STR73xFxx
ARM7TDMI™ 32-bit MCU with Flash, 3x CAN,
4 UARTs, 20 timers, ADC, 12 comm. interfaces
Features
■
■
■
■
■
Core
– ARM7TDMI 32-bit RISC CPU
– 32 MIPS @ 36 MHz
Memories
– Up to 256 Kbytes Flash program memory
(10,000 cycles endurance, data retention
20 years @ 85° C)
– 16 Kbytes RAM
Clock, reset and supply management
– 4.5 - 5.5 V application supply and I/Os
– Embedded 1.8 V regulator for core supply
– Embedded oscillator running from external
4-8 MHz crystal or ceramic resonator
– Up to 36 MHz CPU frequency with internal
PLL
– 32 kHz or 2 MHz internal RC oscillator,
software configurable for fast startup and
backup clock
– Real-time clock for clock-calendar function
– Wake-up timer driven by internal RC for
wake-up from STOP mode
– 5 power saving modes: SLOW, WFI,
LPWFI, STOP and HALT modes
Nested interrupt controller
– Fast interrupt handling with multiple vectors
– 64 maskable IRQs with 64 vectors and 16
priority levels
– 2 maskable FIQ sources
– 16 external interrupts, up to 32 wake-up
lines
TQFP100 14 x 14
TQFP144
20 x 20
LFBGA144 10 x 10 x 1.7
■
DMA
– 4 DMA controllers with 4 channels each
■
Timers
– 16-bit watchdog timer (WDG)
– 6/10 16-bit timers (TIM) each with: 2 input
captures, 2 output compares, PWM and
pulse counter modes
– 6 16-bit PWM modules (PWM)
– 3 16-bit timebase timers with 8-bit
prescalers
■
12 communications interfaces
– 2 I2C interfaces
– 4 UART asynchronous serial interfaces
– 3 BSPI synchronous serial interfaces
– Up to 3 CAN interfaces (2.0B Active)
■
10-bit A/D converter
– 12/16 channels
– Conversion time: min. 3 µs, range: 0 to 5V
■
Development tools support
– JTAG interface
Table 1.
Up to 112 I/O ports
– 72/112 multifunctional bidirectional I/Os
Reference
STR73xFxx
June 2008
Rev 7
Device summary
Part number
STR730FZ1, STR730FZ2,
STR731FV0, STR731FV1,
STR731FV2,
STR735FZ1, STR735FZ2,
STR736FV0, STR736FV1,
STR736FV2
1/52
www.st.com
52
Contents
STR73xFxx
Contents
1
Scope . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.1
2
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
2.1
3
3.1
Related documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
3.2
Pin description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
2/52
3.2.1
STR730F/STR735F (TQFP144) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
3.2.2
STR730F/STR735F (LFBGA144) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
3.2.3
STR731F/STR736F (TQFP100) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Memory mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Electrical parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.1
5
On-chip peripherals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3.3
4
Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Parameter conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.1.1
Minimum and maximum values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.1.2
Typical values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.1.3
Typical curves . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.1.4
Loading capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.1.5
Pin input voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4.2
Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
4.3
Operating conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
4.3.1
Supply current characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
4.3.2
Clock and timing characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.3.3
Memory characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
4.3.4
EMC characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
4.3.5
I/O port pin characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
4.3.6
10-bit ADC characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
Package characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
5.1
Package mechanical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
5.2
Thermal characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
STR73xFxx
Contents
6
Order codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
7
Known limitations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
8
7.1
Low power wait for interrupt mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
7.2
PLL free running mode at high temperature . . . . . . . . . . . . . . . . . . . . . . 50
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
3/52
Scope
1
STR73xFxx
Scope
This datasheet provides the STR73x ordering information, mechanical and electrical device
characteristics.
For complete information on the STR73xF microcontroller memory, registers and
peripherals. please refer to the STR73x reference manual.
For information on programming, erasing and protection of the internal Flash memory
please refer to the STR7 Flash programming reference manual.
For information on the ARM7TDMI core please refer to the ARM7TDMI technical reference
manual.
1.1
Description
ARM core with embedded Flash & RAM
STR73xF family combines the high performance ARM7TDMI™ CPU with an extensive range
of peripheral functions and enhanced I/O capabilities. All devices have on-chip high-speed
single voltage Flash memory and high-speed RAM. The STR73xF family has an embedded
ARM core and is therefore compatible with all ARM tools and software.
Extensive tools support
STMicroelectronics’ 32-bit, ARM core-based microcontrollers are supported by a complete
range of high-end and low-cost development tools to meet the needs of application
developers. This extensive line of hardware/software tools includes starter kits and complete
development packages all tailored for ST’s ARM core-based MCUs.
The range of development packages includes third-party solutions that come complete with
a graphical development environment and an in-circuit emulator/programmer featuring a
JTAG application interface. These support a range of embedded operating systems (OS),
while several royalty-free OSs are also available.
For more information, please refer to ST MCU site http://www.st.com/mcu
Figure 1 shows the general block diagram of the device family.
4/52
STR73xFxx
Overview
2
Overview
Table 2.
Product overview
Features
STR730FZx
Flash memory - bytes
128K
STR735FZx
256K
128K
256K
STR731FVx
64K
128K
STR736FVx
256K
64K
128K
256K
RAM - bytes
16 K
16 K
Peripheral functions
10 TIM timers, 112 I/Os,
32 wake-up lines, 16 ADC
6 TIM timers, 72 I/Os, 18 wake-up lines,
12 ADC channels
CAN peripherals
3
0
Operating voltage
Operating temperature
Packages
3
0
4.5 to 5.5 V
-40 to +85°C/-40 to +105° C
T=TQFP144 20 x 20
H=LFBGA144 10 x10
T=TQFP100 14x14
Package choice: reduced pin-count TQFP100 or feature-rich 144-pin TQFP or LFBGA
The STR73xF family is available in 3 packages. The TQFP144 and LFBGA144 versions
have the full set of all features. The 100-pin version has fewer timers, I/Os and ADC
channels. Refer to the Device Summary on Page 1 for a comparison of the I/Os available on
each package.
The family includes versions with and without CAN.
High speed Flash memory
The Flash program memory is organized in 32-bit wide memory cells which can be used for
storing both code and data constants. It is accessed by CPU with zero wait states @ 36
MHz.
The STR7 embedded Flash memory can be programmed using in-circuit programming or
in-application programming.
The Flash memory endurance is 10K write/erase cycles and the data retention is 20 years
@ 85° C.
IAP (in-application programming): IAP is the ability to re-program the Flash memory of a
microcontroller while the user program is running.
ICP (in-circuit programming): ICP is the ability to program the Flash memory of a
microcontroller using JTAG protocol while the device is mounted on the user application
board.
