STM8S903K3 STM8S903F3 16 MHz STM8S 8-bit MCU, up to 8 Kbytes Flash, 1 Kbyte RAM, 640 bytes EEPROM,10-bit ADC, 2 timers, UART, SPI, I²C - Switch-off peripheral clocks individually active, low consumption power-on • Permanently and power-down reset Interrupt management Nested interrupt controller with 32 interrupts LQFP32 7x7 UFQFPN32 5x5 • • Up to 28 external interrupts on 7 vectors SDIP32 400 mils Timers Advanced control timer: 16-bit, 4 CAPCOM channels, 3 complementary outputs, dead-time insertion and flexible synchronization • Features general purpose timer, with 3 CAPCOM • 16-bit channels (IC, OC or PWM) • 8-bit basic timer with 8-bit prescaler • Auto wakeup timer • Window and independent watchdog timers Core 16 MHz advanced STM8 core with Harvard architecture and 3-stage pipeline Communications interfaces UART with clock output for synchronous operation, Smartcard, IrDA, LIN master mode TSSOP20 UFQFPN20 3x3 SO20W 300 mils • • Extended instruction set 2 Memories Program memory: 8 Kbytes Flash; data retention 20 years at 55 °C after 10 kcycles • memory: 640 bytes true data EEPROM; • Data endurance 300 kcycles • RAM: 1 Kbytes Clock, reset and supply management 2.95 to 5.5 V operating voltage • clock control, 4 master clock sources: • Flexible Low power crystal resonator oscillator - External clock input - Internal, user-trimmable 16 MHz RC - Internal low power 128 kHz RC • Clock security system with clock monitor management: • Power - Low power modes (wait, active-halt, halt) June 2012 • • SPI interface up to 8 Mbit/s • I C interface up to 400 Kbit/s Analog to digital converter (ADC) 10-bit, ±1 LSB ADC with up to 7 muxed channels + 1 internal channel, scan mode and analog watchdog • • Internal reference voltage measurement I/Os Up to 28 I/Os on a 32-pin package including 21 high sink outputs • robust I/O design, immune against current • Highly injection Development support Embedded single wire interface module (SWIM) for fast on-chip programming and non intrusive debugging • Unique ID: 96-bit key including lot number DocID15590 Rev 8 1/116 www.st.com Contents STM8S903K3 STM8S903F3 Contents 1 2 3 4 Introduction ..............................................................................................................8 Description ...............................................................................................................9 Block diagram ........................................................................................................10 Product overview ...................................................................................................11 4.1 Central processing unit STM8 .....................................................................................11 4.2 Single wire interface module (SWIM) and debug module (DM) ..................................11 4.3 Interrupt controller .......................................................................................................12 4.4 Flash program and data EEPROM memory ................................................................12 4.5 Clock controller ............................................................................................................13 4.6 Power management ....................................................................................................14 4.7 Watchdog timers ..........................................................................................................14 4.8 Auto wakeup counter ...................................................................................................15 4.9 Beeper ........................................................................................................................15 4.10 TIM1 - 16-bit advanced control timer .........................................................................15 4.11 TIM5 - 16-bit general purpose timer ..........................................................................16 4.12 TIM6 - 8-bit basic timer ..............................................................................................16 4.13 Analog-to-digital converter (ADC1) ............................................................................16 4.14 Communication interfaces .........................................................................................17 4.14.1 UART1 ...............................................................................................17 4.14.2 SPI .....................................................................................................18 4.14.3 I²C ......................................................................................................18 5 Pinout and pin description ...................................................................................19 5.1 STM8S903F3 TSSOP20/SO20 pinout ........................................................................20 5.2 STM8S903F3 UFQFPN20 pinout ................................................................................21 5.3 TSSOP/SO/UFQFPN20 pin description ......................................................................22 5.4 STM8S903K3 UFQFPN32/LQFP32/SDIP32 pinout ....................................................23 5.5 UFQFPN/LQFP/SDIP32 pin description ......................................................................24 5.6 Alternate function remapping .......................................................................................26 6 Memory and register map .....................................................................................27 6.1 Memory map 6.2 Register map 6.2.1 6.2.2 6.2.3 ................................................................................................................27 ...............................................................................................................28 I/O port hardware register map ............................................................28 General hardware register map ...........................................................29 CPU/SWIM/debug module/interrupt controller registers .....................38 7 Interrupt vector mapping ......................................................................................41 8 Option bytes ...........................................................................................................43 8.1 STM8S903K3/F3 alternate function remapping bits ....................................................45 2/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Contents 9 Unique ID ................................................................................................................49 10 Electrical characteristics ....................................................................................50 10.1 Parameter conditions .................................................................................................50 10.1.1 Minimum and maximum values .........................................................50 10.1.2 Typical values .....................................................................................50 10.1.3 Typical curves ....................................................................................50 10.1.4 Loading capacitor ...............................................................................50 10.1.5 Pin input voltage .................................................................................50 10.2 Absolute maximum ratings ........................................................................................51 10.3 Operating conditions ..................................................................................................53 10.3.1 VCAP external capacitor ....................................................................54 10.3.2 Supply current characteristics ............................................................55 10.3.3 External clock sources and timing characteristics .............................65 10.3.4 Internal clock sources and timing characteristics ...............................67 10.3.5 Memory characteristics ......................................................................69 10.3.6 I/O port pin characteristics .................................................................70 10.3.7 Reset pin characteristics ....................................................................78 10.3.8 SPI serial peripheral interface ............................................................81 2 10.3.9 I C interface characteristics ...............................................................84 10.3.10 10-bit ADC characteristics ................................................................85 10.3.11 EMC characteristics .........................................................................89 11 Package information ............................................................................................92 11.1 32-pin LQFP package mechanical data .....................................................................92 11.2 32-lead UFQFPN package mechanical data .............................................................94 11.3 20-lead UFQFPN package mechanical data .............................................................95 11.4 UFQFPN recommended footprint ..............................................................................97 11.5 SDIP32 package mechanical data .............................................................................98 11.6 20-pin TSSOP package mechanical data ................................................................100 11.7 20-pin SO package mechanical data .......................................................................101 11.8 Thermal characteristics ............................................................................................102 11.8.1 Reference document ........................................................................103 11.8.2 Selecting the product temperature range .........................................103 12 Ordering information .........................................................................................104 12.1 STM8S903K3/F3 FASTROM microcontroller option list ..........................................104 13 STM8 development tools ..................................................................................110 13.1 Emulation and in-circuit debugging tools .................................................................110 13.2 Software tools ..........................................................................................................110 13.2.1 STM8 toolset ....................................................................................111 13.2.2 C and assembly toolchains ..............................................................111 13.3 Programming tools ..................................................................................................111 14 Revision history .................................................................................................112 DocID15590 Rev 8 3/116 List of tables STM8S903K3 STM8S903F3 List of tables Table 1. STM8S903K3/F3 access line features .......................................................................................9 Table 2. Peripheral clock gating bit assignments in CLK_PCKENR1/2 registers ..................................14 Table 3. TIM timer features ....................................................................................................................16 Table 4. Legend/abbreviations for pinout tables ...................................................................................19 Table 5. TSSOP20/SO20/UFQFPN20 pin description ...........................................................................24 Table 6. UFQFPN32/LQFP32/SDIP32 pin description ...........................................................................24 Table 7. I/O port hardware register map ................................................................................................28 Table 8. General hardware register map ................................................................................................43 Table 9. CPU/SWIM/debug module/interrupt controller registers .........................................................54 Table 10. Interrupt mapping ...................................................................................................................41 Table 11. Option bytes .........................................................................................................................112 Table 12. Option byte description ...........................................................................................................43 Table 13. STM8S903K3 alternate function remapping bits [7:2] for 32-pin packages ...........................45 Table 14. STM8S903F3 alternate function remapping bits [7:2] for 20-pin packages ...........................46 Table 15. STM8S903K3 alternate function remapping bits [1:0] for 32-pin packages .........................102 Table 16. STM8S903F3 alternate function remapping bits [1:0] for 20-pin packages ...........................48 Table 17. Unique ID registers (96 bits) .................................................................................................112 Table 18. Voltage characteristics ...........................................................................................................51 Table 19. Current characteristics ...........................................................................................................51 Table 20. Thermal characteristics ..........................................................................................................52 Table 21. General operating conditions .................................................................................................53 Table 22. Operating conditions at power-up/power-down ......................................................................54 Table 23. Total current consumption with code execution in run mode at VDD = 5 V .............................55 Table 24. Total current consumption with code execution in run mode at VDD = 3.3 V ..........................56 Table 25. Total current consumption in wait mode at VDD = 5 V ............................................................57 Table 26. Total current consumption in wait mode at VDD = 3.3 V .........................................................57 Table 27. Total current consumption in active halt mode at VDD = 5 V ..................................................58 Table 28. Total current consumption in active halt mode at VDD = 3.3 V ...............................................59 Table 29. Total current consumption in halt mode at VDD = 5 V .............................................................60 Table 30. Total current consumption in halt mode at VDD = 3.3 V ..........................................................60 Table 31. Wakeup times .........................................................................................................................60 Table 32. Total current consumption and timing in forced reset state ....................................................61 Table 33. Peripheral current consumption .............................................................................................62 Table 34. HSE user external clock characteristics .................................................................................65 Table 35. HSE oscillator characteristics .................................................................................................65 Table 36. HSI oscillator characteristics ..................................................................................................67 Table 37. LSI oscillator characteristics ...................................................................................................68 Table 38. RAM and hardware registers ..................................................................................................69 Table 39. Flash program memory/data EEPROM memory ....................................................................69 Table 40. I/O static characteristics .........................................................................................................70 Table 41. Output driving current (standard ports) ..................................................................................72 Table 42. Output driving current (true open drain ports) ........................................................................73 Table 43. Output driving current (high sink ports) ..................................................................................73 Table 44. NRST pin characteristics ........................................................................................................78 Table 45. SPI characteristics ..................................................................................................................81 2 Table 46. I C characteristics ..................................................................................................................84 Table 47. ADC characteristics ................................................................................................................85 4/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 List of tables Table 48. ADC accuracy with RAIN < 10 kΩ , VDD= 5 V .........................................................................86 Table 49. ADC accuracy with RAIN < 10 kΩ RAIN, VDD = 3.3 V ..............................................................87 Table 50. EMS data ................................................................................................................................89 Table 51. EMI data .................................................................................................................................90 Table 52. ESD absolute maximum ratings .............................................................................................91 Table 53. Electrical sensitivities .............................................................................................................91 Table 54. 32-pin low profile quad flat package mechanical data .........................................................102 Table 55. 32-lead, ultra thin, fine pitch quad flat no-lead package mechanical data .............................94 Table 56. 20-lead, ultra thin, fine pitch quad flat no-lead package (3 x 3) package mechanical data ....96 Table 57. 32-lead shrink plastic DIP (400 ml) package mechanical data ..............................................99 Table 58. 20-pin, 4.40 mm body, 0.65 mm pitch mechanical data .......................................................101 Table 59. 