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      TMP86FS49BUG(C,JZ)

      TMP86FS49BUG(C,JZ)

      • 厂商:

        TOSHIBA(东芝)

      • 封装:

        LQFP-64

      • 描述:

        IC MCU 8BIT 60KB FLASH 64LQFP

      数据手册:

      下载TMP86FS49BUG(C,JZ).pdf
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        • 数据手册
        • 价格&库存
        TMP86FS49BUG(C,JZ) 数据手册
        8 Bit Microcontroller TLCS-870/C Series TMP86FS49BUG The information contained herein is subject to change without notice. 021023_D TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such TOSHIBA products could cause loss of human life, bodily injury or damage to property. In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and conditions set forth in the “Handling Guide for Semiconductor Devices,” or “TOSHIBA Semiconductor Reliability Handbook” etc. 021023_A The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.). These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury (“Unintended Usage”). Unintended Usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc. Unintended Usage of TOSHIBA products listed in this document shall be made at the customer's own risk. 021023_B The products described in this document shall not be used or embedded to any downstream products of which manufacture, use and/or sale are prohibited under any applicable laws and regulations. 060106_Q The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by TOSHIBA for any infringements of patents or other rights of the third parties which may result from its use. No license is granted by implication or otherwise under any patents or other rights of TOSHIBA or the third parties. 070122_C The products described in this document are subject to foreign exchange and foreign trade control laws. 060925_E For a discussion of how the reliability of microcontrollers can be predicted, please refer to Section 1.3 of the chapter entitled Quality and Reliability Assurance/Handling Precautions. 030619_S © 2007 TOSHIBA CORPORATION All Rights Reserved TMP86FS49BUG Differences among Products Differences in Functions 86CH49 86CM49 86PM49 86CS49 86FS49 ROM 16 Kbytes (Mask) 32 Kbytes (Mask) 32 Kbytes (OTP) 60 Kbytes (Mask) RAM 512 bytes 1 Kbyte 1 Kbyte 2 Kbytes 2 Kbytes 128 bytes (Flash control register contained) I/O 56 pins High-current port 13 pins (sink open drain) Interrupt External: 5 interrupts, Internal: 19 interrupts Timer/counter 16-bit: 2 channels 8-bit: 4 channels UART 2 channels SIO 2 channels I2C 1 channel Key-on wake-up 4 channels 10-bit AD converter (note2) 16 channels Flash Security N.A. VDD Structurer of TEST pin R RIN without protect diode on the VDD side R without pull down resister Absolute Maximum Rating of Power supply(VDD) Read/Write protect Read protect VDD R RIN without protect diode on the VDD side R VDD R without pull down resister without pull down resister 6.5V Emulation chip Package 86FS49B 60 Kbytes (Flash) 128 bytes (Flash control register not contained) DBR(note1) 86FS49A without protect diode on the VDD side R without pull down resister 6.0V TMP86C949XB QFP64P-14140.80A QFP64-P-1414-0.80A LQFP64-P-1010-0.50D SDIP64-P-750-1.78 QFP64-P-1414-0.80A LQFP64-P-1010-0.50D – Note 1: The products with Flash memory (86FS49, 86FS49A, 86FS49B) contain the Flash control register (FLSCR) at 0FFFH in the DBR area. The products with mask ROM or OTP and the emulation chip do not have the FLSCR register. In these devices, therefore, a program that accesses the FLSCR register cannot function properly (executes differently as in the case of a Flash product). Note 2: In this data sheet,the following pin names and register names have been changed from the data sheet of the old edition. Although the names have been changed, their functions remain the same. TMP86FS49BUG OLD name NEW name AD Converter analog input pin name P60(AIN00) P61(AIN01) P62(AIN02) P63(AIN03) P64(AIN04) P65(AIN05) P66(AIN06) P67(AIN07) P70(AIN10) P71(AIN11) P72(AIN12) P73(AIN13) P74(AIN14) P75(AIN15) P76(AIN16) P77(AIN17) P60(AIN0) P61(AIN1) P62(AIN2) P63(AIN3) P64(AIN4) P65(AIN5) P66(AIN6) P67(AIN7) P70(AIN8) P71(AIN9) P72(AIN10) P73(AIN11) P74(AIN12) P75(AIN13) P76(AIN14) P77(AIN15) ADCCR1 register function name 0000:AIN00 0001:AIN01 0010:AIN02 0011:AIN03 0100:AIN04 0101:AIN05 0110:AIN06 0111:AIN07 1000:AIN10 1001:AIN11 1010:AIN12 1011:AIN13 1100:AIN14 1101:AIN15 1110:AIN16 1111:AIN17 0000:AIN0 0001:AIN1 0010:AIN2 0011:AIN3 0100:AIN4 0101:AIN5 0110:AIN6 0111:AIN7 1000:AIN8 1001:AIN9 1010:AIN10 1011:AIN11 1100:AIN12 1101:AIN13 1110:AIN14 1111:AIN15 TMP86FS49BUG Differences in Electrical Characteristics 86CH49 86CM49 86PM49 86CS49 86FS49 [V] [V] [V] 5.5 5.5 5.5 86FS49A 86FS49B [V] [V] 5.5 5.5 3.0 2.7 4.2 8 (b) (Note 1) 0.030 0.034 1 16 [MHz] (b) 4.5 (a) 3.0 2.7 3.0 2.7 1.8 1.8 4.5 (a) 3.6 3.6 (b) 3.0 2.7 (Note 3) 2.0 1.8 1.8 (Note 2) 3.6 1 4.2 8 16 [MHz] (a) 2.0V to 5.5V (-40 to 85°C) (b) 1.8V to 2.0V (-20 to 85°C) 1 4.2 8 16 [MHz] 1.8 (a) 4.5V to 5.5V (-40 to 85°C) (b) 3.0V to 3.6V (-40 to 85°C) 1 4.2 8 0.030 0.034 (a) 3.0 2.7 4.5 (a) 0.030 0.034 3.6 0.030 0.034 4.5 3.6 0.030 0.034 Read / Fetch 4.5 (a) 1.8V to 5.5V (-40 to 85°C) 16 [MHz] (a) 3.0V to 5.5V (-40 to 85°C) (b) 2.7V to 3.0V (-20 to 85°C) 1 4.2 8 16 [MHz] (a) 2.7V to 5.5V (-40 to 85°C) [V] 5.5 (a) 4.5 3.6 - - 3.0 2.7 1.8 0.030 0.034 Erase / Program Operating condition (MCU mode) (a) - - 1 4.2 8 16 [MHz] (a) 4.5V to 5.5V (-10 to 40°C) [V] 5.5 (a) 3.6 - - 1.8 Operating Current 3.0 2.7 0.030 0.034 Operating condition (Serial PROM mode) 4.5 - 2 4.2 8 16 [MHz] (a) 4.5V to 5.5V (-10 to 40°C) Operating current varies with each product. For details, refer to the datasheet (electrical characteristics) of each product. (Note 5) (Note 4) Note 1: With the 86CS49, the operating temperature (Topr) is -20 °C to 85 °C when the supply voltage VDD is less than 2.0 V. Note 2: With the 86FS49, the supply voltage VDD is specified as two separate ranges. While the MCU is operating, do not change the supply voltage from range (a) to range (b) or from range (b) to range (a). Note 3: With the 86FS49A, the operating temperature (Topr) is -20 °C to 85 °C when the supply voltage VDD is less than 3.0 V. Note 4: With the 86FS49A/B, when a program is executing in the Flash memory or when data is being read from the Flash memory, the Flash memory operates in an intermittent manner causing peak currents in the Flash memory momentarily, as shown in Figure. In this case, the supply current IDD (in NORMAL1, NORMAL2 and SLOW1 modes) is defined as the sum of the average peak current and MCU current. Note 5: About the measurement condition of supply current, VIL level of TEST pin is deffrent between 86FS49B and the other 86xx49 series MCUs. The supply current is defined as follows; VIL of TEST pin : VIL ≤ 0.1V (86FS49B), VIL ≤ 0.2V (others) It is described in the section "Electrical characteristics" of TMP86FS49B in detail. 1 machine cycle (4/fc or 4/fs) n Program counter (PC) n+1 n+2 n+3 Momentary Flash current I DDP-P [mA] Max. current Sum of average momentary Typ. current Flash current and MCU current MCU current Intermittent Operation of Flash Memory TMP86FS49BUG Revision History Date Revision 2007/8/28 1 First Release 2008/8/29 2 Contents Revised Caution in Setting the UART Noise Rejection Time When UART is used, settings of RXDNC are limited depending on the transfer clock specified by BRG. The combination "O" is available but please do not select the combination "–". The transfer clock generated by timer/counter interrupt is calculated by the following equation : Transfer clock [Hz] = Timer/counter source clock [Hz] ÷ TTREG set value RXDNC setting BRG setting Transfer clock [Hz] 000 110 (When the transfer clock generated by timer/counter interrupt is the same as the right side column) 11 (Reject pulses shorter than 127/fc[s] as noise) 00 (No noise rejection) 01 (Reject pulses shorter than 31/fc[s] as noise) 10 (Reject pulses shorter than 63/fc[s] as noise) fc/13 O O O – fc/8 O – – – fc/16 O O – – fc/32 O O O – O O O O The setting except the above Table of Contents Differences among Products TMP86FS49BUG 1.1 1.2 1.3 1.4 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pin Assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pin Names and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 3 4 5 2. Operational Description 2.1 CPU Core Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 2.1.1 2.1.2 2.1.3 Memory Address Map............................................................................................................................... 9 Program Memory (Flash) .......................................................................................................................... 9 Data Memory (RAM) ................................................................................................................................. 9 2.2.1 2.2.2 Clock Generator...................................................................................................................................... 10 Timing Generator .................................................................................................................................... 12 2.2 System Clock Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 2.2.2.1 2.2.2.2 Configuration of timing generator Machine cycle 2.2.3.1 2.2.3.2 2.2.3.3 Single-clock mode Dual-clock mode STOP mode 2.2.4.1 2.2.4.2 2.2.4.3 2.2.4.4 STOP mode IDLE1/2 mode and SLEEP1/2 mode IDLE0 and SLEEP0 modes (IDLE0, SLEEP0) SLOW mode 2.2.3 2.2.4 2.3 Operation Mode Control Circuit .............................................................................................................. 13 Operating Mode Control ......................................................................................................................... 18 Reset Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 2.3.1 2.3.2 2.3.3 2.3.4 External Reset Input ............................................................................................................................... 31 Address trap reset .................................................................................................................................. 32 Watchdog timer reset.............................................................................................................................. 32 System clock reset.................................................................................................................................. 32 3. Interrupt Control Circuit 3.1 3.2 Interrupt latches (IL23 to IL2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Interrupt enable register (EIR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 3.2.1 3.2.2 Interrupt master enable flag (IMF) .......................................................................................................... 36 Individual interrupt enable flags (EF23 to EF4) ...................................................................................... 37 3.3.1 3.3.2 Interrupt acceptance processing is packaged as follows........................................................................ 39 Saving/restoring general-purpose registers ............................................................................................ 40 Note 3: . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 3.3 Interrupt Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 3.3.2.1 Using PUSH and POP instructions i 3.3.2.2 Using data transfer instructions 3.3.3 Interrupt return ........................................................................................................................................ 41 3.4.1 3.4.2 Address error detection .......................................................................................................................... 42 Debugging .............................................................................................................................................. 42 3.4 3.5 3.6 3.7 Software Interrupt (INTSW) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 Undefined Instruction Interrupt (INTUNDEF). . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 Address Trap Interrupt (INTATRAP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 External Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 4. Special Function Register (SFR) 4.1 4.2 SFR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 DBR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 5. I/O Ports 5.1 5.2 5.3 5.4 5.5 5.6 5.7 5.8 Port P0 (P07 to P00) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P1 (P17 to P10) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P2 (P22 to P20) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P3 (P37 to P30) (Large Current Port) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P4 (P47 to P40) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P5 (P54 to P50) (Large Current Port) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P6 (P67 to P60) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Port P7 (P77 to P70) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 52 54 55 56 58 59 62 6. Watchdog Timer (WDT) 6.1 6.2 Watchdog Timer Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 Watchdog Timer Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 6.2.1 6.2.2 6.2.3 6.2.4 6.2.5 Malfunction Detection Methods Using the Watchdog Timer ................................................................... Watchdog Timer Enable ......................................................................................................................... Watchdog Timer Disable ........................................................................................................................ Watchdog Timer Interrupt (INTWDT)...................................................................................................... Watchdog Timer Reset ........................................................................................................................... 66 67 68 68 69 6.3.1 6.3.2 6.3.3 6.3.4 Selection of Address Trap in Internal RAM (ATAS) ................................................................................ Selection of Operation at Address Trap (ATOUT) .................................................................................. Address Trap Interrupt (INTATRAP)....................................................................................................... Address Trap Reset ................................................................................................................................ 70 70 70 71 6.3 Address Trap . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 7. Time Base Timer (TBT) 7.1 Configuration .......................................................................................................................................... 73 Control .................................................................................................................................................... 73 Function .................................................................................................................................................. 74 7.2.1 7.2.2 Configuration .......................................................................................................................................... 75 Control .................................................................................................................................................... 75 7.2 ii Time Base Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 7.1.1 7.1.2 7.1.3 Divider Output (DVO) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 8. 16-Bit TimerCounter 1 (TC1) 8.1 8.2 8.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77 TimerCounter Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 Function. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 8.3.1 8.3.2 8.3.3 8.3.4 8.3.5 8.3.6 Timer mode............................................................................................................................................. 80 External Trigger Timer Mode .................................................................................................................. 82 Event Counter Mode ............................................................................................................................... 84 Window Mode ......................................................................................................................................... 85 Pulse Width Measurement Mode............................................................................................................ 86 Programmable Pulse Generate (PPG) Output Mode ............................................................................. 89 9. 16-Bit Timer/Counter2 (TC2) 9.1 9.2 9.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 Function. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 9.3.1 9.3.2 9.3.3 Timer mode............................................................................................................................................. 95 Event counter mode................................................................................................................................ 97 Window mode ......................................................................................................................................... 97 10. 8-Bit TimerCounter (TC3, TC4) 10.1 10.2 10.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 TimerCounter Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 10.3.1 10.3.2 10.3.3 10.3.4 10.3.5 10.3.6 10.3.7 10.3.8 10.3.9 8-Bit Timer Mode (TC3 and 4) ............................................................................................................ 8-Bit Event Counter Mode (TC3, 4) .................................................................................................... 8-Bit Programmable Divider Output (PDO) Mode (TC3, 4)................................................................. 8-Bit Pulse Width Modulation (PWM) Output Mode (TC3, 4).............................................................. 16-Bit Timer Mode (TC3 and 4) .......................................................................................................... 16-Bit Event Counter Mode (TC3 and 4) ............................................................................................ 16-Bit Pulse Width Modulation (PWM) Output Mode (TC3 and 4)...................................................... 16-Bit Programmable Pulse Generate (PPG) Output Mode (TC3 and 4) ........................................... Warm-Up Counter Mode..................................................................................................................... 10.3.9.1 10.3.9.2 105 106 106 109 111 112 112 115 117 Low-Frequency Warm-up Counter Mode (NORMAL1 → NORMAL2 → SLOW2 → SLOW1) High-Frequency Warm-Up Counter Mode (SLOW1 → SLOW2 → NORMAL2 → NORMAL1) 11. 8-Bit TimerCounter (TC5, TC6) 11.1 11.2 11.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 TimerCounter Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 11.3.1 11.3.2 11.3.3 11.3.4 11.3.5 11.3.6 11.3.7 11.3.8 11.3.9 8-Bit Timer Mode (TC5 and 6) ............................................................................................................ 8-Bit Event Counter Mode (TC5, 6) .................................................................................................... 8-Bit Programmable Divider Output (PDO) Mode (TC5, 6)................................................................. 8-Bit Pulse Width Modulation (PWM) Output Mode (TC5, 6).............................................................. 16-Bit Timer Mode (TC5 and 6) .......................................................................................................... 16-Bit Event Counter Mode (TC5 and 6) ............................................................................................ 16-Bit Pulse Width Modulation (PWM) Output Mode (TC5 and 6)...................................................... 16-Bit Programmable Pulse Generate (PPG) Output Mode (TC5 and 6) ........................................... Warm-Up Counter Mode..................................................................................................................... 11.3.9.1 125 126 126 129 131 132 132 135 137 Low-Frequency Warm-up Counter Mode iii 11.3.9.2 (NORMAL1 → NORMAL2 → SLOW2 → SLOW1) High-Frequency Warm-Up Counter Mode (SLOW1 → SLOW2 → NORMAL2 → NORMAL1) 12. Asynchronous Serial interface (UART1 ) 12.1 12.2 12.3 12.4 12.5 12.6 12.7 12.8 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transfer Data Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transfer Rate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Data Sampling Method . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . STOP Bit Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Parity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit/Receive Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.8.1 12.8.2 Data Transmit Operation .................................................................................................................... 144 Data Receive Operation ..................................................................................................................... 144 12.9.1 12.9.2 12.9.3 12.9.4 12.9.5 12.9.6 Parity Error.......................................................................................................................................... Framing Error...................................................................................................................................... Overrun Error ...................................................................................................................................... Receive Data Buffer Full..................................................................................................................... Transmit Data Buffer Empty ............................................................................................................... Transmit End Flag .............................................................................................................................. 12.9 139 140 142 143 143 144 144 144 Status Flag . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 145 145 145 146 146 147 13. Asynchronous Serial interface (UART2 ) 13.1 13.2 13.3 13.4 13.5 13.6 13.7 13.8 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transfer Data Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transfer Rate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Data Sampling Method . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . STOP Bit Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Parity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit/Receive Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.1 13.8.2 Data Transmit Operation .................................................................................................................... 154 Data Receive Operation ..................................................................................................................... 154 13.9.1 13.9.2 13.9.3 13.9.4 13.9.5 13.9.6 Parity Error.......................................................................................................................................... Framing Error...................................................................................................................................... Overrun Error ...................................................................................................................................... Receive Data Buffer Full..................................................................................................................... Transmit Data Buffer Empty ............................................................................................................... Transmit End Flag .............................................................................................................................. 13.9 149 150 152 153 153 154 154 154 Status Flag . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155 155 155 155 156 156 157 14. Synchronous Serial Interface (SIO1) 14.1 14.2 14.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159 Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160 Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162 14.3.1 Clock source Shift edge 14.3.2.1 Transmit mode 14.3.2 iv Serial clock ......................................................................................................................................... 162 14.3.1.1 14.3.1.2 Transfer bit direction ........................................................................................................................... 164 14.3.2.2 14.3.2.3 Receive mode Transmit/receive mode 14.3.3.1 14.3.3.2 14.3.3.3 Transmit mode Receive mode Transmit/receive mode 14.3.3 Transfer modes................................................................................................................................... 165 15. Synchronous Serial Interface (SIO2) 15.1 15.2 15.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177 Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178 Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 180 15.3.1 Serial clock ......................................................................................................................................... 180 15.3.1.1 15.3.1.2 Clock source Shift edge 15.3.2.1 15.3.2.2 15.3.2.3 Transmit mode Receive mode Transmit/receive mode 15.3.3.1 15.3.3.2 15.3.3.3 Transmit mode Receive mode Transmit/receive mode 15.3.2 15.3.3 Transfer bit direction ........................................................................................................................... 182 Transfer modes................................................................................................................................... 183 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.1 16.2 16.3 16.4 16.5 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Software Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The Data Format in the I2C Bus Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I2C Bus Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.5.1 Acknowledgement mode specification................................................................................................ 199 16.5.1.1 16.5.1.2 Acknowledgment mode (ACK = “1”) Non-acknowledgment mode (ACK = “0”) 16.5.3.1 16.5.3.2 Clock source Clock synchronization 16.5.2 16.5.3 Number of transfer bits ....................................................................................................................... 200 Serial clock ......................................................................................................................................... 200 16.5.4 16.5.5 16.5.6 16.5.7 16.5.8 16.5.9 16.5.10 16.5.11 16.5.12 16.5.13 Slave address and address recognition mode specification ............................................................... Master/slave selection ........................................................................................................................ Transmitter/receiver selection............................................................................................................. Start/stop condition generation ........................................................................................................... Interrupt service request and cancel................................................................................................... Setting of I2C bus mode ..................................................................................................................... Arbitration lost detection monitor ...................................................................................................... Slave address match detection monitor............................................................................................ GENERAL CALL detection monitor .................................................................................................. Last received bit monitor................................................................................................................... 16.6.1 16.6.2 16.6.3 Device initialization ............................................................................................................................. 205 Start condition and slave address generation..................................................................................... 205 1-word data transfer............................................................................................................................ 205 16.6 195 195 195 196 197 201 201 201 202 202 203 203 204 204 204 Data Transfer of I2C Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 205 16.6.3.1 16.6.3.2 16.6.4 16.6.5 When the MST is “1” (Master mode) When the MST is “0” (Slave mode) Stop condition generation ................................................................................................................... 208 Restart ................................................................................................................................................ 209 17. 10-bit AD Converter (ADC) 17.1 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 211 v 17.2 17.3 Register configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 212 Function. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 215 17.3.1 17.3.2 17.3.3 Software Start Mode ........................................................................................................................... 215 Repeat Mode ...................................................................................................................................... 215 Register Setting ................................................................................................................................ 216 17.6.1 17.6.2 17.6.3 17.6.4 Restrictions for AD Conversion interrupt (INTADC) usage ................................................................. Analog input pin voltage range ........................................................................................................... Analog input shared pins .................................................................................................................... Noise Countermeasure ....................................................................................................................... 17.4 17.5 17.6 STOP/SLOW Modes during AD Conversion . . . . . . . . . . . . . . . . . . . . . . . . . . . 217 Analog Input Voltage and AD Conversion Result . . . . . . . . . . . . . . . . . . . . . . . 218 Precautions about AD Converter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 219 219 219 219 219 18. Key-on Wakeup (KWU) 18.1 18.2 18.3 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221 Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221 Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221 19. Flash Memory 19.1 Flash Memory Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 224 19.1.1 19.1.2 Flash Memory Command Sequence Execution Control (FLSCR) ..................................... 224 Flash Memory Bank Select Control (FLSCR) ................................................................ 224 19.2.1 19.2.2 19.2.3 19.2.4 19.2.5 19.2.6 Byte Program ...................................................................................................................................... Sector Erase (4-kbyte Erase) ............................................................................................................. Chip Erase (All Erase) ........................................................................................................................ Product ID Entry ................................................................................................................................. Product ID Exit .................................................................................................................................... Security Program ................................................................................................................................ 