The Flash memory can be protected against different types of unwanted access
(read/write/erase). There are two types of protection:
●
Sector write protection
●
Flash debug protection (locks JTAG access)
Flexible power management
To minimize power consumption, you can program the STR73xF to switch to SLOW, WFI
LPWFI, STOP or HALT modes depending on the current system activity in the application.
5/52
Overview
STR73xFxx
Flexible clock control
Two clock sources are used to drive the microcontroller, a main clock driven by an external
crystal or ceramic resonator and an internal backup RC oscillator that operates at 2 MHz or
32 kHz. The embedded PLL can be configured to generate an internal system clock of up to
36 MHz. The PLL output frequency can be programmed using a wide selection of multipliers
and dividers.
Voltage regulators
The STR73xF requires an external 4.5 to 5.5 V power supply. There are two internal Voltage
Regulators for generating the 1.8 V power supply needed by the core and peripherals. The
main VR is switched off and the Low Power VR switched on when the application puts the
STR73xF in Low Power Wait for Interrupt (LPWFI) mode.
Low voltage detectors
The voltage regulator and Flash modules each have an embedded LVD that monitors the
internal 1.8 V supply. If the voltage drops below a certain threshold, the LVD will reset the
STR73xF.
Note:
An external power-on reset must be provided ensure the microcontroller starts-up correctly.
2.1
On-chip peripherals
CAN interfaces
The three CAN modules are compliant with the CAN specification V2.0 part B (active). The
bit rate can be programmed up to 1 MBaud. These are not available in the STR735 and
STR736.
DMA
4 DMA controllers, each with 4 data streams manage memory to memory, peripheral to
peripheral, peripheral to memory and memory to peripheral transfers. The DMA requests
are connected to TIM timers, BSPI0, BSPI1, BSPI2 and ADC. One of the streams can be
configured to be triggered by a software request, independently from any peripheral activity.
16-bit timers (TIM)
Each of the ten timers (six in 100-pin devices) have a 16-bit free-running counter with 7-bit
prescaler, up to two input capture/output compare functions, a pulse counter function, and a
PWM channel with selectable frequency. This provides a total of 16 independent PWMs (12
in 100-pin devices) when added with the PWM modules (see next paragraph).
PWM modules (PWM)
The six 16-bit PWM modules have independently programmable periods and duty-cycles,
with 5+3 bit prescaler factor.
Timebase timers (TB)
The three 16-bit timebase timers with 8-bit prescaler for general purpose time triggering
operations.
Real-time clock (RTC)
The RTC provides a set of continuously running counters driven by separate clock signal
derived from the main oscillator. The RTC can be used as a general timebase or
6/52
STR73xFxx
Overview
clock/calendar/alarm function. When the STR73xF is in LPWFI mode the RTC keeps
running, powered by the low power voltage regulator.
UARTs
The 4 UARTs allow full duplex, asynchronous, communications with external devices with
independently programmable TX and RX baud rates up to 625 Kbaud.
Buffered serial peripheral interfaces (BSPI)
Each of the three BSPIs allow full duplex, synchronous communications with external
devices, master or slave communication at up to 6 Mb/s in master mode and up to 4.5 Mb/s
in slave mode (@36 MHz system clock).
I2C interfaces
The two I2C Interfaces provide multi-master and slave functions, support normal and fast
I2C mode (400 kHz) and 7 or 10-bit addressing modes.
A/D converter
The 10-bit analog to digital converter, converts up to 16 channels in single-shot or
continuous conversion modes (12 channels in 100-pin devices). The minimum conversion
time is 3 µs.
Watchdog
The 16-bit watchdog timer protects the application against hardware or software failures and
ensures recovery by generating a reset.
I/O ports
Up to 112 I/O ports (72 in 100-pin devices) are programmable as general purpose
input/output or alternate function.
External interrupts and wake-up lines
16 external interrupts lines are available for application use. In addition, up to 32 external
Wake-up lines (18 in 100-pin devices) can be used as general purpose interrupts or to
wake-up the application from STOP mode.
7/52
Block diagram
3
STR73xFxx
Block diagram
Figure 1.
RSTIN
STR730F/STR735F block diagram
PRCCU/PLL
FLASH
PROGRAM MEMORY
64/128/256K
ARM7TDMI
CPU
JTAG
V18
VDD
VSS
VDDA
VSSA
RAM
16K
ARM7 NATIVE BUS
JTDI
JTCK
JTMS
JTRST
JTDO
M0
M1
TEST
APB
BRIDGE 0
POWER SUPPLY
VREG
APB
BRIDGE 1
AHB
BRIDGE
AHB BUS
DMA0-3
WATCHDOG
CLOCK MGT (CMU)
XTAL1
XTAL2
I2C0-1
4 AF
INTERRUPT CTL (EIC)
WAKE-UP/INT (WIU)
32 AF
16 AF
A/D CONVERTER (ADC)
UART0, 1, 2, 3
8 AF
12 AF
TIMER (TIM) 2-4
12 AF
BSPI 0-2
WAKE-UP TIMER
(WUT)
6 AF
CAN 0-2*
TIMER (TIM) 0-1
8 AF
6 AF
PWM 0-5
TIMER (TIM) 5-9
20 AF
122 ports
TIMEBASE TIMER
(TB) 0-2
GPIO PORTS 0-6
*CAN peripherals not available on STR735F.
8/52
APB BUS
RTC
APB BUS
OSC
AF: alternate function on I/O port pin
STR73xFxx
Block diagram
Figure 2.
RSTIN
STR731F/STR736 block diagram
PRCCU/PLL
FLASH
PROGRAM MEMORY
64/128/256K
ARM7TDMI
CPU
JTAG
V18
VDD
VSS
VDDA
VSSA
RAM
16K
ARM7 NATIVE BUS
JTDI
JTCK
JTMS
JTRST
JTDO
M0
M1
TEST
APB
BRIDGE 0
POWER SUPPLY
VREG
APB
BRIDGE 1
AHB
BRIDGE
AHB BUS
DMA0-3
WATCHDOG
CLOCK MGT (CMU)
XTAL1
XTAL2
I2C0-1
4 AF
INTERRUPT CTL (EIC)
WAKE-UP/INT (WIU)
18 AF
12 AF
A/D CONVERTER (ADC)
UART0, 1, 2, 3
8 AF
12 AF
TIMER (TIM) 2-4
12 AF
BSPI 0-2
WAKE-UP TIMER
(WUT)
6 AF
CAN 0-2*
TIMER (TIM) 0-1
8 AF
6 AF
PWM 0-5
TIMER (TIM) 5
4 AF
72 ports
APB BUS
RTC
APB BUS
OSC
TIMEBASE TIMER
(TB) 0-2
GPIO PORTS 0-6
*CAN peripherals not available on STR736F.
