUPC) User Interface ............................................................112
18 Memory Controller (MC) ...................................................................... 125
18.1Overview ..............................................................................................................125
18.2Block Diagram .....................................................................................................125
18.3Functional Description .........................................................................................126
18.4Memory Controller (MC) User Interface ..............................................................130
19 Enhanced Embedded Flash Controller (EEFC) ................................. 135
19.1Overview .............................................................................................................135
19.2Product Dependencies ........................................................................................135
19.3Functional Description .........................................................................................135
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19.4Enhanced Embedded Flash Controller (EEFC) User Interface ...........................146
20 Fast Flash Programming Interface (FFPI) .......................................... 151
20.1Overview ..............................................................................................................151
20.2Parallel Fast Flash Programming ........................................................................151
20.3Serial Fast Flash Programming ...........................................................................160
21 AT91SAM Boot Program ...................................................................... 167
21.1Overview ..............................................................................................................167
21.2Flow Diagram ......................................................................................................167
21.3Device Initialization ..............................................................................................167
21.4SAM-BA Boot ......................................................................................................168
21.5In-Application Programming (IAP) Feature ..........................................................171
21.6Hardware and Software Constraints ....................................................................172
22 Peripheral DMA Controller (PDC) ....................................................... 173
22.1Overview ..............................................................................................................173
22.2Block Diagram .....................................................................................................173
22.3Functional Description .........................................................................................174
22.4Peripheral DMA Controller (PDC) User Interface ...............................................176
23 Advanced Interrupt Controller (AIC) ................................................... 183
23.1Overview ..............................................................................................................183
23.2Block Diagram .....................................................................................................184
23.3Application Block Diagram ...................................................................................184
23.4AIC Detailed Block Diagram ................................................................................184
23.5I/O Line Description .............................................................................................185
23.6Product Dependencies ........................................................................................185
23.7Functional Description .........................................................................................186
23.8Advanced Interrupt Controller (AIC) User Interface .............................................196
24 Clock Generator ................................................................................... 207
24.1Overview ..............................................................................................................207
24.2Slow Clock ...........................................................................................................208
24.3Slow Clock RC Oscillator .....................................................................................208
24.4Slow Clock Crystal Oscillator ...............................................................................208
24.5Main Clock ...........................................................................................................209
24.6Divider and PLL Block .........................................................................................210
25 Power Management Controller (PMC) ................................................ 212
25.1Overview ..............................................................................................................212
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25.2Master Clock Controller .......................................................................................212
25.3Processor Clock Controller ..................................................................................212
25.4Peripheral Clock Controller ..................................................................................213
25.5Programmable Clock Output Controller ...............................................................213
25.6The Fast Startup ..................................................................................................213
25.7Programming Sequence ......................................................................................214
25.8Clock Switching Details .......................................................................................217
25.9Power Management Controller (PMC) User Interface ........................................220
26 Debug Unit (DBGU) .............................................................................. 237
26.1Overview ..............................................................................................................237
26.2Block Diagram .....................................................................................................238
26.3Product Dependencies ........................................................................................239
26.4UART Operations ................................................................................................239
26.5Debug Unit (DBGU) User Interface ....................................................................246
27 Parallel Input Output Controller (PIO) ................................................ 261
27.1Overview ..............................................................................................................261
27.2Block Diagram .....................................................................................................262
27.3Product Dependencies ........................................................................................263
27.4Functional Description .........................................................................................264
27.5I/O Lines Programming Example .........................................................................269
27.6Parallel Input/Output Controller (PIO) User Interface ..........................................270
28 Serial Peripheral Interface (SPI) .......................................................... 287
28.1Overview ..............................................................................................................287
28.2Block Diagram .....................................................................................................287
28.3Application Block Diagram ...................................................................................288
28.4Signal Description ...............................................................................................288
28.5Product Dependencies ........................................................................................288
28.6Functional Description .........................................................................................289
28.7Serial Peripheral Interface (SPI) User Interface ..................................................298
29 Two Wire Interface (TWI) ..................................................................... 311
29.1Overview ..............................................................................................................311
29.2List of Abbreviations ............................................................................................311
29.3Block Diagram .....................................................................................................312
29.4Application Block Diagram ...................................................................................312
29.5Product Dependencies ........................................................................................313
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29.6Functional Description .........................................................................................313
29.7Master Mode ........................................................................................................315
29.8Multi-master Mode ...............................................................................................326
29.9Slave Mode ..........................................................................................................329
29.10Two-wire Interface (TWI) User Interface ...........................................................337
30 Universal Synchronous Asynchronous Receiver Transceiver
(USART) ................................................................................................. 351
30.1Overview ..............................................................................................................351
30.2Block Diagram .....................................................................................................352
30.3Application Block Diagram ...................................................................................353
30.4I/O Lines Description ..........................................................................................354
30.5Product Dependencies ........................................................................................355
30.6Functional Description .........................................................................................356
30.7Universal Synchronous Asynchronous Receiver Transmitter (USART)
User Interface ..............................................................................................385
31 Timer Counter (TC) ............................................................................... 407
31.1Overview ..............................................................................................................407
31.2Block Diagram .....................................................................................................408
31.3Pin Name List ......................................................................................................409
31.4Product Dependencies ........................................................................................409
31.5Functional Description .........................................................................................410
31.6Timer Counter (TC) User Interface ......................................................................422
32 Pulse Width Modulation Controller (PWM) ........................................ 439
32.1Overview ..............................................................................................................439
32.2Block Diagram .....................................................................................................439
32.3I/O Lines Description ...........................................................................................440
32.4Product Dependencies ........................................................................................440
32.5Functional Description .........................................................................................440
32.6Pulse Width Modulation Controller (PWM) User Interface ..................................448
33 Analog-to-Digital Converter (ADC) ..................................................... 457
33.1Overview ..............................................................................................................457
33.2Block Diagram .....................................................................................................457
33.3Signal Description ................................................................................................458
33.4Product Dependencies ........................................................................................458
33.5Functional Description .........................................................................................459
33.6Analog-to-Digital Converter (ADC) User Interface ...............................................464
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34 Segment LCD Controller (SLCDC) ...................................................... 475
34.1Overview ..............................................................................................................475
34.2Block Diagram .....................................................................................................476
34.3I/O Lines Description ...........................................................................................477
34.4Product Dependencies ........................................................................................477
34.5Functional Description .........................................................................................478
34.6Waveform Specifications .....................................................................................489
34.7Segment LCD Controller (SLCDC) User Interface ..............................................490
35 AT91SAM7L128/64 Electrical Characteristics ................................... 501
35.1Absolute Maximum Ratings .................................................................................501
35.2DC Characteristics ...............................................................................................502
35.3Power Consumption ............................................................................................505
35.4Crystal Oscillators Characteristics .......................................................................517
35.5PLL Characteristics .............................................................................................520
35.6ADC Characteristics ............................................................................................521
35.7Regulated Charge Pump Characteristics ............................................................522
35.8LCD Voltage Characteristic .................................................................................523
35.9LCD Driver Characteristic ....................................................................................523
35.10AC Characteristics .............................................................................................524
36 AT91SAM7L128/64 Mechanical Characteristics ................................ 531
36.1Package Drawings ...............................................................................................531
36.2Soldering Profile ..................................................................................................533
37 AT91SAM7L128/64 Ordering Information .......................................... 534
38 AT91SAM7L128/64 Errata .................................................................... 535
38.1Marking ................................................................................................................535
38.2AT91SAM7L128/64 .............................................................................................536
Revision History .................................................................................... 539
Table of Contents ....................................................................................... i
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