19.4.1 Flash Memory Control in the Serial PROM Mode............................................................................... 228 19.2 19.3 19.4 Command Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 225 225 225 226 226 226 226 Toggle Bit (D6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 227 Access to the Flash Memory Area. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 228 19.4.1.1 19.4.2 How to write to the flash memory by executing the control program in the RAM area (in the RAM loader mode within the serial PROM mode) Flash Memory Control in the MCU mode............................................................................................ 230 19.4.2.1 How to write to the flash memory by executing a user write control program in the RAM area (in the MCU mode) 20. Serial PROM Mode 20.1 20.2 20.3 20.3.1 20.3.2 20.3.3 20.3.4 Serial PROM Mode Control Pins ........................................................................................................ Pin Function........................................................................................................................................ Example Connection for On-Board Writing......................................................................................... Activating the Serial PROM Mode ...................................................................................................... 20.6.1 20.6.2 20.6.3 Flash Memory Erasing Mode (Operating command: F0H) ................................................................. 241 Flash Memory Writing Mode (Operation command: 30H) .................................................................. 243 RAM Loader Mode (Operation Command: 60H) ................................................................................ 246 20.4 20.5 20.6 vi Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233 Memory Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233 Serial PROM Mode Setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 234 234 234 235 236 Interface Specifications for UART . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237 Operation Command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239 Operation Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239 20.6.4 20.6.5 20.6.6 20.6.7 Flash Memory SUM Output Mode (Operation Command: 90H) ......................................................... Product ID Code Output Mode (Operation Command: C0H).............................................................. Flash Memory Status Output Mode (Operation Command: C3H) ...................................................... Flash Memory security program Setting Mode (Operation Command: FAH) ..................................... 20.8.1 20.8.2 Calculation Method ............................................................................................................................. 254 Calculation data .................................................................................................................................. 255 20.10.1 20.10.2 20.10.3 Password String................................................................................................................................ 257 Handling of Password Error .............................................................................................................. 257 Password Management during Program Development .................................................................... 257 20.7 20.8 248 249 251 252 Error Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 Checksum (SUM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 20.9 Intel Hex Format (Binary) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256 20.10 Passwords . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256 20.11 20.12 20.13 20.14 20.15 Product ID Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flash Memory Status Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Specifying the Erasure Area . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flowchart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . UART Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 258 258 260 261 262 21. Input/Output Circuit 21.1 21.2 Control pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 263 Input/Output Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 264 22. Electrical Characteristics 22.1 22.2 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267 Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268 22.2.1 22.2.2 22.2.3 22.3 22.4 22.5 22.6 DC Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AD Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flash Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.6.1 22.7 22.8 MCU mode (Flash Programming or erasing) ..................................................................................... 268 MCU mode (Except Flash Programming or erasing) ......................................................................... 268 Serial PROM mode ............................................................................................................................. 269 270 272 273 273 Write/Retention Characteristics .......................................................................................................... 273 Recommended Oscillating Conditions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274 Handling Precaution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274 23. Package Dimensions This is a technical document that describes the operating functions and electrical specifications of the 8-bit microcontroller series TLCS-870/C (LSI). vii viii TMP86FS49BUG CMOS 8-Bit Microcontroller TMP86FS49BUG The TMP86FS49BUG is a single-chip 8-bit high-speed and high-functionality microcomputer incorporating 61440 bytes of Flash Memory. It is pin-compatible with the TMP86CM49UG/CS49UG (Mask ROM version). The TMP86FS49BUG can realize operations equivalent to those of the TMP86CM49UG/CS49UG by programming the on-chip Flash Memory. Product No. ROM (FLASH) RAM Package MaskROM MCU Emulation Chip TMP86FS49BUG 61440 bytes 2048 bytes LQFP64-P-1010-0.50D TMP86CM49UG/ CS49UG TMP86C949XB 1.1 Features 1. 8-bit single chip microcomputer TLCS-870/C series - Instruction execution time : 0.25 µs (at 16 MHz) 122 µs (at 32.768 kHz) - 132 types & 731 basic instructions 2. 24interrupt sources (External : 5 Internal : 19) 3. Input / Output ports (56 pins) Large current output: 13pins (Typ. 20mA), LED direct drive 4. Watchdog Timer 5. Prescaler - Time base timer - Divider output function 6. 16-bit timer counter: 1 ch - Timer, External trigger, Window, Pulse width measurement, Event counter, Programmable pulse generate (PPG) modes 7. 16-bit timer counter: 1 ch - Timer, Event counter, Window modes This product uses the Super Flash technology under the licence of Silicon Storage Technology, Inc. Super Flash is registered trademark of Silicon Storage Technology, Inc. • The information contained herein is subject to change without notice. 021023_D • TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such TOSHIBA products could cause loss of human life, bodily injury or damage to property. In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and conditions set forth in the “Handling Guide for Semiconductor Devices,” or “TOSHIBA Semiconductor Reliability Handbook” etc. 021023_A • The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.). These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury (“Unintended Usage”). Unintended Usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc. Unintended Usage of TOSHIBA products listed in this document shall be made at the customer's own risk. 021023_B • The products described in this document shall not be used or embedded to any downstream products of which manufacture, use and/or sale are prohibited under any applicable laws and regulations. 060106_Q • The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by TOSHIBA for any infringements of patents or other rights of the third parties which may result from its use. No license is granted by implication or otherwise under any patents or other rights of TOSHIBA or the third parties. 070122_C • The products described in this document are subject to foreign exchange and foreign trade control laws. 060925_E • For a discussion of how the reliability of microcontrollers can be predicted, please refer to Section 1.3 of the chapter entitled Quality and Reliability Assurance/Handling Precautions. 030619_S Page 1 1.1 Features TMP86FS49BUG 8. 8-bit timer counter : 4 ch - Timer, Event counter, Programmable divider output (PDO), Pulse width modulation (PWM) output, Programmable pulse generation (PPG) modes 9. 8-bit UART : 2 ch 10. High-Speed SIO: 2ch 11. Serial Bus Interface(I2C Bus): 1ch 12. 10-bit successive approximation type AD converter - Analog input: 16 ch 13. Key-on wakeup : 4 ch 14. Clock operation Single clock mode Dual clock mode 15. Low power consumption operation STOP mode: Oscillation stops. (Battery/Capacitor back-up.) SLOW1 mode: Low power consumption operation using low-frequency clock.(High-frequency clock stop.) SLOW2 mode: Low power consumption operation using low-frequency clock.(High-frequency clock oscillate.) IDLE0 mode: CPU stops, and only the Time-Based-Timer(TBT) on peripherals operate using high frequency clock. Release by falling edge of the source clock which is set by TBTCR. IDLE1 mode: CPU stops and peripherals operate using high frequency clock. Release by interruputs(CPU restarts). IDLE2 mode: CPU stops and peripherals operate using high and low frequency clock. Release by interruputs. (CPU restarts). SLEEP0 mode: CPU stops, and only the Time-Based-Timer(TBT) on peripherals operate using low frequency clock.Release by falling edge of the source clock which is set by TBTCR. SLEEP1 mode: CPU stops, and peripherals operate using low frequency clock. Release by interruput.(CPU restarts). SLEEP2 mode: CPU stops and peripherals operate using high and low frequency clock. interruput. 16. Wide operation voltage: 4.5 V to 5.5 V at 16MHz /32.768 kHz 2.7 V to 5.5 V at 8 MHz /32.768 kHz Page 2 Release by TMP86FS49BUG 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 RESET (STOP/INT5) P20 (INT0) P00 (BOOT/RXD1) P01 (TXD1) P02 (INT1) P03 (SI1) P04 (SO1) P05 (SCK1) P06 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 VSS XIN XOUT TEST VDD (XTIN) P21 (XTOUT) P22 (INT3/TC2) P15 (PDO5/PWM5/TC5) P16 (PDO6/PWM6/PPG6/TC6) P17 (SCL) P50 (SDA) P51 P52 P53 P54 P30 P31 P32 P33 P34 P35 P36 P37 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 P14 (TC4/PDO4/PWM4/PPG4) P13 (TC3/PDO3/PWM3) P12 (PPG) P11 (DVO) P10 (TC1) P47 P46 (SCK2) P45 (SO2) P44 (SI2) P43 P42 (TXD2) P41 (RXD2) P40 P77 (AIN15) P76 (AIN14) P75 (AIN13) 1.2 Pin Assignment Figure 1-1 Pin Assignment Page 3 P74(AIN12) P73(AIN11) P72(AIN10) P71(AIN9) P70(AIN8) P67(AIN7/STOP3) P66(AIN6/STOP2) P65(AIN5/STOP1) P64(AIN4/STOP0) P63(AIN3) P62(AIN2) P61(AIN1) P60(AIN0) AVDD VAREF P07(INT2) 1.3 Block Diagram TMP86FS49BUG 1.3 Block Diagram Figure 1-2 Block Diagram Page 4 TMP86FS49BUG 1.4 Pin Names and Functions The TMP86FS49BUG has MCU mode, parallel PROM mode, and serial PROM mode. Table 1-1 shows the pin functions in MCU mode. The serial PROM mode is explained later in a separate chapter. Table 1-1 Pin Names and Functions(1/3) Pin Name Pin Number Input/Output Functions 17 IO I PORT07 External interrupt 2 input 16 IO IO PORT06 Serial clock input/output 1 P05 SO1 15 IO O PORT05 Serial data output 1 P04 SI1 14 IO I PORT04 Serial data input 1 P03 INT1 13 IO I PORT03 External interrupt 1 input P02 TXD1 12 IO O PORT02 UART data output 1 P01 RXD1 BOOT 11 IO I I PORT01 UART data input 1 Serial PROM mode control input 10 IO I PORT00 External interrupt 0 input 51 IO I O PORT17 TC6 input PDO6/PWM6/PPG6 output 50 IO I O PORT16 TC5 input PDO5/PWM5 output 49 IO I I PORT15 TC2 input External interrupt 3 input 48 IO I O PORT14 TC4 input PDO4/PWM4/PPG4 output 47 IO I O PORT13 TC3 input PDO3/PWM3 output 46 IO O PORT12 PPG output 45 IO O PORT11 Divider Output P10 TC1 44 IO I PORT10 TC1 input P22 XTOUT 7 IO O PORT22 Resonator connecting pins(32.768kHz) for inputting external clock P21 XTIN 6 IO I PORT21 Resonator connecting pins(32.768kHz) for inputting external clock P07 INT2 P06 SCK1 P00 INT0 P17 TC6 PDO6/PWM6/PPG6 P16 TC5 PDO5/PWM5 P15 TC2 INT3 P14 TC4 PDO4/PWM4/PPG4 P13 TC3 PDO3/PWM3 P12 PPG P11 DVO Page 5 1.4 Pin Names and Functions TMP86FS49BUG Table 1-1 Pin Names and Functions(2/3) Pin Name Pin Number Input/Output Functions 9 IO I I PORT20 External interrupt 5 input STOP mode release signal input P37 64 IO PORT37 P36 63 IO PORT36 P35 62 IO PORT35 P34 61 IO PORT34 P33 60 IO PORT33 P32 59 IO PORT32 P31 58 IO PORT31 P30 57 IO PORT30 P47 43 IO PORT47 42 IO IO PORT46 Serial clock input/output 2 P45 SO2 41 IO O PORT45 Serial data output 2 P44 SI2 40 IO I PORT44 Serial data input 2 P43 39 IO PORT43 P42 TXD2 38 IO O PORT42 UART data output 2 P41 RXD2 37 IO I PORT41 UART data input 2 P40 36 IO PORT40 P54 56 IO PORT54 P53 55 IO PORT53 P52 54 IO PORT52 P51 SDA 53 IO IO PORT51 I2C bus data P50 SCL 52 IO IO PORT50 I2C bus clock P67 AIN7 STOP3 27 IO I I PORT67 Analog Input7 STOP3 input P66 AIN6 STOP2 26 IO I I PORT66 Analog Input6 STOP2 input P65 AIN5 STOP1 25 IO I I PORT65 Analog Input5 STOP1 input P64 AIN4 STOP0 24 IO I I PORT64 Analog Input4 STOP0 input P20 INT5 STOP P46 SCK2 Page 6 TMP86FS49BUG Table 1-1 Pin Names and Functions(3/3) Pin Name Pin Number Input/Output Functions P63 AIN3 23 IO I PORT63 Analog Input3 P62 AIN2 22 IO I PORT62 Analog Input2 P61 AIN1 21 IO I PORT61 Analog Input1 P60 AIN0 20 IO I PORT60 Analog Input0 P77 AIN15 35 IO I PORT77 Analog Input15 P76 AIN14 34 IO I PORT76 Analog Input14 P75 AIN13 33 IO I PORT75 Analog Input13 P74 AIN12 32 IO I PORT74 Analog Input12 P73 AIN11 31 IO I PORT73 Analog Input11 P72 AIN10 30 IO I PORT72 Analog Input10 P71 AIN9 29 IO I PORT71 Analog Input9 P70 AIN8 28 IO I PORT70 Analog Input8 XIN 2 I Resonator connecting pins for high-frequency clock XOUT 3 O Resonator connecting pins for high-frequency clock RESET 8 I Reset signal TEST 4 I Test pin for out-going test. Normally, be fixed to low. VAREF 18 I Analog Base Voltage Input Pin for A/D Conversion AVDD 19 I Analog Power Supply VDD 5 I +5V VSS 1 I 0(GND) Page 7 1.4 Pin Names and Functions TMP86FS49BUG Page 8 TMP86FS49BUG 2. Operational Description 2.1 CPU Core Functions The CPU core consists of a CPU, a system clock controller, and an interrupt controller. This section provides a description of the CPU core, the program memory, the data memory, and the reset circuit. 2.1.1 Memory Address Map The TMP86FS49BUG memory is composed Flash, RAM, DBR(Data buffer register) and SFR(Special function register). They are all mapped in 64-Kbyte address space. Figure 2-1 shows the TMP86FS49BUG memory address map. 0000H SFR SFR: 64 bytes 003FH 0040H 2048 bytes RAM RAM: Special function register includes: I/O ports Peripheral control registers Peripheral status registers System control registers Program status word Random access memory includes: Data memory Stack 083FH 0F80H DBR: 128 bytes DBR Data buffer register includes: Peripheral control registers Peripheral status registers 0FFFH 1000H Flash: Program memory 61440 bytes Flash FFB0H Vector table for interrupts (16 bytes) FFBFH FFC0H Vector table for vector call instructions (32 bytes) FFDFH FFE0H Vector table for interrupts FFFFH (32 bytes) Figure 2-1 Memory Address Map 2.1.2 Program Memory (Flash) The TMP86FS49BUG has a 61440 bytes (Address 1000H to FFFFH) of program memory (Flash ). 2.1.3 Data Memory (RAM) The TMP86FS49BUG has 2048 bytes (Address 0040H to 083FH) of internal RAM. The first 192 bytes (0040H to 00FFH) of the internal RAM are located in the direct area; instructions with shorten operations are available against such an area. Page 9 2. Operational Description 2.2 System Clock Controller TMP86FS49BUG The data memory contents become unstable when the power supply is turned on; therefore, the data memory should be initialized by an initialization routine. Example :Clears RAM to “00H”. (TMP86FS49BUG) SRAMCLR: LD HL, 0040H ; Start address setup LD A, H ; Initial value (00H) setup LD BC, 07FFH LD (HL), A INC HL DEC BC JRS F, SRAMCLR 2.2 System Clock Controller The system clock controller consists of a clock generator, a timing generator, and a standby controller. Timing generator control register TBTCR 0036H Clock generator XIN fc High-frequency clock oscillator Timing generator XOUT Standby controller 0038H XTIN Low-frequency clock oscillator SYSCR1 fs System clocks 0039H SYSCR2 System control registers XTOUT Clock generator control Figure 2-2 System Colck Control 2.2.1 Clock Generator The clock generator generates the basic clock which provides the system clocks supplied to the CPU core and peripheral hardware. It contains two oscillation circuits: One for the high-frequency clock and one for the low-frequency clock. Power consumption can be reduced by switching of the standby controller to low-power operation based on the low-frequency clock. The high-frequency (fc) clock and low-frequency (fs) clock can easily be obtained by connecting a resonator between the XIN/XOUT and XTIN/XTOUT pins respectively. Clock input from an external oscillator is also possible. In this case, external clock is applied to XIN/XTIN pin with XOUT/XTOUT pin not connected. Page 10 TMP86FS49BUG Low-frequency clock High-frequency clock XIN XOUT XIN XOUT XTIN XTOUT (Open) (a) Crystal/Ceramic resonator XTIN XTOUT (Open) (c) Crystal (b) External oscillator (d) External oscillator Figure 2-3 Examples of Resonator Connection Note:The function to monitor the basic clock directly at external is not provided for hardware, however, with disabling all interrupts and watchdog timers, the oscillation frequency can be adjusted by monitoring the pulse which the fixed frequency is outputted to the port by the program. The system to require the adjustment of the oscillation frequency should create the program for the adjustment in advance. Page 11 2. Operational Description 2.2 System Clock Controller 2.2.2 TMP86FS49BUG Timing Generator The timing generator generates the various system clocks supplied to the CPU core and peripheral hardware from the basic clock (fc or fs). The timing generator provides the following functions. 1. Generation of main system clock 2. Generation of divider output (DVO) pulses 3. Generation of source clocks for time base timer 4. Generation of source clocks for watchdog timer 5. Generation of internal source clocks for timer/counters 6. Generation of warm-up clocks for releasing STOP mode 2.2.2.1 Configuration of timing generator The timing generator consists of a 2-stage prescaler, a 21-stage divider, a main system clock generator, and machine cycle counters. An input clock to the 7th stage of the divider depends on the operating mode, SYSCR2 and TBTCR, that is shown in Figure 2-4. As reset and STOP mode started/canceled, the prescaler and the divider are cleared to “0”. fc or fs Main system clock generator Machine cycle counters SYSCK DV7CK High-frequency clock fc Low-frequency clock fs 1 2 fc/4 S A Divider Y 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 B Multiplexer S B0 B1 A0 Y0 A1 Y1 Multiplexer Warm-up controller Watchdog timer Timer counter, Serial interface, Time-base-timer, divider output, etc. (Peripheral functions) Figure 2-4 Configuration of Timing Generator Page 12 TMP86FS49BUG Timing Generator Control Register TBTCR (0036H) 7 6 (DVOEN) 5 (DVOCK) DV7CK 4 3 DV7CK (TBTEN) Selection of input to the 7th stage of the divider 2 1 0 (TBTCK) (Initial value: 0000 0000) 0: fc/28 [Hz] 1: fs R/W Note 1: In single clock mode, do not set DV7CK to “1”. Note 2: Do not set “1” on DV7CK while the low-frequency clock is not operated stably. Note 3: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz], *: Don’t care Note 4: In SLOW1/2 and SLEEP1/2 modes, the DV7CK setting is ineffective, and fs is input to the 7th stage of the divider. Note 5: When STOP mode is entered from NORMAL1/2 mode, the DV7CK setting is ineffective during the warm-up period after release of STOP mode, and the 6th stage of the divider is input to the 7th stage during this period. 2.2.2.2 Machine cycle Instruction execution and peripheral hardware operation are synchronized with the main system clock. The minimum instruction execution unit is called an “machine cycle”. There are a total of 10 different types of instructions for the TLCS-870/C Series: Ranging from 1-cycle instructions which require one machine cycle for execution to 10-cycle instructions which require 10 machine cycles for execution. A machine cycle consists of 4 states (S0 to S3), and each state consists of one main system clock. 1/fc or 1/fs [s] Main system clock State S0 S1 S2 S3 S0 S1 S2 S3 Machine cycle Figure 2-5 Machine Cycle 2.2.3 Operation Mode Control Circuit The operation mode control circuit starts and stops the oscillation circuits for the high-frequency and lowfrequency clocks, and switches the main system clock. There are three operating modes: Single clock mode, dual clock mode and STOP mode. These modes are controlled by the system control registers (SYSCR1 and SYSCR2). Figure 2-6 shows the operating mode transition diagram. 2.2.3.1 Single-clock mode Only the oscillation circuit for the high-frequency clock is used, and P21 (XTIN) and P22 (XTOUT) pins are used as input/output ports. The main-system clock is obtained from the high-frequency clock. In the single-clock mode, the machine cycle time is 4/fc [s]. (1) NORMAL1 mode In this mode, both the CPU core and on-chip peripherals operate using the high-frequency clock. The TMP86FS49BUG is placed in this mode after reset. Page 13 2. Operational Description 2.2 System Clock Controller TMP86FS49BUG (2) IDLE1 mode In this mode, the internal oscillation circuit remains active. The CPU and the watchdog timer are halted; however on-chip peripherals remain active (Operate using the high-frequency clock). IDLE1 mode is started by SYSCR2 = "1", and IDLE1 mode is released to NORMAL1 mode by an interrupt request from the on-chip peripherals or external interrupt inputs. When the IMF (Interrupt master enable flag) is “1” (Interrupt enable), the execution will resume with the acceptance of the interrupt, and the operation will return to normal after the interrupt service is completed. When the IMF is “0” (Interrupt disable), the execution will resume with the instruction which follows the IDLE1 mode start instruction. (3) IDLE0 mode In this mode, all the circuit, except oscillator and the timer-base-timer, stops operation. This mode is enabled by SYSCR2 = "1". When IDLE0 mode starts, the CPU stops and the timing generator stops feeding the clock to the peripheral circuits other than TBT. Then, upon detecting the falling edge of the source clock selected with TBTCR, the timing generator starts feeding the clock to all peripheral circuits. When returned from IDLE0 mode, the CPU restarts operating, entering NORMAL1 mode back again. IDLE0 mode is entered and returned regardless of how TBTCR is set. When IMF = “1”, EF7 (TBT interrupt individual enable flag) = “1”, and TBTCR = “1”, interrupt processing is performed. When IDLE0 mode is entered while TBTCR = “1”, the INTTBT interrupt latch is set after returning to NORMAL1 mode. 2.2.3.2 Dual-clock mode Both the high-frequency and low-frequency oscillation circuits are used in this mode. P21 (XTIN) and P22 (XTOUT) pins cannot be used as input/output ports. The main system clock is obtained from the high-frequency clock in NORMAL2 and IDLE2 modes, and is obtained from the low-frequency clock in SLOW and SLEEP modes. The machine cycle time is 4/fc [s] in the NORMAL2 and IDLE2 modes, and 4/fs [s] (122 µs at fs = 32.768 kHz) in the SLOW and SLEEP modes. The TLCS-870/C is placed in the signal-clock mode during reset. To use the dual-clock mode, the lowfrequency oscillator should be turned on at the start of a program. (1) NORMAL2 mode In this mode, the CPU core operates with the high-frequency clock. On-chip peripherals operate using the high-frequency clock and/or low-frequency clock. (2) SLOW2 mode In this mode, the CPU core operates with the low-frequency clock, while both the high-frequency clock and the low-frequency clock are operated. As the SYSCR2 becomes "1", the hardware changes into SLOW2 mode. As the SYSCR2 becomes “0”, the hardware changes into NORMAL2 mode. As the SYSCR2 becomes “0”, the hardware changes into SLOW1 mode. Do not clear SYSCR2 to “0” during SLOW2 mode. (3) SLOW1 mode This mode can be used to reduce power-consumption by turning off oscillation of the high-frequency clock. The CPU core and on-chip peripherals operate using the low-frequency clock. Page 14 TMP86FS49BUG Switching back and forth between SLOW1 and SLOW2 modes are performed by SYSCR2. In SLOW1 and SLEEP modes, the input clock to the 1st stage of the divider is stopped; output from the 1st to 6th stages is also stopped. (4) IDLE2 mode In this mode, the internal oscillation circuit remain active. The CPU and the watchdog timer are halted; however, on-chip peripherals remain active (Operate using the high-frequency clock and/or the low-frequency clock). Starting and releasing of IDLE2 mode are the same as for IDLE1 mode, except that operation returns to NORMAL2 mode. (5) SLEEP1 mode In this mode, the internal oscillation circuit of the low-frequency clock remains active. The CPU, the watchdog timer, and the internal oscillation circuit of the high-frequency clock are halted; however, on-chip peripherals remain active (Operate using the low-frequency clock). Starting and releasing of SLEEP mode are the same as for IDLE1 mode, except that operation returns to SLOW1 mode. In SLOW1 and SLEEP1 modes, the input clock to the 1st stage of the divider is stopped; output from the 1st to 6th stages is also stopped. (6) SLEEP2 mode The SLEEP2 mode is the idle mode corresponding to the SLOW2 mode. The status under the SLEEP2 mode is same as that under the SLEEP1 mode, except for the oscillation circuit of the highfrequency clock. (7) SLEEP0 mode In this mode, all the circuit, except oscillator and the timer-base-timer, stops operation. This mode is enabled by setting “1” on bit SYSCR2. When SLEEP0 mode starts, the CPU stops and the timing generator stops feeding the clock to the peripheral circuits other than TBT. Then, upon detecting the falling edge of the source clock selected with TBTCR, the timing generator starts feeding the clock to all peripheral circuits. When returned from SLEEP0 mode, the CPU restarts operating, entering SLOW1 mode back again. SLEEP0 mode is entered and returned regardless of how TBTCR is set. When IMF = “1”, EF7 (TBT interrupt individual enable flag) = “1”, and TBTCR = “1”, interrupt processing is performed. When SLEEP0 mode is entered while TBTCR = “1”, the INTTBT interrupt latch is set after returning to SLOW1 mode. 2.2.3.3 STOP mode In this mode, the internal oscillation circuit is turned off, causing all system operations to be halted. The internal status immediately prior to the halt is held with a lowest power consumption during STOP mode. STOP mode is started by the system control register 1 (SYSCR1), and STOP mode is released by a inputting (Either level-sensitive or edge-sensitive can be programmably selected) to the STOP pin. After the warm-up period is completed, the execution resumes with the instruction which follows the STOP mode start instruction. Page 15 2. Operational Description 2.2 System Clock Controller TMP86FS49BUG IDLE0 mode RESET Reset release Note 2 SYSCR2 = "1" SYSCR1 = "1" SYSCR2 = "1" NORMAL1 mode Interrupt STOP pin input IDLE1 mode (a) Single-clock mode SYSCR2 = "0" SYSCR2 = "1" SYSCR2 = "1" IDLE2 mode NORMAL2 mode Interrupt SYSCR1 = "1" STOP pin input SYSCR2 = "0" SYSCR2 = "1" STOP SYSCR2 = "1" SLEEP2 mode SLOW2 mode Interrupt SYSCR2 = "0" SYSCR2 = "1" SYSCR2 = "1" SLEEP1 mode Interrupt (b) Dual-clock mode SYSCR1 = "1" SLOW1 mode STOP pin input SYSCR2 = "1" Note 2 SLEEP0 mode Note 1: NORMAL1 and NORMAL2 modes are generically called NORMAL; SLOW1 and SLOW2 are called SLOW; IDLE0, IDLE1 and IDLE2 are called IDLE; SLEEP0, SLEEP1 and SLEEP2 are called SLEEP. Note 2: The mode is released by falling edge of TBTCR setting. Figure 2-6 Operating Mode Transition Diagram Table 2-1 Operating Mode and Conditions Oscillator Operating Mode High Frequency Low Frequency RESET NORMAL1 Single clock IDLE1 Oscillation Reset Operate Halt Operate Halt Operate with high frequency Machine Cycle Time 4/fc [s] – 4/fc [s] Halt Oscillation Operate with low frequency Oscillation Halt Operate Operate Operate with low frequency SLOW1 4/fs [s] Stop SLEEP0 STOP Reset Stop SLEEP2 SLEEP1 Reset Halt SLOW2 Dual clock Other Peripherals Stop NORMAL2 IDLE2 TBT Operate IDLE0 STOP CPU Core Halt Stop Halt Page 16 Halt – TMP86FS49BUG System Control Register 1 SYSCR1 7 6 5 4 (0038H) STOP RELM RETM OUTEN 3 2 1 0 WUT (Initial value: 0000 00**) STOP STOP mode start 0: CPU core and peripherals remain active 1: CPU core and peripherals are halted (Start STOP mode) R/W RELM Release method for STOP mode 0: Edge-sensitive release 1: Level-sensitive release R/W RETM Operating mode after STOP mode 0: Return to NORMAL1/2 mode 1: Return to SLOW1 mode R/W Port output during STOP mode 0: High impedance 1: Output kept R/W OUTEN WUT Warm-up time at releasing STOP mode Return to NORMAL mode Return to SLOW mode 00 3 x 216/fc 3 x 213/fs 01 216/fc 213/fs 10 3 x 214/fc 3 x 26/fs 11 214/fc 26/fs R/W Note 1: Always set RETM to “0” when transiting from NORMAL mode to STOP mode. Always set RETM to “1” when transiting from SLOW mode to STOP mode. Note 2: When STOP mode is released with RESET pin input, a return is made to NORMAL1 regardless of the RETM contents. Note 3: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz], *; Don’t care Note 4: Bits 1 and 0 in SYSCR1 are read as undefined data when a read instruction is executed. Note 5: As the hardware becomes STOP mode under OUTEN = “0”, input value is fixed to “0”; therefore it may cause external interrupt request on account of falling edge. Note 6: When the key-on wakeup is used, RELM should be set to "1". Note 7: Port P20 is used as STOP pin. Therefore, when stop mode is started, OUTEN does not affect to P20, and P20 becomes High-Z mode. Note 8: The warmig-up time should be set correctly for using oscillator. System Control Register 2 SYSCR2 (0039H) 7 6 5 4 XEN XTEN SYSCK IDLE 3 2 1 TGHALT 0 (Initial value: 1000 *0**) XEN High-frequency oscillator control 0: Turn off oscillation 1: Turn on oscillation XTEN Low-frequency oscillator control 0: Turn off oscillation 1: Turn on oscillation SYSCK Main system clock select (Write)/main system clock monitor (Read) 0: High-frequency clock (NORMAL1/NORMAL2/IDLE1/IDLE2) 1: Low-frequency clock (SLOW1/SLOW2/SLEEP1/SLEEP2) IDLE CPU and watchdog timer control (IDLE1/2 and SLEEP1/2 modes) 0: CPU and watchdog timer remain active 1: CPU and watchdog timer are stopped (Start IDLE1/2 and SLEEP1/2 modes) TGHALT TG control (IDLE0 and SLEEP0 modes) 0: Feeding clock to all peripherals from TG 1: Stop feeding clock to peripherals except TBT from TG. (Start IDLE0 and SLEEP0 modes) R/W R/W Note 1: A reset is applied if both XEN and XTEN are cleared to “0”, XEN is cleared to “0” when SYSCK = “0”, or XTEN is cleared to “0” when SYSCK = “1”. Note 2: *: Don’t care, TG: Timing generator, *; Don’t care Note 3: Bits 3, 1 and 0 in SYSCR2 are always read as undefined value. Note 4: Do not set IDLE and TGHALT to “1” simultaneously. Note 5: Because returning from IDLE0/SLEEP0 to NORMAL1/SLOW1 is executed by the asynchronous internal clock, the period of IDLE0/SLEEP0 mode might be shorter than the period setting by TBTCR. Note 6: When IDLE1/2 or SLEEP1/2 mode is released, IDLE is automatically cleared to “0”. Note 7: When IDLE0 or SLEEP0 mode is released, TGHALT is automatically cleared to “0”. Note 8: Before setting TGHALT to “1”, be sure to stop peripherals. If peripherals are not stopped, the interrupt latch of peripherals may be set after IDLE0 or SLEEP0 mode is released. Page 17 2. Operational Description 2.2 System Clock Controller 2.2.4 TMP86FS49BUG Operating Mode Control 2.2.4.1 STOP mode STOP mode is controlled by the system control register 1, the STOP pin input and key-on wakeup input (STOP3 to STOP0) which is controlled by the STOP mode release control register (STOPCR). The STOP pin is also used both as a port P20 and an INT5 (external interrupt input 5) pin. STOP mode is started by setting SYSCR1 to “1”. During STOP mode, the following status is maintained. 