AF: alternate function on I/O port pin
9/52
Block diagram
3.1
Related documentation
Available from www.arm.com:
ARM7TDMI technical reference manual
Available from http://www.st.com:
STR73x reference manual (RM0001)
STR7 Flash programming reference manual
STR73x software library user manual
For a list of related application notes refer to http://www.st.com.
10/52
STR73xFxx
STR73xFxx
Block diagram
3.2
Pin description
3.2.1
STR730F/STR735F (TQFP144)
STR730F/STR735F pin configuration (top view)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
STR730F/STR735F
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
P4.14 / SS1
P4.13 / ICAPB9
P4.12 / ICAPA9 / WUP21
P4.11 / OCMPB8
P4.10 / ICAPA6 / WUP20
P4.9 / ICAPB6
P4.8 / OCMPA8
P4.7 / SDA1
P4.6 / SCL1 / WUP19
P4.5 / CAN2RX / WUP18
P4.4 / CAN2TX
P4.3 / ICAPB8 / WUP27
P4.2 / ICAPA8 / WUP26
P4.1 / ICAPB7 / WUP25
P4.0 / ICAPA7 / WUP24
VDD
VSS
JTDO
JTCK
JTMS
JTDI
JTRST
VSS
VDD
P3.15 / AIN15 / INT5
P3.14 / AIN14 / INT4
P3.13 / AIN13 / INT3
P3.12 / AIN12 / INT2
P3.11 / AIN11
P3.10 / AIN10
P3.9 / AIN9
P3.8 / AIN8
VDDA
VSSA
P3.7 / AIN7
P3.6 / AIN6
WUP12 / CAN0RX / P1.14
CAN0TX / P1.15
PWM0 / P2.0
WUP13 / CAN1RX / P2.1
CAN1TX / P2.2
PWM1 / P2.3
PWM2 / P2.4
PWM3 / P2.5
PWM4 / P2.6
PWM5 / P2.7
M0
RSTIN
M1
VDD
VSS
XTAL1
XTAL2
VSS
TDO1 / P2.8
WUP14 / RDI1 / P2.9
WUP16 / P2.10
WUP17 / P2.11
INT14 / P2.12
INT15 / P2.13
WUP15 / SCL0 / P2.14
SDA0 / P2.15
TEST
VBIAS
VSS
VDD
AIN0 / P3.0
AIN1 / P3.1
AIN2 / P3.2
AIN3 / P3.3
AIN4 / P3.4
AIN5 / P3.5
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
OCMPB2 / P0.0
OCMPA2 / P0.1
ICAPA2 / P0.2
ICAPB2 / P0.3
VSS
VDD
OCMPA5 / P0.4
OCMPB5 / P0.5
ICAPA5 / P0.6
ICAPB5 / P0.7
OCMPA6 / P0.8
OCMPB6 / P0.9
OCMPA7 / P0.10
OCMPB7 / P0.11
VDD
VSS
ICAPA3 / P0.12
ICAPB3 / P0.13
OCMPB3 / P0.14
OCMPA3 / P0.15
OCMPA4 / P1.0
OCMPB4 / P1.1
ICAPB4 / P1.2
ICAPA4 / P1.3
VSS
VDD
P1.4
P1.5
OCMPB1 / P1.6
OCMPA1 / P1.7
INT0 / OCMPA0 / P1.8
INT1 / OCMPB0 / P1.9
ICAPB0 / WUP28 / P1.10
ICAPA0 / WUP29 / P1.11
ICAPA1 / WUP30 / P1.12
ICAPB1 / WUP31 / P1.13
144
143
142
141
140
139
138
137
136
135
134
133
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
P6.15 / WUP9
P6.14 / SS0
P6.13 / SCK0 / WUP11
P6.12 / MOSI0
P6.11 / MISO0
P6.10 / WUP8
P6.9 / TDO0
P6.8 / RDI0 / WUP10
P6.7 / WUP7
P6.6 / WUP6
P6.5 / WUP5
P6.4 / TDO3 / WUP4
P6.3 / WUP3
P6.2 / RDI3 / WUP2
P6.1 / WUP1
P6.0 / WUP0
VDD
VSS
V18
P5.15 / INT13
P5.14 / INT12
P5.13 / INT11
P5.12 / INT10
P5.11 / TDO2 / INT9
P5.10 / RDI2 / INT8
P5.9 / INT7
P5.8 / INT6
P5.7 / MISO2
P5.6 / MOSI2
P5.5 / SCK2 / WUP23
P5.4 / SS2
P5.3 / OCMPB9
P5.2 / OCMPA9
P5.1 / MISO1
P5.0 / MOSI1
P4.15 / SCK1 / WUP22
Figure 3.
Note: CAN alternate functions not available on STR735F.
11/52
Block diagram
STR73xFxx
3.2.2
STR730F/STR735F (LFBGA144)
Table 3.