20-lead, plastic small outline (300 mils) mechanical data ....................................................101 Table 60. Thermal characteristics ........................................................................................................102 Table 61. Document revision history ....................................................................................................112 DocID15590 Rev 8 5/116 List of figures STM8S903K3 STM8S903F3 List of figures Figure 1. Block diagram .........................................................................................................................10 Figure 2. Flash memory organization ....................................................................................................13 Figure 3. STM8S903F3 TSSOP20/SO20 pinout ...................................................................................23 Figure 4. STM8S903F3 UFQFPN20 pinout ...........................................................................................23 Figure 5. STM8S903K3 UFQFPN32/LQFP32 pinout ............................................................................23 Figure 6. STM8S903K3 SDIP32 pinout .................................................................................................24 Figure 7. Memory map ...........................................................................................................................27 Figure 8. Pin loading conditions .............................................................................................................50 Figure 9. Pin input voltage .....................................................................................................................51 Figure 10. fCPUmax versus VDD ..............................................................................................................54 Figure 11. External capacitor CEXT .......................................................................................................55 Figure 12. Typ IDD(RUN) vs. VDD HSE user external clock, fCPU = 16 MHz .............................................62 Figure 13. Typ IDD(RUN) vs. fCPU HSE user external clock, VDD = 5 V ....................................................63 Figure 14. Typ IDD(RUN) vs. VDD HSI RC osc, fCPU = 16 MHz .................................................................63 Figure 15. Typ IDD(WFI) vs. VDD HSE user external clock, fCPU = 16 MHz ..............................................64 Figure 16. Typ IDD(WFI) vs. fCPU HSE user external clock, VDD = 5 V .....................................................64 Figure 17. Typ IDD(WFI) vs. VDD HSI RC osc, fCPU = 16 MHz .................................................................64 Figure 18. HSE external clocksource .....................................................................................................65 Figure 19. HSE oscillator circuit diagram ...............................................................................................66 Figure 20. Typical HSI frequency variation vs VDD @ 4 temperatures ..................................................68 Figure 21. Typical LSI frequency variation vs VDD @ 4 temperatures ...................................................68 Figure 22. Typical VIL and VIH vs VDD @ 4 temperatures ......................................................................71 Figure 23. Typical pull-up resistance vs VDD @ 4 temperatures ............................................................72 Figure 24. Typical pull-up current vs VDD @ 4 temperatures .................................................................72 Figure 25. Typ. VOL @ VDD = 5 V (standard ports) ................................................................................74 Figure 26. Typ. VOL @ VDD = 3.3 V (standard ports) .............................................................................74 Figure 27. Typ. VOL @ VDD = 5 V (true open drain ports) ......................................................................75 Figure 28. Typ. VOL @ VDD = 3.3 V (true open drain ports) ...................................................................75 Figure 29. Typ. VOL @ VDD = 5 V (high sink ports) ................................................................................76 Figure 30. Typ. VOL @ VDD = 3.3 V (high sink ports) .............................................................................76 Figure 31. Typ. VDD - VOH@ VDD = 5 V (standard ports) .......................................................................77 Figure 32. Typ. VDD - VOH @ VDD = 3.3 V (standard ports) ...................................................................77 Figure 33. Typ. VDD - VOH@ VDD = 5 V (high sink ports) .......................................................................78 Figure 34. Typ. VDD - VOH@ VDD = 3.3 V (high sink ports) ....................................................................78 Figure 35. Typical NRST VIL and VIH vs VDD @ 4 temperatures ...........................................................79 Figure 36. Typical NRST pull-up resistance vs VDD @ 4 temperatures .................................................80 Figure 37. Typical NRST pull-up current vs VDD @ 4 temperatures ......................................................80 Figure 38. Recommended reset pin protection ......................................................................................81 Figure 39. SPI timing diagram - slave mode and CPHA = 0 ..................................................................83 Figure 40. SPI timing diagram - slave mode and CPHA = 1 ..................................................................83 (1) Figure 41. SPI timing diagram - master mode ...................................................................................84 2 Figure 42. Typical application with I C bus and timing diagram ............................................................85 Figure 43. ADC accuracy characteristics ...............................................................................................88 Figure 44. Typical application with ADC ................................................................................................88 Figure 45. 32-pin low profile quad flat package (7 x 7) ..........................................................................92 Figure 46. 32-lead, ultra thin, fine pitch quad flat no-lead package (5 x 5) ............................................94 Figure 47. 20-lead, ultra thin, fine pitch quad flat no-lead package outline (3 x 3) ................................95 6/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 List of figures Figure 48. Recommended footprint for on-board emulation ..................................................................97 Figure 49. Recommended footprint without on-board emulation ...........................................................98 Figure 50. 32-lead shrink plastic DIP (400 ml) package ........................................................................98 Figure 51. 20-pin, 4.40 mm body, 0.65 mm pitch .................................................................................101 Figure 52. 20-lead, plastic small outline (300 mils) package ...............................................................101 Figure 53. STM8S903K3/F3 ordering information scheme ..................................................................104 DocID15590 Rev 8 7/116 Introduction 1 STM8S903K3 STM8S903F3 Introduction This datasheet contains the description of the device features, pinout, electrical characteristics, mechanical data and ordering information. For complete information on the STM8S microcontroller memory, registers and peripherals, please refer to the STM8S microcontroller family reference manual (RM0016). • information on programming, erasing and protection of the internal Flash memory • For please refer to the STM8S Flash programming manual (PM0051). information on the debug and SWIM (single wire interface module) refer to the STM8 • For SWIM communication protocol and debug module user manual (UM0470). information on the STM8 core, please refer to the STM8 CPU programming manual • For (PM0044). 8/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 2 Description Description The STM8S903K3 and STM8S903F3 8-bit microcontrollers offer 8 Kbytes Flash program memory, plus integrated true data EEPROM. The STM8S microcontroller family reference manual (RM0016) refers to devices in this family as low-density. They provide the following benefits: performance, robustness, and reduced system cost. Device performance and robustness are ensured by advanced core and peripherals made in a state-of-the art technology, a 16 MHz clock frequency, robust I/Os, independent watchdogs with separate clock source, and a clock security system. The system cost is reduced thanks to an integrated true data EEPROM for up to 300 kwrite/erase cycles and a high system integration level with internal clock oscillators, watchdog and brown-out reset. Full documentation is offered as well as a wide choice of development tools. Table 1: STM8S903K3/F3 access line features Device STM8S903K3 STM8S903F3 32 20 Pin count (1) Max. number of GPIOs (I/Os) (2) 28 Ext. interrupt pins 16 28 Timer CAPCOM channels 16 7 Timer complementary outputs 3 2 A/D converter channels 7 5 High sink I/Os 21 12 Low density Flash program memory(bytes) 8K (3) Data EEPROM (bytes) 640 RAM (bytes) Peripheral set 1K 2 Multipurpose timer (TIM1), SPI, I C, UART window WDG, independent WDG, ADC, PWM timer (TIM5), 8-bit timer (TIM6) (1) Including 21 high sink outputs (2) Including 12 high sink outputs (3) No read-while-write (RWW) capability DocID15590 Rev 8 9/116 Block diagram 3 STM8S903K3 STM8S903F3 Block diagram Figure 1: Block diagram Reset block XTAL 1-16 MHz Clock controller Reset Reset RC int. 16 MHz Detector POR BOR RC int. 128 kHz Clock to peripherals and core Window WDG STM8 core Independent WDG 400 Kbit/s I 2C 8 Mbit/s SPI LIN master SPI emul. 8 Kbytes program Flash Debug/SWIM Address and data bus Single wire debug interf. UART1 640 bytes data EEPROM 1 Kbytes RAM 16-bit advanced control timer (TIM1) 16-bit general purpose Timer (TIM5) 10/116 Up to 7 channels ADC1 1/2/4 kHz beep Beeper DocID15590 Rev 8 8-bit basic timer (TIM6) AWU timer Up to 4 CAPCOM channels + 3 complementary outputs Up to 3 CAPCOM channels STM8S903K3 STM8S903F3 4 Product overview Product overview The following section intends to give an overview of the basic features of the device functional modules and peripherals. For more detailed information please refer to the corresponding family reference manual (RM0016). 4.1 Central processing unit STM8 The 8-bit STM8 core is designed for code efficiency and performance. It contains 6 internal registers which are directly addressable in each execution context, 20 addressing modes including indexed indirect and relative addressing and 80 instructions. Architecture and registers Harvard architecture • • 3-stage pipeline • 32-bit wide program memory bus - single cycle fetching for most instructions Y 16-bit index registers - enabling indexed addressing modes with or without offset • Xandandread-modify-write type data manipulations 8-bit accumulator • • 24-bit program counter - 16-Mbyte linear memory space • 16-bit stack pointer - access to a 64 K-level stack • 8-bit condition code register - 7 condition flags for the result of the last instruction Addressing 20 addressing modes • indirect addressing mode for look-up tables located anywhere in the address • Indexed space • Stack pointer relative addressing mode for local variables and parameter passing Instruction set 80 instructions with 2-byte average instruction size • • Standard data movement and logic/arithmetic functions • 8-bit by 8-bit multiplication • 16-bit by 8-bit and 16-bit by 16-bit division • Bit manipulation • Data transfer between stack and accumulator (push/pop) with direct stack access • Data transfer using the X and Y registers or direct memory-to-memory transfers 4.2 Single wire interface module (SWIM) and debug module (DM) The single wire interface module and debug module permits non-intrusive, real-time in-circuit debugging and fast memory programming. DocID15590 Rev 8 11/116 Product overview STM8S903K3 STM8S903F3 SWIM Single wire interface module for direct access to the debug module and memory programming. The interface can be activated in all device operation modes. The maximum data transmission speed is 145 bytes/ms. Debug module The non-intrusive debugging module features a performance close to a full-featured emulator. Beside memory and peripherals, also CPU operation can be monitored in real-time by means of shadow registers. R/W to RAM and peripheral registers in real-time • • R/W access to all resources by stalling the CPU • Breakpoints on all program-memory instructions (software breakpoints) • Two advanced breakpoints, 23 predefined configurations 4.3 Interrupt controller • Nested interrupts with three software priority levels • 32 interrupt vectors with hardware priority • Up to 28 external interrupts on 7 vectors including TLI • Trap and reset interrupts 4.4 Flash program and data EEPROM memory • 8 Kbytes of Flash program single voltage Flash memory • 640 bytes true data EEPROM • User option byte area Write protection (WP) Write protection of Flash program memory and data EEPROM is provided to avoid unintentional overwriting of memory that could result from a user software malfunction. There are two levels of write protection. The first level is known as MASS (memory access security system). MASS is always enabled and protects the main Flash program memory, data EEPROM and option bytes. To perform in-application programming (IAP), this write protection can be removed by writing a MASS key sequence in a control register. This allows the application to write to data EEPROM, modify the contents of main program memory or the device option bytes. A second level of write protection, can be enabled to further protect a specific area of memory known as UBC (user boot code). Refer to the figure below. The size of the UBC is programmable through the UBC option byte, in increments of 1 page (64-byte block) by programming the UBC option byte in ICP mode. This divides the program memory into two areas: Main program memory: Up to 8 Kbytes minus UBC • • User-specific boot code (UBC): Configurable up to 8 Kbytes The UBC area remains write-protected during in-application programming. This means that the MASS keys do not unlock the UBC area. It protects the memory used to store the boot 12/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Product overview program, specific code libraries, reset and interrupt vectors, the reset routine and usually the IAP and communication routines. Figure 2: Flash memory organization Data EEPROM memory Data memory area ( 640 bytes) Option bytes UBC area Remains write protected during IAP Low density Flash program memory (8 Kbytes) Programmable area from 64 bytes(1 page) up to 8 Kbytes (in 1 page steps) Program memory area Write access possible for IAP Read-out protection (ROP) The read-out protection blocks reading and writing the Flash program memory and data EEPROM memory in ICP mode (and debug mode). Once the read-out protection is activated, any attempt to toggle its status triggers a global erase of the program and data memory. Even if no protection can be considered as totally unbreakable, the feature provides a very high level of protection for a general purpose microcontroller. 4.5 Clock controller The clock controller distributes the system clock (fMASTER) coming from different oscillators to the core and the peripherals. It also manages clock gating for low power modes and ensures clock robustness. Features Clock prescaler: To get the best compromise between speed and current consumption the clock frequency to the CPU and peripherals can be adjusted by a programmable prescaler. • clock switching: Clock sources can be changed safely on the fly in run mode • Safe through a configuration register. The clock signal is not switched until the new clock source is ready. The design guarantees glitch-free switching. management: To reduce power consumption, the clock controller can stop the • Clock clock to the core, individual peripherals or memory. clock sources: Four different clock sources can be used to drive the master • Master clock: - 1-16 MHz high-speed external crystal (HSE) DocID15590 Rev 8 13/116 Product overview - STM8S903K3 STM8S903F3 Up to 16 MHz high-speed user-external clock (HSE user-ext) 16 MHz high-speed internal RC oscillator (HSI) 128 kHz low-speed internal RC (LSI) clock: After reset, the microcontroller restarts by default with an internal 2 MHz • Startup clock (HSI/8). The prescaler ratio and clock source can be changed by the application program as soon as the code execution starts. security system (CSS): This feature can be enabled by software. If an HSE clock • Clock failure occurs, the internal RC (16 MHz/8) is automatically selected by the CSS and an interrupt can optionally be generated. main clock output (CCO): This outputs an external clock for use by the • Configurable application. Table 2: Peripheral clock gating bit assignments in CLK_PCKENR1/2 registers Bit Peripheral Bit clock Peripheral Bit clock Peripheral Bit clock Peripheral clock PCKEN17 TIM1 PCKEN13 UART1 PCKEN27 Reserved CKEN23 ADC PCKEN16 IM5 PCKEN12 Reserved PCKEN26 Reserved PCKEN22 AWU PCKEN15 Reserved PCKEN11 SPI PCKEN25 Reserved PCKEN21 Reserved PCKEN14 TIM6 PCKEN10 I C PCKEN24 Reserved PCKEN20 Reserved 4.6 2 Power management For efficent power management, the application can be put in one of four different low-power modes. You can configure each mode to obtain the best compromise between lowest power consumption, fastest start-up time and available wakeup sources. Wait mode: In this mode, the CPU is stopped, but peripherals are kept running. The wakeup is performed by an internal or external interrupt or reset. • halt mode with regulator on: In this mode, the CPU and peripheral clocks are • Active stopped. An internal wakeup is generated at programmable intervals by the auto wake up unit (AWU). The main voltage regulator is kept powered on, so current consumption is higher than in active halt mode with regulator off, but the wakeup time is faster. Wakeup is triggered by the internal AWU interrupt, external interrupt or reset. halt mode with regulator off: This mode is the same as active halt with regulator • Active on, except that the main voltage regulator is powered off, so the wake up time is slower. mode: In this mode the microcontroller uses the least power. The CPU and peripheral • Halt clocks are stopped, the main voltage regulator is powered off. Wakeup is triggered by external event or reset. 4.7 Watchdog timers The watchdog system is based on two independent timers providing maximum security to the applications. 