1. Oscillations are turned off, and all internal operations are halted. 2. The data memory, registers, the program status word and port output latches are all held in the status in effect before STOP mode was entered. 3. The prescaler and the divider of the timing generator are cleared to “0”. 4. The program counter holds the address 2 ahead of the instruction (e.g., [SET (SYSCR1).7]) which started STOP mode. STOP mode includes a level-sensitive mode and an edge-sensitive mode, either of which can be selected with the SYSCR1. Do not use any key-on wakeup input (STOP3 to STOP0) for releasing STOP mode in edge-sensitive mode. Note 1: The STOP mode can be released by either the STOP or key-on wakeup pin (STOP3 to STOP0). However, because the STOP pin is different from the key-on wakeup and can not inhibit the release input, the STOP pin must be used for releasing STOP mode. Note 2: During STOP period (from start of STOP mode to end of warm up), due to changes in the external interrupt pin signal, interrupt latches may be set to “1” and interrupts may be accepted immediately after STOP mode is released. Before starting STOP mode, therefore, disable interrupts. Also, before enabling interrupts after STOP mode is released, clear unnecessary interrupt latches. (1) Level-sensitive release mode (RELM = “1”) In this mode, STOP mode is released by setting the STOP pin high or setting the STOP3 to STOP0 pin input which is enabled by STOPCR. This mode is used for capacitor backup when the main power supply is cut off and long term battery backup. Even if an instruction for starting STOP mode is executed while STOP pin input is high or STOP3 to STOP0 input is low, STOP mode does not start but instead the warm-up sequence starts immediately. Thus, to start STOP mode in the level-sensitive release mode, it is necessary for the program to first confirm that the STOP pin input is low or STOP3 to STOP0 input is high. The following two methods can be used for confirmation. 1. Testing a port. 2. Using an external interrupt input INT5 (INT5 is a falling edge-sensitive input). Example 1 :Starting STOP mode from NORMAL mode by testing a port P20. SSTOPH: LD (SYSCR1), 01010000B ; Sets up the level-sensitive release mode TEST (P2PRD). 0 ; Wait until the STOP pin input goes low level JRS F, SSTOPH ; IMF ← 0 DI SET (SYSCR1). 7 ; Starts STOP mode Page 18 TMP86FS49BUG Example 2 :Starting STOP mode from NORMAL mode with an INT5 interrupt. PINT5: TEST (P2PRD). 0 ; To reject noise, STOP mode does not start if JRS F, SINT5 LD (SYSCR1), 01010000B port P20 is at high ; Sets up the level-sensitive release mode. ; IMF ← 0 DI SET SINT5: (SYSCR1). 7 ; Starts STOP mode RETI VIH STOP pin XOUT pin NORMAL operation STOP operation Warm up Confirm by program that the STOP pin input is low and start STOP mode. NORMAL operation STOP mode is released by the hardware. Always released if the STOP pin input is high. Figure 2-7 Level-sensitive Release Mode Note 1: Even if the STOP pin input is low after warm-up start, the STOP mode is not restarted. Note 2: In this case of changing to the level-sensitive mode from the edge-sensitive mode, the release mode is not switched until a rising edge of the STOP pin input is detected. (2) Edge-sensitive release mode (RELM = “0”) In this mode, STOP mode is released by a rising edge of the STOP pin input. This is used in applications where a relatively short program is executed repeatedly at periodic intervals. This periodic signal (for example, a clock from a low-power consumption oscillator) is input to the STOP pin. In the edge-sensitive release mode, STOP mode is started even when the STOP pin input is high level. Do not use any STOP3 to STOP0 pin input for releasing STOP mode in edge-sensitive release mode. Example :Starting STOP mode from NORMAL mode ; IMF ← 0 DI LD (SYSCR1), 10010000B ; Starts after specified to the edge-sensitive release mode VIH STOP pin XOUT pin NORMAL operation STOP operation Warm up NORMAL operation STOP mode started by the program. STOP operation STOP mode is released by the hardware at the rising edge of STOP pin input. Figure 2-8 Edge-sensitive Release Mode Page 19 2. Operational Description 2.2 System Clock Controller TMP86FS49BUG STOP mode is released by the following sequence. 1. In the dual-clock mode, when returning to NORMAL2, both the high-frequency and lowfrequency clock oscillators are turned on; when returning to SLOW1 mode, only the lowfrequency clock oscillator is turned on. In the single-clock mode, only the high-frequency clock oscillator is turned on. 2. A warm-up period is inserted to allow oscillation time to stabilize. During warm up, all internal operations remain halted. Four different warm-up times can be selected with the SYSCR1 in accordance with the resonator characteristics. 3. When the warm-up time has elapsed, normal operation resumes with the instruction following the STOP mode start instruction. Note 1: When the STOP mode is released, the start is made after the prescaler and the divider of the timing generator are cleared to "0". Note 2: STOP mode can also be released by inputting low level on the RESET pin, which immediately performs the normal reset operation. Note 3: When STOP mode is released with a low hold voltage, the following cautions must be observed. The power supply voltage must be at the operating voltage level before releasing STOP mode. The RESET pin input must also be “H” level, rising together with the power supply voltage. In this case, if an external time constant circuit has been connected, the RESET pin input voltage will increase at a slower pace than the power supply voltage. At this time, there is a danger that a reset may occur if input voltage level of the RESET pin drops below the non-inverting high-level input voltage (Hysteresis input). Table 2-2 Warm-up Time Example (at fc = 16.0 MHz, fs = 32.768 kHz) Warm-up Time [ms] WUT 00 01 10 11 Return to NORMAL Mode Return to SLOW Mode 12.288 4.096 3.072 1.024 750 250 5.85 1.95 Note 1: The warm-up time is obtained by dividing the basic clock by the divider. Therefore, the warm-up time may include a certain amount of error if there is any fluctuation of the oscillation frequency when STOP mode is released. Thus, the warm-up time must be considered as an approximate value. Page 20 Page 21 Figure 2-9 STOP Mode Start/Release Divider Instruction execution Program counter Main system clock Oscillator circuit STOP pin input Divider Instruction execution Program counter Main system clock Oscillator circuit 0 Halt Turn off Turn on Turn on n Count up a+3 Warm up a+2 n+2 n+3 n+4 0 (b) STOP mode release 1 Instruction address a + 2 a+4 2 Instruction address a + 3 a+5 (a) STOP mode start (Example: Start with SET (SYSCR1). 7 instruction located at address a) n+1 SET (SYSCR1). 7 a+3 3 Instruction address a + 4 a+6 0 Halt Turn off TMP86FS49BUG 2. Operational Description 2.2 System Clock Controller 2.2.4.2 TMP86FS49BUG IDLE1/2 mode and SLEEP1/2 mode IDLE1/2 and SLEEP1/2 modes are controlled by the system control register 2 (SYSCR2) and maskable interrupts. The following status is maintained during these modes. 1. Operation of the CPU and watchdog timer (WDT) is halted. On-chip peripherals continue to operate. 2. The data memory, CPU registers, program status word and port output latches are all held in the status in effect before these modes were entered. 3. The program counter holds the address 2 ahead of the instruction which starts these modes. Starting IDLE1/2 and SLEEP1/2 modes by instruction CPU and WDT are halted Yes Reset input Reset No No Interrupt request Yes “0” IMF “1” (Interrupt release mode) Normal release mode Interrupt processing Execution of the instruction which follows the IDLE1/2 and SLEEP1/2 modes start instruction Figure 2-10 IDLE1/2 and SLEEP1/2 Modes Page 22 TMP86FS49BUG • Start the IDLE1/2 and SLEEP1/2 modes After IMF is set to "0", set the individual interrupt enable flag (EF) which releases IDLE1/2 and SLEEP1/2 modes. To start IDLE1/2 and SLEEP1/2 modes, set SYSCR2 to “1”. • Release the IDLE1/2 and SLEEP1/2 modes IDLE1/2 and SLEEP1/2 modes include a normal release mode and an interrupt release mode. These modes are selected by interrupt master enable flag (IMF). After releasing IDLE1/2 and SLEEP1/2 modes, the SYSCR2 is automatically cleared to “0” and the operation mode is returned to the mode preceding IDLE1/2 and SLEEP1/2 modes. IDLE1/2 and SLEEP1/2 modes can also be released by inputting low level on the RESET pin. After releasing reset, the operation mode is started from NORMAL1 mode. (1) Normal release mode (IMF = “0”) IDLE1/2 and SLEEP1/2 modes are released by any interrupt source enabled by the individual interrupt enable flag (EF). After the interrupt is generated, the program operation is resumed from the instruction following the IDLE1/2 and SLEEP1/2 modes start instruction. Normally, the interrupt latches (IL) of the interrupt source used for releasing must be cleared to “0” by load instructions. (2) Interrupt release mode (IMF = “1”) IDLE1/2 and SLEEP1/2 modes are released by any interrupt source enabled with the individual interrupt enable flag (EF) and the interrupt processing is started. After the interrupt is processed, the program operation is resumed from the instruction following the instruction, which starts IDLE1/2 and SLEEP1/2 modes. Note: When a watchdog timer interrupts is generated immediately before IDLE1/2 and SLEEP1/2 modes are started, the watchdog timer interrupt will be processed but IDLE1/2 and SLEEP1/2 modes will not be started. Page 23 Page 24 Figure 2-11 IDLE1/2 and SLEEP1/2 Modes Start/Release Watchdog timer Instruction execution Program counter Interrupt request Main system clock Watchdog timer Instruction execution Program counter Interrupt request Main system clock Watchdog timer Instruction execution Program counter Interrupt request Main system clock Halt Halt Halt Halt Operate Operate Operate Acceptance of interrupt Instruction address a + 2 a+4 (b) IDLE1/2 and SLEEP1/2 modes release 㽳㩷Interrupt release mode a+3 㽲㩷Normal release mode a+3 (a) IDLE1/2 and SLEEP1/2 modes start (Example: Starting with the SET instruction located at address a) Operate SET (SYSCR2). 4 a+2 Halt a+3 2.2 System Clock Controller 2. Operational Description TMP86FS49BUG TMP86FS49BUG 2.2.4.3 IDLE0 and SLEEP0 modes (IDLE0, SLEEP0) IDLE0 and SLEEP0 modes are controlled by the system control register 2 (SYSCR2) and the time base timer control register (TBTCR). The following status is maintained during IDLE0 and SLEEP0 modes. 1. Timing generator stops feeding clock to peripherals except TBT. 2. The data memory, CPU registers, program status word and port output latches are all held in the status in effect before IDLE0 and SLEEP0 modes were entered. 3. The program counter holds the address 2 ahead of the instruction which starts IDLE0 and SLEEP0 modes. Note: Before starting IDLE0 or SLEEP0 mode, be sure to stop (Disable) peripherals. Stopping peripherals by instruction Starting IDLE0, SLEEP0 modes by instruction CPU and WDT are halted Reset input Yes Reset No No TBT source clock falling edge Yes No TBTCR = "1" Yes No TBT interrupt enable Yes (Normal release mode) No IMF = "1" Yes (Interrupt release mode) Interrupt processing Execution of the instruction which follows the IDLE0, SLEEP0 modes start instruction Figure 2-12 IDLE0 and SLEEP0 Modes Page 25 2. Operational Description 2.2 System Clock Controller TMP86FS49BUG • Start the IDLE0 and SLEEP0 modes Stop (Disable) peripherals such as a timer counter. To start IDLE0 and SLEEP0 modes, set SYSCR2 to “1”. • Release the IDLE0 and SLEEP0 modes IDLE0 and SLEEP0 modes include a normal release mode and an interrupt release mode. These modes are selected by interrupt master flag (IMF), the individual interrupt enable flag of TBT and TBTCR. After releasing IDLE0 and SLEEP0 modes, the SYSCR2 is automatically cleared to “0” and the operation mode is returned to the mode preceding IDLE0 and SLEEP0 modes. Before starting the IDLE0 or SLEEP0 mode, when the TBTCR is set to “1”, INTTBT interrupt latch is set to “1”. IDLE0 and SLEEP0 modes can also be released by inputting low level on the RESET pin. After releasing reset, the operation mode is started from NORMAL1 mode. Note: IDLE0 and SLEEP0 modes start/release without reference to TBTCR setting. (1) Normal release mode (IMF•EF7•TBTCR = “0”) IDLE0 and SLEEP0 modes are released by the source clock falling edge, which is setting by the TBTCR. After the falling edge is detected, the program operation is resumed from the instruction following the IDLE0 and SLEEP0 modes start instruction. Before starting the IDLE0 or SLEEP0 mode, when the TBTCR is set to “1”, INTTBT interrupt latch is set to “1”. (2) Interrupt release mode (IMF•EF7•TBTCR = “1”) IDLE0 and SLEEP0 modes are released by the source clock falling edge, which is setting by the TBTCR and INTTBT interrupt processing is started. Note 1: Because returning from IDLE0, SLEEP0 to NORMAL1, SLOW1 is executed by the asynchronous internal clock, the period of IDLE0, SLEEP0 mode might be the shorter than the period setting by TBTCR. Note 2: When a watchdog timer interrupt is generated immediately before IDLE0/SLEEP0 mode is started, the watchdog timer interrupt will be processed but IDLE0/SLEEP0 mode will not be started. Page 26 Page 27 Figure 2-13 IDLE0 and SLEEP0 Modes Start/Release Watchdog timer Instruction execution Program counter TBT clock Halt Halt Halt Watchdog timer Main system clock Halt Instruction execution Program counter TBT clock Main system clock Watchdog timer Instruction execution Program counter Interrupt request Main system clock a+3 Halt Operate Operate (b) IDLE and SLEEP0 modes release 㽳㩷Interrupt release mode a+3 㽲㩷Normal release mode a+3 Acceptance of interrupt Instruction address a + 2 a+4 (a) IDLE0 and SLEEP0 modes start (Example: Starting with the SET instruction located at address a Operate SET (SYSCR2). 2 a+2 TMP86FS49BUG 2. Operational Description 2.2 System Clock Controller 2.2.4.4 TMP86FS49BUG SLOW mode SLOW mode is controlled by the system control register 2 (SYSCR2). The following is the methods to switch the mode with the warm-up counter. (1) Switching from NORMAL2 mode to SLOW1 mode First, set SYSCR2 to switch the main system clock to the low-frequency clock for SLOW2 mode. Next, clear SYSCR2 to turn off high-frequency oscillation. Note: The high-frequency clock can be continued oscillation in order to return to NORMAL2 mode from SLOW mode quickly. Always turn off oscillation of high-frequency clock when switching from SLOW mode to stop mode. Example 1 :Switching from NORMAL2 mode to SLOW1 mode. SET (SYSCR2). 5 ; SYSCR2 ← 1 (Switches the main system clock to the low-frequency clock for SLOW2) CLR (SYSCR2). 7 ; SYSCR2 ← 0 (Turns off high-frequency oscillation) Example 2 :Switching to the SLOW1 mode after low-frequency clock has stabilized. SET (SYSCR2). 6 ; SYSCR2 ← 1 LD (TC5CR), 43H ; Sets mode for TC6, 5 (16-bit mode, fs for source) LD (TC6CR), 05H ; Sets warming-up counter mode LDW (TTREG5), 8000H ; Sets warm-up time (Depend on oscillator accompanied) ; IMF ← 0 DI SET (EIRE). 2 ; IMF ← 1 EI SET ; Enables INTTC6 (TC6CR). 3 ; Starts TC6, 5 CLR (TC6CR). 3 ; Stops TC6, 5 SET (SYSCR2). 5 ; SYSCR2 ← 1 : PINTTC6: (Switches the main system clock to the low-frequency clock) CLR (SYSCR2). 7 ; SYSCR2 ← 0 (Turns off high-frequency oscillation) RETI : VINTTC6: DW PINTTC6 ; INTTC6 vector table Page 28 TMP86FS49BUG (2) Switching from SLOW1 mode to NORMAL2 mode First, set SYSCR2 to turn on the high-frequency oscillation. When time for stabilization (Warm up) has been taken by the timer/counter (TC6,TC5), clear SYSCR2 to switch the main system clock to the high-frequency clock. SLOW mode can also be released by inputting low level on the RESET pin. After releasing reset, the operation mode is started from NORMAL1 mode. Note: After SYSCK is cleared to “0”, executing the instructions is continiued by the low-frequency clock for the period synchronized with low-frequency and high-frequency clocks. High-frequency clock Low-frequency clock Main system clock SYSCK Example :Switching from the SLOW1 mode to the NORMAL2 mode (fc = 16 MHz, warm-up time is 4.0 ms). SET (SYSCR2). 7 ; SYSCR2 ← 1 (Starts high-frequency oscillation) LD (TC5CR), 63H ; Sets mode for TC6, 5 (16-bit mode, fc for source) LD (TC6CR), 05H ; Sets warming-up counter mode LD (TTREG6), 0F8H ; Sets warm-up time ; IMF ← 0 DI SET (EIRE). 2 ; IMF ← 1 EI SET ; Enables INTTC6 (TC6CR). 3 ; Starts TC6, 5 CLR (TC6CR). 3 ; Stops TC6, 5 CLR (SYSCR2). 5 ; SYSCR2 ← 0 : PINTTC6: (Switches the main system clock to the high-frequency clock) RETI : VINTTC6: DW PINTTC6 ; INTTC6 vector table Page 29 Page 30 Figure 2-14 Switching between the NORMAL2 and SLOW Modes SET (SYSCR2). 7 SET (SYSCR2). 5 SLOW1 mode Instruction execution XEN SYSCK Highfrequency clock Lowfrequency clock Main system clock NORMAL2 mode Instruction execution XEN SYSCK Highfrequency clock Lowfrequency clock Main system clock (b) Switching to the NORMAL2 mode Warm up during SLOW2 mode CLR (SYSCR2). 5 (a) Switching to the SLOW mode SLOW2 mode CLR (SYSCR2). 7 NORMAL2 mode SLOW1 mode Turn off 2.2 System Clock Controller 2. Operational Description TMP86FS49BUG TMP86FS49BUG 2.3 Reset Circuit The TMP86FS49BUG has four types of reset generation procedures: An external reset input, an address trap reset, a watchdog timer reset and a system clock reset. Of these reset, the address trap reset, the watchdog timer and the system clock reset are a malfunction reset. When the malfunction reset request is detected, reset occurs during the maximum 24/fc[s]. The malfunction reset circuit such as watchdog timer reset, address trap reset and system clock reset is not initialized when power is turned on. Therefore, reset may occur during maximum 24/fc[s] (1.5µs at 16.0 MHz) when power is turned on. Table 2-3 shows on-chip hardware initialization by reset action. Table 2-3 Initializing Internal Status by Reset Action On-chip Hardware Initial Value Program counter (PC) (FFFEH) Stack pointer (SP) Not initialized General-purpose registers (W, A, B, C, D, E, H, L, IX, IY) (JF) Not initialized Zero flag (ZF) Not initialized Carry flag (CF) Not initialized Half carry flag (HF) Not initialized Sign flag (SF) Not initialized Overflow flag (VF) Not initialized (IMF) 0 (EF) 0 (IL) 0 Interrupt individual enable flags Interrupt latches 2.3.1 Initial Value Prescaler and divider of timing generator 0 Not initialized Jump status flag Interrupt master enable flag On-chip Hardware Watchdog timer Enable Output latches of I/O ports Refer to I/O port circuitry Control registers Refer to each of control register RAM Not initialized External Reset Input The RESET pin contains a Schmitt trigger (Hysteresis) with an internal pull-up resistor. When the RESET pin is held at “L” level for at least 3 machine cycles (12/fc [s]) with the power supply voltage within the operating voltage range and oscillation stable, a reset is applied and the internal state is initialized. When the RESET pin input goes high, the reset operation is released and the program execution starts at the vector address stored at addresses FFFEH to FFFFH. VDD RESET Internal reset Watchdog timer reset Malfunction reset output circuit Address trap reset System clock reset Figure 2-15 Reset Circuit Page 31 2. Operational Description 2.3 Reset Circuit TMP86FS49BUG 2.3.2 Address trap reset If the CPU should start looping for some cause such as noise and an attempt be made to fetch an instruction from the on-chip RAM (when WDTCR1 is set to “1”), DBR or the SFR area, address trap reset will be generated. The reset time is maximum 24/fc[s] (1.5µs at 16.0 MHz). Note:The operating mode under address trapped is alternative of reset or interrupt. The address trap area is alternative. Instruction execution Reset release JP a Instruction at address r Address trap is occurred Internal reset maximum 24/fc [s] 4/fc to 12/fc [s] 16/fc [s] Note 1: Address “a” is in the SFR, DBR or on-chip RAM (WDTCR1 = “1”) space. Note 2: During reset release, reset vector “r” is read out, and an instruction at address “r” is fetched and decoded. Figure 2-16 Address Trap Reset 2.3.3 Watchdog timer reset Refer to Section “Watchdog Timer”. 2.3.4 System clock reset If the condition as follows is detected, the system clock reset occurs automatically to prevent dead lock of the CPU. (The oscillation is continued without stopping.) - In case of clearing SYSCR2 and SYSCR2 simultaneously to “0”. - In case of clearing SYSCR2 to “0”, when the SYSCR2 is “0”. - In case of clearing SYSCR2 to “0”, when the SYSCR2 is “1”. The reset time is maximum 24/fc (1.5 µs at 16.0 MHz). Page 32 TMP86FS49BUG Page 33 2. Operational Description 2.3 Reset Circuit TMP86FS49BUG Page 34 TMP86FS49BUG 3. Interrupt Control Circuit The TMP86FS49BUG has a total of 24 interrupt sources excluding reset. Interrupts can be nested with priorities. Four of the internal interrupt sources are non-maskable while the rest are maskable. Interrupt sources are provided with interrupt latches (IL), which hold interrupt requests, and independent vectors. The interrupt latch is set to “1” by the generation of its interrupt request which requests the CPU to accept its interrupts. Interrupts are enabled or disabled by software using the interrupt master enable flag (IMF) and interrupt enable flag (EF). If more than one interrupts are generated simultaneously, interrupts are accepted in order which is dominated by hardware. However, there are no prioritized interrupt factors among non-maskable interrupts. Interrupt Factors Internal/External Enable Condition Interrupt Latch Vector Address Priority (Reset) Non-maskable – FFFE 1 Internal INTSWI (Software interrupt) Non-maskable – FFFC 2 Internal INTUNDEF (Executed the undefined instruction interrupt) Non-maskable – FFFC 2 Internal INTATRAP (Address trap interrupt) Non-maskable IL2 FFFA 2 Internal INTWDT (Watchdog timer interrupt) Non-maskable IL3 FFF8 2 External INT0 IMF• EF4 = 1, INT0EN = 1 IL4 FFF6 5 Internal INTTC1 IMF• EF5 = 1 IL5 FFF4 6 External INT1 IMF• EF6 = 1 IL6 FFF2 7 Internal INTTBT IMF• EF7 = 1 IL7 FFF0 8 External INT2 IMF• EF8 = 1 IL8 FFEE 9 Internal INTTC4 IMF• EF9 = 1 IL9 FFEC 10 Internal INTTC3 IMF• EF10 = 1 IL10 FFEA 11 Internal INTSBI IMF• EF11 = 1 IL11 FFE8 12 External INT3 IMF• EF12 = 1 IL12 FFE6 13 Internal INTSIO1 IMF• EF13 = 1 IL13 FFE4 14 Internal INTSIO2 IMF• EF14 = 1 IL14 FFE2 15 Internal INTADC IMF• EF15 = 1 IL15 FFE0 16 Internal INTRXD1 IMF• EF16 = 1 IL16 FFBE 17 Internal INTTXD1 IMF• EF17 = 1 IL17 FFBC 18 Internal INTTC6 IMF• EF18 = 1 IL18 FFBA 19 Internal INTTC5 IMF• EF19 = 1 IL19 FFB8 20 Internal INTRXD2 IMF• EF20 = 1 IL20 FFB6 21 Internal INTTXD2 IMF• EF21 = 1 IL21 FFB4 22 Internal INTTC2 IMF• EF22 = 1 IL22 FFB2 23 External INT5 IMF• EF23 = 1 IL23 FFB0 24 Note 1: To use the address trap interrupt (INTATRAP), clear WDTCR1 to “0” (It is set for the “reset request” after reset is cancelled). For details, see “Address Trap”. Note 2: To use the watchdog timer interrupt (INTWDT), clear WDTCR1 to "0" (It is set for the "Reset request" after reset is released). For details, see "Watchdog Timer". Note 3: If an INTADC interrupt request is generated while an interrupt with priority lower than the interrupt latch IL15 (INTADC) is being accepted, the INTADC interrupt latch may be cleared without the INTADC interrupt being processed. For details, refer to the corresponding notes in the chapter on the AD converter. 3.1 Interrupt latches (IL23 to IL2) An interrupt latch is provided for each interrupt source, except for a software interrupt and an executed the undefined instruction interrupt. When interrupt request is generated, the latch is set to “1”, and the CPU is requested to accept the interrupt if its interrupt is enabled. The interrupt latch is cleared to "0" immediately after accepting interrupt. All interrupt latches are initialized to “0” during reset. Page 35 3. Interrupt Control Circuit 3.2 Interrupt enable register (EIR) TMP86FS49BUG The interrupt latches are located on address 002EH, 003CH and 003DH in SFR area. Each latch can be cleared to "0" individually by instruction. However, IL2 and IL3 should not be cleared to "0" by software. For clearing the interrupt latch, load instruction should be used and then IL2 and IL3 should be set to "1". If the read-modify-write instructions such as bit manipulation or operation instructions are used, interrupt request would be cleared inadequately if interrupt is requested while such instructions are executed. Interrupt latches are not set to “1” by an instruction. Since interrupt latches can be read, the status for interrupt requests can be monitored by software. Note: In main program, before manipulating the interrupt enable flag (EF) or the interrupt latch (IL), be sure to clear IMF to "0" (Disable interrupt by DI instruction). Then set IMF newly again as required after operating on the EF or IL (Enable interrupt by EI instruction) In interrupt service routine, because the IMF becomes "0" automatically, clearing IMF need not execute normally on interrupt service routine. However, if using multiple interrupt on interrupt service routine, manipulating EF or IL should be executed before setting IMF="1". Example 1 :Clears interrupt latches ; IMF ← 0 DI LDW (ILL), 1110100000111111B ; IL12, IL10 to IL6 ← 0 ; IMF ← 1 EI Example 2 :Reads interrupt latchess WA, (ILL) ; W ← ILH, A ← ILL TEST (ILL). 7 ; if IL7 = 1 then jump JR F, SSET LD Example 3 :Tests interrupt latches 3.2 Interrupt enable register (EIR) The interrupt enable register (EIR) enables and disables the acceptance of interrupts, except for the non-maskable interrupts (Software interrupt, undefined instruction interrupt, address trap interrupt and watchdog interrupt). Nonmaskable interrupt is accepted regardless of the contents of the EIR. The EIR consists of an interrupt master enable flag (IMF) and the individual interrupt enable flags (EF). These registers are located on address 002CH, 003AH and 003BH in SFR area, and they can be read and written by an instructions (Including read-modify-write instructions such as bit manipulation or operation instructions). 3.2.1 Interrupt master enable flag (IMF) The interrupt enable register (IMF) enables and disables the acceptance of the whole maskable interrupt. While IMF = “0”, all maskable interrupts are not accepted regardless of the status on each individual interrupt enable flag (EF). By setting IMF to “1”, the interrupt becomes acceptable if the individuals are enabled. When an interrupt is accepted, IMF is cleared to “0” after the latest status on IMF is stacked. Thus the maskable interrupts which follow are disabled. By executing return interrupt instruction [RETI/RETN], the stacked data, which was the status before interrupt acceptance, is loaded on IMF again. The IMF is located on bit0 in EIRL (Address: 003AH in SFR), and can be read and written by an instruction. The IMF is normally set and cleared by [EI] and [DI] instruction respectively. During reset, the IMF is initialized to “0”. Page 36 TMP86FS49BUG 3.2.2 Individual interrupt enable flags (EF23 to EF4) Each of these flags enables and disables the acceptance of its maskable interrupt. Setting the corresponding bit of an individual interrupt enable flag to “1” enables acceptance of its interrupt, and setting the bit to “0” disables acceptance. During reset, all the individual interrupt enable flags (EF23 to EF4) are initialized to “0” and all maskable interrupts are not accepted until they are set to “1”. Note:In main program, before manipulating the interrupt enable flag (EF) or the interrupt latch (IL), be sure to clear IMF to "0" (Disable interrupt by DI instruction). Then set IMF newly again as required after operating on the EF or IL (Enable interrupt by EI instruction) In interrupt service routine, because the IMF becomes "0" automatically, clearing IMF need not execute normally on interrupt service routine. However, if using multiple interrupt on interrupt service routine, manipulating EF or IL should be executed before setting IMF="1". Example 1 :Enables interrupts individually and sets IMF ; IMF ← 0 DI LDW : (EIRL), 1110100010100000B ; EF15 to EF13, EF11, EF7, EF5 ← 1 Note: IMF should not be set. : ; IMF ← 1 EI Example 2 :C compiler description example unsigned int _io (3AH) EIRL; /* 3AH shows EIRL address */ _DI(); EIRL = 10100000B; : _EI(); Page 37 3. Interrupt Control Circuit 3.2 Interrupt enable register (EIR) TMP86FS49BUG Interrupt Latches (Initial value: 00000000 000000**) ILH,ILL (003DH, 003CH) 15 14 13 12 11 10 9 8 7 6 5 4 3 2 IL15 IL14 IL13 IL12 IL11 IL10 IL9 IL8 IL7 IL6 IL5 IL4 IL3 IL2 ILH (003DH) 1 0 ILL (003CH) (Initial value: 00000000) ILE (002EH) 7 6 5 4 3 2 1 0 IL23 IL22 IL21 IL20 IL19 IL18 IL17 IL16 ILE (002EH) IL23 to IL2 at RD 0: No interrupt request Interrupt latches at WR 0: Clears the interrupt request 1: (Interrupt latch is not set.) 1: Interrupt request R/W Note 1: To clear any one of bits IL7 to IL4, be sure to write "1" into IL2 and IL3. Note 2: In main program, before manipulating the interrupt enable flag (EF) or the interrupt latch (IL), be sure to clear IMF to "0" (Disable interrupt by DI instruction). Then set IMF newly again as required after operating on the EF or IL (Enable interrupt by EI instruction) In interrupt service routine, because the IMF becomes "0" automatically, clearing IMF need not execute normally on interrupt service routine. However, if using multiple interrupt on interrupt service routine, manipulating EF or IL should be executed before setting IMF="1". Note 3: Do not clear IL with read-modify-write instructions such as bit operations. Interrupt Enable Registers (Initial value: 00000000 0000***0) EIRH,EIRL (003BH, 003AH) 15 14 13 EF15 EF14 EF13 12 11 10 9 8 7 6 5 EF12 EF11 EF10 EF9 EF8 EF7 EF6 EF5 EIRH (003BH) 4 3 2 1 EF4 0 IMF EIRL (003AH) (Initial value: 00000000) EIRE (002CH) 7 6 5 EF23 EF22 EF21 4 3 2 1 0 EF20 EF19 EF18 EF17 EF16 EIRE (002CH) EF23 to EF4 IMF Individual-interrupt enable flag (Specified for each bit) 0: 1: Disables the acceptance of each maskable interrupt. Enables the acceptance of each maskable interrupt. Interrupt master enable flag 0: 1: Disables the acceptance of all maskable interrupts Enables the acceptance of all maskable interrupts R/W Note 1: *: Don’t care Note 2: Do not set IMF and the interrupt enable flag (EF15 to EF4) to “1” at the same time. Note 3: In main program, before manipulating the interrupt enable flag (EF) or the interrupt latch (IL), be sure to clear IMF to "0" (Disable interrupt by DI instruction). Then set IMF newly again as required after operating on the EF or IL (Enable interrupt by EI instruction) In interrupt service routine, because the IMF becomes "0" automatically, clearing IMF need not execute normally on interrupt service routine. However, if using multiple interrupt on interrupt service routine, manipulating EF or IL should be executed before setting IMF="1". Page 38 TMP86FS49BUG 3.3 Interrupt Sequence An interrupt request, which raised interrupt latch, is held, until interrupt is accepted or interrupt latch is cleared to “0” by resetting or an instruction. Interrupt acceptance sequence requires 8 machine cycles (2 µs @16 MHz) after the completion of the current instruction. The interrupt service task terminates upon execution of an interrupt return instruction [RETI] (for maskable interrupts) or [RETN] (for non-maskable interrupts). Figure 3-1 shows the timing chart of interrupt acceptance processing. 