STR730F/STR735F LFBGA ball connections
Ball
Name
Ball
Name
Ball
Name
Ball
Name
A1
P0.0 / OCMPB2
B1
P0.4 / OCMPA5
C1
P0.5 / OCMPB5
D1
VSS
A2
P6.10 / WUP8
B2
P0.1 / OCMPA2
C2
P0.2 / ICAPA2
D2
VDD
A3
P6.9 / TDO0
B3
P6.15 / WUP9
C3
P0.3 / ICAPB2
D3
P0.6 / ICAPA5
A4
P6.12 / MOSI0
B4
P6.13 / SCKO / WUP11
C4
P6.14 / SSO
D4
P0.7 /ICAPB5
A5
P6.6 / WUP6
B5
P6.7 / WUP7
C5
P6.8 / RDI0 / WUP10
D5
P6.11 / MISO0
A6
V18
B6
P6.2 / WUP2 / RDI3
C6
P6.3 / WUP3
D6
P6.4 / WUP4 /TDO3
A7
P5.15 / INT13
B7
P5.14 / INT12
C7
VSS
D7
VDD
A8
P5.8 / INT6
B8
P5.9 / INT7
C8
P5.10 / INT8 / RDI2
D8
P5.12 / INT10
P5.5 / SCK2 / WUP23
A9
P5.2 / OCMPA9
B9
P5.3 / OCMPB9
C9
P5.4 / SS2
D9
A10
P5.7 / MISO2
B10
P5.0 / MOSI1
C10
P5.1 / MISO1
D10
P4.13 / ICAPB9
A11
P5.6 / MOSI2
B11 P4.15 / SCK1 / WUP22 C11
P4.14 / SS1
D11
P4.12 / ICAPA9 / WUP21
A12
P5.11 / TDO2 / INT9
B12
P4.7 / SDA1
D12
P4.11 / OCMPB8
P4.8 / OCMPA8
C12
E1
P0.8 / OCMPA6
F1
VDD
G1
VSS
H1
VDD
E2
P0.9 / OCMPB6
F2
P0.13 / ICAPB3
G2
P1.2 / ICAPB4
H2
P1.8 / OCMPA0 / INT0
E3
P0.10 / OCMPA7
F3
P0.14 / OCMPB3
G3
P1.3 / ICAPA4
H3
P1.9 / OCMPB0 / INT1
E4
P0.11 / OCMPB7
F4
P0.15 / OCMPA3
G4
VSS
H4
P1.10 / ICAPB0 / WUP28
E5
P0.12 / ICAPA3
F5
P1.0 / OCMPA4
G5
P1.5
H5
XTAL2
E6
P6.5 / WUP5
F6
P1.1 / OCMPB4
G6
P2.11 / WUP17
H6
P2.10 / WUP16
E7
P6.0 / WUP0
F7
P6.1 / WUP1
G7
P4.0 / ICAPA7 /
WUP24
H7
P2.15 / SDA 0
E8
P5.13 / INT11
F8
P4.4 / CAN2TX1)
G8
VDD
H8
JTMS
E9
P4.10 / ICAPA6 /
WUP20
F9
P4.3 / ICAPB8 /
WUP27
G9
VSS
H9
VSS
E10
P4.9 / ICAPB6
F10
P4.2 / ICAPA8 /
WUP26
G10
JTDO
H10
VDD
E11
P4.6 / SCL1 / WUP19
F11
P4.1 / ICAPB7 /
WUP25
G11
JTCK
H11
P3.15 / AIN15 / INT5
E12
P4.5 / WUP18 /
CAN2RX 1)
F12
JTDI
G12
nJTRST
H12
P3.14 / AIN14 / INT4
J1
P1.4
K1
P1.6 / OCMPB1
L1
P1.7 / OCMPA1
M1
P1.14 / CAN0RX 1) /
WUP12
J2
P1.11 / ICAPA0 /
WUP29
K2
P1.13 / ICAPB1 /
WUP31
L2
P1.15 / CAN0TX1)
M2
P2.4 / PWM2
J3
P1.12 / ICAPA1 /
WUP30
K3
P2.1 / CAN1RX1) /
WUP13
L3
P2.0 / PWM0
M3
P2.5 / PWM3
J4
P2.7 / PWM5
K4
P2.6 / PWM4
L4
P2.3 / PWM1
M4
P2.2 / CAN1TX1)
J5
VDD
K5
M1
L5
RSTIN
M5
M0
J6
P2.9 / RDI1 / WUP14
K6
P2.8 / TDO1
L6
VSS
M6
VSS
J7
P2.14 / SCL 0 / WUP15
K7
P2.13 / INT15
L7
P2.12 / INT14
M7
XTAL1
J8
P3.1 / AIN1
K8
P3.0 / AIN0
L8
VBIAS
M8
TST
P3.2 / AIN2
J9
P3.13 / AIN13 / INT3
K9
P3.4 / AIN4
L9
P3.3 / AIN3
M9
J10
P3.12 / AIN12 / INT2
K10
VDDA
L10
P3.5 / AIN5
M10
VSS
J11
P3.9 / AIN9
K11
VSSA
L11
P3.7 / AIN7
M11
VDD
J12
P3.8 / AIN8
K12
P3.11 / AIN11
L12
P3.10 / AIN10
M12
P3.6 / AIN6
Note: CAN alternate functions not available on STR735F.
12/52
STR73xFxx
STR731F/STR736F (TQFP100)
STR731F/STR736F pin configuration (top view)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
STR731F/STR736F
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
P4.14 / SS1
P4.10 / ICAPB5 / WUP20
P4.7 / SDA1
P4.6 / SCL1 / WUP19
VDD
VSS
JTDO
JTCK
JTMS
JTDI
JTRST
VSS
VDD
P3.15 / AIN11 / INT5
P3.14 / AIN10 / INT4
P3.13 / AIN9 / INT3
P3.12 / AIN8 / INT2
P3.11 / AIN7
P3.10 / AIN6
P3.9 / AIN5
P3.8 / AIN4
VDDA
VSSA
P3.7 / AIN3
P3.6 / AIN2
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
OCMPB2 / P0.0
OCMPA2 / P0.1
ICAPA2 / P0.2
ICAPB2 / P0.3
OCMPA5 / P0.4
OCMPB5 / P0.5
ICAPA5 / P0.6
VDD
VSS
ICAPA3 / P0.12
ICAPB3 / P0.13
OCMPB3 / P0.14
OCMPA3 / P0.15
OCMPA4 / P1.0
OCMPB4 / P1.1
ICAPB4 / P1.2
ICAPA4 / P1.3
OCMPB1 / P1.6
OCMPA1 / P1.7
INT0 / OCMPA0 / P1.8
INT1 / OCMPB0 / P1.9
ICAPB0 / WUP28 / P1.10
ICAPA0 / WUP29 / P1.11
ICAPA1 / WUP30 / P1.12
ICAPB1 / WUP31 / P1.13
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
P6.14 / SS0
P6.13 / SCK0 / WUP11
P6.12 / MOSI0
P6.11 / MISO0
P6.9 / TDO0
P6.8 / RDI0 / WUP10
P6.6 / WUP6
P6.4 / TDO3 / WUP4
P6.2 / RDI3 / WUP2
P6.0 / WUP0
VDD
VSS
V18
P5.12 / INT10
P5.11 / TDO2 / INT9
P5.10 / RDI2 / INT8
P5.9 / PWM5 / INT7
P5.8 / PWM4 / INT6
P5.7 / MISO2
P5.6 / MOSI2
P5.5 / SCK2 / WUP23
P5.4 / SS2 /PWM3
P5.1 / MISO1
P5.0 / MOSI1
P4.15 / SCK1 / WUP22
Figure 4.
WUP12 / CAN0RX / P1.14
CAN0TX / P1.15
PWM0 / P2.0
WUP13 / CAN1RX / P2.1
CAN1TX / P2.2
PWM1 / P2.3
PWM2 / P2.4
M0
RSTIN
M1
VDD
VSS
XTAL1
XTAL2
VSS
CAN2RX / TDO1 / P2.8
WUP14 / CAN2TX / RDI1 / P2.9
WUP15 / SCL0 / P2.14
SDA0 / P2.15
TEST
VBIAS
VSS
VDD
AIN0 / P3.4
AIN1 / P3.5
3.2.3
Block diagram
Note: CAN alternate functions not available on STR736F.