14/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Product overview Activation of the watchdog timers is controlled by option bytes or by software. Once activated, the watchdogs cannot be disabled by the user program without performing a reset. Window watchdog timer The window watchdog is used to detect the occurrence of a software fault, usually generated by external interferences or by unexpected logical conditions, which cause the application program to abandon its normal sequence. The window function can be used to trim the watchdog behavior to match the application perfectly. The application software must refresh the counter before time-out and during a limited time window. A reset is generated in two situations: 1. Timeout: At 16 MHz CPU clock the time-out period can be adjusted between 75 µs up to 64 ms. 2. Refresh out of window: The downcounter is refreshed before its value is lower than the one stored in the window register. Independent watchdog timer The independent watchdog peripheral can be used to resolve processor malfunctions due to hardware or software failures. It is clocked by the 128 kHZ LSI internal RC clock source, and thus stays active even in case of a CPU clock failure The IWDG time base spans from 60 µs to 1 s. 4.8 Auto wakeup counter • Used for auto wakeup from active halt mode • Clock source: Internal 128 kHz internal low frequency RC oscillator or external clock • LSI clock can be internally connected to TIM1 input capture channel 1 for calibration 4.9 Beeper The beeper function outputs a signal on the BEEP pin for sound generation. The signal is in the range of 1, 2 or 4 kHz. The beeper output port is only available through the alternate function remap option bit AFR7. 4.10 TIM1 - 16-bit advanced control timer This is a high-end timer designed for a wide range of control applications. With its complementary outputs, dead-time control and center-aligned PWM capability, the field of applications is extended to motor control, lighting and half-bridge driver 16-bit up, down and up/down autoreload counter with 16-bit prescaler • independent capture/compare channels (CAPCOM) configurable as input capture, • Four output compare, PWM generation (edge and center aligned mode) and single pulse mode output DocID15590 Rev 8 15/116 Product overview STM8S903K3 STM8S903F3 module to control the timer with external signals or to synchronise with • Synchronization TIM5 or TIM6 • Break input to force the timer outputs into a defined state • Three complementary outputs with adjustable dead time • Encoder mode • Interrupt sources: 3 x input capture/output compare, 1 x overflow/update, 1 x break 4.11 TIM5 - 16-bit general purpose timer • 16-bit autoreload (AR) up-counter • 15-bit prescaler adjustable to fixed power of 2 ratios 1…32768 • 3 individually configurable capture/compare channels • PWM mode • Interrupt sources: 3 x input capture/output compare, 1 x overflow/update module to control the timer with external signals or to synchronize with • Synchronization TIM1 or TIM6 4.12 TIM6 - 8-bit basic timer • 8-bit autoreload, adjustable prescaler ratio to any power of 2 from 1 to 128 • Clock source: CPU clock • Interrupt source: 1 x overflow/update module to control the timer with external signals or to synchronize with • Synchronization TIM1 or TIM5. Table 3: TIM timer features Timer Counter Prescaler size (bits) Counting mode CAPCOM Complementary Ext. Timer channels outputs trigger synchronization/ chaining TIM1 16 Any integer from 1 Up/down to 65536 4 3 Yes TIM5 16 Any power of 2 from 1 to 32768 Up 3 0 No TIM6 8 Any power of 2 from 1 to 128 Up 0 0 No 4.13 Yes Analog-to-digital converter (ADC1) The STM8S903K3 family products contain a 10-bit successive approximation A/D converter (ADC1) with up to 7 external and 1 internal multiplexed input channels and the following main features: Input voltage range: 0 to VDD • 16/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Product overview • Conversion time: 14 clock cycles • Single and continuous and buffered continuous conversion modes • Buffer size (n x 10 bits) where n = number of input channels • Scan mode for single and continuous conversion of a sequence of channels • Analog watchdog capability with programmable upper and lower thresholds • Internal reference voltage on channel AIN7 • Analog watchdog interrupt • External trigger input • Trigger from TIM1 TRGO • End of conversion (EOC) interrupt Internal bandgap reference voltage Channel AIN7 is internally connected to the internal bandgap reference voltage. The internal bandgap reference is constant and can be used, for example, to monitor VDD. It is independent of variations in VDD and ambient temperature TA. 4.14 Communication interfaces The following communication interfaces are implemented: UART1: Full feature UART, synchronous mode, SPI master mode, Smartcard mode, IrDA mode, single wire mode, LIN2.1 master capability • • SPI : Full and half-duplex, 8 Mbit/s • I²C: Up to 400 Kbit/s 4.14.1 UART1 Main features One Mbit/s full duplex SCI • • SPI emulation • High precision baud rate generator • Smartcard emulation • IrDA SIR encoder decoder • LIN master mode • Single wire half duplex mode Asynchronous communication (UART mode) Full duplex communication - NRZ standard format (mark/space) • Programmable transmit and receive baud rates up to 1 Mbit/s (f /16) and capable of • following any standard baud rate regardless of the input frequency • Separate enable bits for transmitter and receiver receiver wakeup modes: • TwoAddress bit (MSB) - Idle line (interrupt) CPU DocID15590 Rev 8 17/116 Product overview STM8S903K3 STM8S903F3 • Transmission error detection with interrupt generation • Parity control Synchronous communication Full duplex synchronous transfers • • SPI master operation • 8-bit data communication • Maximum speed: 1 Mbit/s at 16 MHz (f CPU/16) LIN master mode Emission: Generates 13-bit synch break frame • • Reception: Detects 11-bit break frame 4.14.2 SPI • Maximum speed: 8 Mbit/s (f /2) both for master and slave • Full duplex synchronous transfers • Simplex synchronous transfers on two lines with a possible bidirectional data line • Master or slave operation - selectable by hardware or software • CRC calculation • 1 byte Tx and Rx buffer • Slave/master selection input pin MASTER 4.14.3 I²C master features: • I²C Clock generation - Start and stop generation slave features: • I²C Programmable I2C address detection - Stop bit detection • Generation and detection of 7-bit/10-bit addressing and general call different communication speeds: • Supports - Standard speed (up to 100 kHz) - Fast speed (up to 400 kHz) 18/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 5 Pinout and pin description Pinout and pin description Table 4: Legend/abbreviations for pinout tables Type I= Input, O = Output, S = Power supply Level Input CM = CMOS Output HS = High sink Output speed O1 = Slow (up to 2 MHz) O2 = Fast (up to 10 MHz) O3 = Fast/slow programmability with slow as default state after reset O4 = Fast/slow programmability with fast as default state after reset Port and control configuration Reset state Input float = floating, wpu = weak pull-up Output T = True open drain, OD = Open drain, PP = Push pull Bold X (pin state after internal reset release). Unless otherwise specified, the pin state is the same during the reset phase and after the internal reset release. DocID15590 Rev 8 19/116 Pinout and pin description 5.1 STM8S903K3 STM8S903F3 STM8S903F3 TSSOP20/SO20 pinout Figure 3: STM8S903F3 TSSOP20/SO20 pinout TIM5_CH1[UART1_CK]BEEP/PD4(HS) AIN5/UART1_TX/PD5(HS) AIN6/UART1_RX/PD6(HS) NRST OSCIN/PA1 OSCOUT/PA2 VSS VCAP VDD [SPI_NSS]/TIM5_CH3/PA3(HS) 1 2 3 4 5 6 7 8 9 10 20 19 18 17 16 15 14 13 12 11 PD3(HS)/AIN4/TIM5_CH2/ADC_ETR PD2(HS)/AIN3[TIM5_CH3] PD1(HS)/SWIM PC7(HS)/SPI_MISO[TIM1_CH2] PC6(HS)/SPI_MOSI[TIM1_CH1] PC5(HS)/SPI_SCK[TIM5_CH1] PC4(HS)/TIM1_CH4/CLK_CCO/AIN2/[TIM1_CH2N] PC3(HS)/TIM1_CH3[TLI][TIM1_CH1N] PB4(T)/I2C_SCL[ADC_ETR] PB5(T)/[TIM1_BKIN]I2C_SDA 1. (HS) high sink capability. 2. (T) true open drain (P-buffer and protection diode to VDD not implemented). 3. [ ] alternate function remapping option (if the same alternate function is shown twice, it indicates an exclusive choice not a duplication of the function). 20/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 STM8S903F3 UFQFPN20 pinout 19 18 17 PD2(HS)/AIN3/[TIM5_CH3] PD5(HS)/AIN5/UART1_TX PD4 (HS)/BEEP / TIM5_CH1/UART1_CK 20 PD3 (HS)/AIN4/TIM5_CH2/ADC_ETR PD6(HS)/AIN6/UART1_RX Figure 4: STM8S903F3 UFQFPN20 pinout 16 NRST 1 15 OSCIN/PA1 2 14 PC7(HS)/SPI_MISO/[TIM1_CH2] OSCOUT/PA2 3 13 PC6(HS)/SPI_MOSI/[TIM1_CH1] VSS 4 12 PC5 (HS)/SPI_SCK/[TIM5_CH1] VCAP 5 11 PC4(HS)/TIM1_CH4/CLK_CCO/AIN2/[TIM1_CH2N] 9 PD1(HS)/SWIM 10 [TIM1_CH1N]/[TLI]/TIM1_CH3/(HS)PC3 8 [TIM1_BKIN]/I2C_SDA/(T)PB5 [ADC_ETR]/I2C_SCL/(T)PB4 7 [UART1_TX]/[SPI_NSS]/TIM5_CH3/(HS) PA3 6 VDD 5.2 Pinout and pin description 1. (HS) high sink capability. 2. (T) true open drain (P-buffer and protection diode to VDD not implemented). 3. [ ] alternate function remapping option (if the same alternate function is shown twice, it indicates an exclusive choice not a duplication of the function). DocID15590 Rev 8 21/116 Pinout and pin description 5.3 STM8S903K3 STM8S903F3 Pin description TSSOP20_SO20_UFQFPN20 Table 5: TSSOP20/SO20/UFQFPN20 pin description TSSOP UFQFPN Pin name SO20 4 Type Input floating 20 Output wpu Ext. interrupt High (1) sink Speed OD PP X Main Default alternate function function (after reset) 1 NRST I/O 5 2 (2) PA1/ OSCIN I/O X X X O1 X X Port A1 Resonator/ crystal in 6 3 PA2/ OSCOUT I/O X X X O1 X X Port A2 Resonator/ crystal out 7 4 VSS S Digital ground 8 5 VCAP S 1.8 V regulator capacitor 9 6 VDD S Digital power supply 10 7 PA3/ TIM5_CH3 [SPI_NSS] [UART1_TX] I/O X 11 8 PB5/ I2C_SDA [TIM1_BKIN] I/O X 12 9 PB4/ I2C_SCL [ADC_ETR] I/O X 13 10 PC3/ TIM1_CH3/TLI/[TIM1_CH1N ] I/O X X X 14 11 PC4/ TIM1_CH4/ CLK_CCO/AIN2/[TIM1_CH2N] I/O X X 15 12 PC5/SPI_SCK [TIM5_CH1] I/O X 16 13 PC6/ SPI_MOSI [TIM1_CH1] I/O 17 14 PC7/ SPI_MISO [TIM1_CH2] 18 15 19 X Alternate function after remap [option bit] Reset X HS O3 X X O1 (3) T X O1 (3) T HS O3 X X Port C3 Timer 1 - channel 3 Top level interrupt [AFR3] Timer 1 inverted channel 1 [AFR7] X HS O3 X X Port C4 Timer 1 - channel 4 /configurable clock output Analog input 2 [AFR2]Timer 1 inverted channel 2 [AFR7] X X HS O3 X X Port C5 SPI clock Timer 5 channel 1 [AFR0] X X X HS O3 X X Port C6 PI master out/slave in Timer 1 channel 1 [AFR0] I/O X X X HS O3 X X Port C7 SPI master in/ slave out Timer 1 channel 2[AFR0] (4) PD1/ SWIM I/O X X X HS O4 X X Port D1 SWIM data interface 16 PD2/AIN3/ [TIM5_CH3] I/O X X X HS O3 X X Port D2 20 17 PD3/ AIN4/ TIM5_CH2/ ADC_ETR I/O X X X HS O3 X X Port D3 Analog input 4 Timer 52 channel 2/ADC external trigger 1 18 PD4/ TIM5_CH1/ BEEP [UART1_CK] I/O X X X HS O3 X X Port D4 Timer 5 - channel 1/BEEP output 2 19 PD5/ AIN5/ UART1_TX I/O X X X HS O3 X X Port D5 Analog input 5/ UART1 data transmit 3 20 PD6/ AIN6/ UART1_RX I/O X X X HS O3 X X Port D6 Analog input 6/ UART1 data receive (1) X Port A3 Port B5 Port B4 Timer 52 channel 3 SPI master/ slave select [AFR1]/ UART1 data transmit [AFR1:0] 2 I C data Timer 1 - break input [AFR4] 2 I C clock ADC external trigger [AFR4] Analog input 3 [AFR2] Timer 52 - channel 3 [AFR1] UART clock [AFR2] I/O pins used simultaneously for high current source/sink must be uniformly spaced around the package. In addition, the total driven current must respect the absolute maximum ratings ( see section "Absolute maximum ratings"). (2) When the MCU is in Halt/Active-halt mode, PA1 is automatically configured in input weak pull-up and cannot be used for waking up the device. In this mode, the output state of PA1 is not driven. It is recommended to use PA1 only in input mode if Halt/Active-halt is used in the application. (3) In the open-drain output column, ‘T’ defines a true open-drain I/O (P-buffer, weak pull-up, and protection diode to VDD are not implemented) (4) The PD1 pin is in input pull-up during the reset phase and after internal reset release. 22/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 STM8S903K3 UFQFPN32/LQFP32/SDIP32 pinout VCAP VDD [UART1_TX] [SPI_NSS] TIM5_CH3/(HS) PA3 PB7 [UART1_RX] PF4 PD1 (HS)/SWIM PD3 (HS)/AIN4/TIM5_CH2/ADC_ETR PD2 (HS)[AIN3] [TIM5_CH3] PD5 (HS)/AIN5/UART1_TX PD4 (HS)/BEEP/TIM5_CH1 [UART1_CK] PD0 (HS)/ TIM1_BKIN [CLK_CCO] PC7 (HS)/SPI_MISO [TIM1_CH2] PC6 (HS)/SPI_MOSI [TIM1_CH1] PC5 (HS)/SPI_SCK [TIM5_CH1] PC4 (HS)/TIM1_CH4/CLK_CCO [AIN2] [TIM1_CH2N] PC3 (HS)/TIM1_CH3 [TLI] [TIM1_CH1N] PC2 (HS)/TIM1_CH2 [TIM1_CH3N] PC1 (HS)/TIM1_CH1/UART1_CK [TIM1_CH2N] PE5/SPI_NSS [TIM1_CH1N] TIM1_CH1N/AIN0/(HS) PB0 VSS TIM1_CH2N/AIN1/(HS) PB1 OSCOUT/PA2 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 9 10 11 12 13 14 15 16 TIM1_ETR/AIN3/(HS) PB3 TIM1_CH3N/AIN2/(HS) PB2 OSCIN/PA1 1 2 3 4 5 6 7 8 2 [ADC_ETR] I C_SCL/(T) PB4 NRST PD6 (HS)/AIN6/UART1_RX PD7 (HS)/TLI [ TIM1_CH4] Figure 5: STM8S903K3 UFQFPN32/LQFP32 pinout PB6 2 [TIM1_BKIN] I C_SDA/(T) PB5 5.4 Pinout and pin description 1. (HS) high sink capability. 2. (T) true open drain (P-buffer and protection diode to VDD not implemented). 3. [ ] alternate function remapping option (if the same alternate function is shown twice, it indicates an exclusive choice not a duplication of the function). DocID15590 Rev 8 23/116 Pinout and pin description STM8S903K3 STM8S903F3 Figure 6: STM8S903K3 SDIP32 pinout AIN4/TIM5_CH2/ADC_ETR/PD3(HS) TIM5_CH1[UART1_CK]BEEP/PD4(HS) AIN5/UART1_TX/PD5(HS) AIN6/UART1_RX/PD6(HS) [TIM1_CH4]TLI/PD7(HS) NRST OSCIN/PA1 OSCOUT/PA2 VSS VCAP VDD [UART1_TX][SPI_NSS]/TIM5_CH3/PA3(HS) [UART1_RX]/PF4 PB7 PB6 [TIM1_BKIN]I2C_SDA/PB5(T) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 PD2(HS)[AIN3][TIM5_CH3] PD1(HS)/SWIM PD0(HS)/TIM1_BKIN[CLK_CCO] PC7(HS)/SPI_MISO[TIM1_CH2] PC6(HS)/SPI_MOSI[TIM1_CH1] PC5(HS)/SPI_SCK[TIM5_CH1] PC4(HS)/TIM1_CH4/CLK_CCO[AIN2][TIM1_CH2N] PC3(HS)/TIM1_CH3[TLI][TIM1_CH1N] PC2(HS)/TIM1_CH2[TIM1_CH3N] PC1(HS)/TIM1_CH1/UART1_CK[TIM1_CH2N] PE5/SPI_NSS[TIM1_CH1N] PB0(HS)/AIN0/TIM1_CH1N PB1(HS)/AIN1/TIM1_CH2N PB2(HS)/AIN2/TIM1_CH3N PB3(HS)[AIN3]TIM1_ETR PB4(T)/I2C_SCL[ADC_ETR] 1. (HS) high sink capability. 2. (T) true open drain (P-buffer and protection diode to VDD not implemented). 3. [ ] alternate function remapping option (if the same alternate function is shown twice, it indicates an exclusive choice not a duplication of the function). 5.5 Pin description Table 6: UFQFPN32/LQFP32/SDIP32 pin description SDIP UFQFPN/ Pin name 32 LQFP32 6 Type Input floating Output wpu Ext. interrupt High (1) sink Speed OD PP 1 NRST I/O 7 2 (2) PA1/ OSCIN I/O X X X O1 X X Port A1 Resonator/ crystal in 8 3 PA2/ OSCOUT I/O X X X O1 X X Port A2 Resonator/ crystal out 9 4 VSS S Digital ground 10 5 VCAP S 1.8 V regulator capacitor 11 6 VDD S Digital power supply 12 7 PA3/ TIM5_CH3 [SPI_NSS] [UART1_TX] I/O X X 13 8 PF4 [UART1_RX] I/O X X 14 9 PB7 I/O X X 24/116 X Main Default alternate function Alternate function after remap function [option bit] (after reset) Reset X X HS O3 X X Port A3 O1 X X Port F4 O1 X X Port B7 DocID15590 Rev 8 Timer 52 channel 3 SPI master/ slave select [AFR1]/ UART1 data transmit [AFR1:0] UART1 data receive [AFR1:0] STM8S903K3 STM8S903F3 SDIP UFQFPN/ Pin name 32 LQFP32 Pinout and pin description Type Input floating 15 10 PB6 I/O X 16 11 PB5/ I2C_SDA [TIM1_BKIN] I/O 17 12 PB4/ I2C_SCL [ADC_ETR] 18 13 19 Output wpu X Ext. interrupt High (1) sink Speed OD PP X Main Default alternate function Alternate function after remap function [option bit] (after reset) X O1 X Port B6 X X O1 (3) T I/O X X O1 (3) T PB3/ AIN3/TIM1_ETR I/O X X X HS O3 X X Port B3 Analog input 3/ Timer 1 external trigger 14 PB2/ AIN2/ TIM1_CH3N I/O X X X HS O3 X X Port B2 Analog input 2/ Timer 1 inverted channel 3 20 15 PB1/ AIN1/ TIM1_CH2N I/O X X X HS O3 X X Port B1 Analog input 1/ Timer 1 inverted channel 2 21 16 PB0/ AIN0/ TIM1_CH1N I/O X X X HS O3 X X Port B0 Analog input 0/ Timer 1 inverted channel 1 22 17 PE5/ SPI_NSS [TIM1_CH1N] I/O X X X HS O3 X X Port E5 SPI master/ slave select Timer 1 - inverted channel 1 [AFR1:0] 23 18 PC1/ TIM1_CH1/ UART1_CK [TIM1_CH2N] I/O X X X HS O3 X X Port C1 Timer 1 - channel 1 UART1 clock Timer 1 - inverted channel 2 [AFR1:0] 24 19 PC2/ TIM1_CH2 [TIM1_CH3N] I/O X X X HS O3 X X Port C2 Timer 1 - channel 2 Timer 1 - inverted channel 3 [AFR1:0] 25 20 PC3/ TIM1_CH3/TLI/[TIM1_CH1N ] I/O X X X HS O3 X X Port C3 Timer 1 - channel 3 Top level interrupt [AFR3] Timer 1 inverted channel 1 [AFR7] 26 21 PC4/ TIM1_CH4/ CLK_CCO/AIN2/[TIM1_CH2N] I/O X X X HS O3 X X Port C4 Timer 1 - channel 4 /configurable clock output Analog input 2 [AFR2]Timer 1 inverted channel 2 [AFR7] 27 22 PC5/SPI_SCK [TIM5_CH1] I/O X X X HS O3 X X Port C5 SPI clock Timer 5 channel 1 [AFR0] 28 23 PC6/ SPI_MOSI [TIM1_CH1] I/O X X X HS O3 X X Port C6 PI master out/slave in Timer 1 channel 1 [AFR0] 29 24 PC7/ SPI_MISO [TIM1_CH2] I/O X X X HS O3 X X Port C7 SPI master in/ slave out Timer 1 channel 2[AFR0] 30 25 PD0/ TIM1_BKIN [CLK_CCO] I/O X X X HS O3 X X Port D0 Timer 1 - break input Configurable clock output [AFR5] 31 26 (4) PD1/ SWIM I/O X X X HS O4 X X Port D1 SWIM data interface 32 27 PD2/AIN3/ [TIM5_CH3] I/O X X X HS O3 X X Port D2 1 28 PD3/ AIN4/ TIM5_CH2/ ADC_ETR I/O X X X HS O3 X X Port D3 Analog input 4 Timer 52 channel 2/ADC external trigger 2 29 PD4/ TIM5_CH1/ BEEP [UART1_CK] I/O X X X HS O3 X X Port D4 Timer 5 - channel 1/BEEP output 3 30 PD5/ AIN5/ UART1_TX I/O X X X HS O3 X X Port D5 Analog input 5/ UART1 data transmit 4 31 PD6/ AIN6/ UART1_RX I/O X X X HS O3 X X Port D6 Analog input 6/ UART1 data receive 5 32 PD7/ TLI [TIM1_CH4] I/O X X X HS O3 X X Port D7 Top level interrupt Port B5 Port B4 2 I C data Timer 1 - break input [AFR4] 2 I C clock ADC external trigger [AFR4] Analog input 3 [AFR2] Timer 52 - channel 3 [AFR1] UART clock [AFR2] Timer 1 - channel 4 [AFR6] (1) I/O pins used simultaneously for high current source/sink must be uniformly spaced around the package. In addition, the total driven current must respect the absolute maximum ratings ( see section "Absolute maximum ratings"). (2) When the MCU is in Halt/Active-halt mode, PA1 is automatically configured in input weak pull-up and cannot be used for waking up the device. In this mode, the output state of PA1 is not driven. It is recommended to use PA1 only in input mode if Halt/Active-halt is used in the application. (3) In the open-drain output column, ‘T’ defines a true open-drain I/O (P-buffer, weak pull-up, and protection diode to VDD are not implemented) (4) The PD1 pin is in input pull-up during the reset phase and after internal reset release. DocID15590 Rev 8 25/116 Pinout and pin description 5.6 STM8S903K3 STM8S903F3 Alternate function remapping As shown in the rightmost column of the pin description table, some alternate functions can be remapped at different I/O ports by programming one of eight AFR (alternate function remap) option bits. When the remapping option is active, the default alternate function is no longer available. To use an alternate function, the corresponding peripheral must be enabled in the peripheral registers. Alternate function remapping does not effect GPIO capabilities of the I/O ports (see the GPIO section of the family reference manual, RM0016). 