3.3.1 Interrupt acceptance processing is packaged as follows. a. The interrupt master enable flag (IMF) is cleared to “0” in order to disable the acceptance of any following interrupt. b. The interrupt latch (IL) for the interrupt source accepted is cleared to “0”. c. The contents of the program counter (PC) and the program status word, including the interrupt master enable flag (IMF), are saved (Pushed) on the stack in sequence of PSW + IMF, PCH, PCL. Meanwhile, the stack pointer (SP) is decremented by 3. d. The entry address (Interrupt vector) of the corresponding interrupt service program, loaded on the vector table, is transferred to the program counter. e. The instruction stored at the entry address of the interrupt service program is executed. Note:When the contents of PSW are saved on the stack, the contents of IMF are also saved. Interrupt service task 1-machine cycle Interrupt request Interrupt latch (IL) IMF Execute instruction PC SP Execute instruction a−1 a Execute instruction Interrupt acceptance a+1 b a b+1 b+2 b + 3 n−1 n−2 n Execute RETI instruction c+2 c+1 a n−2 n−1 n-3 a+1 a+2 n Note 1: a: Return address entry address, b: Entry address, c: Address which RETI instruction is stored Note 2: On condition that interrupt is enabled, it takes 38/fc [s] or 38/fs [s] at maximum (If the interrupt latch is set at the first machine cycle on 10 cycle instruction) to start interrupt acceptance processing since its interrupt latch is set. Figure 3-1 Timing Chart of Interrupt Acceptance/Return Interrupt Instruction Example: Correspondence between vector table address for INTTBT and the entry address of the interrupt service program Vector table address FFF0H 03H FFF1H D2H Entry address Vector D203H 0FH D204H 06H Figure 3-2 Vector table address,Entry address Page 39 Interrupt service program 3. Interrupt Control Circuit 3.3 Interrupt Sequence TMP86FS49BUG A maskable interrupt is not accepted until the IMF is set to “1” even if the maskable interrupt higher than the level of current servicing interrupt is requested. In order to utilize nested interrupt service, the IMF is set to “1” in the interrupt service program. In this case, acceptable interrupt sources are selectively enabled by the individual interrupt enable flags. To avoid overloaded nesting, clear the individual interrupt enable flag whose interrupt is currently serviced, before setting IMF to “1”. As for non-maskable interrupt, keep interrupt service shorten compared with length between interrupt requests; otherwise the status cannot be recovered as non-maskable interrupt would simply nested. 3.3.2 Saving/restoring general-purpose registers During interrupt acceptance processing, the program counter (PC) and the program status word (PSW, includes IMF) are automatically saved on the stack, but the accumulator and others are not. These registers are saved by software if necessary. When multiple interrupt services are nested, it is also necessary to avoid using the same data memory area for saving registers. The following methods are used to save/restore the generalpurpose registers. 3.3.2.1 Using PUSH and POP instructions If only a specific register is saved or interrupts of the same source are nested, general-purpose registers can be saved/restored using the PUSH/POP instructions. Example :Save/store register using PUSH and POP instructions PINTxx: PUSH WA ; Save WA register (interrupt processing) POP WA ; Restore WA register RETI ; RETURN Address (Example) SP b-5 A SP b-4 SP b-3 PCL W PCL PCH PCH PCH PSW PSW PSW At acceptance of an interrupt At execution of PUSH instruction PCL At execution of POP instruction b-2 b-1 SP b At execution of RETI instruction Figure 3-3 Save/store register using PUSH and POP instructions 3.3.2.2 Using data transfer instructions To save only a specific register without nested interrupts, data transfer instructions are available. Page 40 TMP86FS49BUG Example :Save/store register using data transfer instructions PINTxx: LD (GSAVA), A ; Save A register (interrupt processing) LD A, (GSAVA) ; Restore A register RETI ; RETURN Main task Interrupt service task Interrupt acceptance Saving registers Restoring registers Interrupt return Saving/Restoring general-purpose registers using PUSH/POP data transfer instruction Figure 3-4 Saving/Restoring General-purpose Registers under Interrupt Processing 3.3.3 Interrupt return Interrupt return instructions [RETI]/[RETN] perform as follows. [RETI]/[RETN] Interrupt Return 1. Program counter (PC) and program status word (PSW, includes IMF) are restored from the stack. 2. Stack pointer (SP) is incremented by 3. As for address trap interrupt (INTATRAP), it is required to alter stacked data for program counter (PC) to restarting address, during interrupt service program. Note:If [RETN] is executed with the above data unaltered, the program returns to the address trap area and INTATRAP occurs again.When interrupt acceptance processing has completed, stacked data for PCL and PCH are located on address (SP + 1) and (SP + 2) respectively. Example 1 :Returning from address trap interrupt (INTATRAP) service program PINTxx: POP WA ; Recover SP by 2 LD WA, Return Address ; PUSH WA ; Alter stacked data (interrupt processing) RETN ; RETURN Page 41 3. Interrupt Control Circuit 3.4 Software Interrupt (INTSW) TMP86FS49BUG Example 2 :Restarting without returning interrupt (In this case, PSW (Includes IMF) before interrupt acceptance is discarded.) PINTxx: INC SP ; Recover SP by 3 INC SP ; INC SP ; (interrupt processing) LD EIRL, data ; Set IMF to “1” or clear it to “0” JP Restart Address ; Jump into restarting address Interrupt requests are sampled during the final cycle of the instruction being executed. Thus, the next interrupt can be accepted immediately after the interrupt return instruction is executed. Note 1: It is recommended that stack pointer be return to rate before INTATRAP (Increment 3 times), if return interrupt instruction [RETN] is not utilized during interrupt service program under INTATRAP (such as Example 2). Note 2: When the interrupt processing time is longer than the interrupt request generation time, the interrupt service task is performed but not the main task. 3.4 Software Interrupt (INTSW) Executing the SWI instruction generates a software interrupt and immediately starts interrupt processing (INTSW is highest prioritized interrupt). Use the SWI instruction only for detection of the address error or for debugging. 3.4.1 Address error detection FFH is read if for some cause such as noise the CPU attempts to fetch an instruction from a non-existent memory address during single chip mode. Code FFH is the SWI instruction, so a software interrupt is generated and an address error is detected. The address error detection range can be further expanded by writing FFH to unused areas of the program memory. Address trap reset is generated in case that an instruction is fetched from RAM, DBR or SFR areas. 3.4.2 Debugging Debugging efficiency can be increased by placing the SWI instruction at the software break point setting address. 3.5 Undefined Instruction Interrupt (INTUNDEF) Taking code which is not defined as authorized instruction for instruction causes INTUNDEF. INTUNDEF is generated when the CPU fetches such a code and tries to execute it. INTUNDEF is accepted even if non-maskable interrupt is in process. Contemporary process is broken and INTUNDEF interrupt process starts, soon after it is requested. Note: The undefined instruction interrupt (INTUNDEF) forces CPU to jump into vector address, as software interrupt (SWI) does. 3.6 Address Trap Interrupt (INTATRAP) Fetching instruction from unauthorized area for instructions (Address trapped area) causes reset output or address trap interrupt (INTATRAP). INTATRAP is accepted even if non-maskable interrupt is in process. Contemporary process is broken and INTATRAP interrupt process starts, soon after it is requested. Note: The operating mode under address trapped, whether to be reset output or interrupt processing, is selected on watchdog timer control register (WDTCR). Page 42 TMP86FS49BUG 3.7 External Interrupts The TMP86FS49BUG has 5 external interrupt inputs. These inputs are equipped with digital noise reject circuits (Pulse inputs of less than a certain time are eliminated as noise). Edge selection is also possible with INT1 to INT3. The INT0/P00 pin can be configured as either an external interrupt input pin or an input/output port, and is configured as an input port during reset. Edge selection, noise reject control and INT0/P00 pin function selection are performed by the external interrupt control register (EINTCR). Source INT0 INT1 INT2 INT3 INT5 Pin INT0 INT1 INT2 INT3 INT5 Enable Conditions Release Edge Digital Noise Reject IMF Œ EF4 Œ INT0EN=1 Falling edge Pulses of less than 2/fc [s] are eliminated as noise. Pulses of 7/fc [s] or more are considered to be signals. In the SLOW or the SLEEP mode, pulses of less than 1/fs [s] are eliminated as noise. Pulses of 3.5/fs [s] or more are considered to be signals. IMF Œ EF6 = 1 Falling edge or Rising edge Pulses of less than 15/fc or 63/fc [s] are eliminated as noise. Pulses of 49/fc or 193/fc [s] or more are considered to be signals. In the SLOW or the SLEEP mode, pulses of less than 1/fs [s] are eliminated as noise. Pulses of 3.5/fs [s] or more are considered to be signals. IMF Œ EF8 = 1 Falling edge or Rising edge Pulses of less than 7/fc [s] are eliminated as noise. Pulses of 25/fc [s] or more are considered to be signals. In the SLOW or the SLEEP mode, pulses of less than 1/fs [s] are eliminated as noise. Pulses of 3.5/fs [s] or more are considered to be signals. IMF Œ EF12 = 1 Falling edge or Rising edge Pulses of less than 7/fc [s] are eliminated as noise. Pulses of 25/fc [s] or more are considered to be signals. In the SLOW or the SLEEP mode, pulses of less than 1/fs [s] are eliminated as noise. Pulses of 3.5/fs [s] or more are considered to be signals. Falling edge Pulses of less than 2/fc [s] are eliminated as noise. Pulses of 7/fc [s] or more are considered to be signals. In the SLOW or the SLEEP mode, pulses of less than 1/fs [s] are eliminated as noise. Pulses of 3.5/fs [s] or more are considered to be signals. IMF Œ EF23 = 1 Note 1: In NORMAL1/2 or IDLE1/2 mode, if a signal with no noise is input on an external interrupt pin, it takes a maximum of "signal establishment time + 6/fs[s]" from the input signal's edge to set the interrupt latch. Note 2: When INT0EN = "0", IL4 is not set even if a falling edge is detected on the INT0 pin input. Note 3: When a pin with more than one function is used as an output and a change occurs in data or input/output status, an interrupt request signal is generated in a pseudo manner. In this case, it is necessary to perform appropriate processing such as disabling the interrupt enable flag. Page 43 3. Interrupt Control Circuit 3.7 External Interrupts TMP86FS49BUG External Interrupt Control Register EINTCR 7 6 5 4 3 2 1 (0037H) INT1NC INT0EN - - INT3ES INT2ES INT1ES 0 (Initial value: 00** 000*) INT1NC Noise reject time select 0: Pulses of less than 63/fc [s] are eliminated as noise 1: Pulses of less than 15/fc [s] are eliminated as noise R/W INT0EN P00/INT0 pin configuration 0: P00 input/output port 1: INT0 pin (Port P00 should be set to an input mode) R/W INT3 ES INT3 edge select 0: Rising edge 1: Falling edge R/W INT2 ES INT2 edge select 0: Rising edge 1: Falling edge R/W INT1 ES INT1 edge select 0: Rising edge 1: Falling edge R/W Note 1: fc: High-frequency clock [Hz], *: Don’t care Note 2: When the system clock frequency is switched between high and low or when the external interrupt control register (EINTCR) is overwritten, the noise canceller may not operate normally. It is recommended that external interrupts are disabled using the interrupt enable register (EIR). Note 3: The maximum time from modifying INT1NC until a noise reject time is changed is 26/fc. Page 44 TMP86FS49BUG 4. Special Function Register (SFR) The TMP86FS49BUG adopts the memory mapped I/O system, and all peripheral control and data transfers are performed through the special function register (SFR) or the data buffer register (DBR). The SFR is mapped on address 0000H to 003FH, DBR is mapped on address 0F80H to 0FFFH. This chapter shows the arrangement of the special function register (SFR) and data buffer register (DBR) for TMP86FS49BUG. 4.1 SFR Address Read Write 0000H P0DR 0001H P1DR 0002H P2DR 0003H P3DR 0004H P4DR 0005H P5DR 0006H P6DR 0007H P7DR 0008H P0OUTCR 0009H P1CR 000AH P4OUTCR 000BH P0PRD - 000CH P2PRD - 000DH P3PRD - 000EH P4PRD - 000FH P5PRD - 0010H TC1DRAL 0011H TC1DRAH 0012H TC1DRBL 0013H TC1DRBH 0014H TTREG3 0015H TTREG4 0016H TTREG5 0017H TTREG6 0018H PWREG3 0019H PWREG4 001AH PWREG5 001BH PWREG6 001CH ADCCR1 001DH ADCCR2 001EH ADCDR2 001FH ADCDR1 0020H SIO1CR 0021H SIO1SR - 0022H SIO1RDB SIO1TDB 0023H TC2CR 0024H TC2DRL 0025H TC2DRH Page 45 4. Special Function Register (SFR) 4.1 SFR TMP86FS49BUG Address Read Write 0026H TC1CR 0027H TC3CR 0028H TC4CR 0029H TC5CR 002AH 002BH TC6CR SIO2RDB SIO2TDB 002CH EIRE 002DH Reserved 002EH ILE 002FH Reserved 0030H Reserved 0031H SIO2CR 0032H SIO2SR 0033H Reserved 0034H - WDTCR1 0035H - WDTCR2 0036H TBTCR 0037H EINTCR 0038H SYSCR1 0039H SYSCR2 003AH EIRL 003BH EIRH 003CH ILL 003DH ILH 003EH Reserved 003FH PSW Note 1: Do not access reserved areas by the program. Note 2: − ; Cannot be accessed. Note 3: Write-only registers and interrupt latches cannot use the read-modify-write instructions (Bit manipulation instructions such as SET, CLR, etc. and logical operation instructions such as AND, OR, etc.). Page 46 TMP86FS49BUG 4.2 DBR Address Read Write 0F80H Reserved 0F81H Reserved 0F82H Reserved 0F83H Reserved 0F84H Reserved 0F85H Reserved 0F86H Reserved 0F87H Reserved 0F88H Reserved 0F89H Reserved 0F8AH Reserved 0F8BH Reserved 0F8CH Reserved 0F8DH Reserved 0F8EH Reserved 0F8FH Reserved 0F90H SBISRA 0F91H SBICRA SBIDBR 0F92H - I2CAR 0F93H SBISRB SBICRB 0F94H 0F95H Reserved UART1SR UART1CR1 0F96H - UART1CR2 0F97H RD1BUF TD1BUF 0F98H UART2SR UART2CR1 0F99H - UART2CR2 0F9AH RD2BUF TD2BUF 0F9BH P6CR1 0F9CH P6CR2 0F9DH P7CR1 0F9EH P7CR2 0F9FH - Address Read 0FA0H STOPCR Write Reserved : : : : 0FBFH Reserved Address Read 0FC0H Write Reserved : : : : 0FDFH Reserved Page 47 4. Special Function Register (SFR) 4.2 DBR TMP86FS49BUG Address Read Write 0FE0H Reserved 0FE1H Reserved 0FE2H Reserved 0FE3H Reserved 0FE4H Reserved 0FE5H Reserved 0FE6H Reserved 0FE7H Reserved 0FE8H Reserved 0FE9H Reserved 0FEAH Reserved 0FEBH Reserved 0FECH Reserved 0FEDH Reserved 0FEEH Reserved 0FEFH Reserved 0FF0H Reserved 0FF1H Reserved 0FF2H Reserved 0FF3H Reserved 0FF4H Reserved 0FF5H Reserved 0FF6H Reserved 0FF7H Reserved 0FF8H Reserved 0FF9H Reserved 0FFAH Reserved 0FFBH Reserved 0FFCH Reserved 0FFDH Reserved 0FFEH Reserved 0FFFH FLSCR Note 1: Do not access reserved areas by the program. Note 2: − ; Cannot be accessed. Note 3: Write-only registers and interrupt latches cannot use the read-modify-write instructions (Bit manipulation instructions such as SET, CLR, etc. and logical operation instructions such as AND, OR, etc.). Page 48 TMP86FS49BUG 5. I/O Ports The TMP86FS49BUG has 8 parallel input/output ports (56 pins) as follows. Primary Function Secondary Functions Port P0 8-bit I/O port External interrupt, Serial PROM mode cotrol input, serial interface input/output, UART input/output. Port P1 8-bit I/O port External interrupt, timer counter input/output, divider output. Port P2 3-bit I/O port Low-frequency resonator connections, external interrupt input, STOP mode release signal input. Port P3 8-bit I/O port Port P4 8-bit I/O port Serial interface input/output and UART input/output. Port P5 5-bit I/O port Serial bus interface input/output. Port P6 8-bit I/O port Analog input and key-on wakeup input. Port P7 8-bit I/O port Analog input. Each output port contains a latch, which holds the output data. All input ports do not have latches, so the external input data should be externally held until the input data is read from outside or reading should be performed several times before processing. Figure 5-1 shows input/output timing examples. External data is read from an I/O port in the S1 state of the read cycle during execution of the read instruction. This timing cannot be recognized from outside, so that transient input such as chattering must be processed by the program. Output data changes in the S2 state of the write cycle during execution of the instruction which writes to an I/O port. Fetch cycle S0 Instruction execution cycle S1 S2 S3 Example: LD Fetch cycle S0 S1 S2 S3 Read cycle S0 S1 S2 S3 A, (x) Input strobe Data input (a) Input timing Fetch cycle S0 Instruction execution cycle S1 S2 S3 Example: LD Fetch cycle S0 S1 S2 S3 Write cycle S0 S1 S2 S3 (x), A Output strobe Old Data output (b) Output timing Note: The positions of the read and write cycles may vary, depending on the instruction. Figure 5-1 Input/Output Timing (Example) Page 49 New 5. I/O Ports 5.1 Port P0 (P07 to P00) TMP86FS49BUG 5.1 Port P0 (P07 to P00) Port P0 is an 8-bit input/output port. Port P0 is also used as an external interrupt input, Serial PROM mode control input, a serial interface input/output and an UART input/output. When used as an input port, an external interrupt input, a serial interface input/output and an UART input/output, the corresponding output latch (P0DR) should be set to "1". During reset, the P0DR is initialized to "1", and the P0OUTCR is initialized to "0". It can be selected whether output circuit of P0 port is a C-MOS output or a sink open drain individually, by setting P0OUTCR. When a corresponding bit of P0OUTCR is "0", the output circuit is selected to a sink open drain and when a corresponding bit of P0OUTCR is "1", the output circuit is selected to a C-MOS output. When used as an input port, an external interrupt input, a serial interface input and an UART input, the corresponding output control (P0OUTCR) should be set to "0" after P0DR is set to "1". P0 port output latch (P0DR) and P0 port terminal input (P0PRD) are located on their respective address. When read the output latch data, the P0DR should be read. When read the terminal input data, the P0PRD register should be read. Table 5-1 Register Programming for Multi-function Ports (P07 to P00) Programmed Value Function P0DR P0OUTCR Port input, external interrupt input, serial interface input or UART input, Serial PROM mode cotrol input “1” “0” Port “0” output “0” Port “1” output, serial interface output or UART output “1” Programming for each applications STOP OUTEN P0OUTCRi D Q P0OUTCRi input Data input (P0PRD) Output latch read (P0DR) Data output (P0DR) Control output D Q P0i Output latch Control input Note: i = 7 to 0 Figure 5-2 Port 0 and P0OUTCR Page 50 TMP86FS49BUG P0DR (0000H) R/W 7 6 5 4 3 2 1 0 P07 INT2 P06 SCK1 P05 SO1 P04 SI1 P03 INT1 P02 TXD1 P01 RXD1 BOOT INT0 P00 (Initial value: 0000 0000) P0OUTCR (0008H) P0OUTCR P0PRD (000BH) Read only (Initial value: 1111 1111) P07 Port P0 output circuit control (Set for each bit individually) P06 P05 P04 P03 P02 Page 51 P01 0: Sink open-drain output 1: C-MOS output P00 R/W 5. I/O Ports 5.2 Port P1 (P17 to P10) TMP86FS49BUG 5.2 Port P1 (P17 to P10) Port P1 is an 8-bit input/output port which can be configured as an input or output in one-bit unit. Port P1 is also used as a timer/counter input/output, an external interrupt input and a divider output. Input/output mode is specified by the P1 control register (P1CR). During reset, the P1CR is initialized to "0" and port P1 becomes an input mode. And the P1DR is initialized to "0". When used as an input port, a timer/counter input and an external interrupt input, the corresponding bit of P1CR should be set to "0". When used as an output port, the corresponding bit of P1CR should be set to "1". When used as a timer/counter output and a divider output, P1DR is set to "1" beforehand and the corresponding bit of P1CR should be set to "1". When P1CR is "1", the content of the corresponding output latch is read by reading P1DR. Table 5-2 Register Programming for Multi-function Ports Programmed Value Function P1DR P1CR * “0” Port “0” output “0” “1” Port “1” output, a timer output or a divider output “1” “1” Port input, timer/counter input or external interrupt input Note: Asterisk (*) indicates “1” or “0” either of which can be selected. STOP OUTEN P1CRi D Q D Q P1CRi input Data input (P1DR) Data output (P1DR) P1i Output latch Control output Control input Note: i = 7 to 0 Figure 5-3 Port 1 and P1CR Note: The port set to an input mode reads the terminal input data. Therefore, when the input and output modes are used together, the content of the output latch which is specified as input mode might be changed by executing a bit Manipulation instruction. Page 52 TMP86FS49BUG P1DR (0001H) R/W 7 6 5 4 3 2 P17 TC6 P16 TC5 P14 TC4 P13 TC3 PWM6 PWM5 P15 TC2 INT3 PWM4 PWM3 PDO6 PDO5 PDO4 PDO3 PPG6 P1CR (0009H) 7 1 0 P12 P11 PPG DVO P10 TC1 (Initial value: 0000 0000) PPG4 6 5 4 3 2 1 0 (Initial value: 0000 0000) P1CR I/O control for port P1 (Specified for each bit) Page 53 0: Input mode 1: Output mode R/W 5. I/O Ports 5.3 Port P2 (P22 to P20) TMP86FS49BUG 5.3 Port P2 (P22 to P20) Port P2 is a 3-bit input/output port. It is also used as an external interrupt, a STOP mode release signal input, and low-frequency crystal oscillator connection pins. When used as an input port or a secondary function pins, respective output latch (P2DR) should be set to “1”. During reset, the P2DR is initialized to “1”. A low-frequency crystal oscillator (32.768 kHz) is connected to pins P21 (XTIN) and P22 (XTOUT) in the dualclock mode. In the single-clock mode, pins P21 and P22 can be used as normal input/output ports. It is recommended that pin P20 should be used as an external interrupt input, a STOP mode release signal input, or an input port. If it is used as an output port, the interrupt latch is set on the falling edge of the output pulse. P2 port output latch (P2DR) and P2 port terminal input (P2PRD) are located on their respective address. When read the output latch data, the P2DR should be read and when read the terminal input data, the P2PRD register should be read. If a read instruction is executed for port P2, read data of bits 7 to 3 are unstable. Data input (P20PRD) Data input (P20) Data output (P20) D P20 (INT5, STOP) Q Output latch Contorl input Data input (P21PRD) Osc. enable Output latch read (P21) Data output (P21) D P21 (XTIN) Q Output latch Data input (P22PRD) Output latch read (P22) Data output (P22) D P22 (XTOUT) Q Output latch STOP OUTEN XTEN fs Figure 5-4 Port 2 P2DR (0002H) R/W 7 6 5 4 3 2 1 0 P22 XTOUT P21 XTIN P20 INT5 (Initial value: **** *111) STOP P2PRD (000CH) Read only P22 P21 P20 Note: Port P20 is used as STOP pin. Therefore, when stop mode is started, OUTEN does not affect to P20, and P20 becomes high-Z mode. Page 54 TMP86FS49BUG 5.4 Port P3 (P37 to P30) (Large Current Port) Port P3 is an 8-bit input/output port. When used as an input port, the corresponding output latch (P3DR) should be set to "1". During reset, the P3DR is initialized to "1". P3 port output latch (P3DR) and P3 port terminal input (P3PRD) are located on their respective address. When read the output latch data, the P3DR should be read. When read the terminal input data, the P3PRD register should be read. STOP OUTEN Data input (P3PRD) Output latch read (P3DR) Data output (P3DR) D P3i Q Note: i = 7 to 0 Figure 5-5 Port 3 P3DR (0003H) 7 6 5 4 3 2 1 0 P37 P36 P35 P34 P33 P32 P31 P30 P37 P36 P35 P34 P33 P32 P31 P30 R/W P3PRD (000DH) Read only Page 55 (Initial value: 1111 1111) 5. I/O Ports 5.5 Port P4 (P47 to P40) TMP86FS49BUG 5.5 Port P4 (P47 to P40) Port P4 is an 8-bit input/output port. Port P4 is also used as a serial interface input/output and an UART input/output. When used as an input port, a serial interface input/output and an UART input/output, the corresponding output latch (P4DR) should be set to "1". During reset, the P4DR is initialized to "1", and the P4OUTCR is initialized to "0". It can be selected whether output circuit of P4 port is a C-MOS output or a sink open drain individually, by setting P4OUTCR. When a corresponding bit of P4OUTCR is "0", the output circuit is selected to a sink open drain and when a corresponding bit of P4OUTCR is "1", the output circuit is selected to a C-MOS output. When used as an input port, a serial interface input and an UART input, the corresponding output control (P4OUTCR) should be set to "0" after P4DR is set to "1". P4 port output latch (P4DR) and P4 port terminal input (P4PRD) are located on their respective address. When read the output latch data, the P4DR should be read. When read the terminal input data, the P4PRD register should be read. Table 5-3 Register Programming for Multi-function Ports (P47 to P40) Programmed Value Function P4DR P4OUTCR Port input UART input or serial interface input “1” “0” Port “0” output “0” Port “1” output UART output or serial interface output “1” Programming for each applications STOP OUTEN P4OUTCRi D Q P4OUTCRi input Data input (P4PRD) Output latch read (P4DR) Data output (P4DR) Control output D Q P4i Output latch Control input Note: i = 7 to 0 Figure 5-6 Port 4 Page 56 TMP86FS49BUG P4DR (0004H) R/W 7 P47 6 5 4 3 2 1 0 P46 P45 SO2 P44 SI2 P43 P42 TXD2 P41 RXD2 P40 SCK2 (Initial value: 0000 0000) P4OUTCR (000AH) P4OUTCR P4PRD (000EH) Read only (Initial value: 1111 1111) P47 Port P4 output circuit control (Set for each bit individually) P46 P45 P44 P43 P42 Page 57 P41 0: Sink open-drain output 1: C-MOS output P40 R/W 5. I/O Ports 5.6 Port P5 (P54 to P50) (Large Current Port) TMP86FS49BUG 5.6 Port P5 (P54 to P50) (Large Current Port) Port P5 is an 5-bit input/output port. Port P5 is also used as an I2C Bus input/output. When used as an input port and I2C Bus input/output, the corresponding output latch (P5DR) should be set to "1". During reset, the P5DR is initialized to "1". P5 port output latch (P5DR) and P5 port terminal input (P5PRD) are located on their respective address. When read the output latch data, the P5DR should be read. When read the terminal input data, the P5PRD register should be read. If a read instruction is executed for port P5, read data of bit 7 to 5 are unstable. STOP OUTEN Data input (P5PRD) Output latch read (P5DR) Data output (P5DR) D Q P5i Output latch Control output Control input Note: i = 4 to 0 Figure 5-7 Port 5 P5DR (0005H) R/W P5PRD (000FH) Read only 7 6 5 4 3 2 1 0 P54 P53 P52 P51 SDA P50 SCL P54 P53 P52 P51 P50 Page 58 (Initial value: ***1 1111) TMP86FS49BUG 5.7 Port P6 (P67 to P60) Port P6 is an 8-bit input/output port which can be configured as an input or output in one-bit unit. Port P6 is also used as an analog input and key-on wakeup input. Input/output mode is specified by the P6 control register (P6CR1) and P6 input control register (P6CR2). During reset, the P6CR1 is initialized to "0" the P6CR2 is initialized to "1" and port P6 becomes an input mode. And the P6DR is initialized to "0". When used as an output port, the corresponding bit of P6CR1 should be set to "1". When used as an input port , the corresponding bit of P6CR1 should be set to "0" and then, the corresponding bit of P6CR2 should be set to "1". When used as a key-on wakeup input , the corresponding bit of P6CR1 should be set to "0" and then, the corresponding bit of STOPkEN should be set to "1". When used as an analog input, the corresponding bit of P6CR1 should be set to "0" and then, the corresponding bit of P6CR2 should be set to "0". When P6CR1 is "1", the content of the corresponding output latch is read by reading P6DR. Table 5-4 Register Programming for Multi-function Ports Programmed Value Function P6DR P6CR1 P6CR2 STOPkEN Port input * “0” “1” * Key-on wakeup input * "0" * "1" Analog input * “0” “0” * Port “0” output “0” “1” * * Port “1” output “1” “1” * * Note: Asterisk (*) indicates “1” or “0” either of which can be selected. Table 5-5 Values Read from P6DR and Register Programming Conditions Values Read from P6DR P6CR1 P6CR2 “0” “0” “0” “0” “1” Terminal input data “0” “1” Output latch contents “1” Page 59 5. I/O Ports 5.7 Port P6 (P67 to P60) TMP86FS49BUG P6CR2i D Q D Q D Q P6CR2i input P6CR1i P6CR1i input Control input Data input (P6DRi) Data output (P6DRi) P6i STOP OUTTEN Analog input AINDS SAIN a) P63 to P60 Key-on wakeup STOPkEN P6CR2j D Q D Q D Q P6CR2j input P6CR1j P6CR1j input Data input (P6DRj) Data output (P6DRj) P6j STOP OUTTEN Analog input AINDS SAIN b) P67 to P64 Note 1: i = 3 to 0, j = 7 to 4, k = 3 to 0 Note 2: STOP is bit7 in SYSCR1. Note 3: SAIN is AD input select signal. Note 4: STOPkEN is input select signal in a key-on wakeup. Figure 5-8 Port 6, P6CR1 and P6CR2 Page 60 TMP86FS49BUG P6DR (0006H) R/W P6CR1 (0F9BH) P6CR2 (0F9CH) 7 6 5 4 3 2 1 0 P67 AIN7 STOP3 P66 AIN6 STOP2 P65 AIN5 STOP1 P64 AIN4 STOP0 P63 AIN3 P62 AIN2 P61 AIN1 P60 AIN0 7 6 5 4 3 2 1 0 (Initial value: 0000 0000) (Initial value: 0000 0000) P6CR1 I/O control for port P6 (Specified for each bit) 7 6 5 4 3 0: Input mode 1: Output mode 2 1 R/W 0 (Initial value: 1111 1111) P6CR2 P6 port input control (Specified for each bit) 0: Analog input 1: Port input R/W Note 1: The port placed in input mode reads the pin input state. Therefore, when the input and output modes are used together, the output latch contents for the port in input mode might be changed by executing a bit manipulation instruction. Note 2: When used as an analog inport, be sure to clear the corresponding bit of P6CR2 to disable the port input. Note 3: Do not set the output mode (P6CR1 = “1”) for the pin used as an analog input pin. Note 4: Pins not used for analog input can be used as I/O ports. During AD conversion, output instructions should not be executed to keep a precision. In addition, a variable signal should not be input to a port adjacent to the analog input during AD conversion. Page 61 5. I/O Ports 5.8 Port P7 (P77 to P70) TMP86FS49BUG 5.8 Port P7 (P77 to P70) Port P7 is an 8-bit input/output port which can be configured as an input or output in one-bit unit. Port P7 is also used as an analog input. Input/output mode is specified by the P7 control register (P7CR1) and P7 input control register (P7CR2). During reset, the P7CR1 is initialized to "0" the P7CR2 is initialized to "1" and port P7 becomes an input mode. And the P7DR is initialized to "0". When used as an output port, the corresponding bit of P7CR1 should be set to "1". When used as an input port, the corresponding bit of P7CR1 should be set to "0" and then, the corresponding bit of P7CR2 should be set to "1". When used as an analog input, the corresponding bit of P7CR1 should be set to "0" and then, the corresponding bit of P7CR2 should be set to "0". When P7CR1 is "1", the content of the corresponding output latch is read by reading P7DR. Table 5-6 Register Programming for Multi-function Ports Programmed Value Function P7DR P7CR1 P7CR2 Port input * “0” “1” Analog input * “0” “0” Port “0” output “0” “1” * Port “1” output “1” “1” * Note: Asterisk (*) indicates “1” or “0” either of which can be selected. Table 5-7 Values Read from P7DR and Register Programming Conditions Values Read from P7DR P7CR1 P7CR2 “0” “0” “0” “0” “1” Terminal input data “0” “1” Output latch contents “1” Page 62 TMP86FS49BUG P7CR2i D Q D Q D Q P7CR2i input P7CR1i P7CR1i input Control input Data input (P7DRi) Data output (P7DRi) P7i STOP OUTTEN Analog input AINDS SAIN Note 1: i = 7 to 0 Note 2: STOP is bit7 in SYSCR1. Note 3: SAIN is AD input select signal. Figure 5-9 Port 7, P7CR1 and P7CR2 P7DR (0007H) R/W P7CR1 (0F9DH) P7CR2 (0F9EH) 7 6 5 4 3 2 1 0 P77 AIN15 P76 AIN14 P75 AIN13 P74 AIN12 P73 AIN11 P72 AIN10 P71 AIN9 P70 AIN8 7 6 5 4 3 2 1 0 (Initial value: 0000 0000) (Initial value: 0000 0000) P7CR1 I/O control for port P7 (Specified for each bit) 7 6 5 4 3 0: Input mode 1: Output mode 2 1 R/W 0 (Initial value: 1111 1111) P7CR2 P7 port input control (Specified for each bit) 0: Analog input 1: Port input R/W Note 1: The port placed in input mode reads the pin input state. Therefore, when the input and output modes are used together, the output latch contents for the port in input mode might be changed by executing a bit manipulation instruction. Note 2: When used as an analog inport, be sure to clear the corresponding bit of P7CR2 to disable the port input. Note 3: Do not set the output mode (P7CR1 = “1”) for the pin used as an analog input pin. Note 4: Pins not used for analog input can be used as I/O ports. During AD conversion, output instructions should not be executed to keep a precision. In addition, a variable signal should not be input to a port adjacent to the analog input during AD conversion. Page 63 5. I/O Ports 5.8 Port P7 (P77 to P70) TMP86FS49BUG Page 64 TMP86FS49BUG 6. Watchdog Timer (WDT) The watchdog timer is a fail-safe system to detect rapidly the CPU malfunctions such as endless loops due to spurious noises or the deadlock conditions, and return the CPU to a system recovery routine. The watchdog timer signal for detecting malfunctions can be programmed only once as “reset request” or “interrupt request”. Upon the reset release, this signal is initialized to “reset request”. When the watchdog timer is not used to detect malfunctions, it can be used as the timer to provide a periodic interrupt. Note: Care must be taken in system design since the watchdog timer functions are not be operated completely due to effect of disturbing noise. 