13/52
Block diagram
STR73xFxx
Legend / Abbreviations for Table 4:
Type:
I = input, O = output, S = supply, HiZ= high impedance,
In/Output level:
TT= TTL 0.8 V / 2 V with input trigger
CT= CMOS 0.3VDD/0.7VDD with input trigger
Port and control configuration:
Input:
pu/pd = with internal 100 kΩ weak pull-up or pull down
Output:
OD = open drain (logic level)
PP = push-pull
Interrupts:
INTx = external interrupt line
WUPx = wake-up interrupt line
The reset state (during and just after the reset) of the I/O ports is input floating (Input tristate
TTL mode). To avoid excess power consumption, unused I/O ports must be tied to ground.
Table 4.
STR73xF pin description
Output
I/O
TT
2mA X X Port 0.0
TIM2: output compare B output
2
B2
2
P0.1/OCMPA2
I/O
TT
2mA X X Port 0.1
TIM2: output compare A output
3
C2
3
P0.2/ICAPA2
I/O
TT
2mA X X Port 0.2
TIM2: input capture A input
4
C3
4
P0.3/ICAPB2
I/O
TT
2mA X X Port 0.3
TIM2: input capture B input
5
D1
VSS
S
Ground
6
D2
VDD
S
Supply voltage (5 V)
7
B1
5
P0.4/OCMPA5
I/O
TT
2mA X X Port 0.4
TIM5: output compare A output
8
C1
6
P0.5/OCMPB5
I/O
TT
2mA X X Port 0.5
TIM5: output compare B output
9
D3
7
P0.6/ICAPA5
I/O
TT
2mA X X Port 0.6
TIM5: input capture A input
10
D4
P0.7/ICAPB5
I/O
TT
2mA X X Port 0.7
TIM5: input capture B input
11
E1
P0.8/OCMPA6
I/O
TT
2mA X X Port 0.8
TIM6: output compare A output
12
E2
P0.9/OCMPB6
I/O
TT
2mA X X Port 0.9
TIM6: output compare B output
13
E3
P0.10/OCMPA7 I/O
TT
2mA X X Port 0.10 TIM7: output compare A output
14
E4
P0.11/OCMPB
7
TT
2mA X X Port 0.11 TIM7: output compare B output
15
F1
8
VDD
S
Supply voltage (5 V)
16
G1
9
VSS
S
Ground
17
E5
10 P0.12/ICAPA3
I/O
TT
2mA X X Port 0.12 TIM3: input capture A input
18
F2
11 P0.13/ICAPB3
I/O
TT
2mA X X Port 0.13 TIM3: input capture B input
14/52
I/O
PP
P0.0/OCMPB2
OD
1
Capability
Input Level
A1
interrupt
Type
1
Pin name
pu/pd
TQFP100
Main
function
(after
reset)
LFBGA144
Input
TQFP144
Pin n°
Alternate function
STR73xFxx
Table 4.
Block diagram
STR73xF pin description
Output
TT
2mA X X Port 0.14 TIM3: output compare B output
20
F4
13 P0.15/OCMPA3 I/O
TT
2mA X X Port 0.15 TIM3: output compare A output
21
F5
14 P1.0/OCMPA4
I/O
TT
2mA X X Port 1.0
TIM4: output compare A output
22
F6
15 P1.1/OCMPB4
I/O
TT
2mA X X Port 1.1
TIM4: output compare B output
23
G2
16 P1.2/ICAPB4
I/O
TT
2mA X X Port 1.2
TIM4: input capture B input
24
G3
17 P1.3/ICAPA4
I/O
TT
2mA X X Port 1.3
TIM4: input capture A input
25
G4
VSS
S
Ground
26
H1
VDD
S
Supply voltage (5 V)
27
J1
P1.4
I/O
TT
2mA X X Port 1.4
28
G5
P1.5
I/O
TT
2mA X X Port 1.5
29
K1
18 P1.6/OCMPB1
I/O
TT
2mA X X Port 1.6
TIM1: output compare B output
30
L1
19 P1.7/OCMPA1
I/O
TT
2mA X X Port 1.7
TIM1: output compare A output
31
H2
20 P1.8/OCMPA0
I/O
TT
INT0
2mA X X Port 1.8
TIM0: output compare A output
32
H3
21 P1.9/OCMPB0
I/O
TT
INT1
2mA X X Port 1.9
TIM0: output compare B output
33
H4
22 P1.10/ICAPB0
I/O
TT
WUP28 2mA X X Port 1.10 TIM0: input capture B input
34
J2
23 P1.11/ICAPA0
I/O
TT
WUP29 2mA X X Port 1.11 TIM0: input capture A input
35
J3
24 P1.12/ICAPA1
I/O
TT
WUP30 2mA X X Port 1.12 TIM1: input capture A input
36
K2
25 P1.13/ICAPB1
I/O
TT
WUP31 2mA X X Port 1.13 TIM1: input capture B input
37
M1
26 P1.14/CAN0RX I/O
TT
WUP12 2mA X X Port 1.14 CAN0: receive data input
38
L2
27 P1.15/CAN0TX
I/O
TT
2mA X X Port 1.15 CAN0: transmit data output
39
L3
28 P2.0/PWM0
I/O
TT
2mA X X Port 2.0
40
K3
29 P2.1/CAN1RX
I/O
TT
WUP13 2mA X X Port 2.1
41
M4
30 P2.2/CAN1TX
I/O
TT
2mA X X Port 2.2
CAN1: transmit data output
42
L4
31 P2.3/PWM1
I/O
TT
2mA X X Port 2.3
PWM1: PWM output
43
M2
32 P2.4/PWM2
I/O
TT
2mA X X Port 2.4
PWM2: PWM output
44
M3
P2.5/PWM3
I/O
TT
2mA X X Port 2.5
PWM3: PWM output
45
K4
P2.6/PWM4
I/O
TT
2mA X X Port 2.6
PWM4: PWM output
46
J4
P2.7/PWM5
I/O
TT
2mA X X Port 2.7
PWM5: PWM output
47
M5
33 M0
I
TT
pd
BOOT: mode selection 0 input
48
L5
34 RSTIN
I
CT
pu
Reset input
49
K5
35 M1
I
TT
pd
BOOT: mode selection 1 input
PP
I/O
P0.14/OCMPB
3
OD
12
Capability
Input Level
F3
interrupt
Type
19
Pin name
pu/pd
TQFP100
Main
function
(after
reset)
LFBGA144
Input
TQFP144
Pin n°
Alternate function
PWM0: PWM output
CAN1: receive data input
15/52
Block diagram
Table 4.
STR73xFxx
STR73xF pin description
Input
Output
51
M6
37 VSS
S
Ground
52
M7
38 XTAL1
I
Oscillator amplifier circuit input and
internal clock generator input.