26/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Memory and register map 6 Memory and register map 6.1 Memory map Figure 7: Memory map 0x00 0000 RAM (1 Kbyte) 0x00 03FF 0x00 0800 513 bytes stack Reserved 0x00 3FFF 0x00 4000 0x00 427F 0x00 4280 0x00 47FF 0x00 4800 0x00 480A 0x00 480B 0x00 4864 0x00 4865 0x00 4870 0x00 4871 0x00 4FFF 0x00 5000 640 bytes data EEPROM Reserved Option bytes Reserved Unique ID Reserved GPIO and periph. reg. 0x00 57FF 0x00 5800 Reserved 0x00 7EFF 0x00 7F00 0x00 7FFF 0x00 8000 0x00 807F 0x00 8080 0x00 9FFF 0x00 A000 CPU/SWIM/debug/ITC registers 32 interrupt vectors Flash program memory (8 Kbytes) Reserved 0x02 7FFF DocID15590 Rev 8 27/116 Memory and register map STM8S903K3 STM8S903F3 6.2 Register map 6.2.1 I/O port hardware register map Table 7: I/O port hardware register map Address Reset status Register label Register name 0x00 5000 PA_ODR Port A data output latch register 0x00 5001 PA_IDR Port A input pin value register PA_DDR Port A data direction register 0x00 0x00 5003 PA_CR1 Port A control register 1 0x00 0x00 5004 PA_CR2 Port A control register 2 0x00 0x00 5005 PB_ODR Port B data output latch register 0x00 0x00 5006 PB_IDR Port B input pin value register PB_DDR Port B data direction register 0x00 0x00 5008 PB_CR1 Port B control register 1 0x00 0x00 5009 PB_CR2 Port B control register 2 0x00 0x00 500A PC_ODR Port C data output latch register 0x00 0x00 500B PB_IDR Port C input pin value register PC_DDR Port C data direction register 0x00 0x00 500D PC_CR1 Port C control register 1 0x00 0x00 500E PC_CR2 Port C control register 2 0x00 0x00 500F PD_ODR Port D data output latch register 0x00 0x00 5010 PD_IDR Port D input pin value register PD_DDR Port D data direction register 0x00 0x00 5012 PD_CR1 Port D control register 1 0x02 0x00 5013 PD_CR2 Port D control register 2 0x00 0x00 5014 PE_ODR Port E data output latch register 0x00 0x00 5015 PE_IDR Port E input pin value register 0x00 5016 PE_DDR Port E data direction register 0x00 0x00 5017 PE_CR1 Port E control register 1 0x00 0x00 5002 0x00 5007 0x00 500C 0x00 5011 Block Port A Port B Port C Port D 0x00 (1) 0xXX (1) 0xXX (1) 0xXX (1) 0xXX (1) 0xXX Port E 28/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Address Block Memory and register map Reset status Register label Register name PE_CR2 Port E control register 2 0x00 0x00 5019 PF_ODR Port F data output latch register 0x00 0x00 501A PF_IDR Port F input pin value register PF_DDR Port F data direction register 0x00 0x00 501C PF_CR1 Port F control register 1 0x00 0x00 501D PF_CR2 Port F control register 2 0x00 0x00 5018 Port E Port F 0x00 501B (1) 0xXX (1) Depends on the external circuitry. 6.2.2 General hardware register map Table 8: General hardware register map Address 0x00 501E to Block Register label Register name Reset status FLASH_CR1 Flash control register 1 0x00 FLASH_CR2 Flash control register 2 0x00 FLASH_NCR2 Flash complementary control register 2 0xFF FLASH _FPR Flash protection register 0x00 FLASH _NFPR Flash complementary protection register 0xFF FLASH _IAPSR Flash in-application programming status register 0x00 Flash program memory unprotection register 0x00 Reserved area (60 bytes) 0x00 5059 0x00 505A Flash 0x00 505B 0x00 505C 0x00 505D 0x00 505E 0x00 505F 0x00 5060 to Reserved area (2 bytes) 0x00 5061 0x00 5062 0x00 5063 Flash FLASH _PUKR Reserved area (1 byte) DocID15590 Rev 8 29/116 Memory and register map Address 0x00 5064 0x00 5065 to STM8S903K3 STM8S903F3 Block Register label Register name Reset status Flash FLASH _DUKR Data EEPROM unprotection register 0x00 EXTI_CR1 External interrupt control register 1 0x00 EXTI_CR2 External interrupt control register 2 0x00 Reserved area (59 bytes) 0x00 509F 0x00 50A0 ITC 0x00 50A1 0x00 50A2 to Reserved area (17 bytes) 0x00 50B2 0x00 50B3 0x00 50B4 to RST RST_SR Reset status register 0xXX Reserved area (12 bytes) 0x00 50BF 0x00 50C0 CLK 0x00 50C1 0x00 50C2 0x00 50C3 0x00 50C4 0x00 50C5 0x00 50C6 0x00 50C7 0x00 50C8 0x00 50C9 0x00 50CA 30/116 CLK_ICKR Internal clock control register 0x01 CLK_ECKR External clock control register 0x00 CLK_CMSR Clock master status register 0xE1 CLK_SWR Clock master switch register 0xE1 CLK_SWCR Clock switch control register 0xXX CLK_CKDIVR Clock divider register 0x18 CLK_PCKENR1 Peripheral clock gating register 1 0xFF CLK_CSSR Clock security system register 0x00 CLK_CCOR Configurable clock control register 0x00 CLK_PCKENR2 Peripheral clock gating register 2 0xFF Reserved area (1 byte) CLK DocID15590 Rev 8 (1) STM8S903K3 STM8S903F3 Address Block 0x00 50CC 0x00 50CD 0x00 50CE to Memory and register map Register label Register name Reset status CLK_HSITRIMR HSI clock calibration trimming register 0x00 CLK_SWIMCCR SWIM clock control register 0bXXXX XXX0 WWDG_CR WWDG control register 0x7F WWDG_WR WWDR window register 0x7F Reserved area (3 bytes) 0x00 50D0 0x00 50D1 WWDG 0x00 50D2 0x00 50D3 to Reserved area (13 bytes) 00 50DF 0x00 50E0 IWDG 0x00 50E1 0x00 50E2 0x00 50E3 to IWDG_KR IWDG key register IWDG_PR IWDG prescaler register 0x00 IWDG_RLR IWDG reload register 0xFF AWU_CSR1 AWU control/status register 1 0x00 AWU_APR AWU asynchronous prescaler buffer register 0x3F AWU_TBR AWU timebase selection register 0x00 BEEP_CSR BEEP control/status register 0x1F SPI_CR1 SPI control register 1 0x00 SPI_CR2 SPI control register 2 0x00 0xXX (2) Reserved area (13 bytes) 0x00 50EF 0x00 50F0 AWU 0x00 50F1 0x00 50F2 0x00 50F3 0x00 50F4 to BEEP Reserved area (12 bytes) 0x00 50FF 0x00 5200 0x00 5201 SPI DocID15590 Rev 8 31/116 Memory and register map Address Block 0x00 5202 0x00 5203 0x00 5204 0x00 5205 0x00 5206 0x00 5207 0x00 5208 to STM8S903K3 STM8S903F3 Register label Register name Reset status SPI_ICR SPI interrupt control register 0x00 SPI_SR SPI status register 0x02 SPI_DR SPI data register 0x00 SPI_CRCPR SPI CRC polynomial register 0x07 SPI_RXCRCR SPI Rx CRC register 0xFF SPI_TXCRCR SPI Tx CRC register 0xFF Reserved area (8 bytes) 0x00 520F 2 0x00 5210 0x00 5211 0x00 5212 0x00 5213 0x00 5214 0x00 5215 0x00 5216 0x00 5217 0x00 5218 0x00 5219 0x00 521A 0x00 521B 32/116 I C 2 0x00 2 0x00 2 0x00 2 0x00 2 0x00 2 0x00 2 0x00 2 0x00 2 0x0x 2 0x00 2 0x00 I2C_CR1 I C control register 1 I2C_CR2 I C control register 2 I2C_FREQR I C frequency register I2C_OARL I C Own address register low I2C_OARH I C Own address register high Reserved I2C_DR I C data register I2C_SR1 I C status register 1 I2C_SR2 I C status register 2 I2C_SR3 I C status register 3 I2C_ITR I C interrupt control register I2C_CCRL I C Clock control register low DocID15590 Rev 8 STM8S903K3 STM8S903F3 Address Block 0x00 521C 0x00 521D 0x00 521E 0x00 521F to Memory and register map Register label Register name I2C_CCRH I C Clock control register high I2C_TRISER I C TRISE register I2C_PECR Reset status 2 0x00 2 0x02 I C packet error checking register 2 0x00 UART1_SR UART1 status register 0xC0 UART1_DR UART1 data register 0xXX UART1_BRR1 UART1 baud rate register 1 0x00 UART1_BRR2 UART1 baud rate register 2 0x00 UART1_CR1 UART1 control register 1 0x00 UART1_CR2 UART1 control register 2 0x00 UART1_CR3 UART1 control register 3 0x00 UART1_CR4 UART1 control register 4 0x00 UART1_CR5 UART1 control register 5 0x00 UART1_GTR UART1 guard time register 0x00 UART1_PSCR UART1 precaler register 0x00 TIM1_CR1 TIM1 control register 1 0x00 TIM1_CR2 TIM1 control register 2 0x00 Reserved area (17 bytes) 0x00 522F 0x00 5230 UART1 0x00 5231 0x00 5232 0x00 5233 0x00 5234 0x00 5235 0x00 5236 0x00 5237 0x00 5238 0x00 5239 0x00 523A 0x00 523B to Reserved area (21 bytes) 0x00 523F 0x00 5250 0x00 5251 TIM1 DocID15590 Rev 8 33/116 Memory and register map Address 0x00 5252 0x00 5253 0x00 5254 0x00 5255 0x00 5256 0x00 5257 0x00 5258 0x00 5259 0x00 525A 0x00 525B 0x00 525C 0x00 525D 0x00 525E 0x00 525F 0x00 5260 0x00 5261 0x00 5262 0x00 5263 0x00 5264 0x00 5265 34/116 Block STM8S903K3 STM8S903F3 Register label Register name Reset status TIM1_SMCR TIM1 slave mode control register 0x00 TIM1_ETR TIM1 external trigger register 0x00 TIM1_IER TIM1 interrupt enable register 0x00 TIM1_SR1 TIM1 status register 1 0x00 TIM1_SR2 TIM1 status register 2 0x00 TIM1_EGR TIM1 event generation register 0x00 TIM1_CCMR1 TIM1 capture/compare mode register 1 0x00 TIM1_CCMR2 TIM1 capture/compare mode register 2 0x00 TIM1_CCMR3 TIM1 capture/compare mode register 3 0x00 TIM1_CCMR4 TIM1 capture/compare mode register 4 0x00 TIM1_CCER1 TIM1_CCER2 TIM1 capture/compare enable register 1 TIM1 capture/compare enable register 2 0x00 0x00 TIM1_CNTRH TIM1 counter high 0x00 TIM1_CNTRL TIM1 counter low 0x00 TIM1_PSCRH TIM1 prescaler register high 0x00 TIM1_PSCRL TIM1 prescaler register low 0x00 TIM1_ARRH TIM1 auto-reload register high 0xFF TIM1_ARRL TIM1 auto-reload register low 0xFF TIM1_RCR TIM1 repetition counter register 0x00 TIM1_CCR1H TIM1 capture/compare register 1 high 0x00 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Address Block 0x00 5266 0x00 5267 0x00 5268 0x00 5269 0x00 526A 0x00 526B 0x00 526C 0x00 526D 0x00 526E 0x00 526F 0x00 5270 to Memory and register map Register label Register name Reset status TIM1_CCR1L TIM1 capture/compare register 1 low 0x00 TIM1_CCR2H TIM1 capture/compare register 2 high 0x00 TIM1_CCR2L TIM1 capture/compare register 2 low 0x00 TIM1_CCR3H TIM1 capture/compare register 3 high 0x00 TIM1_CCR3L TIM1 capture/compare register 3 low 0x00 TIM1_CCR4H TIM1 capture/compare register 4 high 0x00 TIM1_CCR4L TIM1 capture/compare register 4 low 0x00 TIM1_BKR TIM1 break register 0x00 TIM1_DTR TIM1 dead-time register 0x00 TIM1_OISR TIM1 output idle state register 0x00 TIM5_CR1 TIM5 control register 1 0x00 TIM5_CR2 TIM5 control register 2 0x00 TIM5_SMCR TIM5 slave mode control register 0x00 TIM5_IER TIM5 interrupt enable register 0x00 TIM5_SR1 TIM5 status register 1 0x00 TIM5_SR2 TIM5 status register 2 0x00 TIM5_EGR TIM5 event generation register 0x00 TIM5_CCMR1 TIM5 capture/compare mode register 1 0x00 Reserved area (147 bytes) 0x00 52FF 0x00 5300 0x00 5301 0x00 5302 0x00 5303 0x00 5304 0x00 5305 0x00 5306 0x00 5307 TIM5 DocID15590 Rev 8 35/116 Memory and register map Address Block 0x00 5308 0x00 5309 Register label Register name Reset status TIM5_CCMR2 TIM5 capture/compare mode register 2 0x00 TIM5_CCMR3 TIM5 capture/compare mode register 3 0x00 TIM5_CCER1 0x00 530A TIM5_CCER2 0x00 530B 00 530C0x 0x00 530D 0x00 530E 0x00 530F 0x00 5310 0x00 5311 0x00 5312 0x00 5313 0x00 5314 0x00 5315 0x00 5316 0x00 5317 to STM8S903K3 STM8S903F3 TIM5 capture/compare enable register 1 TIM5 capture/compare enable register 2 0x00 0x00 TIM5_CNTRH TIM5 counter high 0x00 TIM5_CNTRL TIM5 counter low 0x00 TIM5_PSCR TIM5 prescaler register 0x00 TIM5_ARRH TIM5 auto-reload register high 0xFF TIM5_ARRL TIM5 auto-reload register low 0xFF TIM5_CCR1H TIM5 capture/compare register 1 high 0x00 TIM5_CCR1L TIM5 capture/compare register 1 low 0x00 TIM5_CCR2H TIM5 capture/compare register 2 high 0x00 TIM5_CCR2L TIM5 capture/compare register 2 low 0x00 TIM5_CCR3H TIM5 capture/compare register 3 high 0x00 TIM5_CCR3L TIM5 capture/compare register 3 low 0x00 TIM6_CR1 TIM6 control register 1 0x00 TIM6_CR2 TIM6 control register 2 0x00 TIM6_SMCR TIM6 slave mode control register 0x00 Reserved area (43 bytes) 0x00 533F 0x00 5340 0x00 5341 0x00 5342 36/116 TIM6 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Address Block 0x00 5343 0x00 5344 0x00 5345 0x00 5346 0x00 5347 0x00 5348 0x00 5349 to Memory and register map Register label Register name Reset status TIM6_IER TIM6 interrupt enable register 0x00 TIM6_SR TIM6 status register 0x00 TIM6_EGR TIM6 event generation register 0x00 TIM6_CNTR TIM6 counter 0x00 TIM6_PSCR TIM6 prescaler register 0x00 TIM6_ARR TIM6 auto-reload register 0xFF ADC data buffer registers 0x00 ADC _CSR ADC control/status register 0x00 ADC_CR1 ADC configuration register 1 0x00 ADC_CR2 ADC configuration register 2 0x00 ADC_CR3 ADC configuration register 3 0x00 ADC_DRH ADC data register high 0xXX ADC_DRL ADC data register low 0xXX ADC_TDRH ADC Schmitt trigger disable register high 0x00 ADC_TDRL ADC Schmitt trigger disable register low 0x00 ADC_HTRH ADC high threshold register high 0x03 Reserved area (153 bytes) 0x00 53DF 0x00 53E0 to ADC1 ADC _DBxR 0x00 53F3 0x00 53F4 to Reserved area (12 bytes) 0x00 53FF 0x00 5400 0x00 5401 0x00 5402 0x00 5403 0x00 5404 0x00 5405 0x00 5406 0x00 5407 0x00 5408 ADC1 cont’d DocID15590 Rev 8 37/116 Memory and register map Address Block 0x00 5409 0x00 540A 0x00 540B 0x00 540C 0x00 540D 0x00 540E 0x00 540F 0x00 5410 to STM8S903K3 STM8S903F3 Register label Register name Reset status ADC_HTRL ADC high threshold register low 0xFF ADC_LTRH ADC low threshold register high 0x00 ADC_LTRL ADC low threshold register low 0x00 ADC_AWSRH ADC analog watchdog status register high 0x00 ADC_AWSRL ADC analog watchdog status register low 0x00 ADC _AWCRH ADC analog watchdog control register high 0x00 ADC_AWCRL ADC analog watchdog control register low 0x00 Reserved area (1008 bytes) 0x00 57FF (1) Depends on the previous reset source. (2) Write only register. 6.2.3 CPU/SWIM/debug module/interrupt controller registers Table 9: CPU/SWIM/debug module/interrupt controller registers Address Register label Register name Reset status 0x00 7F00 A Accumulator 0x00 0x00 7F01 PCE Program counter extended 0x00 0x00 7F02 PCH Program counter high 0x00 0x00 7F03 PCL Program counter low 0x00 XH X index register high 0x00 0x00 7F05 XL X index register low 0x00 0x00 7F06 YH Y index register high 0x00 0x00 7F07 YL Y index register low 0x00 0x00 7F08 SPH Stack pointer high 0x03 0x00 7F04 38/116 Block (1) CPU DocID15590 Rev 8 STM8S903K3 STM8S903F3 Address Block Memory and register map Register label Register name Reset status 0x00 7F09 SPL Stack pointer low 0xFF 0x00 7F0A CCR Condition code register 0x28 0x00 7F0B to 0x00 7F5F 0x00 7F60 Reserved area (85 bytes) CPU CFG_GCR Global configuration register 0x00 0x00 7F70 ITC_SPR1 Interrupt software priority register 1 0xFF 0x00 7F71 ITC_SPR2 Interrupt software priority register 2 0xFF 0x00 7F72 ITC_SPR3 Interrupt software priority register 3 0xFF ITC_SPR4 Interrupt software priority register 4 0xFF 0x00 7F74 ITC_SPR5 Interrupt software priority register 5 0xFF 0x00 7F75 ITC_SPR6 Interrupt software priority register 6 0xFF 0x00 7F76 ITC_SPR7 Interrupt software priority register 7 0xFF 0x00 7F77 ITC_SPR8 Interrupt software priority register 8 0xFF 0x00 7F73 ITC 0x00 7F78 to 0x00 7F79 0x00 7F80 Reserved area (2 bytes) SWIM SWIM_CSR 0x00 7F81 to 0x00 7F8F SWIM control status register 0x00 Reserved area (15 bytes) 0x00 7F90 DM_BK1RE DM breakpoint 1 register extended byte 0xFF 0x00 7F91 DM_BK1RH DM breakpoint 1 register high byte 0xFF 0x00 7F92 DM_BK1RL DM breakpoint 1 register low byte 0xFF 0x00 7F93 DM_BK2RE DM breakpoint 2 register extended byte 0xFF DM_BK2RH DM breakpoint 2 register high byte 0xFF 0x00 7F95 DM_BK2RL DM breakpoint 2 register low byte 0xFF 0x00 7F96 DM_CR1 DM debug module control register 1 0x00 0x00 7F97 DM_CR2 DM debug module control register 2 0x00 0x00 7F98 DM_CSR1 DM debug module control/status register 1 0x10 0x00 7F99 DM_CSR2 DM debug module control/status register 2 0x00 0x00 7F94 DM DocID15590 Rev 8 39/116 Memory and register map Address 0x00 7F9A Block STM8S903K3 STM8S903F3 Register label Register name Reset status DM_ENFCTR DM enable function register 0xFF 0x00 7F9B to 0x00 7F9F (1) Reserved area (5 bytes) Accessible by debug module only 40/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 7 Interrupt vector mapping Interrupt vector mapping Table 10: Interrupt mapping IRQ Source no. block Description Wakeup from Wakeup from halt mode active-halt mode Vector address RESET Reset Yes Yes 0x00 8000 TRAP Software interrupt - - 0x00 8004 0 TLI External top level interrupt - - 0x00 8008 1 AWU Auto wake up from halt - Yes 0x00 800C 2 CLK Clock controller - - 0x00 8010 3 EXTI0 Port A external interrupts Yes 4 EXTI1 Port B external interrupts Yes Yes 0x00 8018 5 EXTI2 Port C external interrupts Yes Yes 0x00 801C 6 EXTI3 Port D external interrupts Yes Yes 0x00 8020 7 EXTI4 Port E external interrupts Yes Yes 0x00 8024 8 EXTI5 Port F 9 (1) Yes (1) 0x00 8014 0x00 8028 Reserved - - 0x00 802C Yes Yes 0x00 8030 10 SPI End of transfer 11 TIM1 TIM1 update/ overflow/ underflow/ trigger/ break - 0x00 8034 12 TIM1 TIM1 capture/ compare - - 0x00 8038 13 TIM5 TIM5 update/ overflow/ trigger - - 0x00 803C 14 TIM5 TIM5 capture/ compare - - 0x00 8040 15 Reserved - - 0x00 8044 16 Reserved - - 0x00 8048 17 UART1 Tx complete - - 0x00 804C 18 UART1 Receive register DATA FULL - - 0x00 8050 19 I C I C interrupt Yes Yes 0x00 8054 20 Reserved - - 0x00 8058 21 Reserved - - 0x00 805C 2 2 DocID15590 Rev 8 41/116 Interrupt vector mapping STM8S903K3 STM8S903F3 IRQ Source no. block Description Wakeup from Wakeup from halt mode active-halt mode Vector address 22 ADC1 ADC1 end of conversion/ analog watchdog interrupt - - 0x00 8060 23 TIM6 TIM6 update/ overflow/ trigger - - 0x00 8064 24 Flash EOP/ WR_PG_DIS - - 0x00 8068 Reserved (1) 0x00 806C to 0x00 807C Except PA1 42/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 8 Option bytes Option bytes Option bytes contain configurations for device hardware features as well as the memory protection of the device. They are stored in a dedicated block of the memory. Except for the ROP (read-out protection) byte, each option byte has to be stored twice, in a regular form (OPTx) and a complemented one (NOPTx) for redundancy. Option bytes can be modified in ICP mode (via SWIM) by accessing the EEPROM address shown in the table below. Option bytes can also be modified ‘on the fly’ by the application in IAP mode, except the ROP option that can only be modified in ICP mode (via SWIM). Refer to the STM8S Flash programming manual (PM0051) and STM8 SWIM communication protocol and debug module user manual (UM0470) for information on SWIM programming procedures. Table 11: Option bytes Addr. Option name Option Option bits byte no. 7 6 5 4 3 2 1 0 Factory default setting 0x4800 Read-out protection (ROP) OPT0 ROP [7:0] 0x00 0x4801 User boot code(UBC) OPT1 UBC [7:0] 0x00 NOPT1 NUBC [7:0] 0xFF OPT2 AFR7 AFR6 AFR5 AFR4 AFR3 AFR2 AFR1 AFR0 NOPT2 NAFR7 NAFR6 NAFR5 NAFR4 NAFR3 NAFR2 NAFR1 NAFR0 0xFF OPT3 Reserved HSI TRIM LSI_ EN IWDG _HW WWDG _HW WWDG _HALT 0x00 NOPT3 Reserved NHSI TRIM NLSI_ EN NIWDG _HW NWWDG _HW NWW G_HALT 0xFF OPT4 Reserved EXT CLK CKAWU SEL PRS C1 PRS C0 0x00 NOPT4 Reserved NEXT CLK NCKA WUSEL NPRSC1 NPR SC0 0xFF OPT5 HSECNT [7:0] 0x00 NOPT5 NHSECNT [7:0] 0xFF 0x4802 0x4803 0x4804 0x4805h Alternate function remapping (AFR) Miscell. option 0x4806 0x4807 Clock option 0x4808 0x4809 HSE clock startup 0x480A 0x00 Table 12: Option byte description Option byte no. OPT0 Description ROP[7:0] Memory readout protection (ROP) 0xAA: Enable readout protection (write access via SWIM protocol) DocID15590 Rev 8 43/116 Option bytes Option byte no. STM8S903K3 STM8S903F3 Description Note: Refer to the family reference manual (RM0016) section on Flash/EEPROM memory readout protection for details. OPT1 UBC[7:0] User boot code area 0x00: no UBC, no write-protection 0x01: Page 0 defined as UBC, memory write-protected 0x02: Pages 0 to 1 defined as UBC, memory write-protected. Page 0 and 1 contain the interrupt vectors. ... 