6.1 Watchdog Timer Configuration Reset release 23 15 Binary counters Selector fc/2 or fs/2 fc/221 or fs/213 fc/219 or fs/211 fc/217 or fs/29 Clock Clear R Overflow 1 WDT output 2 S 2 Q Interrupt request Internal reset Q S R WDTEN WDTT Writing disable code Writing clear code WDTOUT Controller 0034H WDTCR1 0035H WDTCR2 Watchdog timer control registers Figure 6-1 Watchdog Timer Configuration Page 65 Reset request INTWDT interrupt request 6. Watchdog Timer (WDT) 6.2 Watchdog Timer Control TMP86FS49BUG 6.2 Watchdog Timer Control The watchdog timer is controlled by the watchdog timer control registers (WDTCR1 and WDTCR2). The watchdog timer is automatically enabled after the reset release. 6.2.1 Malfunction Detection Methods Using the Watchdog Timer The CPU malfunction is detected, as shown below. 1. Set the detection time, select the output, and clear the binary counter. 2. Clear the binary counter repeatedly within the specified detection time. If the CPU malfunctions such as endless loops or the deadlock conditions occur for some reason, the watchdog timer output is activated by the binary-counter overflow unless the binary counters are cleared. When WDTCR1 is set to “1” at this time, the reset request is generated and then internal hardware is initialized. When WDTCR1 is set to “0”, a watchdog timer interrupt (INTWDT) is generated. The watchdog timer temporarily stops counting in the STOP mode including the warm-up or IDLE/SLEEP mode, and automatically restarts (continues counting) when the STOP/IDLE/SLEEP mode is inactivated. Note:The watchdog timer consists of an internal divider and a two-stage binary counter. When the clear code 4EH is written, only the binary counter is cleared, but not the internal divider. The minimum binary-counter overflow time, that depends on the timing at which the clear code (4EH) is written to the WDTCR2 register, may be 3/ 4 of the time set in WDTCR1. Therefore, write the clear code using a cycle shorter than 3/4 of the time set to WDTCR1. Example :Setting the watchdog timer detection time to 221/fc [s], and resetting the CPU malfunction detection Within 3/4 of WDT detection time LD (WDTCR2), 4EH : Clears the binary counters. LD (WDTCR1), 00001101B : WDTT ← 10, WDTOUT ← 1 LD (WDTCR2), 4EH : Clears the binary counters (always clears immediately before and after changing WDTT). (WDTCR2), 4EH : Clears the binary counters. (WDTCR2), 4EH : Clears the binary counters. : : LD Within 3/4 of WDT detection time : : LD Page 66 TMP86FS49BUG Watchdog Timer Control Register 1 WDTCR1 (0034H) 7 WDTEN 6 5 4 3 (ATAS) (ATOUT) WDTEN Watchdog timer enable/disable 2 1 0 WDTT WDTOUT (Initial value: **11 1001) 0: Disable (Writing the disable code to WDTCR2 is required.) 1: Enable NORMAL1/2 mode WDTT WDTOUT Watchdog timer detection time [s] Watchdog timer output select DV7CK = 0 DV7CK = 1 SLOW1/2 mode 00 225/fc 217/fs 217/fs 01 223/fc 215/fs 215fs 10 221fc 213/fs 213fs 11 219/fc 211/fs 211/fs 0: Interrupt request 1: Reset request Write only Write only Write only Note 1: After clearing WDTOUT to “0”, the program cannot set it to “1”. Note 2: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz], *: Don’t care Note 3: WDTCR1 is a write-only register and must not be used with any of read-modify-write instructions. If WDTCR1 is read, a don’t care is read. Note 4: To activate the STOP mode, disable the watchdog timer or clear the counter immediately before entering the STOP mode. After clearing the counter, clear the counter again immediately after the STOP mode is inactivated. Note 5: To clear WDTEN, set the register in accordance with the procedures shown in “6.2.3 Watchdog Timer Disable”. Watchdog Timer Control Register 2 WDTCR2 (0035H) 7 6 5 4 3 2 1 0 (Initial value: **** ****) WDTCR2 Write Watchdog timer control code 4EH: Clear the watchdog timer binary counter (Clear code) B1H: Disable the watchdog timer (Disable code) D2H: Enable assigning address trap area Others: Invalid Write only Note 1: The disable code is valid only when WDTCR1 = 0. Note 2: *: Don’t care Note 3: The binary counter of the watchdog timer must not be cleared by the interrupt task. Note 4: Write the clear code 4EH using a cycle shorter than 3/4 of the time set in WDTCR1. 6.2.2 Watchdog Timer Enable Setting WDTCR1 to “1” enables the watchdog timer. Since WDTCR1 is initialized to “1” during reset, the watchdog timer is enabled automatically after the reset release. Page 67 6. Watchdog Timer (WDT) 6.2 Watchdog Timer Control 6.2.3 TMP86FS49BUG Watchdog Timer Disable To disable the watchdog timer, set the register in accordance with the following procedures. Setting the register in other procedures causes a malfunction of the microcontroller. 1. Set the interrupt master flag (IMF) to “0”. 2. Set WDTCR2 to the clear code (4EH). 3. Set WDTCR1 to “0”. 4. Set WDTCR2 to the disable code (B1H). Note:While the watchdog timer is disabled, the binary counters of the watchdog timer are cleared. Example :Disabling the watchdog timer : IMF ← 0 DI LD (WDTCR2), 04EH : Clears the binary counter LDW (WDTCR1), 0B101H : WDTEN ← 0, WDTCR2 ← Disable code Table 6-1 Watchdog Timer Detection Time (Example: fc = 16.0 MHz, fs = 32.768 kHz) Watchdog Timer Detection Time[s] WDTT 6.2.4 NORMAL1/2 mode DV7CK = 0 DV7CK = 1 SLOW mode 00 2.097 4 4 01 524.288 m 1 1 10 131.072 m 250 m 250 m 11 32.768 m 62.5 m 62.5 m Watchdog Timer Interrupt (INTWDT) When WDTCR1 is cleared to “0”, a watchdog timer interrupt request (INTWDT) is generated by the binary-counter overflow. A watchdog timer interrupt is the non-maskable interrupt which can be accepted regardless of the interrupt master flag (IMF). When a watchdog timer interrupt is generated while the other interrupt including a watchdog timer interrupt is already accepted, the new watchdog timer interrupt is processed immediately and the previous interrupt is held pending. Therefore, if watchdog timer interrupts are generated continuously without execution of the RETN instruction, too many levels of nesting may cause a malfunction of the microcontroller. To generate a watchdog timer interrupt, set the stack pointer before setting WDTCR1. Example :Setting watchdog timer interrupt LD SP, 083FH : Sets the stack pointer LD (WDTCR1), 00001000B : WDTOUT ← 0 Page 68 TMP86FS49BUG 6.2.5 Watchdog Timer Reset When a binary-counter overflow occurs while WDTCR1 is set to “1”, a watchdog timer reset request is generated. When a watchdog timer reset request is generated, the internal hardware is reset. The reset time is maximum 24/fc [s] (1.5 µs @ fc = 16.0 MHz). Note:When a watchdog timer reset is generated in the SLOW1 mode, the reset time is maximum 24/fc (high-frequency clock) since the high-frequency clock oscillator is restarted. However, when crystals have inaccuracies upon start of the high-frequency clock oscillator, the reset time should be considered as an approximate value because it has slight errors. 219/fc [s] 217/fc Clock Binary counter (WDTT=11) 1 2 3 0 1 2 3 0 Overflow INTWDT interrupt request (WDTCR1= "0") Internal reset A reset occurs (WDTCR1= "1") Write 4EH to WDTCR2 Figure 6-2 Watchdog Timer Interrupt Page 69 6. Watchdog Timer (WDT) 6.3 Address Trap TMP86FS49BUG 6.3 Address Trap The Watchdog Timer Control Register 1 and 2 share the addresses with the control registers to generate address traps. Watchdog Timer Control Register 1 7 WDTCR1 (0034H) 6 5 4 3 ATAS ATOUT (WDTEN) 2 1 (WDTT) 0 (WDTOUT) (Initial value: **11 1001) ATAS Select address trap generation in the internal RAM area 0: Generate no address trap 1: Generate address traps (After setting ATAS to “1”, writing the control code D2H to WDTCR2 is required) ATOUT Select operation at address trap 0: Interrupt request 1: Reset request Write only Watchdog Timer Control Register 2 WDTCR2 (0035H) 7 5 4 3 2 1 0 (Initial value: **** ****) WDTCR2 6.3.1 6 Write Watchdog timer control code and address trap area control code D2H: Enable address trap area selection (ATRAP control code) 4EH: Clear the watchdog timer binary counter (WDT clear code) B1H: Disable the watchdog timer (WDT disable code) Others: Invalid Write only Selection of Address Trap in Internal RAM (ATAS) WDTCR1 specifies whether or not to generate address traps in the internal RAM area. To execute an instruction in the internal RAM area, clear WDTCR1 to “0”. To enable the WDTCR1 setting, set WDTCR1 and then write D2H to WDTCR2. Executing an instruction in the SFR or DBR area generates an address trap unconditionally regardless of the setting in WDTCR1. 6.3.2 Selection of Operation at Address Trap (ATOUT) When an address trap is generated, either the interrupt request or the reset request can be selected by WDTCR1. 6.3.3 Address Trap Interrupt (INTATRAP) While WDTCR1 is “0”, if the CPU should start looping for some cause such as noise and an attempt be made to fetch an instruction from the on-chip RAM (while WDTCR1 is “1”), DBR or the SFR area, address trap interrupt (INTATRAP) will be generated. An address trap interrupt is a non-maskable interrupt which can be accepted regardless of the interrupt master flag (IMF). When an address trap interrupt is generated while the other interrupt including an address trap interrupt is already accepted, the new address trap is processed immediately and the previous interrupt is held pending. Therefore, if address trap interrupts are generated continuously without execution of the RETN instruction, too many levels of nesting may cause a malfunction of the microcontroller. To generate address trap interrupts, set the stack pointer beforehand. Page 70 TMP86FS49BUG 6.3.4 Address Trap Reset While WDTCR1 is “1”, if the CPU should start looping for some cause such as noise and an attempt be made to fetch an instruction from the on-chip RAM (while WDTCR1 is “1”), DBR or the SFR area, address trap reset will be generated. When an address trap reset request is generated, the internal hardware is reset. The reset time is maximum 24/fc [s] (1.5 µs @ fc = 16.0 MHz). Note:When an address trap reset is generated in the SLOW1 mode, the reset time is maximum 24/fc (high-frequency clock) since the high-frequency clock oscillator is restarted. However, when crystals have inaccuracies upon start of the high-frequency clock oscillator, the reset time should be considered as an approximate value because it has slight errors. Page 71 6. Watchdog Timer (WDT) 6.3 Address Trap TMP86FS49BUG Page 72 TMP86FS49BUG 7. Time Base Timer (TBT) The time base timer generates time base for key scanning, dynamic displaying, etc. It also provides a time base timer interrupt (INTTBT). 7.1 Time Base Timer 7.1.1 Configuration MPX fc/223 or fs/215 fc/221 or fs/213 fc/216 or fs/28 fc/214 or fs/26 fc/213 or fs/25 fc/212 or fs/24 fc/211 or fs/23 fc/29 or fs/2 Source clock IDLE0, SLEEP0 release request Falling edge detector INTTBT interrupt request 3 TBTCK TBTEN TBTCR Time base timer control register Figure 7-1 Time Base Timer configuration 7.1.2 Control Time Base Timer is controlled by Time Base Timer control register (TBTCR). Time Base Timer Control Register 7 TBTCR (0036H) 6 (DVOEN) TBTEN 5 (DVOCK) Time Base Timer enable / disable 4 3 (DV7CK) TBTEN 2 1 0 TBTCK (Initial Value: 0000 0000) 0: Disable 1: Enable NORMAL1/2, IDLE1/2 Mode TBTCK Time Base Timer interrupt Frequency select : [Hz] DV7CK = 0 DV7CK = 1 SLOW1/2 SLEEP1/2 Mode 000 fc/223 fs/215 fs/215 001 fc/221 fs/213 fs/213 010 fc/216 fs/28 – 011 fc/2 14 6 – 100 fc/213 fs/25 – 101 fc/2 12 4 – 110 fc/211 fs/23 – 111 9 fs/2 – fc/2 Note 1: fc; High-frequency clock [Hz], fs; Low-frequency clock [Hz], *; Don't care Page 73 fs/2 fs/2 R/W 7. Time Base Timer (TBT) 7.1 Time Base Timer TMP86FS49BUG Note 2: The interrupt frequency (TBTCK) must be selected with the time base timer disabled (TBTEN="0"). (The interrupt frequency must not be changed with the disable from the enable state.) Both frequency selection and enabling can be performed simultaneously. Example :Set the time base timer frequency to fc/216 [Hz] and enable an INTTBT interrupt. LD (TBTCR) , 00000010B ; TBTCK ← 010 LD (TBTCR) , 00001010B ; TBTEN ← 1 ; IMF ← 0 DI SET (EIRL) . 7 Table 7-1 Time Base Timer Interrupt Frequency ( Example : fc = 16.0 MHz, fs = 32.768 kHz ) Time Base Timer Interrupt Frequency [Hz] TBTCK 7.1.3 NORMAL1/2, IDLE1/2 Mode NORMAL1/2, IDLE1/2 Mode SLOW1/2, SLEEP1/2 Mode DV7CK = 0 DV7CK = 1 000 1.91 1 1 001 7.63 4 4 010 244.14 128 – 011 976.56 512 – 100 1953.13 1024 – 101 3906.25 2048 – 110 7812.5 4096 – 111 31250 16384 – Function An INTTBT ( Time Base Timer Interrupt ) is generated on the first falling edge of source clock ( The divider output of the timing generator which is selected by TBTCK. ) after time base timer has been enabled. The divider is not cleared by the program; therefore, only the first interrupt may be generated ahead of the set interrupt period ( Figure 7-2 ). Source clock TBTCR INTTBT Interrupt period Enable TBT Figure 7-2 Time Base Timer Interrupt Page 74 TMP86FS49BUG 7.2 Divider Output (DVO) Approximately 50% duty pulse can be output using the divider output circuit, which is useful for piezoelectric buzzer drive. Divider output is from DVO pin. 7.2.1 Configuration Output latch D Data output Q DVO pin MPX A B C Y D S 2 fc/213 or fs/25 fc/212 or fs/24 fc/211 or fs/23 fc/210 or fs/22 Port output latch TBTCR DVOCK DVOEN TBTCR DVO pin output Divider output control register (a) configuration (b) Timing chart Figure 7-3 Divider Output 7.2.2 Control The Divider Output is controlled by the Time Base Timer Control Register. Time Base Timer Control Register 7 TBTCR (0036H) DVOEN DVOEN 6 5 DVOCK 4 3 (DV7CK) (TBTEN) Divider output enable / disable 2 1 0 (TBTCK) (Initial value: 0000 0000) 0: Disable 1: Enable R/W DV7CK = 0 DV7CK = 1 SLOW1/2 SLEEP1/2 Mode 00 fc/213 fs/25 fs/25 01 fc/212 fs/24 fs/24 10 fc/211 fs/23 fs/23 11 fc/210 fs/22 fs/22 NORMAL1/2, IDLE1/2 Mode DVOCK Divider Output (DVO) frequency selection: [Hz] R/W Note: Selection of divider output frequency (DVOCK) must be made while divider output is disabled (DVOEN="0"). Also, in other words, when changing the state of the divider output frequency from enabled (DVOEN="1") to disable(DVOEN="0"), do not change the setting of the divider output frequency. Page 75 7. Time Base Timer (TBT) 7.2 Divider Output (DVO) TMP86FS49BUG Example :1.95 kHz pulse output (fc = 16.0 MHz) LD (TBTCR) , 00000000B ; DVOCK ← "00" LD (TBTCR) , 10000000B ; DVOEN ← "1" Table 7-2 Divider Output Frequency ( Example : fc = 16.0 MHz, fs = 32.768 kHz ) Divider Output Frequency [Hz] DVOCK NORMAL1/2, IDLE1/2 Mode DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 Mode 00 1.953 k 1.024 k 1.024 k 01 3.906 k 2.048 k 2.048 k 10 7.813 k 4.096 k 4.096 k 11 15.625 k 8.192 k 8.192 k Page 76 B A TC1㩷㫇㫀㫅 Falling Decoder Page 77 B C fc/27 fc/23 Figure 8-1 TimerCounter 1 (TC1) S ACAP1 TC1CR Y Y S A B Source clock Start Clear Selector TC1DRA CMP PPG output mode 16-bit timer register A, B TC1DRB 16-bit up-counter MPPG1 INTTC1 interript S Match Q Enable Toggle Set Clear Pulse width measurement mode TC1S clear TFF1 PPG output mode Internal reset Write to TC1CR Note: Function I/O may not operate depending on I/O port setting. For more details, see the chapter "I/O Port". Capture Window mode TC1 control register TC1CK 2 A fc/211, fs/23 Clear Set Q Command start METT1 External trigger start D Edge detector Rising External trigger TC1S 2 Port (Note) Pulse width measurement mode Y S MCAP1 Clear Set Toggle Q Port (Note) 㪧㪧㪞 pin TMP86FS49BUG 8. 16-Bit TimerCounter 1 (TC1) 8.1 Configuration 8. 16-Bit TimerCounter 1 (TC1) 8.2 TimerCounter Control TMP86FS49BUG 8.2 TimerCounter Control The TimerCounter 1 is controlled by the TimerCounter 1 control register (TC1CR) and two 16-bit timer registers (TC1DRA and TC1DRB). Timer Register 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 TC1DRA (0011H, 0010H) TC1DRAH (0011H) TC1DRAL (0010H) (Initial value: 1111 1111 1111 1111) Read/Write TC1DRB (0013H, 0012H) TC1DRBH (0013H) TC1DRBL (0012H) (Initial value: 1111 1111 1111 1111) Read/Write (Write enabled only in the PPG output mode) TimerCounter 1 Control Register TC1CR (0026H) TFF1 7 6 TFF1 ACAP1 MCAP1 METT1 MPPG1 5 4 3 TC1S 2 1 TC1CK 0 Read/Write (Initial value: 0000 0000) TC1M Timer F/F1 control 0: Clear 1: Set ACAP1 Auto capture control 0:Auto-capture disable 1:Auto-capture enable MCAP1 Pulse width measurement mode control 0:Double edge capture 1:Single edge capture METT1 External trigger timer mode control 0:Trigger start 1:Trigger start and stop MPPG1 PPG output control 0:Continuous pulse generation 1:One-shot TC1S TC1 start control R/W R/W Timer Extrigger Event Window Pulse 00: Stop and counter clear O O O O O O 01: Command start O – – – – O 10: Rising edge start (Ex-trigger/Pulse/PPG) Rising edge count (Event) Positive logic count (Window) – O O O O O 11: Falling edge start (Ex-trigger/Pulse/PPG) Falling edge count (Event) Negative logic count (Window) – O O O O O Divider SLOW, SLEEP mode NORMAL1/2, IDLE1/2 mode TC1CK TC1 source clock select [Hz] DV7CK = 0 DV7CK = 1 00 fc/211 fs/23 DV9 fs/23 01 fc/27 fc/27 DV5 – 10 fc/23 fc/23 DV1 – 11 TC1M TC1 operating mode select PPG R/W R/W External clock (TC1 pin input) 00: Timer/external trigger timer/event counter mode 01: Window mode 10: Pulse width measurement mode 11: PPG (Programmable pulse generate) output mode R/W Note 1: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz] Note 2: The timer register consists of two shift registers. A value set in the timer register becomes valid at the rising edge of the first source clock pulse that occurs after the upper byte (TC1DRAH and TC1DRBH) is written. Therefore, write the lower byte and the upper byte in this order (it is recommended to write the register with a 16-bit access instruction). Writing only the lower byte (TC1DRAL and TC1DRBL) does not enable the setting of the timer register. Note 3: To set the mode, source clock, PPG output control and timer F/F control, write to TC1CR during TC1S=00. Set the timer F/ F1 control until the first timer start after setting the PPG mode. Page 78 TMP86FS49BUG Note 4: Auto-capture can be used only in the timer, event counter, and window modes. Note 5: To set the timer registers, the following relationship must be satisfied. TC1DRA > TC1DRB > 1 (PPG output mode), TC1DRA > 1 (other modes) Note 6: Set TFF1 to “0” in the mode except PPG output mode. Note 7: Set TC1DRB after setting TC1M to the PPG output mode. Note 8: When the STOP mode is entered, the start control (TC1S) is cleared to “00” automatically, and the timer stops. After the STOP mode is exited, set the TC1S to use the timer counter again. Note 9: Use the auto-capture function in the operative condition of TC1. A captured value may not be fixed if it's read after the execution of the timer stop or auto-capture disable. Read the capture value in a capture enabled condition. Note 10:Since the up-counter value is captured into TC1DRB by the source clock of up-counter after setting TC1CR to "1". Therefore, to read the captured value, wait at least one cycle of the internal source clock before reading TC1DRB for the first time. Page 79 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG 8.3 Function TimerCounter 1 has six types of operating modes: timer, external trigger timer, event counter, window, pulse width measurement, programmable pulse generator output modes. 8.3.1 Timer mode In the timer mode, the up-counter counts up using the internal clock. When a match between the up-counter and the timer register 1A (TC1DRA) value is detected, an INTTC1 interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting. Setting TC1CR to “1” captures the up-counter value into the timer register 1B (TC1DRB) with the auto-capture function. Use the auto-capture function in the operative condition of TC1. A captured value may not be fixed if it's read after the execution of the timer stop or auto-capture disable. Read the capture value in a capture enabled condition. Since the up-counter value is captured into TC1DRB by the source clock of up-counter after setting TC1CR to "1". Therefore, to read the captured value, wait at least one cycle of the internal source clock before reading TC1DRB for the first time. Table 8-1 Internal Source Clock for TimerCounter 1 (Example: fc = 16 MHz, fs = 32.768 kHz) NORMAL1/2, IDLE1/2 mode TC1CK SLOW, SLEEP mode DV7CK = 0 DV7CK = 1 Resolution [µs] Maximum Time Setting [s] Resolution [µs] Maximum Time Setting [s] Resolution [µs] Maximum Time Setting [s] 00 128 8.39 244.14 16.0 244.14 16.0 01 8.0 0.524 8.0 0.524 – – 10 0.5 32.77 m 0.5 32.77 m – – Example 1 :Setting the timer mode with source clock fc/211 [Hz] and generating an interrupt 1 second later (fc = 16 MHz, TBTCR = “0”) LDW ; Sets the timer register (1 s ÷ 211/fc = 1E84H) (TC1DRA), 1E84H DI SET ; IMF= “0” (EIRL). 5 ; Enables INTTC1 EI ; IMF= “1” LD (TC1CR), 00000000B ; Selects the source clock and mode LD (TC1CR), 00010000B ; Starts TC1 LD (TC1CR), 01010000B ; ACAP1 ← 1 : : LD WA, (TC1DRB) Example 2 :Auto-capture ; Reads the capture value Note: Since the up-counter value is captured into TC1DRB by the source clock of up-counter after setting TC1CR to "1". Therefore, to read the captured value, wait at least one cycle of the internal source clock before reading TC1DRB for the first time. Page 80 TMP86FS49BUG Timer start Source clock Counter 0 TC1DRA ? 1 2 3 n−1 4 n 0 1 3 2 4 5 6 n Match detect INTTC1 interruput request Counter clear (a) Timer mode Source clock m−2 Counter m−1 m m+1 m+2 n−1 Capture TC1DRB ? m−1 m n n+1 Capture m+1 m+2 ACAP1 (b) Auto-capture Figure 8-2 Timer Mode Timing Chart Page 81 n−1 n n+1 7 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG 8.3.2 External Trigger Timer Mode In the external trigger timer mode, the up-counter starts counting by the input pulse triggering of the TC1 pin, and counts up at the edge of the internal clock. For the trigger edge used to start counting, either the rising or falling edge is defined in TC1CR. • When TC1CR is set to “1” (trigger start and stop) When a match between the up-counter and the TC1DRA value is detected after the timer starts, the up-counter is cleared and halted and an INTTC1 interrupt request is generated. If the edge opposite to trigger edge is detected before detecting a match between the up-counter and the TC1DRA, the up-counter is cleared and halted without generating an interrupt request. Therefore, this mode can be used to detect exceeding the specified pulse by interrupt. After being halted, the up-counter restarts counting when the trigger edge is detected. • When TC1CR is set to “0” (trigger start) When a match between the up-counter and the TC1DRA value is detected after the timer starts, the up-counter is cleared and halted and an INTTC1 interrupt request is generated. The edge opposite to the trigger edge has no effect in count up. The trigger edge for the next counting is ignored if detecting it before detecting a match between the up-counter and the TC1DRA. Since the TC1 pin input has the noise rejection, pulses of 4/fc [s] or less are rejected as noise. A pulse width of 12/fc [s] or more is required to ensure edge detection. The rejection circuit is turned off in the SLOW1/2 or SLEEP1/2 mode, but a pulse width of one machine cycle or more is required. Example 1 :Generating an interrupt 1 ms after the rising edge of the input pulse to the TC1 pin (fc =16 MHz) LDW ; 1ms ÷ 27/fc = 7DH (TC1DRA), 007DH DI SET ; IMF= “0” (EIRL). 5 ; Enables INTTC1 interrupt EI ; IMF= “1” LD (TC1CR), 00000100B ; Selects the source clock and mode LD (TC1CR), 00100100B ; Starts TC1 external trigger, METT1 = 0 Example 2 :Generating an interrupt when the low-level pulse with 4 ms or more width is input to the TC1 pin (fc =16 MHz) LDW ; 4 ms ÷ 27/fc = 1F4H (TC1DRA), 01F4H DI SET ; IMF= “0” (EIRL). 5 ; Enables INTTC1 interrupt EI ; IMF= “1” LD (TC1CR), 00000100B ; Selects the source clock and mode LD (TC1CR), 01110100B ; Starts TC1 external trigger, METT1 = 1 Page 82 TMP86FS49BUG At the rising edge (TC1S = 10) Count start Count start TC1 pin input Source clock Up-counter 0 1 2 TC1DRA 3 n−1 n 4 n Match detect 1 0 2 3 Count clear INTTC1 interrupt request (a) Trigger start (METT1 = 0) Count clear Count start At the rising edge (TC1S = 10) Count start TC1 pin input Source clock Up-counter TC1DRA 0 1 2 m−1 m 3 0 1 2 n n 3 Match detect 0 Count clear INTTC1 interrupt request Note: m < n (b) Trigger start and stop (METT1 = 1) Figure 8-3 External Trigger Timer Mode Timing Chart Page 83 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG 8.3.3 Event Counter Mode In the event counter mode, the up-counter counts up at the edge of the input pulse to the TC1 pin. Either the rising or falling edge of the input pulse is selected as the count up edge in TC1CR. When a match between the up-counter and the TC1DRA value is detected, an INTTC1 interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting at each edge of the input pulse to the TC1 pin. Since a match between the up-counter and the value set to TC1DRA is detected at the edge opposite to the selected edge, an INTTC1 interrupt request is generated after a match of the value at the edge opposite to the selected edge. Two or more machine cycles are required for the low-or high-level pulse input to the TC1 pin. Setting TC1CR to “1” captures the up-counter value into TC1DRB with the auto capture function. Use the auto-capture function in the operative condition of TC1. A captured value may not be fixed if it's read after the execution of the timer stop or auto-capture disable. Read the capture value in a capture enabled condition. Since the up-counter value is captured into TC1DRB by the source clock of up-counter after setting TC1CR to "1". Therefore, to read the captured value, wait at least one cycle of the internal source clock before reading TC1DRB for the first time. Timer start TC1 pin Input Up-counter TC1DRA 0 ? 1 n−1 2 n 0 1 n Match detect INTTC1 interrput request Counter clear Figure 8-4 Event Counter Mode Timing Chart Table 8-2 Input Pulse Width to TC1 Pin Minimum Pulse Width [s] NORMAL1/2, IDLE1/2 Mode SLOW1/2, SLEEP1/2 Mode High-going 23/fc 23/fs Low-going 23/fc 23/fs Page 84 2 At the rising edge (TC1S = 10) TMP86FS49BUG 8.3.4 Window Mode In the window mode, the up-counter counts up at the rising edge of the pulse that is logical ANDed product of the input pulse to the TC1 pin (window pulse) and the internal source clock. Either the positive logic (count up during high-going pulse) or negative logic (count up during low-going pulse) can be selected. When a match between the up-counter and the TC1DRA value is detected, an INTTC1 interrupt is generated and the up-counter is cleared. Define the window pulse to the frequency which is sufficiently lower than the internal source clock programmed with TC1CR. Count start Count stop Count start Timer start TC1 pin input Internal clock Counter TC1DRA 0 ? 1 2 3 4 5 6 7 0 1 2 3 7 Match detect INTTC1 interrput request Counter clear (a) Positive logic (TC1S = 10) Timer start Count start Count stop Count start TC1 pin input Internal clock 0 Counter TC1DRA ? 1 2 3 4 5 6 7 8 9 0 1 9 Match detect INTTC1 interrput request (b) Negative logic (TC1S = 11) Figure 8-5 Window Mode Timing Chart Page 85 Counter clear 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG 8.3.5 Pulse Width Measurement Mode In the pulse width measurement mode, the up-counter starts counting by the input pulse triggering of the TC1 pin, and counts up at the edge of the internal clock. Either the rising or falling edge of the internal clock is selected as the trigger edge in TC1CR. Either the single- or double-edge capture is selected as the trigger edge in TC1CR. • When TC1CR is set to “1” (single-edge capture) Either high- or low-level input pulse width can be measured. To measure the high-level input pulse width, set the rising edge to TC1CR. To measure the low-level input pulse width, set the falling edge to TC1CR. When detecting the edge opposite to the trigger edge used to start counting after the timer starts, the up-counter captures the up-counter value into TC1DRB and generates an INTTC1 interrupt request. The up-counter is cleared at this time, and then restarts counting when detecting the trigger edge used to start counting. • When TC1CR is set to “0” (double-edge capture) The cycle starting with either the high- or low-going input pulse can be measured. To measure the cycle starting with the high-going pulse, set the rising edge to TC1CR. To measure the cycle starting with the low-going pulse, set the falling edge to TC1CR. When detecting the edge opposite to the trigger edge used to start counting after the timer starts, the up-counter captures the up-counter value into TC1DRB and generates an INTTC1 interrupt request. The up-counter continues counting up, and captures the up-counter value into TC1DRB and generates an INTTC1 interrupt request when detecting the trigger edge used to start counting. The up-counter is cleared at this time, and then continues counting. Note 1: The captured value must be read from TC1DRB until the next trigger edge is detected. If not read, the captured value becomes a don’t care. It is recommended to use a 16-bit access instruction to read the captured value from TC1DRB. Note 2: For the single-edge capture, the counter after capturing the value stops at “1” until detecting the next edge. Therefore, the second captured value is “1” larger than the captured value immediately after counting starts. Note 3: The first captured value after the timer starts may be read incorrectively, therefore, ignore the first captured value. Page 86 TMP86FS49BUG Example :Duty measurement (resolution fc/27 [Hz]) CLR (INTTC1SW). 0 ; INTTC1 service switch initial setting Address set to convert INTTC1SW at each INTTC1 LD (TC1CR), 00000110B ; Sets the TC1 mode and source clock DI SET ; IMF= “0” (EIRL). 5 ; Enables INTTC1 EI LD ; IMF= “1” (TC1CR), 00100110B ; Starts TC1 with an external trigger at MCAP1 = 0 CPL (INTTC1SW). 