53
H5
39 XTAL2
O
Oscillator amplifier circuit output.
54
L6
40 VSS
S
Ground
K6
P2.8/TDO1/CA
41
N2RX
55
I/O
TT
PP
Supply voltage (5 V)
OD
S
Capability
36 VDD
interrupt
J5
pu/pd
TQFP100
50
Pin name
Type
LFBGA144
Main
function
(after
reset)
TQFP144
Input Level
Pin n°
2mA X X Port 2.8
P2.9/RDI1/CAN
I/O
2TX
TT
WUP14 2mA X X Port 2.9
H6
P2.10
I/O
TT
WUP16 2mA X X Port 2.10
58
G6
P2.11
I/O
TT
WUP17 2mA X X Port 2.11
59
L7
P2.12
I/O
TT
INT14
2mA X X Port 2.12
60
K7
P2.13
I/O
TT
INT15
2mA X X Port 2.13
61
J7
43 P2.14/SCL0
I/O
TT
62
H7
44 P2.15/SDA0
I/O
TT
63
M8
45 Test
56
J6
57
42
I
Alternate function
UART1:
transmit data
output
CAN2: receive
data input
(TQFP100
only)
UART1:
receive data
input
CAN2:
transmit data
output
(TQFP100
only)
WUP15 2mA X X Port 2.14 I2C0: serial clock
2mA X X Port 2.15 I2C0: serial data
pd
Reserved pin. Must be tied to ground
S
Internal RC oscillator bias. A 1.3 MΩ
external resistor has to be connected to
this pin when a 32 kHZ RC oscillator
frequency is used.
65 M10 47 VSS
S
Ground
66 M11 48 VDD
S
Supply voltage (5 V)
64
L8
46 VBIAS
67
K8
P3.0/AIN0
I/O
TT
2mA X X Port 3.0
ADC: analog input 0
68
J8
P3.1/AIN1
I/O
TT
2mA X X Port 3.1
ADC: analog input 1
69
M9
P3.2/AIN2
I/O
TT
2mA X X Port 3.2
ADC: analog input 2
70
L9
P3.3/AIN3
I/O
TT
2mA X X Port 3.3
ADC: analog input 3
71
K9
49 P3.4/AIN4
I/O
TT
2mA X X Port 3.4
ADC: analog input 4
(AIN0 in TQFP100)
72
L10
50 P3.5/AIN5
I/O
TT
2mA X X Port 3.5
ADC: Analog input 5
(AIN1 in TQFP100)
16/52
STR73xFxx
Table 4.
Block diagram
STR73xF pin description
Output
Main
function
(after
reset)
52 P3.7/AIN7
I/O
TT
2mA X X Port 3.7
ADC: analog input 7
(AIN3 in TQFP100)
75
K11
53 VSSA
S
Reference ground for A/D converter
76
K10
54 VDDA
S
Reference voltage for A/D converter
77
J12
55 P3.8/AIN8
I/O
TT
2mA X X Port 3.8
ADC: analog input 8
(AIN4 in TQFP100)
78
J11
56 P3.9/AIN9
I/O
TT
2mA X X Port 3.9
ADC: analog input 9
(AIN5 in TQFP100)
79
L12
57 P3.10/AIN10
I/O
TT
2mA X X Port 3.10
ADC: analog input 10
(AIN6 in TQFP100)
80
K12
58 P3.11/AIN11
I/O
TT
2mA X X Port 3.11
ADC: analog input 11
(AIN7 in TQFP100)
81
J10
59 P3.12/AIN12
I/O
TT
INT2
2mA X X Port 3.12
ADC: analog input 12
(AIN8 in TQFP100)
82
J9
60 P3.13/AIN13
I/O
TT
INT3
2mA X X Port 3.13
ADC: analog input 13
(AIN9 in TQFP100)
83
H12
61 P3.14/AIN14
I/O
TT
INT4
2mA X X Port 3.14
ADC: analog input 14
(AIN10 in TQFP100)
84
H11
62 P3.15/AIN15
I/O
TT
INT5
2mA X X Port 3.15
ADC: analog input 15
(AIN11 in TQFP100)
85
H10
63 VDD
86
H9
64 VSS
S
PP
L11
OD
74
Capability
ADC: analog input 6
(AIN2 in TQFP100)
interrupt
2mA X X Port 3.6
Pin name
pu/pd
TT
TQFP100
I/O
LFBGA144
73 M12 51 P3.6/AIN6
TQFP144
Input Level
Input
Type
Pin n°
Alternate function
Supply voltage (5 V)
S
Ground
87
G12 65 JTRST
I
TT
pu
JTAG reset Input
88
F12
66 JTDI
I
TT
pu
JTAG data input
89
H8
67 JTMS
I
TT
pu
JTAG mode selection Input
90
G11 68 JTCK
I
TT
pd
JTAG clock Input
91
G10 69 JTDO
O
92
G9
70 VSS
S
Ground
93
G8
71 VDD
S
Supply voltage (5 V)
94
G7
P4.0/ICAPA7
I/O
TT
WUP24 2mA X X Port 4.0
TIM7: input capture A input
95
F11
P4.1/ICAPB7
I/O
TT
WUP25 2mA X X Port 4.1
TIM7: input capture B input
96
F10
P4.2/ICAPA8
I/O
TT
WUP26 2mA X X Port 4.2
TIM8: input capture A input
4mA
JTAG data output.
Note: Reset state = HiZ
17/52
Block diagram
Table 4.