0x7F: Pages 0 to 126 defined as UBC, memory write-protected Other values: Pages 0 to 127 defined as UBC, memory write-protected Note: Refer to the family reference manual (RM0016) section on Flash write protection for more details. OPT2 AFR[7:0] Refer to following section for alternate function remapping decriptions of bits [7:2] and [1:0] respectively. OPT3 HSITRIM:High speed internal clock trimming register size 0: 3-bit trimming supported in CLK_HSITRIMR register 1: 4-bit trimming supported in CLK_HSITRIMR register LSI_EN:Low speed internal clock enable 0: LSI clock is not available as CPU clock source 1: LSI clock is available as CPU clock source IWDG_HW: Independent watchdog 0: IWDG Independent watchdog activated by software 1: IWDG Independent watchdog activated by hardware WWDG_HW: Window watchdog activation 0: WWDG window watchdog activated by software 1: WWDG window watchdog activated by hardware WWDG_HALT: Window watchdog reset on halt 44/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Option byte no. Option bytes Description 0: No reset generated on halt if WWDG active 1: Reset generated on halt if WWDG active OPT4 EXTCLK: External clock selection 0: External crystal connected to OSCIN/OSCOUT 1: External clock signal on OSCIN CKAWUSEL:Auto wake-up unit/clock 0: LSI clock source selected for AWU 1: HSE clock with prescaler selected as clock source for for AWU PRSC[1:0] AWU clock prescaler 0x: 16 MHz to 128 kHz prescaler 10: 8 MHz to 128 kHz prescaler 11: 4 MHz to 128 kHz prescaler OPT5 HSECNT[7:0]:HSE crystal oscillator stabilization time 0x00: 2048 HSE cycles 0xB4: 128 HSE cycles 0xD2: 8 HSE cycles 0xE1: 0.5 HSE cycles 8.1 STM8S903K3/F3 alternate function remapping bits Table 13: STM8S903K3 alternate function remapping bits [7:2] for 32-pin packages Option byte no. OPT2 (1) Description AFR7 Alternate function remapping option 7 (2) 0: AFR7 remapping option inactive: Default alternate functions . 1: Port C3 alternate function = TIM1_CH1N; port C4 alternate function = TIM1_CH2N. AFR6 Alternate function remapping option 6 (2) 0: AFR6 remapping option inactive: Default alternate function . 1: Port D7 alternate function = TIM1_CH4. DocID15590 Rev 8 45/116 Option bytes STM8S903K3 STM8S903F3 Option byte no. (1) Description AFR5 Alternate function remapping option 5 (2) 0: AFR5 remapping option inactive: Default alternate function . 1: Port D0 alternate function = CLK_CCO. AFR4 Alternate function remapping option 4 (2) 0: AFR4 remapping option inactive: Default alternate functions . 1: Port B4 alternate function = ADC_ETR; port B5 alternate function = TIM1_BKIN. AFR3 Alternate function remapping option 3 (2) 0: AFR3 remapping option inactive: Default alternate function . 1: Port C3 alternate function = TLI. AFR2 Alternate function remapping option 2 (2) 0: AFR2 remapping option inactive: Default alternate functions . 1: Port C4 alternate function = AIN2; port D2 alternate function = AIN3; port D4 alternate function = UART1_CK. (1) Do not use more than one remapping option in the same port. (2) Refer to pinout description. Table 14: STM8S903F3 alternate function remapping bits [7:2] for 20-pin packages Option byte no. OPT2 (1) Description AFR7 Alternate function remapping option 7 (2) 0: AFR7 remapping option inactive: Default alternate functions 1: Port C3 alternate function = TIM1_CH1N; port C4 alternate function = TIM1_CH2N. AFR6 Alternate function remapping option 6 Reserved. AFR5 Alternate function remapping option 5 Reserved. AFR4 Alternate function remapping option 4 (2) 0: AFR4 remapping option inactive: Default alternate functions . 1: Port B4 alternate function = ADC_ETR; port B5 alternate function = TIM1_BKIN. AFR3 Alternate function remapping option 3 46/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Option byte no. Option bytes (1) Description (2) 0: AFR3 remapping option inactive: Default alternate function . 1: Port C3 alternate function = TLI. AFR2 Alternate function remapping option 2 Reserved. (1) Do not use more than one remapping option in the same port. (2) Refer to pinout description. Table 15: STM8S903K3 alternate function remapping bits [1:0] for 32-pin packages AFR1 option bit value AFR0 option bit value I/O port 0 0 AFR1 and AFR0 remapping options inactive: (1) Default alternate functions 0 1 PC5 TIM5_CH1 PC6 TIM1_CH1 PC7 TIM1_CH2 1 1 (1) 0 1 PA3 Alternate function mapping SPI_NSS PD2 TIM5_CH3 PD2 TIM5_CH3 PC5 TIM5_CH1 PC6 TIM1_CH1 PC7 TIM1_CH2 PC2 TIM1_CH3N PC1 TIM1_CH2N PE5 TIM1_CH1N PA3 UART1_TX PF4 UART1_RX Refer to pinout description. DocID15590 Rev 8 47/116 Option bytes STM8S903K3 STM8S903F3 Table 16: STM8S903F3 alternate function remapping bits [1:0] for 20-pin packages AFR1 option bit value AFR0 option bit value I/O port 0 0 AFR1 and AFR0 remapping options inactive: (1) Default alternate functions 0 1 PC5 TIM5_CH1 PC6 TIM1_CH1 PC7 TIM1_CH2 1 1 (1) 48/116 0 1 PA3 Alternate function mapping SPI_NSS PD2 TIM5_CH3 PD2 TIM5_CH3 PC5 TIM5_CH1 PC6 TIM1_CH1 PC7 TIM1_CH2 PC2 — PC1 — PE5 TIM1_CH1N PA3 UART1_TX PF4 UART1_RX Refer to pinout description. DocID15590 Rev 8 STM8S903K3 STM8S903F3 9 Unique ID Unique ID The devices feature a 96-bit unique device identifier which provides a reference number that is unique for any device and in any context. The 96 bits of the identifier can never be altered by the user. The unique device identifier can be read in single bytes and may then be concatenated using a custom algorithm. The unique device identifier is ideally suited: For use as serial numbers • use as security keys to increase the code security in the program memory while using • For and combining this unique ID with software cryptograhic primitives and protocols before programming the internal memory. • To activate secure boot processes Table 17: Unique ID registers (96 bits) Address Content description 0x4865 0x4866 0x4867 Unique ID bits 7 6 5 4 3 1 0 U_ID[7:0] X co-ordinate on the wafer U_ID[15:8] U_ID[23:16] 0x4868 Y co-ordinate on the wafer 0x4869 Wafer number U_ID[39:32] U_ID[31:24] 0x486A U_ID[47:40] 0x486B U_ID[55:48] 0x486C U_ID[63:56] 0x486D 2 Lot number U_ID[71:64] 0x486E U_ID[79:72] 0x486F U_ID[87:80] 0x4870 U_ID[95:88] DocID15590 Rev 8 49/116 Electrical characteristics STM8S903K3 STM8S903F3 10 Electrical characteristics 10.1 Parameter conditions Unless otherwise specified, all voltages are referred to VSS. 10.1.1 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 ± 3 Σ). 10.1.2 Typical values Unless otherwise specified, typical data are based on TA = 25 °C, 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 ± 2 Σ). 10.1.3 Typical curves Unless otherwise specified, all typical curves are given only as design guidelines and are not tested. 10.1.4 Loading capacitor The loading conditions used for pin parameter measurement are shown in the following figure. Figure 8: Pin loading conditions STM8 pin 50 pF 10.1.5 Pin input voltage The input voltage measurement on a pin of the device is described in the following figure. 50/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 9: Pin input voltage STM8 pin VIN 10.2 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 18: Voltage characteristics Symbol Ratings Min VDDx - VSS Supply voltage VIN Input voltage on true open drain pins (1) (2) (2) Input voltage on any other pin |VDDx - VDD| |VSSx - VSS| VESD (1) Variations between different power pins Max Unit -0.3 6.5 VSS - 0.3 6.5 VSS - 0.3 VDD + 0.3 - 50 V mV Variations between all the different ground pins - 50 See "Absolute maximum ratings (electrical sensitivity)" Electrostatic discharge voltage All power (VDD) and ground (VSS) pins must always be connected to the external power 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 VIN<VSS. For true open-drain pads, there is no positive injection current, and the corresponding VIN maximum must always be respected Table 19: Current characteristics Symbol IVDD Ratings (1) Unit 100 mA Max (2) Total current into VDD power lines (source) DocID15590 Rev 8 51/116 Electrical characteristics STM8S903K3 STM8S903F3 Symbol Ratings IVSS Total current out of VSS ground lines (sink) 80 IIO Output current sunk by any I/O and control pin 20 IINJ(PIN) (1) Max (2) Output current source by any I/Os and control pin - 20 Injected current on NRST pin ±4 Injected current on OSCIN pin ±4 Unit (3) (4) (5) ±4 Injected current on any other pin ΣI INJ(PIN) (3) (5) Total injected current (sum of all I/O and control pins) ± 20 (1) Data based on characterization results, not tested in production. (2) All power (VDD) and ground (VSS) pins must always be connected to the external supply. (3) 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 VIN<VSS. For true open-drain pads, there is no positive injection current, and the corresponding VIN maximum must always be respected (4) ADC accuracy vs. negative injection current: Injecting negative current on any of the analog input pins should be avoided as this significantly reduces the accuracy of the conversion being performed on another analog input. It is recommended to add a Schottky diode (pin to ground) to standard analog pins which may potentially inject negative current. Any positive injection current within the limits specified for IINJ(PIN) and ΣIINJ(PIN) in the I/O port pin characteristics section does not affect the ADC accuracy. (5) When several inputs are submitted to a current injection, the maximum ΣIINJ(PIN) is the absolute sum of the positive and negative injected currents (instantaneous values). These results are based on characterization with ΣIINJ(PIN) maximum current injection on four I/O port pins of the device. Table 20: Thermal characteristics 52/116 Symbol Ratings Value TSTG Storage temperature range TJ Maximum junction temperature Unit -65 to +150 °C DocID15590 Rev 8 150 STM8S903K3 STM8S903F3 10.3 Electrical characteristics Operating conditions Table 21: General operating conditions Symbol Parameter fCPU Internal CPU clock frequency VDD VCAP (1) Conditions (3) TJ Unit 16 MHz Standard operating voltage 2.95 5.5 V CEXT: capacitance of external capacitor 470 3300 nF - 0.3 Ω ESL of external capacitor - 15 nH Power dissipation at TA = 85 °C TSSOP20 for suffix 6 SO20W - 182 mW - 1000 UFQFPN20 - 198 LQFP32 - 333 UFQFPN32 - 526 SDIP32 - 333 TSSOP20 - 45 SO20W - 250 UFQFPN20 - 49 LQFP32 - 83 UFQFPN32 - 132 SDIP32 - 83 Ambient temperature for 6 suffix Maximum power dissipation version -40 85 Ambient temperature for 3 suffix Maximum power dissipation version -40 125 Junction temperature range 6 suffix version -40 105 3 suffix version -40 130 (2) at 1 MHz Power dissipation at TA = 125 °C for suffix 3 TA Max 0 ESR of external capacitor PD Min °C (1) Care should be taken when selecting the capacitor, due to its tolerance, as well as the parameter dependency on temperature, DC bias and frequency in addition to other factors. The parameter maximum value must be respected for the full application range. (2) This frequency of 1 MHz as a condition for VCAP parameters is given by design of internal regulator DocID15590 Rev 8 53/116 Electrical characteristics (3) STM8S903K3 STM8S903F3 To calculate PDmax(TA), use the formula PDmax = (TJmax - TA)/ΘJA (see Thermal characteristics). Figure 10: fCPUmax versus VDD f CPU (MHz) Functionality 16 not guaranteed in this area 12 Functionality guaranteed @TA-40 to 125 °C 8 4 0 2.95 4.0 5.0 5.5 Supply voltage Table 22: Operating conditions at power-up/power-down Symbol Parameter Conditions tVDD VDD rise time rate (1) VDD fall time rate Min Typ Max 2 ∞ 2 ∞ tTEMP Reset release delay VDD rising VIT+ Power-on reset threshold 2.6 VIT- Brown-out reset threshold 2.5 VHYS(BOR) Brown-out reset hysteresis Unit µs/V 1.7 ms 2.7 2.85 V 2.65 2.8 70 mV (1) Reset is always generated after a tTEMP delay. The application must ensure that VDD is still above the minimum ooperating voltage (VDD min) when the tTEMP delay has elapsed. 10.3.1 VCAP external capacitor Stabilization for the main regulator is achieved connecting an external capacitor CEXT to the VCAP pin. CEXT is specified in the Operating conditions section. Care should be taken to limit the series inductance to less than 15 nH. 54/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 11: External capacitor CEXT C ESR ESL Rleak 1. ESR is the equivalent series resistance and ESL is the equivalent inductance. 10.3.2 Supply current characteristics The current consumption is measured as described in Pin input voltage. 10.3.2.1 Total current consumption in run mode The MCU is placed under the following conditions: All I/O pins in input mode with a static value at VDD or VSS (no load) • peripherals are disabled (clock stopped by peripheral clock gating registers) except if • All explicitly mentioned. Subject to general operating conditions for VDD and TA. Table 23: Total current consumption with code execution in run mode at VDD = 5 V Symbol Parameter Conditions Typ HSE crystal osc. (16 MHz) fCPU = fMASTER = IDD(RUN) Supply current fCPU = fMASTER/128 = in run mode, 125 kHz code executed from RAM fCPU = fMASTER/128 = 15.625 kHz fCPU = fMASTER = 128 kHz Supply current in run mode, fCPU = fMASTER = code executed 16 MHz from Flash IDD(RUN) Supply current fCPU = fMASTER = in run mode, 2 MHz code executed from Flash 2.3 - 2 2.35 HSI RC osc. (16 MHz) 1.7 2 HSE user ext. clock (16 MHz) 0.86 - HSI RC osc. (16 MHz) 0.7 0.87 HSI RC osc. (16 MHz/8) 0.46 0.58 LSI RC osc. (128 kHz) 0.41 0.55 HSE crystal osc. (16 MHz) 4.5 - HSE user ext. clock (16 MHz) 4.3 4.75 HSI RC osc. (16 MHz) 3.7 4.5 0.84 1.05 HSE user ext. clock (16 MHz) 16 MHz (1) Max (2) HSI RC osc. (16 MHz/8) DocID15590 Rev 8 Unit mA mA 55/116 Electrical characteristics Symbol Parameter STM8S903K3 STM8S903F3 Conditions fCPU = fMASTER/128 = 125 kHz fCPU = fMASTER/128 = 15.625 kHz fCPU = fMASTER = 128 kHz (1) Typ Max HSI RC osc. (16 MHz) 0.72 0.9 HSI RC osc. (16 MHz/8) 0.46 0.58 LSI RC osc. (128 kHz) 0.42 0.57 (1) Data based on characterization results, not tested in production. (2) Default clock configuration measured with all peripherals off. Unit Table 24: Total current consumption with code execution in run mode at VDD = 3.3 V Symbol Parameter Conditions Typ HSE crystal osc. (16 MHz) fCPU = fMASTER = 16 MHz Supply current fCPU = fMASTER/ in run mode, 128 = 125 kHz code executed from RAM fCPU = fMASTER/ 128 = 15.625 kHz fCPU = fMASTER = IDD(RUN) 128 kHz 1.8 - 2 2.3 HSI RC osc. (16 MHz) 1.5 2 HSE user ext. clock (16 MHz) 0.81 - HSI RC osc. (16 MHz) 0.7 0.87 HSI RC osc. (16 MHz/8) 0.46 0.58 LSI RC osc. (128 kHz) 0.41 0.55 HSE user ext. clock (16 MHz) HSE crystal osc. (16 MHz) 16 MHz Supply current f CPU = fMASTER = in run mode, code executed 2 MHz from Flash fCPU = fMASTER/ fCPU = fMASTER/ 56/116 Unit mA fCPU = fMASTER = 128 = 125 kHz (1) Max 4 - HSE user ext. clock (16 MHz) 3.9 4.7 HSI RC osc. (16 MHz) 3.7 4.5 HSI RC osc. (16 MHz/8) 0.84 1.05 HSI RC osc. (16 MHz) 0.72 0.9 HSI RC osc. (16 MHz/8) 0.46 0.58 (2) DocID15590 Rev 8 STM8S903K3 STM8S903F3 Symbol Parameter Electrical characteristics Conditions Typ (1) Max Unit 128 = 15.625 kHz fCPU = fMASTER = LSI RC osc. (128 kHz) 128 kHz (1) Data based on characterization results, not tested in production. (2) Default clock configuration measured with all peripherals off. 10.3.2.2 0.42 0.57 Total current consumption in wait mode Table 25: Total current consumption in wait mode at VDD = 5 V Symbol Parameter Conditions fCPU = fMASTER = 16 MHz IDD(WFI) Typ HSE crystal osc. (16 MHz) 1.6 - HSE user ext. clock (16 MHz) 1.1 1.3 HSI RC osc. (16 MHz) 0.89 1.1 0.7 0.88 fCPU = fMASTER/128 = Supply HSI RC osc. (16 MHz) current in 125 kHz wait mode fCPU = fMASTER/128 = (2) HSI RC osc. (16 MHz/8) 15.625 kHz fCPU = fMASTER = 128 kHz (1) Max mA LSI RC osc. (128 kHz) (1) Data based on characterization results, not tested in production. (2) Default clock configuration measured with all peripherals off. Unit 0.45 0.57 0.4 0.54 Table 26: Total current consumption in wait mode at VDD = 3.3 V Symbol Parameter Conditions Typ Max (1) Unit HSE crystal osc. IDD(WFI) Supply current in wait mode fCPU = fMASTER = (16 MHz) 16 MHz HSE user ext. clock 1.1 mA (16 MHz) DocID15590 Rev 8 1.1 1.3 57/116 Electrical characteristics Symbol Parameter STM8S903K3 STM8S903F3 Conditions Typ Max (1) Unit HSI RC osc. (16 MHz) fCPU = fMASTER/ 128 = HSI RC osc. 125 kHz (16 MHz) fCPU = fMASTER/ 128 = HSI RC osc. (2) 15.625 kHz (16 MHz/8) fCPU = fMASTER= LSI RC osc. 128 kHz (128 kHz) (1) Data based on characterization results, not tested in production. (2) Default clock configuration measured with all peripherals off. 10.3.2.3 0.89 1.1 0.7 0.88 0.45 0.57 0.4 0.54 Total current consumption in active halt mode Table 27: Total current consumption in active halt mode at VDD = 5 V Conditions Main voltage regulator (2) (MVR) Flash mode Supply current IDD(AH) in active halt mode On Operating mode Supply current IDD(AH) in active halt mode On Operating mode Supply current IDD(AH) in active halt mode On Power-down mode Supply current IDD(AH) in active halt mode On Power-down mode Supply current IDD(AH) in active halt mode Off Operating mode Symbol Parameter 58/116 (3) Clock source Typ Max Max at 85 at 125 °C Unit °C (1) (1) 1030 - - 200 260 300 970 - - 150 200 230 66 85 110 HSE crystal osc. (16 MHz) LSI RC osc. (128 kHz) HSE crystal osc. (16 MHz) LSI RC osc. (128 kHz) LSI RC osc. (128 kHz) DocID15590 Rev 8 μA STM8S903K3 STM8S903F3 Electrical characteristics Conditions Symbol Parameter Main voltage regulator (2) (MVR) Supply current IDD(AH) in active halt mode (3) Flash mode Max Max at 85 at 125 °C °C Unit Typ Clock source (1) (1) 20 40 LSI RC osc. Power-down mode 10 (128 kHz) (1) Data based on characterization results, not tested in production (2) Configured by the REGAH bit in the CLK_ICKR register. (3) Configured by the AHALT bit in the FLASH_CR1 register. Table 28: Total current consumption in active halt mode at VDD = 3.3 V Conditions Symbol Parameter IDD(AH) Supply current in active halt mode Main voltage regulator (2) (MVR) On (3) Flash mode Clock source HSE crystal Operating mode osc. (16 MHz) Typ Max at Max at 85 °C 125 °C Unit (1) (1) 550 - - 200 260 290 970 - - 150 200 230 66 80 105 10 18 35 μA LSI RC osc. IDD(AH) Supply current in active halt mode IDD(AH) Operating mode On Power-down mode IDD(AH) IDD(AH) IDD(AH) Supply current in active halt mode (128 kHz) HSE crystal osc. (16 MHz) (128 kHz) Operating mode LSI RC osc. Off Power-down mode μA LSI RC osc. (128 kHz) (1) Data based on characterization results, not tested in production (2) Configured by the REGAH bit in the CLK_ICKR register. (3) Configured by the AHALT bit in the FLASH_CR1 register. DocID15590 Rev 8 59/116 Electrical characteristics 10.3.2.4 STM8S903K3 STM8S903F3 Total current consumption in halt mode Table 29: Total current consumption in halt mode at VDD = 5 V Symbol Parameter Conditions Typ Supply current in halt mode Flash in operating mode, HSI clock after wakeup 63 IDD(H) (1) Max at Max at (1) (1) 85 °C 125 °C 75 Unit 105 μA Flash in power-down mode, HSI clock after wakeup 6.0 20 55 Data based on characterization results, not tested in production Table 30: Total current consumption in halt mode at VDD = 3.3 V Symbol Parameter Conditions Typ Supply current in halt mode Flash in operating mode, HSI clock after wakeup 60 IDD(H) (1) Max at Max at (1) (1) 85 °C 125 °C 75 Unit 100 μA Flash in power-down mode, HSI clock after wakeup 4.5 17 30 Data based on characterization results, not tested in production 10.3.2.5 Low power mode wakeup times Table 31: Wakeup times Symbol Parameter Wakeup time from tWU(WFI) - See (2) note 0.56 - fCPU = fMASTER = 16 MHz Wakeup time active MVR voltage halt mode to run regulator (4) Flash in operating (5) mode (after on Wakeup time active MVR voltage Flash in HSI halt mode to run regulator (after mode (4) on power-down (5) mode DocID15590 Rev 8 Max Unit HSI mode (3) 60/116 0 to 16 MHz mode (3) tWU(AH) Typ wait mode to run (3) (1) Conditions (6) 1 (6) 2 wakeup) wakeup) (6) 3 - μs STM8S903K3 STM8S903F3 Symbol Parameter Conditions Wakeup time active MVR voltage halt mode to run regulator (3) (4) Typ Flash in operating (5) mode Wakeup time active MVR voltage Flash in HSI halt mode to run regulator (after power-down (5) off Wakeup time from Flash in operating mode mode (6) - (6) - 48 50 wakeup) (5) halt mode to run (3) Unit wakeup) mode mode (5) Flash in power-down mode (1) Data guaranteed by design, not tested in production. (2) tWU(WFI) = 2 x 1/fmaster + 6 x 1/fCPU. (3) Measured from interrupt event to interrupt vector fetch. (4) Configured by the REGAH bit in the CLK_ICKR register. (5) Configured by the AHALT bit in the FLASH_CR1 register. (6) Plus 1 LSI clock depending on synchronization. 