0 ; INTTC1 interrupt, inverts and tests INTTC1 service switch JRS F, SINTTC1 LD A, (TC1DRBL) LD W,(TC1DRBH) LD (HPULSE), WA ; Stores high-level pulse width in RAM A, (TC1DRBL) ; Reads TC1DRB (Cycle) : PINTTC1: ; Reads TC1DRB (High-level pulse width) RETI SINTTC1: LD LD W,(TC1DRBH) LD (WIDTH), WA ; Stores cycle in RAM : RETI ; Duty calculation : VINTTC1: DW PINTTC1 ; INTTC1 Interrupt vector WIDTH HPULSE TC1 pin INTTC1 interrupt request INTTC1SW Page 87 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG Count start TC1 pin input Count start Trigger (TC1S = "10") Internal clock Counter 0 1 2 3 4 1 Capture n n-1 n 0 TC1DRB INTTC1 interrupt request 2 3 [Application] High-or low-level pulse width measurement (a) Single-edge capture (MCAP1 = "1") Count start Count start TC1 pin input (TC1S = "10") Internal clock Counter 0 1 2 3 4 n+1 TC1DRB n n+1 n+2 n+3 Capture n m-2 m-1 m 0 1 Capture m INTTC1 interrupt request [Application] (1) Cycle/frequency measurement (2) Duty measurement (b) Double-edge capture (MCAP1 = "0") Figure 8-6 Pulse Width Measurement Mode Page 88 2 TMP86FS49BUG 8.3.6 Programmable Pulse Generate (PPG) Output Mode In the programmable pulse generation (PPG) mode, an arbitrary duty pulse is generated by counting performed in the internal clock. To start the timer, TC1CR specifies either the edge of the input pulse to the TC1 pin or the command start. TC1CR specifies whether a duty pulse is produced continuously or not (one-shot pulse). • When TC1CR is set to “0” (Continuous pulse generation) When a match between the up-counter and the TC1DRB value is detected after the timer starts, the level of the PPG pin is inverted and an INTTC1 interrupt request is generated. The up-counter continues counting. When a match between the up-counter and the TC1DRA value is detected, the level of the PPG pin is inverted and an INTTC1 interrupt request is generated. The up-counter is cleared at this time, and then continues counting and pulse generation. When TC1S is cleared to “00” during PPG output, the PPG pin retains the level immediately before the counter stops. • When TC1CR is set to “1” (One-shot pulse generation) When a match between the up-counter and the TC1DRB value is detected after the timer starts, the level of the PPG pin is inverted and an INTTC1 interrupt request is generated. The up-counter continues counting. When a match between the up-counter and the TC1DRA value is detected, the level of the PPG pin is inverted and an INTTC1 interrupt request is generated. TC1CR is cleared to “00” automatically at this time, and the timer stops. The pulse generated by PPG retains the same level as that when the timer stops. Since the output level of the PPG pin can be set with TC1CR when the timer starts, a positive or negative pulse can be generated. Since the inverted level of the timer F/F1 output level is output to the PPG pin, specify TC1CR to “0” to set the high level to the PPG pin, and “1” to set the low level to the PPG pin. Upon reset, the timer F/F1 is initialized to “0”. Note 1: To change TC1DRA or TC1DRB during a run of the timer, set a value sufficiently larger than the count value of the counter. Setting a value smaller than the count value of the counter during a run of the timer may generate a pulse different from that specified. Note 2: Do not change TC1CR during a run of the timer. TC1CR can be set correctly only at initialization (after reset). When the timer stops during PPG, TC1CR can not be set correctly from this point onward if the PPG output has the level which is inverted of the level when the timer starts. (Setting TC1CR specifies the timer F/F1 to the level inverted of the programmed value.) Therefore, the timer F/F1 needs to be initialized to ensure an arbitrary level of the PPG output. To initialize the timer F/F1, change TC1CR to the timer mode (it is not required to start the timer mode), and then set the PPG mode. Set TC1CR at this time. Note 3: In the PPG mode, the following relationship must be satisfied. TC1DRA > TC1DRB Note 4: Set TC1DRB after changing the mode of TC1M to the PPG mode. Page 89 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG Example :Generating a pulse which is high-going for 800 µs and low-going for 200 µs (fc = 16 MHz) Setting port LD (TC1CR), 10000111B ; Sets the PPG mode, selects the source clock LDW (TC1DRA), 007DH ; Sets the cycle (1 ms ÷ 27/fc ms = 007DH) LDW (TC1DRB), 0019H ; Sets the low-level pulse width (200 µs ÷ 27/fc = 0019H) LD (TC1CR), 10010111B ; Starts the timer Example :After stopping PPG, setting the PPG pin to a high-level to restart PPG (fc = 16 MHz) Setting port LD (TC1CR), 10000111B ; Sets the PPG mode, selects the source clock LDW (TC1DRA), 007DH ; Sets the cycle (1 ms ÷ 27/fc µs = 007DH) LDW (TC1DRB), 0019H ; Sets the low-level pulse width (200 µs ÷ 27/fc = 0019H) LD (TC1CR), 10010111B ; Starts the timer : : LD (TC1CR), 10000111B ; Stops the timer LD (TC1CR), 10000100B ; Sets the timer mode LD (TC1CR), 00000111B ; Sets the PPG mode, TFF1 = 0 LD (TC1CR), 00010111B ; Starts the timer I/O port output latch shared with PPG output Data output Port output enable Q D PPG pin R Function output TC1CR Set Write to TC1CR Internal reset Clear Match to TC1DRB Match to TC1DRA Q Toggle Timer F/F1 INTTC1 interrupt request TC1CR clear Figure 8-7 PPG Output Page 90 TMP86FS49BUG Timer start Internal clock Counter 0 1 TC1DRB n TC1DRA m 2 n n+1 m 0 1 2 n n+1 m 0 1 2 Match detect PPG pin output INTTC1 interrupt request Note: m > n (a) Continuous pulse generation (TC1S = 01) Count start TC1 pin input Trigger Internal clock Counter 0 TC1DRB n TC1DRA m 1 n n+1 m 0 PPG pin output INTTC1 interrupt request [Application] One-shot pulse output (b) One-shot pulse generation (TC1S = 10) Figure 8-8 PPG Mode Timing Chart Page 91 Note: m > n 8. 16-Bit TimerCounter 1 (TC1) 8.3 Function TMP86FS49BUG Page 92 TMP86FS49BUG 9. 16-Bit Timer/Counter2 (TC2) 9.1 Configuration TC2 pin Port (Note) TC2S H Window 23, 15 fc/2 fs/2 fc/213, fs/25 fc/28 fc/23 fc fs A B C D E F S 3 Clear B Timer/ event counter 16-bit up counter Y A S Source clock CMP TC2M Match INTTC2 interrupt TC2S TC2CK TC2CR TC2DR TC2 control register 16-bit timer register 2 Note: When control input/output is used, I/O port setting should be set correctly. For details, refer to the section "I/O ports". Figure 9-1 Timer/Counter2 (TC2) Page 93 9. 16-Bit Timer/Counter2 (TC2) 9.2 Control TMP86FS49BUG 9.2 Control The timer/counter 2 is controlled by a timer/counter 2 control register (TC2CR) and a 16-bit timer register 2 (TC2DR). TC2DR (0025H, 0024H) TC2CR (0023H) TC2S 15 7 14 13 12 11 10 9 8 7 6 5 2 TC2DRH (0025H) TC2DRL (0024H) R/W 6 5 4 TC2S TC2 start control 3 2 1 TC2 source clock select Unit : [Hz] TC2M 0 (Initial value: **00 00*0) 0:Stop and counter clear 1:Start R/W Divider SLOW1/2 mode SLEEP1/2 mode fs/215 DV21 fs/215 fs/215 fc/213 fs/25 DV11 fs/25 fs/25 010 fc/28 fc/28 DV6 – – 011 3 3 fc/2 DV1 – – DV7CK = 0 DV7CK = 1 000 fc/223 001 fc/2 100 – – – fc (Note7) – 101 fs fs – – – R/W Reserved External clock (TC2 pin input) 111 TC2 operating mode select 1 0 TC2CK 110 TC2M 3 (Initial value: 1111 1111 1111 1111) NORMAL1/2, IDLE1/2 mode TC2CK 4 0:Timer/event counter mode 1:Window mode R/W Note 1: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz], *: Don't care Note 2: When writing to the Timer Register 2 (TC2DR), always write to the lower side (TC2DRL) and then the upper side (TC2DRH) in that order. Writing to only the lower side (TC2DRL) or the upper side (TC2DRH) has no effect. Note 3: The timer register 2 (TC2DR) uses the value previously set in it for coincidence detection until data is written to the upper side (TC2DRH) after writing data to the lower side (TC2DRL). Note 4: Set the mode and source clock when the TC2 stops (TC2S = 0). Note 5: Values to be loaded to the timer register must satisfy the following condition. TC2DR > 1 (TC2DR15 to TC2DR11 > 1 at warm up) Note 6: If a read instruction is executed for TC2CR, read data of bit 7, 6 and 1 are unstable. Note 7: The high-frequency clock (fc) canbe selected only when the time mode at SLOW2 mode is selected. Note 8: On entering STOP mode, the TC2 start control (TC2S) is cleared to "0" automatically. So, the timer stops. Once the STOP mode has been released, to start using the timer counter, set TC2S again. Page 94 TMP86FS49BUG 9.3 Function The timer/counter 2 has three operating modes: timer, event counter and window modes. And if fc or fs is selected as the source clock in timer mode, when switching the timer mode from SLOW1 to NORMAL2, the timer/counter2 can generate warm-up time until the oscillator is stable. 9.3.1 Timer mode In this mode, the internal clock is used for counting up. The contents of TC2DR are compared with the contents of up counter. If a match is found, a timer/counter 2 interrupt (INTTC2) is generated, and the counter is cleared. Counting up is resumed after the counter is cleared. When fc is selected for source clock at SLOW2 mode, lower 11-bits of TC2DR are ignored and generated a interrupt by matching upper 5-bits only. Though, in this situation, it is necessary to set TC2DRH only. Table 9-1 Source Clock (Internal clock) for Timer/Counter2 (at fc = 16 MHz, DV7CK=0) NORMAL1/2, IDLE1/2 mode TC2C K SLOW1/2 mode DV7CK = 0 SLEEP1/2 mode DV7CK = 1 Resolution Maximum Time Setting Resolution Maximum Time Setting Resolution Maximum Time Setting Resolution Maximum Time Setting 000 524.29 [ms] 9.54 [h] 1 [s] 18.2 [h] 1 [s] 18.2 [h] 1 [s] 18.2 [h] 001 512.0 [ms] 33.55 [s] 0.98 [ms] 1.07 [min] 0.98 [ms] 1.07 [min] 0.98 [ms] 1.07 [min] 010 16.0 [ms] 1.05 [s] 16.0 [ms] 1.05 [s] – – – – 011 0.5 [ms] 32.77 [ms] 0.5 [ms] 32.77 [ms] – – – – 100 – – – – 62.5 [ns] – – – 101 30.52 [ms] 2 [s] 30.52 [ms] 2 [s] – – – – Note:When fc is selected as the source clock in timer mode, it is used at warm-up for switching from SLOW1 mode to NORMAL2 mode. Example :Sets the timer mode with source clock fc/23 [Hz] and generates an interrupt every 25 ms (at fc = 16 MHz ) LDW ; Sets TC2DR (25 ms ³ 28/fc = 061AH) (TC2DR), 061AH DI SET ; IMF= “0” (EIRE). 6 ; Enables INTTC2 interrupt EI ; IMF= “1” LD (TC2CR), 00001000B ; Source clock / mode select LD (TC2CR), 00101000B ; Starts Timer Page 95 9. 16-Bit Timer/Counter2 (TC2) 9.3 Function TMP86FS49BUG Timer start Source clock Up-counter 0 1 2 3 4 n 0 Match detect TC2DR 㫅 INTTC2 interrupt Figure 9-2 Timer Mode Timing Chart Page 96 1 2 3 Counter clear TMP86FS49BUG 9.3.2 Event counter mode In this mode, events are counted on the rising edge of the TC2 pin input. The contents of TC2DR are compared with the contents of the up counter. If a match is found, an INTTC2 interrupt is generated, and the counter is cleared. Counting up is resumed every the rising edge of the TC2 pin input after the up counter is cleared. Match detect is executed on the falling edge of the TC2 pin. Therefore, an INTTC2 interrupt is generated at the falling edge after the match of TC2DR and up counter. The minimum input pulse width of TC2 pin is shown in Table 9-2. Two or more machine cycles are required for both the “H” and “L” levels of the pulse width. Example :Sets the event counter mode and generates an INTTC2 interrupt 640 counts later. LDW (TC2DR), 640 ; Sets TC2DR DI ; IMF= “0” SET (EIRE). 6 ;Enables INTTC2 interrupt EI ; IMF= “1” LD (TC2CR), 00011100B ; TC2 source vclock / mode select LD (TC2CR), 00111100B ; Starts TC2 Table 9-2 Timer/Counter 2 External Input Clock Pulse Width Minimum Input Pulse Width [s] NORMAL1/2, IDLE1/2 mode SLOW1/2, SLEEP1/2 mode “H” width 23/fc 23/fs “L” width 23/fc 23/fs Timer start TC2 pin input 0 Counter 1 2 3 n Match detect TC2DR 0 1 2 3 Counter clear n INTTC2 interrupt Figure 9-3 Event Counter Mode Timing Chart 9.3.3 Window mode In this mode, counting up performed on the rising edge of an internal clock during TC2 external pin input (Window pulse) is “H” level. The contents of TC2DR are compared with the contents of up counter. If a match found, an INTTC2 interrupt is generated, and the up-counter is cleared. The maximum applied frequency (TC2 input) must be considerably slower than the selected internal clock by the TC2CR. Note:It is not available window mode in the SLOW/SLEEP mode. Therefore, at the window mode in NORMAL mode, the timer should be halted by setting TC2CR to "0" before the SLOW/SLEEP mode is entered. Page 97 9. 16-Bit Timer/Counter2 (TC2) 9.3 Function TMP86FS49BUG Example :Generates an interrupt, inputting “H” level pulse width of 120 ms or more. (at fc = 16 MHz, TBTCR = “0” ) LDW ; Sets TC2DR (120 ms ³ 213/fc = 00EAH) (TC2DR), 00EAH DI ; IMF= “0” SET (EIRE). 6 ; Enables INTTC2 interrupt LD (TC2CR), 00000101B ; TC2sorce clock / mode select LD (TC2CR), 00100101B ; Starts TC2 EI ; IMF= “1” Timer start TC2 pin input Internal clock Counter TC2DR 㪇 1 n 2 0 1 2 㫅 Match detect INTTC2 interrupt Figure 9-4 Window Mode Timing Chart Page 98 Counter clear 3 TMP86FS49BUG 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration PWM mode Overflow fc/211 or fs/23 7 fc/2 5 fc/2 fc/23 fs fc/2 fc TC4 pin A B C D E F G H Y A B INTTC4 interrupt request Clear Y 8-bit up-counter TC4S S PDO, PPG mode A B S 16-bit mode S TC4M TC4S TFF4 Toggle Q Set Clear Y 16-bit mode Timer, Event Counter mode S TC4CK PDO4/PWM4/ PPG4 pin Timer F/F4 A Y TC4CR B TTREG4 PWREG4 PWM, PPG mode DecodeEN PDO, PWM, PPG mode TFF4 16-bit mode TC3S PWM mode fc/211 or fs/23 fc/27 5 fc/2 3 fc/2 fs fc/2 fc TC3 pin Y 8-bit up-counter Overflow 16-bit mode PDO mode 16-bit mode Timer, Event Couter mode S TC3M TC3S TFF3 INTTC3 interrupt request Clear A B C D E F G H Toggle Q Set Clear PDO3/PWM3/ pin Timer F/F3 TC3CK TC3CR PWM mode TTREG3 PWREG3 DecodeEN TFF3 Figure 10-1 8-Bit TimerCounter 3, 4 Page 99 PDO, PWM mode 16-bit mode 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration TMP86FS49BUG 10.2 TimerCounter Control The TimerCounter 3 is controlled by the TimerCounter 3 control register (TC3CR) and two 8-bit timer registers (TTREG3, PWREG3). TimerCounter 3 Timer Register TTREG3 (0014H) R/W 7 PWREG3 (0018H) R/W 7 6 5 4 3 2 1 0 (Initial value: 1111 1111) 6 5 4 3 2 1 0 (Initial value: 1111 1111) Note 1: Do not change the timer register (TTREG3) setting while the timer is running. Note 2: Do not change the timer register (PWREG3) setting in the operating mode except the 8-bit and 16-bit PWM modes while the timer is running. TimerCounter 3 Control Register TC3CR (0027H) TFF3 7 TFF3 6 5 4 TC3CK Time F/F3 control 3 2 TC3S 0: 1: 1 0 TC3M (Initial value: 0000 0000) Clear Set R/W NORMAL1/2, IDLE1/2 mode TC3CK Operating clock selection [Hz] DV7CK = 0 DV7CK = 1 SLOW1/2 SLEEP1/2 mode 000 fc/211 fs/23 fs/23 001 fc/27 fc/27 – 010 fc/25 fc/25 – 011 fc/23 fc/23 – 100 fs fs fs 101 fc/2 fc/2 – 110 fc fc fc (Note 8) 111 TC3S TC3 start control 0: 1: 000: 001: TC3M TC3M operating mode select 010: 011: 1**: R/W TC3 pin input Operation stop and counter clear Operation start R/W 8-bit timer/event counter mode 8-bit programmable divider output (PDO) mode 8-bit pulse width modulation (PWM) output mode 16-bit mode (Each mode is selectable with TC4M.) Reserved R/W Note 1: fc: High-frequency clock [Hz] fs: Low-frequency clock[Hz] Note 2: Do not change the TC3M, TC3CK and TFF3 settings while the timer is running. Note 3: To stop the timer operation (TC3S= 1 → 0), do not change the TC3M, TC3CK and TFF3 settings. To start the timer operation (TC3S= 0 → 1), TC3M, TC3CK and TFF3 can be programmed. Note 4: To use the TimerCounter in the 16-bit mode, set the operating mode by programming TC4CR, where TC3M must be fixed to 011. Note 5: To use the TimerCounter in the 16-bit mode, select the source clock by programming TC3CK. Set the timer start control and timer F/F control by programming TC4CR and TC4CR, respectively. Note 6: The operating clock settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 10-1 and Table 10-2. Page 100 TMP86FS49BUG Note 7: The timer register settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 103. Note 8: The operating clock fc in the SLOW or SLEEP mode can be used only as the high-frequency warm-up mode. Page 101 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration TMP86FS49BUG The TimerCounter 4 is controlled by the TimerCounter 4 control register (TC4CR) and two 8-bit timer registers (TTREG4 and PWREG4). TimerCounter 4 Timer Register TTREG4 (0015H) R/W 7 PWREG4 (0019H) R/W 7 6 5 4 3 2 1 0 (Initial value: 1111 1111) 6 5 4 3 2 1 0 (Initial value: 1111 1111) Note 1: Do not change the timer register (TTREG4) setting while the timer is running. Note 2: Do not change the timer register (PWREG4) setting in the operating mode except the 8-bit and 16-bit PWM modes while the timer is running. TimerCounter 4 Control Register TC4CR (0028H) TFF4 7 TFF4 6 5 4 TC4CK Timer F/F4 control 3 2 TC4S 0: 1: 1 0 TC4M (Initial value: 0000 0000) Clear Set R/W NORMAL1/2, IDLE1/2 mode TC4CK Operating clock selection [Hz] DV7CK = 0 DV7CK = 1 SLOW1/2 SLEEP1/2 mode 000 fc/211 fs/23 fs/23 001 fc/27 fc/27 – 010 fc/25 fc/25 – 011 fc/2 3 3 – 100 fs fs fs 101 fc/2 fc/2 – 110 fc fc – 111 TC4S TC4 start control 0: 1: 000: 001: 010: TC4M TC4M operating mode select 011: 100: 101: 110: 111: fc/2 R/W TC4 pin input Operation stop and counter clear Operation start R/W 8-bit timer/event counter mode 8-bit programmable divider output (PDO) mode 8-bit pulse width modulation (PWM) output mode Reserved 16-bit timer/event counter mode Warm-up counter mode 16-bit pulse width modulation (PWM) output mode 16-bit PPG mode R/W Note 1: fc: High-frequency clock [Hz] fs: Low-frequency clock [Hz] Note 2: Do not change the TC4M, TC4CK and TFF4 settings while the timer is running. Note 3: To stop the timer operation (TC4S= 1 → 0), do not change the TC4M, TC4CK and TFF4 settings. To start the timer operation (TC4S= 0 → 1), TC4M, TC4CK and TFF4 can be programmed. Note 4: When TC4M= 1** (upper byte in the 16-bit mode), the source clock becomes the TC3 overflow signal regardless of the TC4CK setting. Note 5: To use the TimerCounter in the 16-bit mode, select the operating mode by programming TC4M, where TC3CR must be set to 011. Page 102 TMP86FS49BUG Note 6: To the TimerCounter in the 16-bit mode, select the source clock by programming TC3CR. Set the timer start control and timer F/F control by programming TC4S and TFF4, respectively. Note 7: The operating clock settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 10-1 and Table 10-2. Note 8: The timer register settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 103. Table 10-1 Operating Mode and Selectable Source Clock (NORMAL1/2 and IDLE1/2 Modes) Operating mode fc/211 or fc/27 fc/25 fc/23 fs fc/2 fc TC3 pin input TC4 pin input fs/23 8-bit timer Ο Ο Ο Ο – – – – – 8-bit event counter – – – – – – – Ο Ο 8-bit PDO Ο Ο Ο Ο – – – – – 8-bit PWM Ο Ο Ο Ο Ο Ο Ο – – 16-bit timer Ο Ο Ο Ο – – – – – 16-bit event counter – – – – – – – Ο – Warm-up counter – – – – Ο – – – – 16-bit PWM Ο Ο Ο Ο Ο Ο Ο Ο – 16-bit PPG Ο Ο Ο Ο – – – Ο – Note 1: For 16-bit operations (16-bit timer/event counter, warm-up counter, 16-bit PWM and 16-bit PPG), set its source clock on lower bit (TC3CK). Note 2: Ο : Available source clock Table 10-2 Operating Mode and Selectable Source Clock (SLOW1/2 and SLEEP1/2 Modes) Operating mode fc/211 or fc/27 fc/25 fc/23 fs fc/2 fc TC3 pin input TC4 pin input fs/23 8-bit timer Ο – – – – – – – – 8-bit event counter – – – – – – – Ο Ο 8-bit PDO Ο – – – – – – – – 8-bit PWM Ο – – – Ο – – – – 16-bit timer Ο – – – – – – – – 16-bit event counter – – – – – – – Ο – Warm-up counter – – – – – – Ο – – 16-bit PWM Ο – – – Ο – – Ο – 16-bit PPG Ο – – – – – – Ο – Note1: For 16-bit operations (16-bit timer/event counter, warm-up counter, 16-bit PWM and 16-bit PPG), set its source clock on lower bit (TC3CK). Note2: Ο : Available source clock Page 103 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration TMP86FS49BUG Table 10-3 Constraints on Register Values Being Compared Operating mode Register Value 8-bit timer/event counter 1≤ (TTREGn) ≤255 8-bit PDO 1≤ (TTREGn) ≤255 8-bit PWM 2≤ (PWREGn) ≤254 16-bit timer/event counter 1≤ (TTREG4, 3) ≤65535 Warm-up counter 256≤ (TTREG4, 3) ≤65535 16-bit PWM 2≤ (PWREG4, 3) ≤65534 16-bit PPG and (PWREG4, 3) + 1 < (TTREG4, 3) 1≤ (PWREG4, 3) < (TTREG4, 3) ≤65535 Note: n = 3 to 4 Page 104 TMP86FS49BUG 10.3 Function The TimerCounter 3 and 4 have the 8-bit timer, 8-bit event counter, 8-bit programmable divider output (PDO), 8bit pulse width modulation (PWM) output modes. The TimerCounter 3 and 4 (TC3, 4) are cascadable to form a 16bit timer. The 16-bit timer has the operating modes such as the 16-bit timer, 16-bit event counter, warm-up counter, 16-bit pulse width modulation (PWM) output and 16-bit programmable pulse generation (PPG) modes. 10.3.1 8-Bit Timer Mode (TC3 and 4) In the timer mode, the up-counter counts up using the internal clock. When a match between the up-counter and the timer register j (TTREGj) value is detected, an INTTCj interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting. Note 1: In the timer mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj and PPGj pins may output pulses. Note 2: In the timer mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the timer mode, the new value programmed in TTREGj is in effect immediately after the programming. Therefore, if TTREGi is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 3, 4 Table 10-4 Source Clock for TimerCounter 3, 4 (Internal Clock) Source Clock NORMAL1/2, IDLE1/2 mode Resolution Maximum Time Setting DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 [Hz] fs/23 [Hz] fs/23 [Hz] 128 µs 244.14 µs 32.6 ms 62.3 ms fc/27 fc/27 – 8 µs – 2.0 ms – fc/25 fc/25 – 2 µs – 510 µs – fc/23 fc/23 – 500 ns – 127.5 µs – fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz Example :Setting the timer mode with source clock fc/27 Hz and generating an interrupt 80 µs later (TimerCounter4, fc = 16.0 MHz) (TTREG4), 0AH : Sets the timer register (80 µs÷27/fc = 0AH). (EIRH). 1 : Enables INTTC4 interrupt. LD (TC4CR), 00010000B : Sets the operating clock to fc/27, and 8-bit timer mode. LD (TC4CR), 00011000B : Starts TC4. LD DI SET EI Page 105 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration TMP86FS49BUG TC4CR Internal Source Clock 1 Counter TTREG4 ? 2 3 n-1 n 0 1 2 n-1 n 0 1 2 0 n Match detect Counter clear INTTC4 interrupt request Counter clear Match detect Figure 10-2 8-Bit Timer Mode Timing Chart (TC4) 10.3.2 8-Bit Event Counter Mode (TC3, 4) In the 8-bit event counter mode, the up-counter counts up at the falling edge of the input pulse to the TCj pin. When a match between the up-counter and the TTREGj value is detected, an INTTCj interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting at the falling edge of the input pulse to the TCj pin. Two machine cycles are required for the low- or high-level pulse input to the TCj pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/24 Hz in the SLOW1/2 or SLEEP1/2 mode. Note 1: In the event counter mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj and PPGj pins may output pulses. Note 2: In the event counter mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the event counter mode, the new value programmed in TTREGj is in effect immediately after the programming. Therefore, if TTREGi is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 3, 4 TC4CR TC4 pin input 0 Counter TTREG4 ? 1 2 n-1 n 0 1 2 n-1 n 0 1 2 0 n Match detect INTTC4 interrupt request Counter clear Match detect Counter clear Figure 10-3 8-Bit Event Counter Mode Timing Chart (TC4) 10.3.3 8-Bit Programmable Divider Output (PDO) Mode (TC3, 4) This mode is used to generate a pulse with a 50% duty cycle from the PDOj pin. In the PDO mode, the up-counter counts up using the internal clock. When a match between the up-counter and the TTREGj value is detected, the logic level output from the PDOj pin is switched to the opposite state and the up-counter is cleared. The INTTCj interrupt request is generated at the time. The logic state opposite to the timer F/Fj logic level is output from the PDOj pin. An arbitrary value can be set to the timer F/Fj by TCjCR. Upon reset, the timer F/Fj value is initialized to 0. To use the programmable divider output, set the output latch of the I/O port to 1. Page 106 TMP86FS49BUG Example :Generating 1024 Hz pulse using TC4 (fc = 16.0 MHz) Setting port LD (TTREG4), 3DH : 1/1024÷27/fc÷2 = 3DH LD (TC4CR), 00010001B : Sets the operating clock to fc/27, and 8-bit PDO mode. LD (TC4CR), 00011001B : Starts TC4. Note 1: In the programmable divider output mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the programmable divider output mode, the new value programmed in TTREGj is in effect immediately after programming. Therefore, if TTREGi is changed while the timer is running, an expected operation may not be obtained. Note 2: When the timer is stopped during PDO output, the PDOj pin holds the output status when the timer is stopped. To change the output status, program TCjCR after the timer is stopped. Do not change the TCjCR setting upon stopping of the timer. Example: Fixing the PDOj pin to the high level when the TimerCounter is stopped CLR (TCjCR).3: Stops the timer. CLR (TCjCR).7: Sets the PDOj pin to the high level. Note 3: j = 3, 4 Page 107 Page 108 ? INTTC4 interrupt request PDO4 pin Timer F/F4 TTREG4 Counter Internal source clock TC4CR TC4CR 0 n 1 Match detect 2 n 0 1 Match detect 2 n 0 1 Match detect 2 n 0 1 Match detect 2 n 0 1 2 3 Set F/F Held at the level when the timer is stopped 0 Write of "1" 10.1 Configuration 10. 8-Bit TimerCounter (TC3, TC4) TMP86FS49BUG Figure 10-4 8-Bit PDO Mode Timing Chart (TC4) TMP86FS49BUG 10.3.4 8-Bit Pulse Width Modulation (PWM) Output Mode (TC3, 4) This mode is used to generate a pulse-width modulated (PWM) signals with up to 8 bits of resolution. The up-counter counts up using the internal clock. When a match between the up-counter and the PWREGj value is detected, the logic level output from the timer F/Fj is switched to the opposite state. The counter continues counting. The logic level output from the timer F/Fj is switched to the opposite state again by the up-counter overflow, and the counter is cleared. The INTTCj interrupt request is generated at this time. Since the initial value can be set to the timer F/Fj by TCjCR, positive and negative pulses can be generated. Upon reset, the timer F/Fj is cleared to 0. (The logic level output from the PWMj pin is the opposite to the timer F/Fj logic level.) Since PWREGj in the PWM mode is serially connected to the shift register, the value set to PWREGj can be changed while the timer is running. The value set to PWREGj during a run of the timer is shifted by the INTTCj interrupt request and loaded into PWREGj. While the timer is stopped, the value is shifted immediately after the programming of PWREGj. If executing the read instruction to PWREGj during PWM output, the value in the shift register is read, but not the value set in PWREGj. Therefore, after writing to PWREGj, the reading data of PWREGj is previous value until INTTCj is generated. For the pin used for PWM output, the output latch of the I/O port must be set to 1. Note 1: In the PWM mode, program the timer register PWREGj immediately after the INTTCj interrupt request is generated (normally in the INTTCj interrupt service routine.) If the programming of PWREGj and the interrupt request occur at the same time, an unstable value is shifted, that may result in generation of the pulse different from the programmed value until the next INTTCj interrupt request is generated. Note 2: When the timer is stopped during PWM output, the PWMj pin holds the output status when the timer is stopped. To change the output status, program TCjCR after the timer is stopped. Do not change the TCjCR upon stopping of the timer. Example: Fixing the PWMj pin to the high level when the TimerCounter is stopped CLR (TCjCR).3: Stops the timer. CLR (TCjCR).7: Sets the PWMj pin to the high level. Note 3: To enter the STOP mode during PWM output, stop the timer and then enter the STOP mode. If the STOP mode is entered without stopping the timer when fc, fc/2 or fs is selected as the source clock, a pulse is output from the PWMj pin during the warm-up period time after exiting the STOP mode. Note 4: j = 3, 4 Table 10-5 PWM Output Mode Source Clock NORMAL1/2, IDLE1/2 mode Resolution Repeated Cycle DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 [Hz] fs/23 [Hz] fs/23 [Hz] 128 µs 244.14 µs 32.8 ms 62.5 ms fc/2 7 – 8 µs – 2.05 ms – fc/2 5 – 2 µs – 512 µs – fc/2 7 fc/2 5 fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz fc/23 fc/23 – 500 ns – 128 µs – fs fs fs 30.5 µs 30.5 µs 7.81 ms 7.81 ms fc/2 fc/2 – 125 ns – 32 µs – fc fc – 62.5 ns – 16 µs – Page 109 Page 110 ? Shift registar 0 Shift INTTC4 interrupt request PWM4 pin Timer F/F4 ? PWREG4 Counter Internal source clock TC4CR TC4CR n n n Match detect 1 n n+1 Shift FF 0 n n n+1 m One cycle period Write to PWREG4 Match detect 1 Shift FF 0 m m m+1 Write to PWREG4 p Match detect m 1 Shift FF 0 p p Match detect 1 p 10.1 Configuration 10. 8-Bit TimerCounter (TC3, TC4) TMP86FS49BUG Figure 10-5 8-Bit PWM Mode Timing Chart (TC4) TMP86FS49BUG 10.3.5 16-Bit Timer Mode (TC3 and 4) In the timer mode, the up-counter counts up using the internal clock. The TimerCounter 3 and 4 are cascadable to form a 16-bit timer. When a match between the up-counter and the timer register (TTREG3, TTREG4) value is detected after the timer is started by setting TC4CR to 1, an INTTC4 interrupt is generated and the up-counter is cleared. After being cleared, the up-counter continues counting. Program the lower byte and upper byte in this order in the timer register. (Programming only the upper or lower byte should not be attempted.) Note 1: In the timer mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj, and PPGj pins may output a pulse. Note 2: In the timer mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the timer mode, the new value programmed in TTREGj is in effect immediately after programming of TTREGj. Therefore, if TTREGj is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 3, 4 Table 10-6 Source Clock for 16-Bit Timer Mode Source Clock Resolution NORMAL1/2, IDLE1/2 mode Maximum Time Setting DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 fs/23 fs/23 128 µs 244.14 µs 8.39 s 16 s fc/27 fc/27 – 8 µs – 524.3 ms – fc/25 fc/25 – 2 µs – 131.1 ms – fc/23 fc/23 – 500 ns – 32.8 ms – fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz Example :Setting the timer mode with source clock fc/27 Hz, and generating an interrupt 300 ms later (fc = 16.0 MHz) (TTREG3), 927CH : Sets the timer register (300 ms÷27/fc = 927CH). (EIRH). 1 : Enables INTTC4 interrupt. LD (TC3CR), 13H :Sets the operating clock to fc/27, and 16-bit timer mode (lower byte). LD (TC4CR), 04H : Sets the 16-bit timer mode (upper byte). LD (TC4CR), 0CH : Starts the timer. LDW DI SET EI TC4CR Internal source clock 0 Counter TTREG3 (Lower byte) TTREG4 (Upper byte) ? ? INTTC4 interrupt request 1 2 3 mn-1 mn 0 1 2 mn-1 mn 0 1 n m Match detect Counter clear Match detect Counter clear Figure 10-6 16-Bit Timer Mode Timing Chart (TC3 and TC4) Page 111 2 0 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration TMP86FS49BUG 10.3.6 16-Bit Event Counter Mode (TC3 and 4) In the event counter mode, the up-counter counts up at the falling edge to the TC3 pin. The TimerCounter 3 and 4 are cascadable to form a 16-bit event counter. When a match between the up-counter and the timer register (TTREG3, TTREG4) value is detected after the timer is started by setting TC4CR to 1, an INTTC4 interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting at the falling edge of the input pulse to the TC3 pin. Two machine cycles are required for the low- or high-level pulse input to the TC3 pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/ 2 in the SLOW1/2 or SLEEP1/2 mode. Program the lower byte (TTREG3), and upper byte (TTREG4) in this order in the timer register. (Programming only the upper or lower byte should not be attempted.) 4 Note 1: In the event counter mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj and PPGj pins may output pulses. Note 2: In the event counter mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the event counter mode, the new value programmed in TTREGj is in effect immediately after the programming. Therefore, if TTREGj is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 3, 4 10.3.7 16-Bit Pulse Width Modulation (PWM) Output Mode (TC3 and 4) This mode is used to generate a pulse-width modulated (PWM) signals with up to 16 bits of resolution. The TimerCounter 3 and 4 are cascadable to form the 16-bit PWM signal generator. The counter counts up using the internal clock or external clock. When a match between the up-counter and the timer register (PWREG3, PWREG4) value is detected, the logic level output from the timer F/F4 is switched to the opposite state. The counter continues counting. The logic level output from the timer F/F4 is switched to the opposite state again by the counter overflow, and the counter is cleared. The INTTC4 interrupt is generated at this time. Two machine cycles are required for the high- or low-level pulse input to the TC3 pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/24 to in the SLOW1/2 or SLEEP1/2 mode. Since the initial value can be set to the timer F/F4 by TC4CR, positive and negative pulses can be generated. Upon reset, the timer F/F4 is cleared to 0. (The logic level output from the PWM4 pin is the opposite to the timer F/F4 logic level.) Since PWREG4 and 3 in the PWM mode are serially connected to the shift register, the values set to PWREG4 and 3 can be changed while the timer is running. The values set to PWREG4 and 3 during a run of the timer are shifted by the INTTCj interrupt request and loaded into PWREG4 and 3. While the timer is stopped, the values are shifted immediately after the programming of PWREG4 and 3. Set the lower byte (PWREG3) and upper byte (PWREG4) in this order to program PWREG4 and 3. (Programming only the lower or upper byte of the register should not be attempted.) If executing the read instruction to PWREG4 and 3 during PWM output, the values set in the shift register is read, but not the values set in PWREG4 and 3. Therefore, after writing to the PWREG4 and 3, reading data of PWREG4 and 3 is previous value until INTTC4 is generated. For the pin used for PWM output, the output latch of the I/O port must be set to 1. Note 1: In the PWM mode, program the timer register PWREG4 and 3 immediately after the INTTC4 interrupt request is generated (normally in the INTTC4 interrupt service routine.) If the programming of PWREGj and the interrupt request occur at the same time, an unstable value is shifted, that may result in generation of pulse different from the programmed value until the next INTTC4 interrupt request is generated. Note 2: When the timer is stopped during PWM output, the PWM4 pin holds the output status when the timer is stopped. To change the output status, program TC4CR after the timer is stopped. Do not program TC4CR upon stopping of the timer. Example: Fixing the PWM4 pin to the high level when the TimerCounter is stopped Page 112 TMP86FS49BUG CLR (TC4CR).3: Stops the timer. CLR (TC4CR).7 : Sets the PWM4 pin to the high level. Note 3: To enter the STOP mode, stop the timer and then enter the STOP mode. If the STOP mode is entered without stopping of the timer when fc, fc/2 or fs is selected as the source clock, a pulse is output from the PWM4 pin during the warm-up period time after exiting the STOP mode. Table 10-7 16-Bit PWM Output Mode Source Clock NORMAL1/2, IDLE1/2 mode Resolution Repeated Cycle DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 fs/23 [Hz] fs/23 [Hz] 128 µs 244.14 µs 8.39 s 16 s fc/27 fc/27 – 8 µs – 524.3 ms – fc/25 fc/25 – 2 µs – 131.1 ms – fc/23 fc/23 – 500 ns – 32.8 ms – fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz fs fs fs 30.5 µs 30.5 µs 2s 2s fc/2 fc/2 – 125 ns – 8.2 ms – fc fc – 62.5 ns – 4.1 ms – Example :Generating a pulse with 1-ms high-level width and a period of 32.768 ms (fc = 16.0 MHz) Setting ports LDW (PWREG3), 07D0H : Sets the pulse width. LD (TC3CR), 33H : Sets the operating clock to fc/23, and 16-bit PWM output mode (lower byte). LD (TC4CR), 056H : Sets TFF4 to the initial value 0, and 16-bit PWM signal generation mode (upper byte). LD (TC4CR), 05EH : Starts the timer. Page 113 Page 114 ? ? PWREG4 (Upper byte) 16-bit shift register 0 a Shift INTTC4 interrupt request PWM4 pin Timer F/F4 ? PWREG3 (Lower byte) Counter Internal source clock TC4CR TC4CR an n an Match detect 1 an an+1 Shift FFFF 0 an an an+1 m b One cycle period Write to PWREG4 Write to PWREG3 Match detect 1 Shift FFFF 0 bm bm bm+1 p c Write to PWREG4 Write to PWREG3 Match detect bm 1 Shift FFFF 0 cp Match detect cp 1 cp 10.1 Configuration 10. 