STR73xFxx
STR73xF pin description
Output
WUP27 2mA X X Port 4.3
TIM8: input capture B input
98
F8
P4.4/CAN2TX
I/O
TT
2mA X X Port 4.4
CAN2: transmit data output
99
E12
P4.5/CAN2RX
I/O
TT
WUP18 2mA X X Port 4.5
CAN2: receive data input
I2C1: serial clock
PP
TT
OD
I/O
Capability
P4.3/ICAPB8
interrupt
F9
Pin name
pu/pd
Input Level
97
TQFP100
Type
Main
function
(after
reset)
LFBGA144
Input
TQFP144
Pin n°
Alternate function
100 E11
72 P4.6/SCL1
I/O
TT
WUP19 2mA X X Port 4.6
101 C12
73 P4.7/SDA1
I/O
TT
2mA X X Port 4.7
I2C1: serial data
102 B12
P4.8/OCMPA8
I/O
TT
2mA X X Port 4.8
TIM8: output compare A output
103 E10
P4.9/ICAPB6
I/O
TT
2mA X X Port 4.9
TIM6: input capture B input
TIM5: input
TIM6: input
capture B
capture A input
WUP20 2mA X X Port 4.10
input
(144-pin pkg
(TQFP100
only)
only)
P4.10/ICAPA6/I
I/O
CAPB5
TT
105 D12
P4.11/OCMPB
8
I/O
TT
106 D11
P4.12/ICAPA9
I/O
TT
WUP21 2mA X X Port 4.12 TIM9: input capture A input
107 D10
P4.13/ICAPB9
I/O
TT
2mA X X Port 4.13 TIM9: input capture B input
104
E9
74
2mA X X Port 4.11 TIM8: output compare B output
108 C11
75 P4.14/SS1
I/O
TT
2mA X X Port 4.14 BSPI1: slave select
109 B11
76 P4.15/SCK1
I/O
TT
WUP22 2mA X X Port 4.15 BSPI1: serial clock
110 B10
77 P5.0/MOSI1
I/O
TT
2mA X X Port 5.0
BSPI1: master output/slave
input
111 C10
78 P5.1/MISO1
I/O
TT
2mA X X Port 5.1
BSPI1: master input/Slave
output
112
A9
P5.2/OCMPA9
I/O
TT
2mA X X Port 5.2
TIM9: output compare A output
113
B9
P5.3/OCMPB9
I/O
TT
2mA X X Port 5.3
TIM9: output compare B output
114
C9
P5.4/SS2/PWM
79
I/O
3
TT
2mA X X Port 5.4
BSPI2: slave
select
115
D9
80 P5.5/SCK2
I/O
TT
WUP23 2mA X X Port 5.5
116 A11
81 P5.6/MOSI2
I/O
TT
2mA X X Port 5.6
BSPI2: master output/slave
input
117 A10
82 P5.7/MISO2
I/O
TT
2mA X X Port 5.7
BSPI2: master input/slave
output
118
83 P5.8/PWM4
I/O
TT
2mA X X Port 5.8
PWM4: PWM output (TQFP100
only)
18/52
A8
INT6
PWM3: PWM
output
(TQFP100
only)
BSPI2: serial clock
STR73xFxx
Table 4.
Block diagram
STR73xF pin description
Output
TT
INT7
2mA X X Port 5.9
120
C8
85 P5.10/RDI2
I/O
TT
INT8
2mA X X Port 5.10 UART2: receive data input
121 A12
86 P5.11/TDO2
I/O
TT
INT9
2mA X X Port 5.11 UART2: transmit data output
122
D8
87 P5.12
I/O
TT
INT10
2mA X X Port 5.12
123
E8
P5.13
I/O
TT
INT11
2mA X X Port 5.13
124
B7
P5.14
I/O
TT
INT12
2mA X X Port 5.14
125
A7
P5.15
I/O
TT
INT13
2mA X X Port 5.15
PP
I/O
OD
84 P5.9/PWM5
Capability
Input Level
B8
interrupt
Type
119
Pin name
pu/pd
TQFP100
Main
function
(after
reset)
LFBGA144
Input
TQFP144
Pin n°
Alternate function
PWM5: PWM output (TQFP100
only)
126
A6
88 V18
S
1.8 V decoupling pin: a
decoupling capacitor
(recommended value: 100 nF)
must be connected between this
pin and nearest VSS pin.
127
C7
89 VSS
S
Ground
128
D7
90 VDD
S
Supply voltage (5 V)
129
E7
91 P6.0
I/O
TT
WUP0 8mA X X Port 6.0
130
F7
P6.1
I/O
TT
WUP1 2mA X X Port 6.1
131
B6
92 P6.2/RDI3
I/O
TT
WUP2 2mA X X Port 6.2
132
C6
P6.3
I/O
TT
WUP3 2mA X X Port 6.3
133
D6
I/O
TT
WUP4 2mA X X Port 6.4
134
E6
P6.5
I/O
TT
WUP5 2mA X X Port 6.5
135
A5
94 P6.6
I/O
TT
WUP6 2mA X X Port 6.6
136
B5
P6.7
I/O
TT
WUP7 2mA X X Port 6.7
137
C5
95 P6.8/RDI0
I/O
TT
WUP10 2mA X X Port 6.8
138
A3
96 P6.9/TDO0
I/O
TT
2mA X X Port 6.9
139
A2
P6.10
I/O
TT
WUP8 2mA X X Port 6.10
140
D5
97 P6.11/MISO0
I/O
TT
2mA X X Port 6.11
BSPI0: master input/slave
output
141
A4
98 P6.12/MOSI0
I/O
TT
2mA X X Port 6.12
BSPI0: master output/slave
input
142
B4
99 P6.13/SCK0
I/O
TT
WUP11 2mA X X Port 6.13 BSPI0: serial clock
143
C4
100 P6.14/SS0
I/O
TT
2mA X X Port 6.14 BSPI0: slave select
144
B3
P6.15
I/O
TT
93 P6.4/TDO3
UART3: receive data input
UART3: transmit data output
UART0: receive data input
UART0: transmit data output
WUP9 2mA X X Port 6.15
19/52
Block diagram
3.3
STR73xFxx
Memory mapping
Figure 5 shows the various memory configurations of the STR73xF system. The system
memory map (from 0x0000_0000 to 0xFFFF_FFFF) is shown on the left part of the figure,
the right part shows maps of the Flash and APB areas. For flexibility the Flash or RAM
addresses can be aliased to Block 0 addresses using the remapping feature
Most reserved memory spaces (gray shaded areas in Figure 5) are protected from access
by the user code. When an access this memory space is attempted, an ABORT signal is
generated. Depending on the type of access, the ARM processor will enter “prefetch abort”
state (Exception vector 0x0000_000C) or “data abort” state (Exception vector
0x0000_0010). It is up to the application software to manage these abort exceptions.
Figure 5.