10.3.2.6 (after off (4) (1) Max HSI mode (3) tWU(H) Electrical characteristics 52 - 54 - Total current consumption and timing in forced reset state Table 32: Total current consumption and timing in forced reset state Symbol Parameter Conditions Typ IDD(R) Supply current in reset VDD = 5 V 400 - VDD = 3.3 V 300 - - 150 (2) state tRESETBL Unit μA Reset pin release to vector fetch (1) Data guaranteed by design, not tested in production. (2) Characterized with all I/Os tied to VSS. 10.3.2.7 (1) Max μs Current consumption of on-chip peripherals Subject to general operating conditions for VDD and TA. DocID15590 Rev 8 61/116 Electrical characteristics STM8S903K3 STM8S903F3 HSI internal RC/fCPU = fMASTER = 16 MHz, VDD = 5 V Table 33: Peripheral current consumption Symbol Parameter Typ. 210 (1) 130 IDD(TIM1) TIM1 supply current IDD(TIM5) TIM5 supply current IDD(TIM6) TIM6 timer supply current IDD(UART1) UART1 supply current IDD(SPI) SPI supply current IDD(I 2 (1) IDD(ADC1) µA 50 (2) 2 C) Unit (1) 120 (2) 45 (2) 65 I C supply current (3) ADC1 supply current when converting 1000 (1) Data based on a differential IDD measurement between reset configuration and timer counter running at 16 MHz. No IC/OC programmed (no I/O pads toggling). Not tested in production. (2) Data based on a differential IDD measurement between the on-chip peripheral when kept under reset and not clocked and the on-chip peripheral when clocked and not kept under reset. No I/O pads toggling. Not tested in production. (3) Data based on a differential IDD measurement between reset configuration and continuous A/D conversions. Not tested in production. 10.3.2.8 Current consumption curves The following figures show typical current consumption measured with code executing in RAM. Figure 12: Typ IDD(RUN) vs. VDD HSE user external clock, fCPU = 16 MHz 62/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 13: Typ IDD(RUN) vs. fCPU HSE user external clock, VDD = 5 V Figure 14: Typ IDD(RUN) vs. VDD HSI RC osc, fCPU = 16 MHz DocID15590 Rev 8 63/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 15: Typ IDD(WFI) vs. VDD HSE user external clock, fCPU = 16 MHz Figure 16: Typ IDD(WFI) vs. fCPU HSE user external clock, VDD = 5 V Figure 17: Typ IDD(WFI) vs. VDD HSI RC osc, fCPU = 16 MHz 64/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 10.3.3 Electrical characteristics External clock sources and timing characteristics HSE user external clock Subject to general operating conditions for VDD and TA. Table 34: HSE user external clock characteristics Symbol Parameter fHSE_ext User external clock source frequency 0 16 OSCIN input pin high level voltage 0.7 x VDD VDD + 0.3 V OSCIN input pin low level voltage VSS 0.3 x VDD -1 +1 VHSEH (1) VHSEL (1) ILEAK_HSE (1) Conditions Min Max Unit MHz V OSCIN input leakage current VSS < VIN < VDD μA Data based on characterization results, not tested in production. Figure 18: HSE external clocksource V HSEH V HSEL External clock source fHSE OSCIN STM8 HSE crystal/ceramic resonator oscillator The HSE clock can be supplied with a 1 to 16 MHz crystal/ceramic resonator oscillator. All the information given in this paragraph is based on characterization results with specified typical external components. In the application, the resonator and the load capacitors have to be placed as close as possible to the oscillator pins in order to minimize output distortion and start-up stabilization time. Refer to the crystal resonator manufacturer for more details (frequency, package, accuracy...). Table 35: HSE oscillator characteristics Symbol Parameter fHSE External high speed oscillator frequency Conditions Min 1 DocID15590 Rev 8 Typ - Max Unit 16 MHz 65/116 Electrical characteristics STM8S903K3 STM8S903F3 Symbol Parameter RF Feedback resistor (1) C Conditions Min Typ Max Unit - 220 - kΩ - - 20 pF - - Recommended load (2) capacitance IDD(HSE) HSE oscillator power consumption C = 20 pF, 6 (startup) (3) fOSC = 16 MHz 1.6 (stabilized) mA C = 10 pF, - 6 (startup) - (3) fOSC =16 MHz gm 1.2 (stabilized) Oscillator transconductance tSU(HSE) (1) (4) Startup time VDD is stabilized 5 - - mA/V - 1 - ms C is approximately equivalent to 2 x crystal Cload. (2) The oscillator selection can be optimized in terms of supply current using a high quality resonator with small Rm value. Refer to crystal manufacturer for more details (3) Data based on characterization results, not tested in production. (4) tSU(HSE) is the start-up time measured from the moment it is enabled (by software) to a stabilized 16 MHz oscillation is reached. This value is measured for a standard crystal resonator and it can vary significantly with the crystal manufacturer. Figure 19: HSE oscillator circuit diagram Rm f HSE to core Lm CO RF CL1 Cm OSCIN gm Resonator Resonator OSCOUT CL2 STM8 HSE oscillator critical g m equation 2 2 gmcrit= (2 × Π × fHSE) × Rm(2Co + C) 66/116 Consumption control DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Rm: Notional resistance (see crystal specification) Lm: Notional inductance (see crystal specification) Cm: Notional capacitance (see crystal specification) Co: Shunt capacitance (see crystal specification) CL1= CL2 = C: Grounded external capacitance gm >> gmcrit 10.3.4 Internal clock sources and timing characteristics Subject to general operating conditions for VDD and TA. High speed internal RC oscillator (HSI) Table 36: HSI oscillator characteristics Symbol Parameter fHSI Frequency ACCHSI Accuracy of HSI User-trimmed with oscillator Conditions Min Typ Max - 16 - - 1.0 -1 - 1 CLK_HSITRIMR register for given VDD and TA Unit - MHz (3) (1) conditions (2) Accuracy of HSI VDD = 5 V, TA = 25°C % oscillator (factory calibrated) VDD = 5 V, -2.0 - 2.0 25 °C ≤ TA ≤ 85 °C 2.95 ≤ VDD≤ 5.5 V, (2) (2) -3.0 - 3.0 - - 1.0 - 170 250 -40 °C ≤ TA ≤ 125 °C tsu(HSI) HSI oscillator wakeup time including (3) μs (2) μA calibration IDD(HSI) HSI oscillator power consumption (1) Refer to application note. (2) Data based on characterization results, not tested in production. (3) Guaranteed by design, not tested in production. DocID15590 Rev 8 67/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 20: Typical HSI frequency variation vs VDD @ 4 temperatures Low speed internal RC oscillator (LSI) Subject to general operating conditions for VDD and TA. Table 37: LSI oscillator characteristics Symbol Parameter fLSI Frequency tsu(LSI) IDD(LSI) Min Typ Max Unit 110 128 150 kHz LSI oscillator wake-up time - - 7 μs LSI oscillator power consumption - 5 - μA Figure 21: Typical LSI frequency variation vs VDD @ 4 temperatures 68/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 10.3.5 Electrical characteristics Memory characteristics RAM and hardware registers Table 38: RAM and hardware registers Symbol Parameter VRM Data retention mode (1) Conditions Min Unit Halt mode (or reset) VIT-max (2) V (1) Minimum supply voltage without losing data stored in RAM (in halt mode or under reset) or in hardware registers (only in halt mode). Guaranteed by design, not tested in production. (2) Refer to the Operating conditions section for the value of VIT-max Flash program memory/data EEPROM memory Table 39: Flash program memory/data EEPROM memory Symbol Parameter VDD Conditions (1) Typ 2.95 - 5.5 - 6 6.6 Min Max Unit Operating voltage (all modes, execution/ fCPU ≤ 16 MHz V write/erase) tprog Standard programming time (including erase) for byte/word/block (1 byte/ 4 bytes/64 bytes) ms Fast programming time for 1 block (64 bytes) terase 3 3.33 - 3 3.33 10 k - - Erase time for 1 block (64 bytes) NRW - (2) Erase/write cycles TA = +85 °C (program memory) cycles Erase/write cycles (2) (data memory) tRET TA = +125 °C 300 k 1M - TRET = 55°C 20 - - Data retention (program and data memory) after 10k erase/write cycles at years TA = +55 °C DocID15590 Rev 8 69/116 Electrical characteristics STM8S903K3 STM8S903F3 Symbol Parameter Conditions Typ Max 1 - - - 2 - (1) Min Unit Data retention (data memory) after 300k erase/write cycles at TRET = 85°C TA = +125 °C IDD Supply current (Flash programming or erasing mA for 1 to 128 bytes) (1) Data based on characterization results, not tested in production. (2) The physical granularity of the memory is 4 bytes, so cycling is performed on 4 bytes even when a write/erase operation addresses a single byte. 10.3.6 I/O port pin characteristics General characteristics Subject to general operating conditions for VDD and TA unless otherwise specified. All unused pins must be kept at a fixed voltage: using the output mode of the I/O for example or an external pull-up or pull-down resistor. Table 40: I/O static characteristics Symbol Parameter Conditions VIL Input low level voltage VDD = 5 V Min Typ Max Unit 0.3 x -0.3 V - VDD V VIH Input high level voltage Vhys Hysteresis Rpu Pull-up resistor tR, tF Rise and fall time (1) (10 % - 90 %) VDD = 5 V, VIN = VSS VDD + 0.7 x VDD - - 700 - mV 30 55 80 kΩ - - 35 - - 125 - - 20 0.3 Fast I/Os Load = 50 pF Standard and high sink I/Os (3) (3) Load = 50 pF Fast I/Os 70/116 DocID15590 Rev 8 (3) ns STM8S903K3 STM8S903F3 Symbol Electrical characteristics Parameter Conditions Min Typ Max Unit - - 50 (3) (2) Load = 20 pF Standard and high sink I/Os Load = 20 pF Ilkg Digital input leakage current VSS ≤ VIN ≤VDD - - ±1 Ilkg ana Analog input leakage current VSS ≤ VIN ≤ VDD - - ±250 - - ±1 Ilkg(inj) Leakage current in adjacent I/O Injection current ±4 mA (2) (2) μA nA μA (1) Hysteresis voltage between Schmitt trigger switching levels. Based on characterization results, not tested in production. (2) Data based on characterisation results, not tested in production. (3) Data guaranteed by design. Figure 22: Typical VIL and VIH vs VDD @ 4 temperatures DocID15590 Rev 8 71/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 23: Typical pull-up resistance vs VDD @ 4 temperatures Figure 24: Typical pull-up current vs VDD @ 4 temperatures Table 41: Output driving current (standard ports) Symbol Parameter Conditions Output low level with 8 pins sunk IIO= 10 mA, VDD = 5 V VOL Output low level with 4 pins sunk IIO = 4 mA, VDD = 3.3 V VOH 72/116 Output high level with 8 pins sourced IIO = 10 mA, VDD = 5 V DocID15590 Rev 8 Min Max - 2.0 - 2.8 (1) 1.0 - Unit V STM8S903K3 STM8S903F3 Electrical characteristics Symbol Parameter Conditions Output high level with 4 pins sourced IIO = 4 mA, VDD = 3.3 V (1) Min Max (1) 2.1 Unit - Data based on characterization results, not tested in production Table 42: Output driving current (true open drain ports) Symbol (1) Parameter Conditions Max VOL Output low level with 2 pins sunk IIO = 10 mA, VDD = 5 V VOL Output low level with 2 pins sunk IIO = 10 mA, VDD = 3.3 V 1.5 VOL Output low level with 2 pins sunk IIO = 20 mA, VDD = 5 V 2.0 Unit 1 .0 (1) V (1) Data based on characterization results, not tested in production Table 43: Output driving current (high sink ports) Symbol VOL Parameter Conditions Output low level with 8 pins sunk IIO = 10 mA, VDD = 5 V Output low level with 4 pins sunk IIO = 10 mA, VDD = 3.3 V VOL Output low level with 4 pins sunk IIO = 20 mA, VDD = 5 V Output high level with 8 pins sourced IIO = 10 mA, VDD = 5 V VOH Output high level with 4 pins sourced IIO = 10 mA, VDD = 3.3 V Output high level with 4 pins sourced IIO = 20 mA, VDD = 5 V (1) Min Max Unit - 0.8 V (1) - 1.0 - 1.5 (1) 4.0 - (1) - (1) - 2.1 3.3 V Data based on characterization results, not tested in production DocID15590 Rev 8 73/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 25: Typ. VOL @ VDD = 5 V (standard ports) Figure 26: Typ. VOL @ VDD = 3.3 V (standard ports) 74/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 27: Typ. VOL @ VDD = 5 V (true open drain ports) Figure 28: Typ. VOL @ VDD = 3.3 V (true open drain ports) DocID15590 Rev 8 75/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 29: Typ. VOL @ VDD = 5 V (high sink ports) Figure 30: Typ. VOL @ VDD = 3.3 V (high sink ports) 76/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 31: Typ. VDD - VOH@ VDD = 5 V (standard ports) Figure 32: Typ. VDD - VOH @ VDD = 3.3 V (standard ports) DocID15590 Rev 8 77/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 33: Typ. VDD - VOH@ VDD = 5 V (high sink ports) Figure 34: Typ. VDD - VOH@ VDD = 3.3 V (high sink ports) 10.3.7 Reset pin characteristics Subject to general operating conditions for VDD and TA unless otherwise specified. Table 44: NRST pin characteristics Symbol Parameter Conditions VIL(NRST) NRST input low (1) Min -0.3 level voltage 78/116 DocID15590 Rev 8 Typ Max - 0.3 x VDD Unit V STM8S903K3 STM8S903F3 Electrical characteristics Symbol Parameter Conditions VIH(NRST) NRST input high (1) level voltage VOL(NRST) IOL=2 mA Typ (2) Unit - VDD + 0.3 - - 0.5 30 55 80 - - 75 (1) NRST pull-up Max 0.7 x VDD NRST output low level voltage RPU(NRST) Min kΩ resistor tI FP(NRST) NRST input filtered (3) pulse ns tIN FP(NRST) NRST input not (3) 500 - - 20 - - filtered pulse tOP(NRST) NRST output pulse (3) (1) Data based on characterization results, not tested in production. (2) The RPU pull-up equivalent resistor is based on a resistive transistor (3) Data guaranteed by design, not tested in production. μs Figure 35: Typical NRST VIL and VIH vs VDD @ 4 temperatures DocID15590 Rev 8 79/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 36: Typical NRST pull-up resistance vs VDD @ 4 temperatures Figure 37: Typical NRST pull-up current vs VDD @ 4 temperatures The reset network shown in the following figure protects the device against parasitic resets. The user must ensure that the level on the NRST pin can go below VIL(NRST) max. (see Table 40: I/O static characteristics ), otherwise the reset is not taken into account internally. For power consumption sensitive applications, the external reset capacitor value can be reduced to limit the charge/discharge current. If NRST signal is used to reset external circuitry, attention must be taken to the charge/discharge time of the external capacitor to fulfill the external devices reset timing conditions. Minimum recommended capacity is 100 nF. 80/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 38: Recommended reset pin protection STM8 VDD RPU External reset circuit NRST Internal reset Filter 0.1 μF (optional) 10.3.8 SPI serial peripheral interface Unless otherwise specified, the parameters given in the following table are derived from tests performed under ambient temperature, fMASTER frequency and VDD supply voltage conditions. tMASTER = 1/fMASTER. Refer to I/O port characteristics for more details on the input/output alternate function characteristics (NSS, SCK, MOSI, MISO). Table 45: SPI characteristics Symbol Parameter fSCK1/ SPI clock tc(SCK) frequency fSCK1/ fSCK1/ tc(SCK) (1) Conditions SPI clock rise and Capacitive load: C = 30 pF tf(SCK) fall time NSS setup time 0 8 0 7 SPI clock frequency tr(SCK) (3) Max Unit Master mode tc(SCK) tsu(NSS) Min (2) MHz MHz 25 Slave mode 4x tMASTER th(NSS) (3) NSS hold time Slave mode 70 tw(SCKH) (3) SCK high and low Master mode tSCK/ tSCK/ tw(SCKL) (3) time 2 - 15 2 +15 tsu(MI) (3) Data input setup Master mode 5 tsu(SI) (3) time Slave mode 5 th(MI) (3) Data input hold Master mode 7 time Slave mode 10 th(SI) (3) DocID15590 Rev 8 ns 81/116 Electrical characteristics Symbol ta(SO) (3) (4) STM8S903K3 STM8S903F3 Parameter (1) Conditions Data output Min Slave mode (3) (5) tMASTER Data output Slave mode 25 disable time tv(SO) (3) Data output valid Slave mode time tv(MO) th(SO) th(MO) (3) (3) (3) Unit 3x access time tdis(SO) Max (2) 65 (after enable edge) Data output valid Master mode time (after enable edge) Data output hold Slave mode time (after enable edge) Data output hold Master mode time (after enable edge) 30 (2) 27 (2) 11 (1) Parameters are given by selecting 10 MHz I/O output frequency. (2) Data characterization in progress. (3) Values based on design simulation and/or characterization results, and not tested in production. (4) Min time is for the minimum time to drive the output and the max time is for the maximum time to validate the data. (5) Min time is for the minimum time to invalidate the output and the max time is for the maximum time to put the data in Hi-Z. 82/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Figure 39: SPI timing diagram - slave mode and CPHA = 0 NSS input SCK Input tSU(NSS) CPHA= 0 CPOL=0 tc(SCK) th(NSS) tw(SCKH) tw(SCKL) CPHA= 0 CPOL=1 tv(SO) ta(SO) MISO OUT P UT tr(SCK) tf(SCK) th(SO) MS B O UT BI T6 OUT tdis(SO) LSB OUT tsu(SI) MOSI I NPUT M SB IN B I T1 IN LSB IN th(SI) ai14134 Figure 40: SPI timing diagram - slave mode and CPHA = 1 NSS input SCK Input tSU(NSS) CPHA=1 CPOL=0 CPHA=1 CPOL=1 tc(SCK) tw(SCKH) tw(SCKL) tv(SO) ta(SO) MISO OUT P UT MS B O UT tsu(SI) MOSI I NPUT th(NSS) th(SO) BI T6 OUT tr(SCK) tf(SCK) tdis(SO) LSB OUT th(SI) M SB IN B I T1 IN LSB IN ai14135 1. Measurement points are made at CMOS levels: 0.3 VDD and 0.7 VDD. DocID15590 Rev 8 83/116 Electrical characteristics STM8S903K3 STM8S903F3 (1) Figure 41: SPI timing diagram - master mode High NSS input SCK output SCK output tc(SCK) CPHA= 0 CPOL=0 CPHA=1 CPOL=0 CPHA= 0 CPOL=1 CPHA=1 CPOL=1 tw(SCKH) tw(SCKL) tsu(MI) MISO INP UT tr(SCK) tf(SCK) MS BIN BI T6 IN LSB IN th(MI) MOSI OUTUT M SB OUT B I T1 OUT tv(MO) LSB OUT th(MO) ai14136b 1. Measurement points are made at CMOS levels: 0.3 VDD and 0.7 VDD. 10.3.9 2 I C interface characteristics 2 Table 46: I C characteristics Symbol Parameter 2 (2) Min tw(SCLL) 2 (1) Standard mode I C (2) Max (2) Min (2) - 1.3 - tw(SCLH) SCL clock high time 4.0 - 0.6 - tsu(SDA) SDA setup time 250 - 100 - th(SDA) SDA data hold time 0 (3) - 0 (4) 900 tr(SCL) tf(SDA) tf(SCL) μs (3) SDA and SCL