8-Bit TimerCounter (TC3, TC4) TMP86FS49BUG Figure 10-7 16-Bit PWM Mode Timing Chart (TC3 and TC4) TMP86FS49BUG 10.3.8 16-Bit Programmable Pulse Generate (PPG) Output Mode (TC3 and 4) This mode is used to generate pulses with up to 16-bits of resolution. The timer counter 3 and 4 are cascadable to enter the 16-bit PPG mode. The counter counts up using the internal clock or external clock. When a match between the up-counter and the timer register (PWREG3, PWREG4) value is detected, the logic level output from the timer F/F4 is switched to the opposite state. The counter continues counting. The logic level output from the timer F/F4 is switched to the opposite state again when a match between the up-counter and the timer register (TTREG3, TTREG4) value is detected, and the counter is cleared. The INTTC4 interrupt is generated at this time. Two machine cycles are required for the high- or low-level pulse input to the TC3 pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/24 to in the SLOW1/ 2 or SLEEP1/2 mode. Since the initial value can be set to the timer F/F4 by TC4CR, positive and negative pulses can be generated. Upon reset, the timer F/F4 is cleared to 0. (The logic level output from the PPG4 pin is the opposite to the timer F/F4.) Set the lower byte and upper byte in this order to program the timer register. (TTREG3 → TTREG4, PWREG3 → PWREG4) (Programming only the upper or lower byte should not be attempted.) For PPG output, set the output latch of the I/O port to 1. Example :Generating a pulse with 1-ms high-level width and a period of 16.385 ms (fc = 16.0 MHz) Setting ports LDW (PWREG3), 07D0H : Sets the pulse width. LDW (TTREG3), 8002H : Sets the cycle period. LD (TC3CR), 33H : Sets the operating clock to fc/23, and16-bit PPG mode (lower byte). LD (TC4CR), 057H : Sets TFF4 to the initial value 0, and 16-bit PPG mode (upper byte). LD (TC4CR), 05FH : Starts the timer. Note 1: In the PPG mode, do not change the PWREGi and TTREGi settings while the timer is running. Since PWREGi and TTREGi are not in the shift register configuration in the PPG mode, the new values programmed in PWREGi and TTREGi are in effect immediately after programming PWREGi and TTREGi. Therefore, if PWREGi and TTREGi are changed while the timer is running, an expected operation may not be obtained. Note 2: When the timer is stopped during PPG output, the PPG4 pin holds the output status when the timer is stopped. To change the output status, program TC4CR after the timer is stopped. Do not change TC4CR upon stopping of the timer. Example: Fixing the PPG4 pin to the high level when the TimerCounter is stopped CLR (TC4CR).3: Stops the timer CLR (TC4CR).7: Sets the PPG4 pin to the high level Note 3: i = 3, 4 Page 115 Page 116 ? TTREG4 (Upper byte) INTTC4 interrupt request PPG4 pin Timer F/F4 ? ? TTREG3 (Lower byte) PWREG4 (Upper byte) n PWREG3 (Lower byte) ? 0 Counter Internal source clock TC4CR TC4CR m r q mn Match detect 1 mn mn+1 Match detect qr-1 qr 0 mn Match detect 1 mn mn+1 Match detect qr-1 qr 0 mn Match detect 1 F/F clear 0 Held at the level when the timer stops mn mn+1 Write of "0" 10.1 Configuration 10. 8-Bit TimerCounter (TC3, TC4) TMP86FS49BUG Figure 10-8 16-Bit PPG Mode Timing Chart (TC3 and TC4) TMP86FS49BUG 10.3.9 Warm-Up Counter Mode In this mode, the warm-up period time is obtained to assure oscillation stability when the system clocking is switched between the high-frequency and low-frequency. The timer counter 3 and 4 are cascadable to form a 16-bit TimerCounter. The warm-up counter mode has two types of mode; switching from the high-frequency to low-frequency, and vice-versa. Note 1: In the warm-up counter mode, fix TCiCR to 0. If not fixed, the PDOi, PWMi and PPGi pins may output pulses. Note 2: In the warm-up counter mode, only upper 8 bits of the timer register TTREG4 and 3 are used for match detection and lower 8 bits are not used. Note 3: i = 3, 4 10.3.9.1 Low-Frequency Warm-up Counter Mode (NORMAL1 → NORMAL2 → SLOW2 → SLOW1) In this mode, the warm-up period time from a stop of the low-frequency clock fs to oscillation stability is obtained. Before starting the timer, set SYSCR2 to 1 to oscillate the low-frequency clock. When a match between the up-counter and the timer register (TTREG4, 3) value is detected after the timer is started by setting TC4CR to 1, the counter is cleared by generating the INTTC4 interrupt request. After stopping the timer in the INTTC4 interrupt service routine, set SYSCR2 to 1 to switch the system clock from the high-frequency to low-frequency, and then clear of SYSCR2 to 0 to stop the high-frequency clock. Table 10-8 Setting Time of Low-Frequency Warm-Up Counter Mode (fs = 32.768 kHz) Minimum Time Setting (TTREG4, 3 = 0100H) Maximum Time Setting (TTREG4, 3 = FF00H) 7.81 ms 1.99 s Example :After checking low-frequency clock oscillation stability with TC4 and 3, switching to the SLOW1 mode SET (SYSCR2).6 : SYSCR2 ← 1 LD (TC3CR), 43H : Sets TFF3=0, source clock fs, and 16-bit mode. LD (TC4CR), 05H : Sets TFF4=0, and warm-up counter mode. LD (TTREG3), 8000H : Sets the warm-up time. (The warm-up time depends on the oscillator characteristic.) : IMF ← 0 DI SET (EIRH). 1 : IMF ← 1 EI SET : PINTTC4: : Enables the INTTC4. (TC4CR).3 : Starts TC4 and 3. : CLR (TC4CR).3 : Stops TC4 and 3. SET (SYSCR2).5 : SYSCR2 ← 1 (Switches the system clock to the low-frequency clock.) CLR (SYSCR2).7 : SYSCR2 ← 0 (Stops the high-frequency clock.) RETI : VINTTC4: DW : PINTTC4 : INTTC4 vector table Page 117 10. 8-Bit TimerCounter (TC3, TC4) 10.1 Configuration TMP86FS49BUG 10.3.9.2 High-Frequency Warm-Up Counter Mode (SLOW1 → SLOW2 → NORMAL2 → NORMAL1) In this mode, the warm-up period time from a stop of the high-frequency clock fc to the oscillation stability is obtained. Before starting the timer, set SYSCR2 to 1 to oscillate the high-frequency clock. When a match between the up-counter and the timer register (TTREG4, 3) value is detected after the timer is started by setting TC4CR to 1, the counter is cleared by generating the INTTC4 interrupt request. After stopping the timer in the INTTC4 interrupt service routine, clear SYSCR2 to 0 to switch the system clock from the low-frequency to high-frequency, and then SYSCR2 to 0 to stop the low-frequency clock. Table 10-9 Setting Time in High-Frequency Warm-Up Counter Mode Minimum time Setting (TTREG4, 3 = 0100H) Maximum time Setting (TTREG4, 3 = FF00H) 16 µs 4.08 ms Example :After checking high-frequency clock oscillation stability with TC4 and 3, switching to the NORMAL1 mode SET (SYSCR2).7 : SYSCR2 ← 1 LD (TC3CR), 63H : Sets TFF3=0, source clock fc, and 16-bit mode. LD (TC4CR), 05H : Sets TFF4=0, and warm-up counter mode. LD (TTREG3), 0F800H : Sets the warm-up time. (The warm-up time depends on the oscillator characteristic.) : IMF ← 0 DI SET (EIRH). 1 : IMF ← 1 EI SET : PINTTC4: : Enables the INTTC4. (TC4CR).3 : Starts the TC4 and 3. : CLR (TC4CR).3 : Stops the TC4 and 3. CLR (SYSCR2).5 : SYSCR2 ← 0 (Switches the system clock to the high-frequency clock.) CLR (SYSCR2).6 : SYSCR2 ← 0 (Stops the low-frequency clock.) RETI VINTTC4: : : DW PINTTC4 : INTTC4 vector table Page 118 TMP86FS49BUG 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration PWM mode Overflow fc/211 or fs/23 7 fc/2 5 fc/2 fc/23 fs fc/2 fc TC6 pin A B C D E F G H Y A B INTTC6 interrupt request Clear Y 8-bit up-counter TC6S S PDO, PPG mode A B S 16-bit mode S TC6M TC6S TFF6 Toggle Q Set Clear Y 16-bit mode Timer, Event Counter mode S TC6CK PDO6/PWM6/ PPG6 pin Timer F/F6 A Y TC6CR B TTREG6 PWREG6 PWM, PPG mode DecodeEN PDO, PWM, PPG mode TFF6 16-bit mode TC5S PWM mode fc/211 or fs/23 fc/27 5 fc/2 3 fc/2 fs fc/2 fc TC5 pin Y 8-bit up-counter Overflow 16-bit mode PDO mode 16-bit mode Timer, Event Couter mode S TC5M TC5S TFF5 INTTC5 interrupt request Clear A B C D E F G H Toggle Q Set Clear PDO5/PWM5/ pin Timer F/F5 TC5CK TC5CR PWM mode TTREG5 PWREG5 DecodeEN TFF5 Figure 11-1 8-Bit TimerCounter 5, 6 Page 119 PDO, PWM mode 16-bit mode 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration TMP86FS49BUG 11.2 TimerCounter Control The TimerCounter 5 is controlled by the TimerCounter 5 control register (TC5CR) and two 8-bit timer registers (TTREG5, PWREG5). TimerCounter 5 Timer Register TTREG5 (0016H) R/W 7 PWREG5 (001AH) R/W 7 6 5 4 3 2 1 0 (Initial value: 1111 1111) 6 5 4 3 2 1 0 (Initial value: 1111 1111) Note 1: Do not change the timer register (TTREG5) setting while the timer is running. Note 2: Do not change the timer register (PWREG5) setting in the operating mode except the 8-bit and 16-bit PWM modes while the timer is running. TimerCounter 5 Control Register TC5CR (0029H) TFF5 7 TFF5 6 5 4 TC5CK Time F/F5 control 3 2 TC5S 0: 1: 1 0 TC5M (Initial value: 0000 0000) Clear Set R/W NORMAL1/2, IDLE1/2 mode TC5CK Operating clock selection [Hz] DV7CK = 0 DV7CK = 1 SLOW1/2 SLEEP1/2 mode 000 fc/211 fs/23 fs/23 001 fc/27 fc/27 – 010 fc/25 fc/25 – 011 fc/23 fc/23 – 100 fs fs fs 101 fc/2 fc/2 – 110 fc fc fc (Note 8) 111 TC5S TC5 start control 0: 1: 000: 001: TC5M TC5M operating mode select 010: 011: 1**: R/W TC5 pin input Operation stop and counter clear Operation start R/W 8-bit timer/event counter mode 8-bit programmable divider output (PDO) mode 8-bit pulse width modulation (PWM) output mode 16-bit mode (Each mode is selectable with TC6M.) Reserved R/W Note 1: fc: High-frequency clock [Hz] fs: Low-frequency clock[Hz] Note 2: Do not change the TC5M, TC5CK and TFF5 settings while the timer is running. Note 3: To stop the timer operation (TC5S= 1 → 0), do not change the TC5M, TC5CK and TFF5 settings. To start the timer operation (TC5S= 0 → 1), TC5M, TC5CK and TFF5 can be programmed. Note 4: To use the TimerCounter in the 16-bit mode, set the operating mode by programming TC6CR, where TC5M must be fixed to 011. Note 5: To use the TimerCounter in the 16-bit mode, select the source clock by programming TC5CK. Set the timer start control and timer F/F control by programming TC6CR and TC6CR, respectively. Note 6: The operating clock settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 11-1 and Table 11-2. Page 120 TMP86FS49BUG Note 7: The timer register settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 113. Note 8: The operating clock fc in the SLOW or SLEEP mode can be used only as the high-frequency warm-up mode. Page 121 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration TMP86FS49BUG The TimerCounter 6 is controlled by the TimerCounter 6 control register (TC6CR) and two 8-bit timer registers (TTREG6 and PWREG6). TimerCounter 6 Timer Register TTREG6 (0017H) R/W 7 PWREG6 (001BH) R/W 7 6 5 4 3 2 1 0 (Initial value: 1111 1111) 6 5 4 3 2 1 0 (Initial value: 1111 1111) Note 1: Do not change the timer register (TTREG6) setting while the timer is running. Note 2: Do not change the timer register (PWREG6) setting in the operating mode except the 8-bit and 16-bit PWM modes while the timer is running. TimerCounter 6 Control Register TC6CR (002AH) TFF6 7 TFF6 6 5 4 TC6CK Timer F/F6 control 3 2 TC6S 0: 1: 1 0 TC6M (Initial value: 0000 0000) Clear Set R/W NORMAL1/2, IDLE1/2 mode TC6CK Operating clock selection [Hz] DV7CK = 0 DV7CK = 1 SLOW1/2 SLEEP1/2 mode 000 fc/211 fs/23 fs/23 001 fc/27 fc/27 – 010 fc/25 fc/25 – 011 fc/2 3 3 – 100 fs fs fs 101 fc/2 fc/2 – 110 fc fc – 111 TC6S TC6 start control 0: 1: 000: 001: 010: TC6M TC6M operating mode select 011: 100: 101: 110: 111: fc/2 R/W TC6 pin input Operation stop and counter clear Operation start R/W 8-bit timer/event counter mode 8-bit programmable divider output (PDO) mode 8-bit pulse width modulation (PWM) output mode Reserved 16-bit timer/event counter mode Warm-up counter mode 16-bit pulse width modulation (PWM) output mode 16-bit PPG mode R/W Note 1: fc: High-frequency clock [Hz] fs: Low-frequency clock [Hz] Note 2: Do not change the TC6M, TC6CK and TFF6 settings while the timer is running. Note 3: To stop the timer operation (TC6S= 1 → 0), do not change the TC6M, TC6CK and TFF6 settings. To start the timer operation (TC6S= 0 → 1), TC6M, TC6CK and TFF6 can be programmed. Note 4: When TC6M= 1** (upper byte in the 16-bit mode), the source clock becomes the TC5 overflow signal regardless of the TC6CK setting. Note 5: To use the TimerCounter in the 16-bit mode, select the operating mode by programming TC6M, where TC5CR must be set to 011. Page 122 TMP86FS49BUG Note 6: To the TimerCounter in the 16-bit mode, select the source clock by programming TC5CR. Set the timer start control and timer F/F control by programming TC6S and TFF6, respectively. Note 7: The operating clock settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 11-1 and Table 11-2. Note 8: The timer register settings are limited depending on the timer operating mode. For the detailed descriptions, see Table 113. Table 11-1 Operating Mode and Selectable Source Clock (NORMAL1/2 and IDLE1/2 Modes) Operating mode fc/211 or fc/27 fc/25 fc/23 fs fc/2 fc TC5 pin input TC6 pin input fs/23 8-bit timer Ο Ο Ο Ο – – – – – 8-bit event counter – – – – – – – Ο Ο 8-bit PDO Ο Ο Ο Ο – – – – – 8-bit PWM Ο Ο Ο Ο Ο Ο Ο – – 16-bit timer Ο Ο Ο Ο – – – – – 16-bit event counter – – – – – – – Ο – Warm-up counter – – – – Ο – – – – 16-bit PWM Ο Ο Ο Ο Ο Ο Ο Ο – 16-bit PPG Ο Ο Ο Ο – – – Ο – Note 1: For 16-bit operations (16-bit timer/event counter, warm-up counter, 16-bit PWM and 16-bit PPG), set its source clock on lower bit (TC5CK). Note 2: Ο : Available source clock Table 11-2 Operating Mode and Selectable Source Clock (SLOW1/2 and SLEEP1/2 Modes) Operating mode fc/211 or fc/27 fc/25 fc/23 fs fc/2 fc TC5 pin input TC6 pin input fs/23 8-bit timer Ο – – – – – – – – 8-bit event counter – – – – – – – Ο Ο 8-bit PDO Ο – – – – – – – – 8-bit PWM Ο – – – Ο – – – – 16-bit timer Ο – – – – – – – – 16-bit event counter – – – – – – – Ο – Warm-up counter – – – – – – Ο – – 16-bit PWM Ο – – – Ο – – Ο – 16-bit PPG Ο – – – – – – Ο – Note1: For 16-bit operations (16-bit timer/event counter, warm-up counter, 16-bit PWM and 16-bit PPG), set its source clock on lower bit (TC5CK). Note2: Ο : Available source clock Page 123 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration TMP86FS49BUG Table 11-3 Constraints on Register Values Being Compared Operating mode Register Value 8-bit timer/event counter 1≤ (TTREGn) ≤255 8-bit PDO 1≤ (TTREGn) ≤255 8-bit PWM 2≤ (PWREGn) ≤254 16-bit timer/event counter 1≤ (TTREG6, 5) ≤65535 Warm-up counter 256≤ (TTREG6, 5) ≤65535 16-bit PWM 2≤ (PWREG6, 5) ≤65534 16-bit PPG and (PWREG6, 5) + 1 < (TTREG6, 5) 1≤ (PWREG6, 5) < (TTREG6, 5) ≤65535 Note: n = 5 to 6 Page 124 TMP86FS49BUG 11.3 Function The TimerCounter 5 and 6 have the 8-bit timer, 8-bit event counter, 8-bit programmable divider output (PDO), 8bit pulse width modulation (PWM) output modes. The TimerCounter 5 and 6 (TC5, 6) are cascadable to form a 16bit timer. The 16-bit timer has the operating modes such as the 16-bit timer, 16-bit event counter, warm-up counter, 16-bit pulse width modulation (PWM) output and 16-bit programmable pulse generation (PPG) modes. 11.3.1 8-Bit Timer Mode (TC5 and 6) In the timer mode, the up-counter counts up using the internal clock. When a match between the up-counter and the timer register j (TTREGj) value is detected, an INTTCj interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting. Note 1: In the timer mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj and PPGj pins may output pulses. Note 2: In the timer mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the timer mode, the new value programmed in TTREGj is in effect immediately after the programming. Therefore, if TTREGi is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 5, 6 Table 11-4 Source Clock for TimerCounter 5, 6 (Internal Clock) Source Clock NORMAL1/2, IDLE1/2 mode Resolution Maximum Time Setting DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 [Hz] fs/23 [Hz] fs/23 [Hz] 128 µs 244.14 µs 32.6 ms 62.3 ms fc/27 fc/27 – 8 µs – 2.0 ms – fc/25 fc/25 – 2 µs – 510 µs – fc/23 fc/23 – 500 ns – 127.5 µs – fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz Example :Setting the timer mode with source clock fc/27 Hz and generating an interrupt 80 µs later (TimerCounter6, fc = 16.0 MHz) (TTREG6), 0AH : Sets the timer register (80 µs÷27/fc = 0AH). (EIRE). 2 : Enables INTTC6 interrupt. LD (TC6CR), 00010000B : Sets the operating clock to fc/27, and 8-bit timer mode. LD (TC6CR), 00011000B : Starts TC6. LD DI SET EI Page 125 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration TMP86FS49BUG TC6CR Internal Source Clock 1 Counter TTREG6 ? 2 3 n-1 n 0 1 2 n-1 n 0 1 2 0 n Match detect Counter clear INTTC6 interrupt request Counter clear Match detect Figure 11-2 8-Bit Timer Mode Timing Chart (TC6) 11.3.2 8-Bit Event Counter Mode (TC5, 6) In the 8-bit event counter mode, the up-counter counts up at the falling edge of the input pulse to the TCj pin. When a match between the up-counter and the TTREGj value is detected, an INTTCj interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting at the falling edge of the input pulse to the TCj pin. Two machine cycles are required for the low- or high-level pulse input to the TCj pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/24 Hz in the SLOW1/2 or SLEEP1/2 mode. Note 1: In the event counter mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj and PPGj pins may output pulses. Note 2: In the event counter mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the event counter mode, the new value programmed in TTREGj is in effect immediately after the programming. Therefore, if TTREGi is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 5, 6 TC6CR TC6 pin input 0 Counter TTREG6 ? 1 2 n-1 n 0 1 2 n-1 n 0 1 2 0 n Match detect INTTC6 interrupt request Counter clear Match detect Counter clear Figure 11-3 8-Bit Event Counter Mode Timing Chart (TC6) 11.3.3 8-Bit Programmable Divider Output (PDO) Mode (TC5, 6) This mode is used to generate a pulse with a 50% duty cycle from the PDOj pin. In the PDO mode, the up-counter counts up using the internal clock. When a match between the up-counter and the TTREGj value is detected, the logic level output from the PDOj pin is switched to the opposite state and the up-counter is cleared. The INTTCj interrupt request is generated at the time. The logic state opposite to the timer F/Fj logic level is output from the PDOj pin. An arbitrary value can be set to the timer F/Fj by TCjCR. Upon reset, the timer F/Fj value is initialized to 0. To use the programmable divider output, set the output latch of the I/O port to 1. Page 126 TMP86FS49BUG Example :Generating 1024 Hz pulse using TC6 (fc = 16.0 MHz) Setting port LD (TTREG6), 3DH : 1/1024÷27/fc÷2 = 3DH LD (TC6CR), 00010001B : Sets the operating clock to fc/27, and 8-bit PDO mode. LD (TC6CR), 00011001B : Starts TC6. Note 1: In the programmable divider output mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the programmable divider output mode, the new value programmed in TTREGj is in effect immediately after programming. Therefore, if TTREGi is changed while the timer is running, an expected operation may not be obtained. Note 2: When the timer is stopped during PDO output, the PDOj pin holds the output status when the timer is stopped. To change the output status, program TCjCR after the timer is stopped. Do not change the TCjCR setting upon stopping of the timer. Example: Fixing the PDOj pin to the high level when the TimerCounter is stopped CLR (TCjCR).3: Stops the timer. CLR (TCjCR).7: Sets the PDOj pin to the high level. Note 3: j = 5, 6 Page 127 Page 128 ? INTTC6 interrupt request PDO6 pin Timer F/F6 TTREG6 Counter Internal source clock TC6CR TC6CR 0 n 1 Match detect 2 n 0 1 Match detect 2 n 0 1 Match detect 2 n 0 1 Match detect 2 n 0 1 2 3 Set F/F Held at the level when the timer is stopped 0 Write of "1" 11.1 Configuration 11. 8-Bit TimerCounter (TC5, TC6) TMP86FS49BUG Figure 11-4 8-Bit PDO Mode Timing Chart (TC6) TMP86FS49BUG 11.3.4 8-Bit Pulse Width Modulation (PWM) Output Mode (TC5, 6) This mode is used to generate a pulse-width modulated (PWM) signals with up to 8 bits of resolution. The up-counter counts up using the internal clock. When a match between the up-counter and the PWREGj value is detected, the logic level output from the timer F/Fj is switched to the opposite state. The counter continues counting. The logic level output from the timer F/Fj is switched to the opposite state again by the up-counter overflow, and the counter is cleared. The INTTCj interrupt request is generated at this time. Since the initial value can be set to the timer F/Fj by TCjCR, positive and negative pulses can be generated. Upon reset, the timer F/Fj is cleared to 0. (The logic level output from the PWMj pin is the opposite to the timer F/Fj logic level.) Since PWREGj in the PWM mode is serially connected to the shift register, the value set to PWREGj can be changed while the timer is running. The value set to PWREGj during a run of the timer is shifted by the INTTCj interrupt request and loaded into PWREGj. While the timer is stopped, the value is shifted immediately after the programming of PWREGj. If executing the read instruction to PWREGj during PWM output, the value in the shift register is read, but not the value set in PWREGj. Therefore, after writing to PWREGj, the reading data of PWREGj is previous value until INTTCj is generated. For the pin used for PWM output, the output latch of the I/O port must be set to 1. Note 1: In the PWM mode, program the timer register PWREGj immediately after the INTTCj interrupt request is generated (normally in the INTTCj interrupt service routine.) If the programming of PWREGj and the interrupt request occur at the same time, an unstable value is shifted, that may result in generation of the pulse different from the programmed value until the next INTTCj interrupt request is generated. Note 2: When the timer is stopped during PWM output, the PWMj pin holds the output status when the timer is stopped. To change the output status, program TCjCR after the timer is stopped. Do not change the TCjCR upon stopping of the timer. Example: Fixing the PWMj pin to the high level when the TimerCounter is stopped CLR (TCjCR).3: Stops the timer. CLR (TCjCR).7: Sets the PWMj pin to the high level. Note 3: To enter the STOP mode during PWM output, stop the timer and then enter the STOP mode. If the STOP mode is entered without stopping the timer when fc, fc/2 or fs is selected as the source clock, a pulse is output from the PWMj pin during the warm-up period time after exiting the STOP mode. Note 4: j = 5, 6 Table 11-5 PWM Output Mode Source Clock NORMAL1/2, IDLE1/2 mode Resolution Repeated Cycle DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 [Hz] fs/23 [Hz] fs/23 [Hz] 128 µs 244.14 µs 32.8 ms 62.5 ms fc/2 7 – 8 µs – 2.05 ms – fc/2 5 – 2 µs – 512 µs – fc/2 7 fc/2 5 fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz fc/23 fc/23 – 500 ns – 128 µs – fs fs fs 30.5 µs 30.5 µs 7.81 ms 7.81 ms fc/2 fc/2 – 125 ns – 32 µs – fc fc – 62.5 ns – 16 µs – Page 129 Page 130 ? Shift registar 0 Shift INTTC6 interrupt request PWM6 pin Timer F/F6 ? PWREG6 Counter Internal source clock TC6CR TC6CR n n n Match detect 1 n n+1 Shift FF 0 n n n+1 m One cycle period Write to PWREG6 Match detect 1 Shift FF 0 m m m+1 Write to PWREG6 p Match detect m 1 Shift FF 0 p p Match detect 1 p 11.1 Configuration 11. 8-Bit TimerCounter (TC5, TC6) TMP86FS49BUG Figure 11-5 8-Bit PWM Mode Timing Chart (TC6) TMP86FS49BUG 11.3.5 16-Bit Timer Mode (TC5 and 6) In the timer mode, the up-counter counts up using the internal clock. The TimerCounter 5 and 6 are cascadable to form a 16-bit timer. When a match between the up-counter and the timer register (TTREG5, TTREG6) value is detected after the timer is started by setting TC6CR to 1, an INTTC6 interrupt is generated and the up-counter is cleared. After being cleared, the up-counter continues counting. Program the lower byte and upper byte in this order in the timer register. (Programming only the upper or lower byte should not be attempted.) Note 1: In the timer mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj, and PPGj pins may output a pulse. Note 2: In the timer mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the timer mode, the new value programmed in TTREGj is in effect immediately after programming of TTREGj. Therefore, if TTREGj is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 5, 6 Table 11-6 Source Clock for 16-Bit Timer Mode Source Clock Resolution NORMAL1/2, IDLE1/2 mode Maximum Time Setting DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 fs/23 fs/23 128 µs 244.14 µs 8.39 s 16 s fc/27 fc/27 – 8 µs – 524.3 ms – fc/25 fc/25 – 2 µs – 131.1 ms – fc/23 fc/23 – 500 ns – 32.8 ms – fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz Example :Setting the timer mode with source clock fc/27 Hz, and generating an interrupt 300 ms later (fc = 16.0 MHz) (TTREG5), 927CH : Sets the timer register (300 ms÷27/fc = 927CH). (EIRE). 2 : Enables INTTC6 interrupt. LD (TC5CR), 13H :Sets the operating clock to fc/27, and 16-bit timer mode (lower byte). LD (TC6CR), 04H : Sets the 16-bit timer mode (upper byte). LD (TC6CR), 0CH : Starts the timer. LDW DI SET EI TC6CR Internal source clock 0 Counter TTREG5 (Lower byte) TTREG6 (Upper byte) ? ? INTTC6 interrupt request 1 2 3 mn-1 mn 0 1 2 mn-1 mn 0 1 n m Match detect Counter clear Match detect Counter clear Figure 11-6 16-Bit Timer Mode Timing Chart (TC5 and TC6) Page 131 2 0 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration TMP86FS49BUG 11.3.6 16-Bit Event Counter Mode (TC5 and 6) In the event counter mode, the up-counter counts up at the falling edge to the TC5 pin. The TimerCounter 5 and 6 are cascadable to form a 16-bit event counter. When a match between the up-counter and the timer register (TTREG5, TTREG6) value is detected after the timer is started by setting TC6CR to 1, an INTTC6 interrupt is generated and the up-counter is cleared. After being cleared, the up-counter restarts counting at the falling edge of the input pulse to the TC5 pin. Two machine cycles are required for the low- or high-level pulse input to the TC5 pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/ 2 in the SLOW1/2 or SLEEP1/2 mode. Program the lower byte (TTREG5), and upper byte (TTREG6) in this order in the timer register. (Programming only the upper or lower byte should not be attempted.) 4 Note 1: In the event counter mode, fix TCjCR to 0. If not fixed, the PDOj, PWMj and PPGj pins may output pulses. Note 2: In the event counter mode, do not change the TTREGj setting while the timer is running. Since TTREGj is not in the shift register configuration in the event counter mode, the new value programmed in TTREGj is in effect immediately after the programming. Therefore, if TTREGj is changed while the timer is running, an expected operation may not be obtained. Note 3: j = 5, 6 11.3.7 16-Bit Pulse Width Modulation (PWM) Output Mode (TC5 and 6) This mode is used to generate a pulse-width modulated (PWM) signals with up to 16 bits of resolution. The TimerCounter 5 and 6 are cascadable to form the 16-bit PWM signal generator. The counter counts up using the internal clock or external clock. When a match between the up-counter and the timer register (PWREG5, PWREG6) value is detected, the logic level output from the timer F/F6 is switched to the opposite state. The counter continues counting. The logic level output from the timer F/F6 is switched to the opposite state again by the counter overflow, and the counter is cleared. The INTTC6 interrupt is generated at this time. Two machine cycles are required for the high- or low-level pulse input to the TC5 pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/24 to in the SLOW1/2 or SLEEP1/2 mode. Since the initial value can be set to the timer F/F6 by TC6CR, positive and negative pulses can be generated. Upon reset, the timer F/F6 is cleared to 0. (The logic level output from the PWM6 pin is the opposite to the timer F/F6 logic level.) Since PWREG6 and 5 in the PWM mode are serially connected to the shift register, the values set to PWREG6 and 5 can be changed while the timer is running. The values set to PWREG6 and 5 during a run of the timer are shifted by the INTTCj interrupt request and loaded into PWREG6 and 5. While the timer is stopped, the values are shifted immediately after the programming of PWREG6 and 5. Set the lower byte (PWREG5) and upper byte (PWREG6) in this order to program PWREG6 and 5. (Programming only the lower or upper byte of the register should not be attempted.) If executing the read instruction to PWREG6 and 5 during PWM output, the values set in the shift register is read, but not the values set in PWREG6 and 5. Therefore, after writing to the PWREG6 and 5, reading data of PWREG6 and 5 is previous value until INTTC6 is generated. For the pin used for PWM output, the output latch of the I/O port must be set to 1. Note 1: In the PWM mode, program the timer register PWREG6 and 5 immediately after the INTTC6 interrupt request is generated (normally in the INTTC6 interrupt service routine.) If the programming of PWREGj and the interrupt request occur at the same time, an unstable value is shifted, that may result in generation of pulse different from the programmed value until the next INTTC6 interrupt request is generated. Note 2: When the timer is stopped during PWM output, the PWM6 pin holds the output status when the timer is stopped. To change the output status, program TC6CR after the timer is stopped. Do not program TC6CR upon stopping of the timer. Example: Fixing the PWM6 pin to the high level when the TimerCounter is stopped Page 132 TMP86FS49BUG CLR (TC6CR).3: Stops the timer. CLR (TC6CR).7 : Sets the PWM6 pin to the high level. Note 3: To enter the STOP mode, stop the timer and then enter the STOP mode. If the STOP mode is entered without stopping of the timer when fc, fc/2 or fs is selected as the source clock, a pulse is output from the PWM6 pin during the warm-up period time after exiting the STOP mode. Table 11-7 16-Bit PWM Output Mode Source Clock NORMAL1/2, IDLE1/2 mode Resolution Repeated Cycle DV7CK = 0 DV7CK = 1 SLOW1/2, SLEEP1/2 mode fc/211 fs/23 [Hz] fs/23 [Hz] 128 µs 244.14 µs 8.39 s 16 s fc/27 fc/27 – 8 µs – 524.3 ms – fc/25 fc/25 – 2 µs – 131.1 ms – fc/23 fc/23 – 500 ns – 32.8 ms – fc = 16 MHz fs = 32.768 kHz fc = 16 MHz fs = 32.768 kHz fs fs fs 30.5 µs 30.5 µs 2s 2s fc/2 fc/2 – 125 ns – 8.2 ms – fc fc – 62.5 ns – 4.1 ms – Example :Generating a pulse with 1-ms high-level width and a period of 32.768 ms (fc = 16.0 MHz) Setting ports LDW (PWREG5), 07D0H : Sets the pulse width. LD (TC5CR), 33H : Sets the operating clock to fc/23, and 16-bit PWM output mode (lower byte). LD (TC6CR), 056H : Sets TFF6 to the initial value 0, and 16-bit PWM signal generation mode (upper byte). LD (TC6CR), 05EH : Starts the timer. Page 133 Page 134 ? ? PWREG6 (Upper byte) 16-bit shift register 0 a Shift INTTC6 interrupt request PWM6 pin Timer F/F6 ? PWREG5 (Lower byte) Counter Internal source clock TC6CR TC6CR an n an Match detect 1 an an+1 Shift FFFF 0 an an an+1 m b One cycle period Write to PWREG6 Write to PWREG5 Match detect 1 Shift FFFF 0 bm bm bm+1 p c Write to PWREG6 Write to PWREG5 Match detect bm 1 Shift FFFF 0 cp Match detect cp 1 cp 11.1 Configuration 11. 