Memory map
APB memory space
32 Kbytes
Addressable memory space
4 Gbytes
0xFFFF FFFF
0xFFFF 8000
APB TO ARM7
BRIDGE
0xFFFF FFFF
32K
EIC
1K
ADC
1K
CMU
RTC
1K
DMA 0-3
1K
TIM 4
1K
TIM 3
1K
TIM 2
1K
BSPI 2
1K
BSPI 1
1K
BSPI 0
1K
GP I/O 0-6
1K
PWM 0-5
1K
CAN 2(4)
1K
(4)
CAN 1
1K
CAN 0(4)
1K
APB BRIDGE 1 REGS
1K
reserved
1K
WAKEUP
1K
reserved
1K
TIM 5-9
1K
TIM 1
1K
0xFFFF FC00
0xFFFF FBFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
7
Flash memory space
64K/128/256 Kbytes
0xE000 0000
0xDFFF FFFF
F800
F7FF
F600
F400
F3FF
0xFFFF F000
0xFFFF EFFF
0xFFFF EC00
0xFFFF EBFF
0x8010 DFFF
6
0x8010 C000
0x8010 0017
0x8010 0000
System Memory 8K
Flash registers
20B
0xFFFF E800
0xFFFF E7FF
0xFFFF E400
0xFFFF E3FF
0xFFFF E000
0xFFFF DFFF
0xC000 0000
0xBFFF FFFF
0xFFFF DC00
0xFFFF DBFF
0xFFFF D800
0xFFFF D7FF
5
0xA000 3FFF
0xA000 0000
0x9FFF FFFF
0xFFFF D400
0xFFFF D3FF
RAM
16K
0xFFFF D000
0xFFFF CFFF
0xFFFF CC00
0xFFFF CBFF
0xFFFF C800
0xFFFF C7FF
4
0x8010 0017
0x8000 0000
0x7FFF FFFF
0xFFFF C400
0xFFFF C3FF
Flash
64K/128K/256K
0xFFFF C000
0xFFFF BFFF
0xFFFF BC00
0xFFFF BBFF
0xFFFF B800
0xFFFF B7FF
3
0x6000 03FF
0x6000 0000
0x5FFF FFFF
0xFFFF B400
0xFFFF B3FF
PRCCU
1K
0xFFFF B000
0xFFFF AFFF
0x8003 FFFF
B0F7(2)
2
0x4000 003F
0x4000 0000
0x3FFF FFFF
64K
0x8003 0000
0x8002 FFFF
CONFIG. REGS
B0F6(2)
64B
64K
0x8002 0000
0x8001 FFFF
1
0x2000 000F
0x2000 0000
0x1FFF FFFF
B0F5(3)
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
0xFFFF
A800
A7FF
A600
A400
A3FF
A200
A000
9FFF
9E00
9C00
9BFF
16B
0x8001 0000
0x8000 FFFF
0
Flash (1)
64K/128K/256K
0x8000
0x8000
0x8000
0x8000
0x8000
0x8000
0x8000
0x8000
0x8000
8000
7FFF
6000
5FFF
4000
3FFF
2000
1FFF
0000
0xFFFF 9000
0xFFFF 8FFF
32K
B0F1
8K
8K
8K
B0TF
8K
B0F3
B0F2
TIM 0
WAKEUPTIM
WDG
UART 3
UART 1
UART 2
UART 0
0xFFFF 8C00
0xFFFF 8BFF
1K
1K
1K
1K
TB 0-2
1K
reserved
1K
reserved
1K
reserved
1K
I2C 1
1K
I2C
1K
0xFFFF 9800
0xFFFF 97FF
0xFFFF 9400
0xFFFF 93FF
NATIVE ARBITER
B0F4
0x0010 0017
0x0000 0000
64K
0xFFFF AC00
0xFFFF ABFF
0xFFFF 8800
0xFFFF 87FF
0xFFFF 8400
0xFFFF 83FF
0
APB BRIDGE 0 REGS
1K
0xFFFF 8000
(1) Flash aliased at 0x0000 0000h by system decoder for booting with valid instruction upon RESET from Block B0 (8 Kbytes)
(2) Only available in STR73xZ2/V2
(3) Only available in STR73xZ2/V2 and STR73xZ1/V1
(4) Only available in STR730/STR731
20/52
access to gray shaded area will return an ABORT
Drawing not to scale
STR73xFxx
Electrical parameters
4
Electrical parameters
4.1
Parameter conditions
Unless otherwise specified, all voltages are referred to VSS.
4.1.1
Minimum and maximum values
Unless otherwise specified the minimum and maximum values are guaranteed in the worst
conditions of ambient temperature, supply voltage and frequencies by tests in production on
100% of the devices with an ambient temperature at TA=25° C and TA=TAmax (given by the
selected temperature range).
Data based on characterization results, design simulation and/or technology characteristics
are indicated in the table footnotes and are not tested in production. Based on
characterization, the minimum and maximum values refer to sample tests and represent the
mean value plus or minus three times the standard deviation (mean±3Σ).
4.1.2
Typical values
Unless otherwise specified, typical data are based on TA=25° C and VDD=5 V. They are
given only as design guidelines and are not tested.
Typical ADC accuracy values are determined by characterization of a batch of samples from
a standard diffusion lot over the full temperature range, where 95% of the devices have an
error less than or equal to the value indicated (mean±2Σ).
4.1.3
Typical curves
Unless otherwise specified, all typical curves are given only as design guidelines and are
not tested.
4.1.4
Loading capacitor
The loading conditions used for pin parameter measurement are shown in Figure 6.
4.1.5
Pin input voltage
The input voltage measurement on a pin of the device is described in Figure 7.
Figure 6.
Pin loading conditions
Figure 7.
Pin input voltage
STR7 PIN
STR7 PIN
L=50pF
VIN
21/52
Electrical parameters
4.2
STR73xFxx
Absolute maximum ratings
Stresses above those listed as “absolute maximum ratings” may cause permanent damage
to the device. This is a stress rating only and functional operation of the device under these
conditions is not implied. Exposure to maximum rating conditions for extended periods may
affect device reliability.
Table 5.
Voltage characteristics
Symbol
Ratings
Min
Max
Unit
External 5 V Supply voltage
-0.3
6.0
V
VSSA
Reference ground for A/D converter
VSS
VSS
V
VDDA- VSSA
Reference voltage for A/D converter
-0.3
VDD+0.3
Input voltage on any pin
-0.3
VDD+0.3
Variations between different 5 V
power pins
-
0.3
Variations between all the different
ground pins
-
0.3
VDD - VSS
VIN
|ΔVDDx|
V
mV
|VSSX - VSS|
VESD(HBM)
Electrostatic discharge voltage
(Human Body Model)
VESD(MM)
Electrostatic discharge voltage
(Machine Model)
Table 6.
see : Absolute maximum ratings
(electrical sensitivity) on page 36
Current characteristics
Symbol
Ratings
Max.
IVDD
Total current into VDD power lines (source) 1)
100
IVSS
Total current out of VSS ground lines (sink) 1)
100
Output current sunk by any I/O and control pin
10
Output current source by any I/O and control pin
10
Injected current on any other pin 4) &5)
±10
Total injected current (sum of all I/O and control pins) 4)
±75
IIO
IINJ(PIN) 2) & 3)
ΣIINJ(PIN) 2)
Unit
mA
1. All 5 V power (VDD, VDDA) and ground (VSS, VSSA) pins must always be connected to the external 5 V
supply
2. IINJ(PIN) must never be exceeded. This is implicitly insured if VIN maximum is respected. If VIN maximum
cannot be respected, the injection current must be limited externally to the IINJ(PIN) value. A positive
injection is induced by VIN>VDD while a negative injection is induced by VINV33 while a negative injection is
induced by VIN