rise time - 1000 - 300 SDA and SCL fall time - 300 - 300 th(STA) START condition hold time 4.0 - 0.6 - tsu(STA) Repeated START condition setup time 4.7 - 0.6 - 84/116 Unit Max 4.7 tr(SDA) SCL clock low time Fast mode I C ns μs DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Symbol Parameter 2 (2) STOP condition setup time tw(STO:STA) STOP to START condition time (bus free) Cb Fast mode I C (2) Min tsu(STO) 2 (1) Standard mode I C (2) Max Unit (2) Min Max 4.0 - 0.6 - 4.7 - 1.3 - μs - 400 - 400 pF Capacitive load for each bus line (1) fMASTER, must be at least 8 MHz to achieve max fast I C speed (400kHz) 2 (2) Data based on standard I C protocol requirement, not tested in production 2 (3) The maximum hold time of the start condition has only to be met if the interface does not stretch the low time (4) The device must internally provide a hold time of at least 300 ns for the SDA signal in order to bridge the undefined region of the falling edge of SCL 2 Figure 42: Typical application with I C bus and timing diagram VDD 4.7kΩ VDD 4.7kΩ I2C bus STM8S 100Ω SDA 100Ω SCL REPEATED START START tsu(STA) tw(STO:STA) SDA tr(SDA) tf(SDA) tsu(SDA) th(SDA) tr(SCL) tf(SCL) START STOP SCL th(STA) tw(SCLH) tw(SCLL) tsu(STO) ai17490 1. Measurement points are made at CMOS levels: 0.3 x VDD and 0.7 x VDD. 10.3.10 10-bit ADC characteristics Subject to general operating conditions for VDD, fMASTER, and TA unless otherwise specified. Table 47: ADC characteristics Symbol Parameter Conditions fADC VDD =2.95 to 5.5 V ADC clock frequency DocID15590 Rev 8 Min Typ Max 1 - 4 Unit MHz 85/116 Electrical characteristics STM8S903K3 STM8S903F3 Symbol Parameter Conditions Min Typ Max 1 - 6 VSS - VDD V 1.19 1.22 1.25 V - 3 - pF fADC = 4 MHz - 0.75 - µs fADC = 6 MHz - 0.5 - - 7 - VDD =4.5 to 5.5 V VAIN (1) Conversion voltage range VBGREF Internal bandgap reference voltage CADC tS (1) VDD =2.95 to 5.5 V Internal sample and hold capacitor Minimum sampling time tSTAB Wake-up time from standby tCONV Minimum total conversion fADC = 4 MHz time (including sampling time, fADC = 6 MHz 10-bit resolution) Unit µs 3.5 µs 2.33 µs 14 1/fADC (1) During the sample time the input capacitance CAIN (3 pF max) can be charged/discharged by the external source. The internal resistance of the analog source must allow the capacitance to reach its final voltage level within tS. After the end of the sample time tS, changes of the analog input voltage have no effect on the conversion result. Values for the sample clock tS depend on programming. Table 48: ADC accuracy with RAIN < 10 kΩ , VDD= 5 V Symbol Parameter |ET| Total unadjusted error |EO| |EG| |ED| 86/116 Conditions (2) Offset error (2) (2) Gain error (2) Differential linearity error Typ (1) Max fADC = 2 MHz 1.6 3.5 fADC = 4 MHz 2.2 4 fADC = 6 MHz 2.4 4.5 fADC = 2 MHz 1.1 2.5 fADC = 4 MHz 1.5 3 fADC = 6 MHz 1.8 3 fADC = 2 MHz 1.5 3 fADC = 4 MHz 2.1 3 fADC = 6 MHz 2.2 4 fADC = 2 MHz 0.7 1.5 fADC = 4 MHz 0.7 1.5 DocID15590 Rev 8 Unit LSB STM8S903K3 STM8S903F3 Symbol |EL| (1) Electrical characteristics Parameter Conditions (2) Integral linearity error Typ (1) Max fADC = 6 MHz 0.7 1.5 fADC = 2 MHz 0.6 1.5 fADC = 4 MHz 0.8 2 fADC = 6 MHz 0.8 2 Unit Data based on characterisation results, not tested in production. (2) ADC accuracy vs. negative injection current: Injecting negative current on any of the analog input pins should be avoided as this significantly reduces the accuracy of the conversion being performed on another analog input. It is recommended to add a Schottky diode (pin to ground) to standard analog pins which may potentially inject negative current. Any positive injection current within the limits specified for IINJ(PIN) and ΣIINJ(PIN) in the I/O port pin characteristics section does not affect the ADC accuracy. Table 49: ADC accuracy with RAIN < 10 kΩ RAIN, VDD = 3.3 V Parameter Conditions |ET| Total unadjusted error fADC = 2 MHz 1.6 3.5 fADC = 4 MHz 1.9 4 fADC = 2 MHz 1 2.5 fADC = 4 MHz 1.5 2.5 fADC = 2 MHz 1.3 3 fADC = 4 MHz 2 3 fADC = 2 MHz 0.7 1 fADC = 4 MHz 0.7 1.5 fADC = 2 MHz 0.6 1.5 fADC = 4 MHz 0.8 2 |EO| |EG| |ED| |EL| (1) Offset error Gain error Differential linearity error Integral linearity error Typ (1) Symbol Max Unit LSB Data based on characterisation results, not tested in production. DocID15590 Rev 8 87/116 Electrical characteristics STM8S903K3 STM8S903F3 Figure 43: ADC accuracy characteristics 1. Example of an actual transfer curve. 2. The ideal transfer curve 3. End point correlation line ET = Total unadjusted error: maximum deviation between the actual and the ideal transfer curves. EO = Offset error: deviation between the first actual transition and the first ideal one. EG = Gain error: deviation between the last ideal transition and the last actual one. ED = Differential linearity error: maximum deviation between actual steps and the ideal one. EL = Integral linearity error: maximum deviation between any actual transition and the end point correlation line. Figure 44: Typical application with ADC VDD VAIN RAIN CAIN 88/116 AINx STM8 VT 0.6 V 10-bit A/D conversion VT 0.6 V DocID15590 Rev 8 IL ± 1 µA CADC STM8S903K3 STM8S903F3 10.3.11 Electrical characteristics EMC characteristics Susceptibility tests are performed on a sample basis during product characterization. 10.3.11.1 Functional EMS (electromagnetic susceptibility) While executing a simple application (toggling 2 LEDs through I/O ports), the product is stressed by two electromagnetic events until a failure occurs (indicated by the LEDs). FESD: Functional electrostatic discharge (positive and negative) is applied on all pins of the device until a functional disturbance occurs. This test conforms with the IEC 61000-4-2 standard. • A burst of fast transient voltage (positive and negative) is applied to V and V • FTB: through a 100 pF capacitor, until a functional disturbance occurs. This test conforms with DD SS the IEC 61000-4-4 standard. A device reset allows normal operations to be resumed. The test results are given in the table below based on the EMS levels and classes defined in application note AN1709 (EMC design guide for STMicrocontrollers). 10.3.11.2 Designing hardened software to avoid noise problems EMC characterization and optimization are performed at component level with a typical application environment and simplified MCU software. It should be noted that good EMC performance is highly dependent on the user application and the software in particular. Therefore it is recommended that the user applies EMC software optimization and prequalification tests in relation with the EMC level requested for his application. Prequalification trials Most of the common failures (unexpected reset and program counter corruption) can be recovered by applying a low state on the NRST pin or the oscillator pins for 1 second. To complete these trials, ESD stress can be applied directly on the device, over the range of specification values. When unexpected behavior is detected, the software can be hardened to prevent unrecoverable errors occurring. See application note AN1015 (Software techniques for improving microcontroller EMC performance). Table 50: EMS data Symbol Parameter VFESD VEFTB Conditions Level/ class Voltage limits to be applied on any I/O pin to VDD = 3.3 V, TA = 25 °C, fMASTER = 16 MHz induce a functional (HSI clock), conforming to IEC 61000-4-2 disturbance 2/B (1) Fast transient voltage burst limits to be applied through 100 pF on VDD VDD= 3.3 V, TA = 25 °C ,fMASTER = 16 MHz and VSS pins to induce a (HSI clock),conforming to IEC 61000-4-4 functional disturbance 4/A (1) DocID15590 Rev 8 89/116 Electrical characteristics STM8S903K3 STM8S903F3 (1) Data obtained with HSI clock configuration, after applying HW recommendations described in AN2860 (EMC guidelines for STM8S microcontrollers). 10.3.11.3 Electromagnetic interference (EMI) Based on a simple application running on the product (toggling 2 LEDs through the I/O ports), the product is monitored in terms of emission. This emission test is in line with the norm SAE IEC 61967-2 which specifies the board and the loading of each pin. Table 51: EMI data Conditions Symbol Parameter Max fHSE/fCPU General conditions Monitored frequency band 16 MHz/ 16 MHz/ 8 MHz Peak level (1) VDD = 5 V 0.1 MHz to TA = 25 °C 30 MHz Unit 16 MHz 5 5 4 5 5 5 2.5 2.5 LQFP32 package 30 MHz to Conforming to 130 MHz SAE IEC 61967-2 130 MHz to SEMI dBμV 1 GHz SAE EMI level (1) SAE EMI level Data based on characterisation results, not tested in production. 10.3.11.4 Absolute maximum ratings (electrical sensitivity) Based on three different tests (ESD, DLU and LU) using specific measurement methods, the product is stressed to determine its performance in terms of electrical sensitivity. For more details, refer to the application note AN1181. 10.3.11.5 Electrostatic discharge (ESD) Electrostatic discharges (a positive then a negative pulse separated by 1 second) are applied to the pins of each sample according to each pin combination. The sample size depends on the number of supply pins in the device (3 parts*(n+1) supply pin). One model can be simulated: 90/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Electrical characteristics Human body model. This test conforms to the JESD22-A114A/A115A standard. For more details, refer to the application note AN1181. Table 52: ESD absolute maximum ratings Symbol Ratings Conditions VESD(HBM) Electrostatic discharge TA = 25°C, conforming to voltage JESD22-A114 Class Maximum Unit (1) value A 4000 (Human body model) V VESD(CDM) (1) Electrostatic discharge TA LQFP32 package = voltage 25°C, conforming to (Charge device model) SD22-C101 IV 1000 Data based on characterization results, not tested in production 10.3.11.6 Static latch-up Two complementary static tests are required on six parts to assess the latch-up performance: A supply overvoltage (applied to each power supply pin) • injection (applied to each input, output and configurable I/O pin) are performed • Aoncurrent each sample. This test conforms to the EIA/JESD 78 IC latch-up standard. For more details, refer to the application note AN1181. Table 53: Electrical sensitivities (1) Symbol Parameter Conditions Class LU Static latch-up class TA = 25 °C A TA = 85 °C A TA = 125 °C A (1) Class description: A Class is an STMicroelectronics internal specification. All its limits are higher than the JEDEC specifications, that means when a device belongs to class A it exceeds the JEDEC standard. B class strictly covers all the JEDEC criteria (international standard). DocID15590 Rev 8 91/116 Package information 11 STM8S903K3 STM8S903F3 Package information In order to meet environmental requirements, ST offers these devices in different grades of ® ® ECOPACK packages, depending on their level of environmental compliance. ECOPACK ® specifications, grade definitions and product status are available at: www.st.com. ECOPACK is an ST trademark. 11.1 32-pin LQFP package mechanical data Figure 45: 32-pin low profile quad flat package (7 x 7) ccc C D D1 D3 24 A A2 17 16 25 L1 b E3 32 E1 E 9 Pin 1 identification L A1 1 K c 8 5V_ME Table 54: 32-pin low profile quad flat package mechanical data Dim. (1) mm Min inches Typ A 92/116 Max Min Typ 1.600 A1 0.050 A2 1.350 b 0.300 c 0.090 D 8.800 D1 6.800 Max 0.0630 0.150 0.0020 1.400 1.450 0.0531 0.0551 0.0571 0.370 0.450 0.0118 0.0146 0.0177 0.200 0.0035 9.000 9.200 0.3465 0.3543 0.3622 7.000 7.200 0.2677 0.2756 0.2835 DocID15590 Rev 8 0.0059 0.0079 STM8S903K3 STM8S903F3 Dim. Package information (1) mm Min D3 inches Typ Max Min 5.600 Typ Max 0.2205 E 8.800 9.000 9.200 0.3465 0.3543 0.3622 E1 6.800 7.000 7.200 0.2677 0.2756 0.2835 E3 5.600 0.2205 e 0.800 0.0315 L 0.450 L1 0.750 0.0177 1.000 k 0.0° ccc (1) 0.600 3.5° 0.0236 0.0295 0.0394 7.0° 0.0° 3.5° 0.100 7.0° 0.0039 Values in inches are converted from mm and rounded to 4 decimal digits DocID15590 Rev 8 93/116 Package information 11.2 STM8S903K3 STM8S903F3 32-lead UFQFPN package mechanical data Figure 46: 32-lead, ultra thin, fine pitch quad flat no-lead package (5 x 5) AOB8_ME 1. Drawing is not to scale. 2. All leads/pads should also be soldered to the PCB to improve the lead/pad solder joint life. 3. There is an exposed die pad on the underside of the UFQFPN package. It is recommended to connect and solder this backside pad to PCB ground. 4. Dimensions are in millimeters. Table 55: 32-lead, ultra thin, fine pitch quad flat no-lead package mechanical data Dim. (1) mm inches Min Max A 0.500 0.550 0.600 A1 0 0.020 0.050 A3 94/116 Typ 0.200 DocID15590 Rev 8 Min 0.0197 Typ Max 0.0217 0.0236 0.0008 0.0020 0.0079 STM8S903K3 STM8S903F3 Dim. Package information (1) mm inches Min Typ Max Typ Max b 0.180 0.250 0.300 0.0071 0.0098 0.0118 D 4.850 5.000 5.150 0.1909 0.1969 0.2028 D2 3.200 3.450 3.700 0.1260 E 4.850 5.000 5.150 0.1909 0.1969 0.2028 E2 3.200 3.450 3.700 0.1260 0.1358 0.1457 e 0.300 0.0197 0.400 0.500 ddd (1) 0.1457 0.500 L 11.3 Min 0.0118 0.0157 0.080 0.0197 0.0031 Values in inches are converted from mm and rounded to 4 decimal digits. 20-lead UFQFPN package mechanical data Figure 47: 20-lead, ultra thin, fine pitch quad flat no-lead package outline (3 x 3) D E Pin 1 TOP VIEW L1 D ddd L4 e 10 A3 L2 5 11 e b E 1 15 20 16 L3 A1 BOTTOM VIEW A SIDE VIEW 103_A0A5_ME DocID15590 Rev 8 95/116 Package information STM8S903K3 STM8S903F3 1. Drawing is not to scale. Table 56: 20-lead, ultra thin, fine pitch quad flat no-lead package (3 x 3) package mechanical data Dim. Min inches Typ Max Min Typ D 3.000 0.1181 E 3.000 0.1181 Max A 0.500 0.550 0.600 0.0197 0.0217 0.0236 A1 0.000 0.020 0.050 0.0000 0.0008 0.0020 A3 0.152 0.0060 e 0.500 0.0197 L1 0.500 0.550 0.600 0.0197 0.0217 0.0236 L2 0.300 0.350 0.400 0.0118 0.0138 0.0157 L3 0.150 0.0059 L4 0.200 0.0079 b 0.180 ddd 0.050 (1) 96/116 (1) mm 0.250 0.300 0.0071 0.0098 0.0020 Values in inches are converted from mm and rounded to 4 decimal digits. DocID15590 Rev 8 0.0118 STM8S903K3 STM8S903F3 11.4 Package information UFQFPN recommended footprint Figure 48: Recommended footprint for on-board emulation 0.5mm 0.8mm [0.032"] 4mm [0.157"] 0.5mm 1.65mm [0.065"] 0.9mm [0.035"] 0.3mm [0.012"] 4mm [0.157"] ai15319 Bottom view 1. Drawing is not to scale DocID15590 Rev 8 97/116 Package information STM8S903K3 STM8S903F3 Figure 49: Recommended footprint without on-board emulation 1. Drawing is not to scale 2. Dimensions are in millimeters 11.5 SDIP32 package mechanical data Figure 50: 32-lead shrink plastic DIP (400 ml) package E E1 A2 A1 B1 B A L e eA C eB D 32 17 1 16 76_ME 98/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Package information Table 57: 32-lead shrink plastic DIP (400 ml) package mechanical data Dim. (1) mm Min inches Typ 3.759 Max A 3.556 5.080 A1 0.508 A2 3.048 3.556 4.572 B 0.356 0.457 B1 0.762 C Min 0.1400 Typ Max 0.1480 0.2000 0.1200 0.1400 0.1800 0.584 0.0140 0.0180 0.0230 1.016 1.397 0.0300 0.0400 0.0550 0.203 0.254 0.356 0.0079 0.0100 0.0140 D 27.430 27.940 28.450 1.0799 1.1000 1.1201 E 9.906 10.410 11.050 0.3900 0.4098 0.4350 E1 7.620 8.890 9.398 0.3000 0.3500 0.3700 0.0200 e 1.778 0.0700 eA 10.160 0.4000 eB L (1) 12.700 2.540 3.048 3.810 0.5000 0.1000 0.1200 0.1500 Values in inches are converted from mm and rounded to 4 decimal digits DocID15590 Rev 8 99/116 Package information 11.6 STM8S903K3 STM8S903F3 20-pin TSSOP package mechanical data Figure 51: 20-pin, 4.40 mm body, 0.65 mm pitch D 20 11 c E1 1 E 10 k aaa CP A1 A L A2 L1 b e YA_ME Table 58: 20-pin, 4.40 mm body, 0.65 mm pitch mechanical data Dim. (1) mm Min inches Typ A Min Typ 1.200 A1 0.050 A2 0.800 b Max 0.0472 0.150 0.0020 1.050 0.0315 0.190 0.300 0.0075 0.0118 c 0.090 0.200 0.0035 0.0079 D 6.400 6.500 6.600 0.2520 0.2559 0.2598 E 6.200 6.400 6.600 0.2441 0.2520 0.2598 E1 4.300 4.400 4.500 0.1693 0.1732 0.1772 e L L1 100/116 Max 1.000 0.650 0.450 0.600 0.0059 0.0394 0.0413 0.0256 0.750 1.000 DocID15590 Rev 8 0.0177 0.0236 0.0394 0.0295 STM8S903K3 STM8S903F3 Dim. Package information (1) mm inches Min k Typ Max 0.0° 8.0° aaa (1) 11.7 Min Typ Max 0.0° 8.0° 0.100 0.0039 Values in inches are converted from mm and rounded to 4 decimal digits 20-pin SO package mechanical data Figure 52: 20-lead, plastic small outline (300 mils) package D 20 11 h x 45° C E 1 H 10 A B ddd A1 e A1 k L Z7_ME Table 59: 20-lead, plastic small outline (300 mils) mechanical data Dim. (1) mm Min inches Typ Max Min Typ Max A 2.350 2.650 0.0925 0.1043 A1 0.100 0.300 0.0039 0.0118 B 0.330 0.510 0.013 0.0201 C 0.230 0.320 0.0091 0.0126 D 12.600 13.000 0.4961 0.5118 E 7.400 7.600 0.2913 0.2992 e 1.270 DocID15590 Rev 8 0.0500 101/116 Package information Dim. STM8S903K3 STM8S903F3 (1) mm inches Min Typ Max Typ Max H 10.000 10.650 0.3937 0.4193 h 0.250 0.750 0.0098 0.0295 L 0.400 1.270 0.0157 0.0500 k 0.0° 8.0° 0.0° 8.0° ddd (1) 11.8 Min 0.100 0.0039 Values in inches are converted from mm and rounded to 4 decimal digits Thermal characteristics The maximum chip junction temperature (TJ max) must never exceed the values given in Operating conditions. The maximum chip-junction temperature, TJmax, in degrees Celsius, may be calculated using the following equation: TJmax = TAmax + (PDmax x ΘJA ) Where: TAmax is the maximum ambient temperature in °C • • Θ is the package junction-to-ambient thermal resistance in °C/W • P is the sum of P and P (PDmax = P + P ) P is the product of I andV , expressed in Watts. This is the maximum chip internal • power. • P represents the maximum power dissipation on output pins JA Dmax INTmax INTmax DD I/Omax INTmax I/Omax DD I/Omax Where: PI/Omax =Σ (VOL*IOL) + Σ((VDD-VOH)*IOH), taking into account the actual VOL/IOL and VOH/IOH of the I/Os at low and high level in the application. Table 60: Thermal characteristics Symbol ΘJA ΘJA 102/116 (1) Parameter Value Thermal resistance junction-ambient TSSOP20 - 4 x 4 mm Thermal resistance junction-ambient SO20W - 300 mils DocID15590 Rev 8 110 20 Unit °C/W °C/W STM8S903K3 STM8S903F3 Symbol ΘJA ΘJA ΘJA Package information (1) Parameter Value Thermal resistance junction-ambient UFQFPN20 - 3 x 3 mm Thermal resistance junction-ambient LQFP32 - 7 x 7 mm Thermal resistance junction-ambient 101 60 Unit °C/W °C/W 38 °C/W 60 °C/W UFQFPN32 - 5 x 5 mm ΘJA Thermal resistance junction-ambient SDIP32 - 400 mils (1) Thermal resistances are based on JEDEC JESD51-2 with 4-layer PCB in a natural convection environment. 11.8.1 Reference document JESD51-2 integrated circuits thermal test method environment conditions - natural convection (still air). Available from www.jedec.org. 11.8.2 Selecting the product temperature range When ordering the microcontroller, the temperature range is specified in the order code. The following example shows how to calculate the temperature range needed for a given application. Assuming the following application conditions: Maximum ambient temperature TAmax= 75 °C (measured according to JESD51-2) • • I = 8 mA, V = 5 V • Maximum 20 I/Os used at the same time in output at low level with DDmax DD IOL = 8 mA, VOL= 0.4 V • PINTmax = 8 mA x 5 V = 400 mW Amax PDmax = 400 mW + 64 mW Thus: PDmax = 464 mW TJmax for LQFP32 can be calculated as follows, using the thermal resistance ΘJA: TJmax = 75 °C + (60 °C/W x 464 mW) = 75 °C + 27.8 °C = 102.8 °C This is within the range of the suffix 6 version parts (-40 < TJ < 105 °C). In this case, parts must be ordered at least with the temperature range suffix 6. DocID15590 Rev 8 103/116 Ordering information 12 STM8S903K3 STM8S903F3 Ordering information Figure 53: STM8S903K3/F3 ordering information scheme Example: STM8 S 903 K 3 T 6 TR Product class STM8 microcontroller Family type S = Standard Sub-family type 903 = 903 sub-family Pin count K = 32 pins F = 20 pins Program memory size 3 = 8 Kbytes Package type 1 B = SDIP T = LQFP U = UFQFPN P = TSSOP M = SO Temperature range 3 = -40 °C to 125 °C 6 = -40 °C to 85 °C Package pitch Blank = 0.5 or 0.65 mm C = 0.8 mm (3) (2) Packing No character = Tray or tube TR = Tape and reel 1. A dedicated ordering information scheme will be released if, in the future, memory programming service (FastROM) is required. The letter "P" will be added after STM8S. Three unique letters identifying the customer application code will also be visible in the codification. Example: STM8SP903K3MACTR. 2. UFQFPN, TSSOP, and SO packages. 3. LQFP package. For a list of available options (e.g. memory size, package) and orderable part numbers or for further information on any aspect of this device, please go to www.st.com or contact the ST Sales Office nearest to you. 12.1 STM8S903K3/F3 FASTROM microcontroller option list (last update: April 2010) 104/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Ordering information Customer ........................................................................................................... Address ........................................................................................................... Contact ........................................................................................................... Phone no. ........................................................................................................... Reference FASTROM code FASTROM code name is assigned by STMicroelectronics Preferable format for programing code is .Hex (.s19 is accepted) If data EEPROM programing is required, a seperate file must be sent with the requested data. Important: See the option byte section in the datasheet for authorized option byte combinations and a detailed explanation. Do not use more than one remapping option in the same port. It is forbidden to enable both AFR1 and AFR0. Device type/memory size/package FASTROM device 8 Kbyte TSSOP20 [ ] STM8S903F3 SO20 [ ] STM8S903F3 UFQFPN20 [ ] STM8S903F3 LQFP32 [ ] STM8S903K3 UFQFPN32 [ ] STM8S903K3 Conditioning (check only one option) [ ] Tape & reel or [ ] Tray Special marking (check only one option) [ ] No [ ] Yes Authorized characters are letters, digits, '.', '-', '/' and spaces only. Maximum character counts are: LQFP32: 2 lines of 7 characters max: "_ _ _ _ _ _ _" and "_ _ _ _ _ _ _" TSSOP20: 1 line of 10 characters max: "_ _ _ _ _ _ _ _ _ _" SO20: 1 line of 13 characters max: "_ _ _ _ _ _ _ _ _ _ _ _ _" UFQFPN32: 1 line of 7 characters max: "_ _ _ _ _ _ _" UFQFPN20: 1 line of 4 characters max: "_ _ _ _ " Three characters are reserved for code identification. Temperature range [ ] -40°C to +85°C or [ ] -40°C to +125°C DocID15590 Rev 8 105/116 Ordering information STM8S903K3 STM8S903F3 Padding value for unused program memory (check only one option) [ ]0xFF Fixed value [ ]0x83 TRAP instruction opcode [ ]0x75 Illegal opcode (causes a reset when executed) OPT0 memory readout protection (check only one option) [ ] Disable or [ ] Enable OPT1 user boot code area (UBC) 0x(_ _) fill in the hexadecimal value, refering to the datasheet and the binary format below. UBC, bit0 [ ] 0: Reset [ ] 1: Set UBC bit1 [ ] 0: Reset [ ] 1: Set UBC bit2 [ ] 0: Reset [ ] 1: Set UBC bit3 [ ] 0: Reset [ ] 1: Set UBC bit4 [ ] 0: Reset [ ] 1: Set UBC bit5 [ ] 0: Reset [ ] 1: Set UBC bit6 [ ] 0: Reset [ ] 1: Set UBC bit7 [ ] 0: Reset [ ] 1: Set Note: If the UBC area is not used, please select all bits at reset states. OPT2 alternate function remapping for STM8S903K3 Do not use more than one remapping option in the same port. 106/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 AFR1, AFR0 (check only one option) Ordering information [ ] 00: Remapping options inactive. Default alternate functions used. Refer to pinout description. [ ] 01: Port C5 alternate function = TIM5_CH1, port C6 alternate function = TIM1_CH1, and port C7 alternate function = TIM1_CH2. [ ] 10: Port A3 alternate function = SPI_NSS and port D2 alternate function = TIM5_CH3. [ ] 11: Port D2 alternate function = TIM5_CH3, port C5 alternate function = TIM5_CH1, port C6 alternate function = TIM1_CH1, port C7 alternate function = TIM1_CH2, port C2 alternate function = TIM1_CH3N, port C1 alternate function = TIM1_CH2N, port E5 alternate function = TIM1_CH1N, port A3 alternate function = UART1_TX, and port F4 alternate function = UART1_RX. AFR2 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port C4 alternate function = AIN2, port D2 alternate function = AIN3, port D4 alternate function = UART1_CK. AFR3 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port C3 alternate function = TLI. AFR4 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port B4 alternate function = ADC_ETR, port B5 alternate function = TIM1_BKIN. AFR5 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port D0 alternate function = CLK_CCO. AFR6 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port D7 alternate function = TIM1_CH4. AFR7 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port C3 alternate function = TIM1_CH1N, port C4 alternate function = TIM1_CH2N. DocID15590 Rev 8 107/116 Ordering information STM8S903K3 STM8S903F3 OPT2 alternate function remapping for STM8S903F3 Do not use more than one remapping option in the same port. AFR1, AFR0 (check only one option) [ ] 00: Remapping options inactive. Default alternate functions used. Refer to pinout description. [ ] 01: Port C5 alternate function = TIM5_CH1, port C6 alternate function = TIM1_CH1, and port C7 alternate function = TIM1_CH2. [ ] 10: Port A3 alternate function = SPI_NSS and port D2 alternate function = TIM5_CH3. [ ] 11: Port D2 alternate function = TIM5_CH3, port C5 alternate function = TIM5_CH1, port C6 alternate function = TIM1_CH1, port C7 alternate function = TIM1_CH2, port E5 alternate function = TIM1_CH1N, port A3 alternate function = UART1_TX, and port F4 alternate function = UART1_RX. AFR2 AFR3 (check only one option) Reserved [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port C3 alternate function = TLI. AFR4 (check only one option) [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port B4 alternate function = ADC_ETR, port B5 alternate function = TIM1_BKIN. AFR5 AFR6 AFR7 (check only one option) Reserved Reserved [ ] 0: Remapping option inactive. Default alternate functions used. Refer to pinout description. [ ] 1: Port C3 alternate function = TIM1_CH1N, port C4 alternate function = TIM1_CH2N. OPT3 watchdog WWDG_HALT (check only one option) WWDG_HW (check only one option) 108/116 [ ] 0: No reset generated on halt if WWDG active [ ] 1: Reset generated on halt if WWDG active [ ] 0: WWDG activated by software [ ] 1: WWDG activated by hardware DocID15590 Rev 8 STM8S903K3 STM8S903F3 IWDG_HW (check only one option) LSI_EN (check only one option) HSITRIM (check only one option) Ordering information [ ] 0: IWDG activated by software [ ] 1: IWDG activated by hardware [ ] 0: LSI clock is not available as CPU clock source [ ] 1: LSI clock is available as CPU clock source [ ] 0: 3-bit trimming supported in CLK_HSITRIMR register [ ] 1: 4-bit trimming supported in CLK_HSITRIMR register OPT4 wakeup PRSC (check only one option) [ ] for 16 MHz to 128 kHz prescaler [ ] for 8 MHz to 128 kHz prescaler [ ] for 4 MHz to 128 kHz prescaler CKAWUSEL (check only one option) EXTCLK (check only one option) [ ] LSI clock source selected for AWU [ ] HSE clock with prescaler selected as clock source for for AWU [ ] External crystal connected to OSCIN/OSCOUT [ ] External clock signal on OSCIN OPT5 crystal oscillator stabilization HSECNT (check only one option) [ ] 2048 HSE cycles [ ] 128 HSE cycles [ ] 8 HSE cycles [ ] 0.5 HSE cycles OPT6 is reserved Comments: ........................................................................................................... Supply operating range in ........................................................................................................... the application: Notes: ........................................................................................................... DocID15590 Rev 8 109/116 STM8 development tools 13 STM8S903K3 STM8S903F3 STM8 development tools Development tools for the STM8 microcontrollers include the full-featured STice emulation system supported by a complete software tool package including C compiler, assembler and integrated development environment with high-level language debugger. In addition, the STM8 is to be supported by a complete range of tools including starter kits, evaluation boards and a low-cost in-circuit debugger/programmer. 13.1 Emulation and in-circuit debugging tools The STice emulation system offers a complete range of emulation and in-circuit debugging features on a platform that is designed for versatility and cost-effectiveness. In addition, STM8 application development is supported by a low-cost in-circuit debugger/programmer. The STice is the fourth generation of full featured emulators from STMicroelectronics. It offers new advanced debugging capabilities including profiling and coverage to help detect and eliminate bottlenecks in application execution and dead code when fine tuning an application. In addition, STice offers in-circuit debugging and programming of STM8 microcontrollers via the STM8 single wire interface module (SWIM), which allows non-intrusive debugging of an application while it runs on the target microcontroller. For improved cost effectiveness, STice is based on a modular design that allows you to order exactly what you need to meet your development requirements and to adapt your emulation system to support existing and future ST microcontrollers. STice key features Occurrence and time profiling and code coverage (new features) • • Advanced breakpoints with up to 4 levels of conditions • Data breakpoints • Program and data trace recording up to 128 KB records • Read/write on the fly of memory during emulation • In-circuit debugging/programming via SWIM protocol • 8-bit probe analyzer • 1 input and 2 output triggers • Power supply follower managing application voltages between 1.62 to 5.5 V that allows you to specify the components you need to meet your development • Modularity requirements and adapt to future requirements by free software tools that include integrated development environment (IDE), • Supported programming software interface and assembler for STM8. 13.2 Software tools STM8 development tools are supported by a complete, free software package from STMicroelectronics that includes ST Visual Develop (STVD) IDE and the ST Visual Programmer (STVP) software interface. STVD provides seamless integration of the Cosmic and Raisonance C compilers for STM8, which are available in a free version that outputs up to 16 Kbytes of code. 110/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 13.2.1 STM8 development tools STM8 toolset STM8 toolset with STVD integrated development environment and STVP programming software is available for free download at www.st.com/mcu. This package includes: ST Visual Develop – Full-featured integrated development environment from ST, featuring Seamless integration of C and ASM toolsets • • Full-featured debugger • Project management • Syntax highlighting editor • Integrated programming interface • Support of advanced emulation features for STice such as code profiling and coverage ST Visual Programmer (STVP) – Easy-to-use, unlimited graphical interface allowing read, write and verify of your STM8 microcontroller’s Flash program memory, data EEPROM and option bytes. STVP also offers project mode for saving programming configurations and automating programming sequences. 13.2.2 C and assembly toolchains Control of C and assembly toolchains is seamlessly integrated into the STVD integrated development environment, making it possible to configure and control the building of your application directly from an easy-to-use graphical interface. Available toolchains include: Cosmic C compiler for STM8 – Available in a free version that outputs up to 16 Kbytes of code. For more information, see www.cosmic-software.com. • C compiler for STM8 – Available in a free version that outputs up to • Raisonance 16 Kbytes of code. For more information, see www.raisonance.com. assembler linker – Free assembly toolchain included in the STVD toolset, which • STM8 allows you to assemble and link your application source code. 13.3 Programming tools During the development cycle, STice provides in-circuit programming of the STM8 Flash microcontroller on your application board via the SWIM protocol. Additional tools are to include a low-cost in-circuit programmer as well as ST socket boards, which provide dedicated programming platforms with sockets for programming your STM8. For production environments, programmers will include a complete range of gang and automated programming solutions from third-party tool developers already supplying programmers for the STM8 family. DocID15590 Rev 8 111/116 Revision history 14 STM8S903K3 STM8S903F3 Revision history Table 61: Document revision history Date Revision Changes 30-Apr-2009 1 Initial revision 03-Jun-2009 2 Added bullet point concerning unique identifier to Features section on cover page. Highlighted internal reference voltage in Analog-to-digital converter (ADC1) section. Updated wpu and PP status of PB5/12C_SDA[TIM1_BKIN] and PB4/12C_SCL[ADC_ETR] pins in Pin description. Updated Figure 7: Memory map. Added Unique ID section. Added TBD values to Table 45: SPI characteristics. Added max values to Table 48: ADC accuracy with RAIN < 10 kΩ , VDD= 5 V and Table 49: ADC accuracy with RAIN < 10 kΩ RAIN, VDD = 3.3 V . 22-Apr-2010 3 Added SO20W, TSSOP20, SDIP32, and UFQFPN32 packages. Added STM8S903F3 part number. Updated datasheet status to full datasheet. Updated definition of alternate function remapping option in Table 4: Legend/abbreviations for pinout tables . Updated Px_IDR reset value in Table 7: I/O port hardware register map table. Removed ESR low limit and update high limit for CEXT conditions in Table 21: General operating conditions. Operating conditions: updated VCAP and ESR low limit, added ESL parameter, as well as PD in Table 21: General operating conditions. Functional EMS (electromagnetic susceptibility): changed ESD to FESD (functional ESD); added name of AN1709; replaced IEC 1000 with IEC 61000. Designing hardened software to avoid noise problems replaced IEC 1000 with IEC 61000, added title of AN1015, and added footnote to Table 50: EMS data. Electromagnetic interference (EMI) replaced J 1752/3 with IEC 61967-2 and updated data of Table 51: EMI data. Removed note 3 related to Accuracy of HSI oscillator. 112/116 DocID15590 Rev 8 STM8S903K3 STM8S903F3 Date Revision history Revision Changes Updated ΘJA in Table 15: STM8S903K3 alternate function remapping bits [1:0] for 32-pin packages. Changed ΘJA to 60°C/W in Selecting the product temperature range section. Ordering information: replaced package pitch digit by VFQFPN/UFQFPN package, and added footnote regarding possible future release of a dedicated ordering information scheme. Added SO20W, TSSOP20, SDIP32, and UFQFPN32. Added STM8S903K3/F3 FASTROM microcontroller option list. 30-Apr-2010 4 Modified PD at TA = 85 °C for SO20W in Table 21: General operating conditions. 08-Sep-2010 5 Removed VFQFPN32 package. Updated "reset state" of Table 4: Legend/abbreviations for pinout tables in Pinout and pin description. Table 5: TSSOP20/SO20/UFQFPN20 pin description: updated pins 13/25/20, 14/26/21, 19/32/27, 1/2/29, 2/3/30, and 3/4/31; added footnote to PD1/SWIM pin. General hardware register map: standardized all reset state values; updated the reset state values of RST_SR, CLK_SWCR, CLK_HSITRIMR, CLK_SWIMCCR, IWDG_KR, and ADC_DRx registers in the "General hardware register map" table. Changed title of Table 13: STM8S903K3 alternate function remapping bits [7:2] for 32-pin packages. Added Table 14: STM8S903F3 alternate function remapping bits [7:2] for 20-pin packages. Changed title of Table 15: STM8S903K3 alternate function remapping bits [1:0] for 32-pin packages. Added Table 16: STM8S903F3 alternate function remapping bits [1:0] for 20-pin packages. Reset pin characteristics: replaced 0.01 µF with 0.1 µF in the "Recommended reset pin protection" diagram. Added #unique_58/title_4B4D811961B64279B556EDC351811802 Updated footnote 1 in Table 48: ADC accuracy with RAIN < 10 kΩ , VDD= 5 V and Table 49: ADC accuracy with RAIN < 10 kΩ RAIN, VDD = 3.3 V . #unique_77/CD14: updated existing footnote and added three additional footnotes. DocID15590 Rev 8 113/116 Revision history Date STM8S903K3 STM8S903F3 Revision Changes Updated "special marking" and "OPT2 alternate function remapping" sections in the STM8S903K3/F3 FASTROM microcontroller option list. 28-Jul-2011 6 Added note for OPT1 option list. Updated OPT2 option list for STM8S903K3 and created OPT2 option list for STM8S903F3 in STM8S903K3/F3 FASTROM microcontroller option list. Updated UART1 interrupt vector addresses in table Table 10: Interrupt mapping Updated note related to true open-drain outputs in Table 5: TSSOP20/SO20/UFQFPN20 pin description and Table 5: TSSOP20/SO20/UFQFPN20 pin description. Added UFQFPN20 package. Remove CLK_CANCCR register from Table 8: General hardware register map . Added note for Px_IDR registers in Table 7: I/O port hardware register map. Updated title of Ordering information. Removed Typical HSI accuracy curve in High speed internal RC oscillator (HSI). Updated value of recommended external capacitor to 100 nF inReset pin characteristics. Updated disclaimer. 04-Apr-2012 7 Internal reference voltage renamed internal bandgap reference voltage. Updated notes related to VCAP in Table 21: General operating conditions. Added values of tR/tF for 50 pF load capacitance, and updated note in Table 40: I/O static characteristics. Updated typical and maximum values of RPU in Table 40: I/O static characteristics and Table 44: NRST pin characteristics. Changed SCK input to SCK output in SPI serial peripheral interface Modified Figure 47: 20-lead, ultra thin, fine pitch quad flat no-lead package outline (3 x 3)to add package top view. 13-Jun-2012 114/116 8 Restored Figure 44: Typical application with ADC DocID15590 Rev 8 STM8S903K3 STM8S903F3 Date Revision history Revision Changes Modified Figure 47: 20-lead, ultra thin, fine pitch quad flat no-lead package outline (3 x 3) to add package top view. 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