8-Bit TimerCounter (TC5, TC6) TMP86FS49BUG Figure 11-7 16-Bit PWM Mode Timing Chart (TC5 and TC6) TMP86FS49BUG 11.3.8 16-Bit Programmable Pulse Generate (PPG) Output Mode (TC5 and 6) This mode is used to generate pulses with up to 16-bits of resolution. The timer counter 5 and 6 are cascadable to enter the 16-bit PPG mode. The counter counts up using the internal clock or external clock. When a match between the up-counter and the timer register (PWREG5, PWREG6) value is detected, the logic level output from the timer F/F6 is switched to the opposite state. The counter continues counting. The logic level output from the timer F/F6 is switched to the opposite state again when a match between the up-counter and the timer register (TTREG5, TTREG6) value is detected, and the counter is cleared. The INTTC6 interrupt is generated at this time. Two machine cycles are required for the high- or low-level pulse input to the TC5 pin. Therefore, a maximum frequency to be supplied is fc/24 Hz in the NORMAL1/2 or IDLE1/2 mode, and fs/24 to in the SLOW1/ 2 or SLEEP1/2 mode. Since the initial value can be set to the timer F/F6 by TC6CR, positive and negative pulses can be generated. Upon reset, the timer F/F6 is cleared to 0. (The logic level output from the PPG6 pin is the opposite to the timer F/F6.) Set the lower byte and upper byte in this order to program the timer register. (TTREG5 → TTREG6, PWREG5 → PWREG6) (Programming only the upper or lower byte should not be attempted.) For PPG output, set the output latch of the I/O port to 1. Example :Generating a pulse with 1-ms high-level width and a period of 16.385 ms (fc = 16.0 MHz) Setting ports LDW (PWREG5), 07D0H : Sets the pulse width. LDW (TTREG5), 8002H : Sets the cycle period. LD (TC5CR), 33H : Sets the operating clock to fc/23, and16-bit PPG mode (lower byte). LD (TC6CR), 057H : Sets TFF6 to the initial value 0, and 16-bit PPG mode (upper byte). LD (TC6CR), 05FH : Starts the timer. Note 1: In the PPG mode, do not change the PWREGi and TTREGi settings while the timer is running. Since PWREGi and TTREGi are not in the shift register configuration in the PPG mode, the new values programmed in PWREGi and TTREGi are in effect immediately after programming PWREGi and TTREGi. Therefore, if PWREGi and TTREGi are changed while the timer is running, an expected operation may not be obtained. Note 2: When the timer is stopped during PPG output, the PPG6 pin holds the output status when the timer is stopped. To change the output status, program TC6CR after the timer is stopped. Do not change TC6CR upon stopping of the timer. Example: Fixing the PPG6 pin to the high level when the TimerCounter is stopped CLR (TC6CR).3: Stops the timer CLR (TC6CR).7: Sets the PPG6 pin to the high level Note 3: i = 5, 6 Page 135 Page 136 ? TTREG6 (Upper byte) INTTC6 interrupt request PPG6 pin Timer F/F6 ? ? TTREG5 (Lower byte) PWREG6 (Upper byte) n PWREG5 (Lower byte) ? 0 Counter Internal source clock TC6CR TC6CR m r q mn Match detect 1 mn mn+1 Match detect qr-1 qr 0 mn Match detect 1 mn mn+1 Match detect qr-1 qr 0 mn Match detect 1 F/F clear 0 Held at the level when the timer stops mn mn+1 Write of "0" 11.1 Configuration 11. 8-Bit TimerCounter (TC5, TC6) TMP86FS49BUG Figure 11-8 16-Bit PPG Mode Timing Chart (TC5 and TC6) TMP86FS49BUG 11.3.9 Warm-Up Counter Mode In this mode, the warm-up period time is obtained to assure oscillation stability when the system clocking is switched between the high-frequency and low-frequency. The timer counter 5 and 6 are cascadable to form a 16-bit TimerCounter. The warm-up counter mode has two types of mode; switching from the high-frequency to low-frequency, and vice-versa. Note 1: In the warm-up counter mode, fix TCiCR to 0. If not fixed, the PDOi, PWMi and PPGi pins may output pulses. Note 2: In the warm-up counter mode, only upper 8 bits of the timer register TTREG6 and 5 are used for match detection and lower 8 bits are not used. Note 3: i = 5, 6 11.3.9.1 Low-Frequency Warm-up Counter Mode (NORMAL1 → NORMAL2 → SLOW2 → SLOW1) In this mode, the warm-up period time from a stop of the low-frequency clock fs to oscillation stability is obtained. Before starting the timer, set SYSCR2 to 1 to oscillate the low-frequency clock. When a match between the up-counter and the timer register (TTREG6, 5) value is detected after the timer is started by setting TC6CR to 1, the counter is cleared by generating the INTTC6 interrupt request. After stopping the timer in the INTTC6 interrupt service routine, set SYSCR2 to 1 to switch the system clock from the high-frequency to low-frequency, and then clear of SYSCR2 to 0 to stop the high-frequency clock. Table 11-8 Setting Time of Low-Frequency Warm-Up Counter Mode (fs = 32.768 kHz) Minimum Time Setting (TTREG6, 5 = 0100H) Maximum Time Setting (TTREG6, 5 = FF00H) 7.81 ms 1.99 s Example :After checking low-frequency clock oscillation stability with TC6 and 5, switching to the SLOW1 mode SET (SYSCR2).6 : SYSCR2 ← 1 LD (TC5CR), 43H : Sets TFF5=0, source clock fs, and 16-bit mode. LD (TC6CR), 05H : Sets TFF6=0, and warm-up counter mode. LD (TTREG5), 8000H : Sets the warm-up time. (The warm-up time depends on the oscillator characteristic.) : IMF ← 0 DI SET (EIRE). 2 : IMF ← 1 EI SET : PINTTC6: : Enables the INTTC6. (TC6CR).3 : Starts TC6 and 5. : CLR (TC6CR).3 : Stops TC6 and 5. SET (SYSCR2).5 : SYSCR2 ← 1 (Switches the system clock to the low-frequency clock.) CLR (SYSCR2).7 : SYSCR2 ← 0 (Stops the high-frequency clock.) RETI : VINTTC6: DW : PINTTC6 : INTTC6 vector table Page 137 11. 8-Bit TimerCounter (TC5, TC6) 11.1 Configuration TMP86FS49BUG 11.3.9.2 High-Frequency Warm-Up Counter Mode (SLOW1 → SLOW2 → NORMAL2 → NORMAL1) In this mode, the warm-up period time from a stop of the high-frequency clock fc to the oscillation stability is obtained. Before starting the timer, set SYSCR2 to 1 to oscillate the high-frequency clock. When a match between the up-counter and the timer register (TTREG6, 5) value is detected after the timer is started by setting TC6CR to 1, the counter is cleared by generating the INTTC6 interrupt request. After stopping the timer in the INTTC6 interrupt service routine, clear SYSCR2 to 0 to switch the system clock from the low-frequency to high-frequency, and then SYSCR2 to 0 to stop the low-frequency clock. Table 11-9 Setting Time in High-Frequency Warm-Up Counter Mode Minimum time Setting (TTREG6, 5 = 0100H) Maximum time Setting (TTREG6, 5 = FF00H) 16 µs 4.08 ms Example :After checking high-frequency clock oscillation stability with TC6 and 5, switching to the NORMAL1 mode SET (SYSCR2).7 : SYSCR2 ← 1 LD (TC5CR), 63H : Sets TFF5=0, source clock fc, and 16-bit mode. LD (TC6CR), 05H : Sets TFF6=0, and warm-up counter mode. LD (TTREG5), 0F800H : Sets the warm-up time. (The warm-up time depends on the oscillator characteristic.) : IMF ← 0 DI SET (EIRE). 2 : IMF ← 1 EI SET : PINTTC6: : Enables the INTTC6. (TC6CR).3 : Starts the TC6 and 5. : CLR (TC6CR).3 : Stops the TC6 and 5. CLR (SYSCR2).5 : SYSCR2 ← 0 (Switches the system clock to the high-frequency clock.) CLR (SYSCR2).6 : SYSCR2 ← 0 (Stops the low-frequency clock.) RETI VINTTC6: : : DW PINTTC6 : INTTC6 vector table Page 138 TMP86FS49BUG 12. Asynchronous Serial interface (UART1 ) 12.1 Configuration UART control register 1 Transmit data buffer UART1CR1 TD1BUF 3 Receive data buffer RD1BUF 2 INTTXD1 Receive control circuit Transmit control circuit 2 Shift register Shift register Parity bit Stop bit Noise rejection circuit RXD1 TXD1 INTRXD1 Transmit/receive clock Y M P X S fc/13 fc/26 fc/52 fc/104 fc/208 fc/416 INTTC3 fc/96 A B C D E F G H A B C 6 fc/2 fc/27 8 fc/2 S 2 Y 4 2 Counter UART1SR UART1CR2 UART status register UART control register 2 MPX: Multiplexer Baud rate generator Figure 12-1 UART1 (Asynchronous Serial Interface) Page 139 12. Asynchronous Serial interface (UART1 ) 12.2 Control TMP86FS49BUG 12.2 Control UART1 is controlled by the UART1 Control Registers (UART1CR1, UART1CR2). The operating status can be monitored using the UART status register (UART1SR). UART1 Control Register1 UART1CR1 (0F95H) 7 6 5 4 3 TXE RXE STBT EVEN PE 2 1 0 BRG (Initial value: 0000 0000) TXE Transfer operation 0: 1: Disable Enable RXE Receive operation 0: 1: Disable Enable STBT Transmit stop bit length 0: 1: 1 bit 2 bits EVEN Even-numbered parity 0: 1: Odd-numbered parity Even-numbered parity Parity addition 0: 1: No parity Parity PE BRG 000: 001: 010: 011: 100: 101: 110: 111: Transmit clock select Write only fc/13 [Hz] fc/26 fc/52 fc/104 fc/208 fc/416 TC3 ( Input INTTC3) fc/96 Note 1: When operations are disabled by setting TXE and RXE bit to “0”, the setting becomes valid when data transmit or receive complete. When the transmit data is stored in the transmit data buffer, the data are not transmitted. Even if data transmit is enabled, until new data are written to the transmit data buffer, the current data are not transmitted. Note 2: The transmit clock and the parity are common to transmit and receive. Note 3: UART1CR1 and UART1CR1 should be set to “0” before UART1CR1 is changed. UART1 Control Register2 UART1CR2 (0F96H) 7 6 5 4 3 2 1 0 RXDNC RXDNC Selection of RXD input noise rejection time STOPBR Receive stop bit length 00: 01: 10: 11: 0: 1: STOPBR (Initial value: **** *000) No noise rejection (Hysteresis input) Rejects pulses shorter than 31/fc [s] as noise Rejects pulses shorter than 63/fc [s] as noise Rejects pulses shorter than 127/fc [s] as noise Write only 1 bit 2 bits Note: When UART1CR2 = “01”, pulses longer than 96/fc [s] are always regarded as signals; when UART1CR2 = “10”, longer than 192/fc [s]; and when UART1CR2 = “11”, longer than 384/fc [s]. Page 140 TMP86FS49BUG UART1 Status Register UART1SR (0F95H) 7 6 5 4 3 2 1 PERR FERR OERR RBFL TEND TBEP 0 (Initial value: 0000 11**) PERR Parity error flag 0: 1: No parity error Parity error FERR Framing error flag 0: 1: No framing error Framing error OERR Overrun error flag 0: 1: No overrun error Overrun error RBFL Receive data buffer full flag 0: 1: Receive data buffer empty Receive data buffer full TEND Transmit end flag 0: 1: On transmitting Transmit end TBEP Transmit data buffer empty flag 0: 1: Transmit data buffer full (Transmit data writing is finished) Transmit data buffer empty Note: When an INTTXD is generated, TBEP flag is set to "1" automatically. UART1 Receive Data Buffer RD1BUF (0F97H) 7 6 5 4 3 2 1 0 Read only (Initial value: 0000 0000) UART1 Transmit Data Buffer TD1BUF (0F97H) 7 6 5 4 3 2 1 0 Write only (Initial value: 0000 0000) Page 141 Read only 12. Asynchronous Serial interface (UART1 ) 12.3 Transfer Data Format TMP86FS49BUG 12.3 Transfer Data Format In UART1, an one-bit start bit (Low level), stop bit (Bit length selectable at high level, by UART1CR1), and parity (Select parity in UART1CR1; even- or odd-numbered parity by UART1CR1) are added to the transfer data. The transfer data formats are shown as follows. PE STBT 0 Frame Length 8 1 2 3 9 10 0 Start Bit 0 Bit 1 0 1 Start Bit 0 1 0 Start 1 1 Start 11 Bit 6 Bit 7 Stop 1 Bit 1 Bit 6 Bit 7 Stop 1 Stop 2 Bit 0 Bit 1 Bit 6 Bit 7 Parity Stop 1 Bit 0 Bit 1 Bit 6 Bit 7 Parity Stop 1 12 Stop 2 Figure 12-2 Transfer Data Format Without parity / 1 STOP bit With parity / 1 STOP bit Without parity / 2 STOP bit With parity / 2 STOP bit Figure 12-3 Caution on Changing Transfer Data Format Note: In order to switch the transfer data format, perform transmit operations in the above Figure 12-3 sequence except for the initial setting. Page 142 TMP86FS49BUG 12.4 Transfer Rate The baud rate of UART1 is set of UART1CR1. The example of the baud rate are shown as follows. Table 12-1 Transfer Rate (Example) Source Clock BRG 16 MHz 8 MHz 4 MHz 000 76800 [baud] 38400 [baud] 19200 [baud] 001 38400 19200 9600 010 19200 9600 4800 011 9600 4800 2400 100 4800 2400 1200 101 2400 1200 600 When TC3 is used as the UART1 transfer rate (when UART1CR1 = “110”), the transfer clock and transfer rate are determined as follows: Transfer clock [Hz] = TC3 source clock [Hz] / TTREG3 setting value Transfer Rate [baud] = Transfer clock [Hz] / 16 12.5 Data Sampling Method The UART1 receiver keeps sampling input using the clock selected by UART1CR1 until a start bit is detected in RXD1 pin input. RT clock starts detecting “L” level of the RXD1 pin. Once a start bit is detected, the start bit, data bits, stop bit(s), and parity bit are sampled at three times of RT7, RT8, and RT9 during one receiver clock interval (RT clock). (RT0 is the position where the bit supposedly starts.) Bit is determined according to majority rule (The data are the same twice or more out of three samplings). RXD1 pin Start bit RT0 1 2 3 Bit 0 4 5 6 7 8 9 10 11 12 13 14 15 0 1 2 3 4 5 6 7 8 9 10 11 2 3 4 5 6 7 8 9 10 11 RT clock Start bit Internal receive data Bit 0 (a) Without noise rejection circuit RXD1 pin Start bit RT0 1 2 3 Bit 0 4 5 6 7 8 9 10 11 12 13 14 15 0 1 RT clock Internal receive data Start bit Bit 0 (b) With noise rejection circuit Figure 12-4 Data Sampling Method Page 143 12. Asynchronous Serial interface (UART1 ) 12.6 STOP Bit Length TMP86FS49BUG 12.6 STOP Bit Length Select a transmit stop bit length (1 bit or 2 bits) by UART1CR1. 12.7 Parity Set parity / no parity by UART1CR1 and set parity type (Odd- or Even-numbered) by UART1CR1. 12.8 Transmit/Receive Operation 12.8.1 Data Transmit Operation Set UART1CR1 to “1”. Read UART1SR to check UART1SR = “1”, then write data in TD1BUF (Transmit data buffer). Writing data in TD1BUF zero-clears UART1SR, transfers the data to the transmit shift register and the data are sequentially output from the TXD1 pin. The data output include a one-bit start bit, stop bits whose number is specified in UART1CR1 and a parity bit if parity addition is specified. Select the data transfer baud rate using UART1CR1. When data transmit starts, transmit buffer empty flag UART1SR is set to “1” and an INTTXD1 interrupt is generated. While UART1CR1 = “0” and from when “1” is written to UART1CR1 to when send data are written to TD1BUF, the TXD1 pin is fixed at high level. When transmitting data, first read UART1SR, then write data in TD1BUF. Otherwise, UART1SR is not zero-cleared and transmit does not start. 12.8.2 Data Receive Operation Set UART1CR1 to “1”. When data are received via the RXD1 pin, the receive data are transferred to RD1BUF (Receive data buffer). At this time, the data transmitted includes a start bit and stop bit(s) and a parity bit if parity addition is specified. When stop bit(s) are received, data only are extracted and transferred to RD1BUF (Receive data buffer). Then the receive buffer full flag UART1SR is set and an INTRXD1 interrupt is generated. Select the data transfer baud rate using UART1CR1. If an overrun error (OERR) occurs when data are received, the data are not transferred to RD1BUF (Receive data buffer) but discarded; data in the RD1BUF are not affected. Note:When a receive operation is disabled by setting UART1CR1 bit to “0”, the setting becomes valid when data receive is completed. However, if a framing error occurs in data receive, the receive-disabling setting may not become valid. If a framing error occurs, be sure to perform a re-receive operation. Page 144 TMP86FS49BUG 12.9 Status Flag 12.9.1 Parity Error When parity determined using the receive data bits differs from the received parity bit, the parity error flag UART1SR is set to “1”. The UART1SR is cleared to “0” when the RD1BUF is read after reading the UART1SR. RXD1 pin Shift register Parity Stop pxxxx0* xxxx0** 1pxxxx0 UART1SR After reading UART1SR then RD1BUF clears PERR. INTRXD1 interrupt Figure 12-5 Generation of Parity Error 12.9.2 Framing Error When “0” is sampled as the stop bit in the receive data, framing error flag UART1SR is set to “1”. The UART1SR is cleared to “0” when the RD1BUF is read after reading the UART1SR. RXD1 pin Shift register Stop Final bit xxxx0* xxx0** 0xxxx0 After reading UART1SR then RD1BUF clears FERR. UART1SR INTRXD1 interrupt Figure 12-6 Generation of Framing Error 12.9.3 Overrun Error When all bits in the next data are received while unread data are still in RD1BUF, overrun error flag UART1SR is set to “1”. In this case, the receive data is discarded; data in RD1BUF are not affected. The UART1SR is cleared to “0” when the RD1BUF is read after reading the UART1SR. Page 145 12. Asynchronous Serial interface (UART1 ) 12.9 Status Flag TMP86FS49BUG UART1SR RXD1 pin Stop Final bit Shift register xxx0** RD1BUF yyyy xxxx0* 1xxxx0 UART1SR After reading UART1SR then RD1BUF clears OERR. INTRXD1 interrupt Figure 12-7 Generation of Overrun Error Note:Receive operations are disabled until the overrun error flag UART1SR is cleared. 12.9.4 Receive Data Buffer Full Loading the received data in RD1BUF sets receive data buffer full flag UART1SR to "1". The UART1SR is cleared to “0” when the RD1BUF is read after reading the UART1SR. RXD1 pin Stop Final bit Shift register xxx0** RD1BUF yyyy xxxx0* 1xxxx0 xxxx After reading UART1SR then RD1BUF clears RBFL. UART1SR INTRXD1 interrupt Figure 12-8 Generation of Receive Data Buffer Full Note:If the overrun error flag UART1SR is set during the period between reading the UART1SR and reading the RD1BUF, it cannot be cleared by only reading the RD1BUF. Therefore, after reading the RD1BUF, read the UART1SR again to check whether or not the overrun error flag which should have been cleared still remains set. 12.9.5 Transmit Data Buffer Empty When no data is in the transmit buffer TD1BUF, that is, when data in TD1BUF are transferred to the transmit shift register and data transmit starts, transmit data buffer empty flag UART1SR is set to “1”. The UART1SR is cleared to “0” when the TD1BUF is written after reading the UART1SR. Page 146 TMP86FS49BUG Data write TD1BUF xxxx *****1 Shift register TXD1 pin Data write zzzz yyyy 1xxxx0 *1xxxx ****1x *****1 Start Bit 0 Final bit Stop 1yyyy0 UART1SR After reading UART1SR writing TD1BUF clears TBEP. INTTXD1 interrupt Figure 12-9 Generation of Transmit Data Buffer Empty 12.9.6 Transmit End Flag When data are transmitted and no data is in TD1BUF (UART1SR = “1”), transmit end flag UART1SR is set to “1”. The UART1SR is cleared to “0” when the data transmit is started after writing the TD1BUF. Shift register TXD1 pin ***1xx ****1x *****1 1yyyy0 Stop Start *1yyyy Bit 0 Data write for TD1BUF UART1SR UART1SR INTTXD1 interrupt Figure 12-10 Generation of Transmit End Flag and Transmit Data Buffer Empty Page 147 12. Asynchronous Serial interface (UART1 ) 12.9 Status Flag TMP86FS49BUG Page 148 TMP86FS49BUG 13. Asynchronous Serial interface (UART2 ) 13.1 Configuration UART control register 1 Transmit data buffer UART2CR1 TD2BUF 3 Receive data buffer RD2BUF 2 INTTXD2 Receive control circuit Transmit control circuit 2 Shift register Shift register Parity bit Stop bit Noise rejection circuit RXD2 TXD2 INTRXD2 Transmit/receive clock Y M P X S fc/13 fc/26 fc/52 fc/104 fc/208 fc/416 INTTC5 fc/96 A B C D E F G H A B C 6 fc/2 fc/27 8 fc/2 S 2 Y 4 2 Counter UART2SR UART2CR2 UART status register UART control register 2 MPX: Multiplexer Baud rate generator Figure 13-1 UART2 (Asynchronous Serial Interface) Page 149 13. Asynchronous Serial interface (UART2 ) 13.2 Control TMP86FS49BUG 13.2 Control UART2 is controlled by the UART2 Control Registers (UART2CR1, UART2CR2). The operating status can be monitored using the UART status register (UART2SR). UART2 Control Register1 UART2CR1 (0F98H) 7 6 5 4 3 TXE RXE STBT EVEN PE 2 1 0 BRG (Initial value: 0000 0000) TXE Transfer operation 0: 1: Disable Enable RXE Receive operation 0: 1: Disable Enable STBT Transmit stop bit length 0: 1: 1 bit 2 bits EVEN Even-numbered parity 0: 1: Odd-numbered parity Even-numbered parity Parity addition 0: 1: No parity Parity PE BRG 000: 001: 010: 011: 100: 101: 110: 111: Transmit clock select Write only fc/13 [Hz] fc/26 fc/52 fc/104 fc/208 fc/416 TC5 ( Input INTTC5) fc/96 Note 1: When operations are disabled by setting TXE and RXE bit to “0”, the setting becomes valid when data transmit or receive complete. When the transmit data is stored in the transmit data buffer, the data are not transmitted. Even if data transmit is enabled, until new data are written to the transmit data buffer, the current data are not transmitted. Note 2: The transmit clock and the parity are common to transmit and receive. Note 3: UART2CR1 and UART2CR1 should be set to “0” before UART2CR1 is changed. UART2 Control Register2 UART2CR2 (0F99H) 7 6 5 4 3 2 1 0 RXDNC RXDNC Selection of RXD input noise rejection time STOPBR Receive stop bit length 00: 01: 10: 11: 0: 1: STOPBR (Initial value: **** *000) No noise rejection (Hysteresis input) Rejects pulses shorter than 31/fc [s] as noise Rejects pulses shorter than 63/fc [s] as noise Rejects pulses shorter than 127/fc [s] as noise Write only 1 bit 2 bits Note: When UART2CR2 = “01”, pulses longer than 96/fc [s] are always regarded as signals; when UART2CR2 = “10”, longer than 192/fc [s]; and when UART2CR2 = “11”, longer than 384/fc [s]. Page 150 TMP86FS49BUG UART2 Status Register UART2SR (0F98H) 7 6 5 4 3 2 1 PERR FERR OERR RBFL TEND TBEP 0 (Initial value: 0000 11**) PERR Parity error flag 0: 1: No parity error Parity error FERR Framing error flag 0: 1: No framing error Framing error OERR Overrun error flag 0: 1: No overrun error Overrun error RBFL Receive data buffer full flag 0: 1: Receive data buffer empty Receive data buffer full TEND Transmit end flag 0: 1: On transmitting Transmit end TBEP Transmit data buffer empty flag 0: 1: Transmit data buffer full (Transmit data writing is finished) Transmit data buffer empty Note: When an INTTXD is generated, TBEP flag is set to "1" automatically. UART2 Receive Data Buffer RD2BUF (0F9AH) 7 6 5 4 3 2 1 0 Read only (Initial value: 0000 0000) UART2 Transmit Data Buffer TD2BUF (0F9AH) 7 6 5 4 3 2 1 0 Write only (Initial value: 0000 0000) Page 151 Read only 13. Asynchronous Serial interface (UART2 ) 13.3 Transfer Data Format TMP86FS49BUG 13.3 Transfer Data Format In UART2, an one-bit start bit (Low level), stop bit (Bit length selectable at high level, by UART2CR1), and parity (Select parity in UART2CR1; even- or odd-numbered parity by UART2CR1) are added to the transfer data. The transfer data formats are shown as follows. PE STBT 0 Frame Length 8 1 2 3 9 10 0 Start Bit 0 Bit 1 0 1 Start Bit 0 1 0 Start 1 1 Start 11 Bit 6 Bit 7 Stop 1 Bit 1 Bit 6 Bit 7 Stop 1 Stop 2 Bit 0 Bit 1 Bit 6 Bit 7 Parity Stop 1 Bit 0 Bit 1 Bit 6 Bit 7 Parity Stop 1 12 Stop 2 Figure 13-2 Transfer Data Format Without parity / 1 STOP bit With parity / 1 STOP bit Without parity / 2 STOP bit With parity / 2 STOP bit Figure 13-3 Caution on Changing Transfer Data Format Note: In order to switch the transfer data format, perform transmit operations in the above Figure 13-3 sequence except for the initial setting. Page 152 TMP86FS49BUG 13.4 Transfer Rate The baud rate of UART2 is set of UART2CR1. The example of the baud rate are shown as follows. Table 13-1 Transfer Rate (Example) Source Clock BRG 16 MHz 8 MHz 4 MHz 000 76800 [baud] 38400 [baud] 19200 [baud] 001 38400 19200 9600 010 19200 9600 4800 011 9600 4800 2400 100 4800 2400 1200 101 2400 1200 600 When TC5 is used as the UART2 transfer rate (when UART2CR1 = “110”), the transfer clock and transfer rate are determined as follows: Transfer clock [Hz] = TC5 source clock [Hz] / TTREG5 setting value Transfer Rate [baud] = Transfer clock [Hz] / 16 13.5 Data Sampling Method The UART2 receiver keeps sampling input using the clock selected by UART2CR1 until a start bit is detected in RXD2 pin input. RT clock starts detecting “L” level of the RXD2 pin. Once a start bit is detected, the start bit, data bits, stop bit(s), and parity bit are sampled at three times of RT7, RT8, and RT9 during one receiver clock interval (RT clock). (RT0 is the position where the bit supposedly starts.) Bit is determined according to majority rule (The data are the same twice or more out of three samplings). RXD2 pin Start bit RT0 1 2 3 Bit 0 4 5 6 7 8 9 10 11 12 13 14 15 0 1 2 3 4 5 6 7 8 9 10 11 2 3 4 5 6 7 8 9 10 11 RT clock Start bit Internal receive data Bit 0 (a) Without noise rejection circuit RXD2 pin Start bit RT0 1 2 3 Bit 0 4 5 6 7 8 9 10 11 12 13 14 15 0 1 RT clock Internal receive data Start bit Bit 0 (b) With noise rejection circuit Figure 13-4 Data Sampling Method Page 153 13. Asynchronous Serial interface (UART2 ) 13.6 STOP Bit Length TMP86FS49BUG 13.6 STOP Bit Length Select a transmit stop bit length (1 bit or 2 bits) by UART2CR1. 13.7 Parity Set parity / no parity by UART2CR1 and set parity type (Odd- or Even-numbered) by UART2CR1. 13.8 Transmit/Receive Operation 13.8.1 Data Transmit Operation Set UART2CR1 to “1”. Read UART2SR to check UART2SR = “1”, then write data in TD2BUF (Transmit data buffer). Writing data in TD2BUF zero-clears UART2SR, transfers the data to the transmit shift register and the data are sequentially output from the TXD2 pin. The data output include a one-bit start bit, stop bits whose number is specified in UART2CR1 and a parity bit if parity addition is specified. Select the data transfer baud rate using UART2CR1. When data transmit starts, transmit buffer empty flag UART2SR is set to “1” and an INTTXD2 interrupt is generated. While UART2CR1 = “0” and from when “1” is written to UART2CR1 to when send data are written to TD2BUF, the TXD2 pin is fixed at high level. When transmitting data, first read UART2SR, then write data in TD2BUF. Otherwise, UART2SR is not zero-cleared and transmit does not start. 13.8.2 Data Receive Operation Set UART2CR1 to “1”. When data are received via the RXD2 pin, the receive data are transferred to RD2BUF (Receive data buffer). At this time, the data transmitted includes a start bit and stop bit(s) and a parity bit if parity addition is specified. When stop bit(s) are received, data only are extracted and transferred to RD2BUF (Receive data buffer). Then the receive buffer full flag UART2SR is set and an INTRXD2 interrupt is generated. Select the data transfer baud rate using UART2CR1. If an overrun error (OERR) occurs when data are received, the data are not transferred to RD2BUF (Receive data buffer) but discarded; data in the RD2BUF are not affected. Note:When a receive operation is disabled by setting UART2CR1 bit to “0”, the setting becomes valid when data receive is completed. However, if a framing error occurs in data receive, the receive-disabling setting may not become valid. If a framing error occurs, be sure to perform a re-receive operation. Page 154 TMP86FS49BUG 13.9 Status Flag 13.9.1 Parity Error When parity determined using the receive data bits differs from the received parity bit, the parity error flag UART2SR is set to “1”. The UART2SR is cleared to “0” when the RD2BUF is read after reading the UART2SR. RXD2 pin Shift register Parity Stop pxxxx0* xxxx0** 1pxxxx0 UART2SR After reading UART2SR then RD2BUF clears PERR. INTRXD2 interrupt Figure 13-5 Generation of Parity Error 13.9.2 Framing Error When “0” is sampled as the stop bit in the receive data, framing error flag UART2SR is set to “1”. The UART2SR is cleared to “0” when the RD2BUF is read after reading the UART2SR. RXD2 pin Shift register Stop Final bit xxxx0* xxx0** 0xxxx0 After reading UART2SR then RD2BUF clears FERR. UART2SR INTRXD2 interrupt Figure 13-6 Generation of Framing Error 13.9.3 Overrun Error When all bits in the next data are received while unread data are still in RD2BUF, overrun error flag UART2SR is set to “1”. In this case, the receive data is discarded; data in RD2BUF are not affected. The UART2SR is cleared to “0” when the RD2BUF is read after reading the UART2SR. Page 155 13. Asynchronous Serial interface (UART2 ) 13.9 Status Flag TMP86FS49BUG UART2SR RXD2 pin Stop Final bit Shift register xxx0** RD2BUF yyyy xxxx0* 1xxxx0 UART2SR After reading UART2SR then RD2BUF clears OERR. INTRXD2 interrupt Figure 13-7 Generation of Overrun Error Note:Receive operations are disabled until the overrun error flag UART2SR is cleared. 13.9.4 Receive Data Buffer Full Loading the received data in RD2BUF sets receive data buffer full flag UART2SR to "1". The UART2SR is cleared to “0” when the RD2BUF is read after reading the UART2SR. RXD2 pin Stop Final bit Shift register xxx0** RD2BUF yyyy xxxx0* 1xxxx0 xxxx After reading UART2SR then RD2BUF clears RBFL. UART2SR INTRXD2 interrupt Figure 13-8 Generation of Receive Data Buffer Full Note:If the overrun error flag UART2SR is set during the period between reading the UART2SR and reading the RD2BUF, it cannot be cleared by only reading the RD2BUF. Therefore, after reading the RD2BUF, read the UART2SR again to check whether or not the overrun error flag which should have been cleared still remains set. 13.9.5 Transmit Data Buffer Empty When no data is in the transmit buffer TD2BUF, that is, when data in TD2BUF are transferred to the transmit shift register and data transmit starts, transmit data buffer empty flag UART2SR is set to “1”. The UART2SR is cleared to “0” when the TD2BUF is written after reading the UART2SR. Page 156 TMP86FS49BUG Data write TD2BUF xxxx *****1 Shift register TXD2 pin Data write zzzz yyyy 1xxxx0 *1xxxx ****1x *****1 Start Bit 0 Final bit Stop 1yyyy0 UART2SR After reading UART2SR writing TD2BUF clears TBEP. INTTXD2 interrupt Figure 13-9 Generation of Transmit Data Buffer Empty 13.9.6 Transmit End Flag When data are transmitted and no data is in TD2BUF (UART2SR = “1”), transmit end flag UART2SR is set to “1”. The UART2SR is cleared to “0” when the data transmit is started after writing the TD2BUF. Shift register TXD2 pin ***1xx ****1x *****1 1yyyy0 Stop Start *1yyyy Bit 0 Data write for TD2BUF UART2SR UART2SR INTTXD2 interrupt Figure 13-10 Generation of Transmit End Flag and Transmit Data Buffer Empty Page 157 13. Asynchronous Serial interface (UART2 ) 13.9 Status Flag TMP86FS49BUG Page 158 TMP86FS49BUG 14. Synchronous Serial Interface (SIO1) The serial interfaces connect to an external device via SI1, SO1, and SCK1 pins. When these pins are used as serial interface, the output latches for each port should be set to "1". 14.1 Configuration Internal data bus SIO1CR SIO1SR SIO1TDB Shift register on transmitter Shift clock Port (Note) Control circuit SO1 pin (Serial data output) MSB/LSB selection Port (Note) Shift register on receiver SI1 pin (Serial data input) SIO1RDB To BUS Port (Note) INTSIO1 interrupt SCK1 pin (Serial data output) Internal clock input Note: Set the register of port correctly for the port assigned as serial interface pins. For details, see the description of the input/output port control register. Figure 14-1 Synchronous Serial Interface (SIO) Page 159 14. Synchronous Serial Interface (SIO1) 14.2 Control TMP86FS49BUG 14.2 Control The SIO is controlled using the serial interface control register (SIO1CR). The operating status of the serial interface can be inspected by reading the status register (SIO1CR). Serial Interface Control Register SIO1CR (0020H) 7 6 SIOS SIOINH SIOS SIOINH SIOM SIODIR 5 4 SIOM 3 2 SIODIR 1 0 SCK (Initial value: 0000 0000) Specify start/stop of transfer 0: Stop 1: Start Forcibly stops transfer (Note 1) 0: – 1: Forcibly stop (Automatically cleared to "0" after stopping) Selects transfer mode 00: Transmit mode 01: Receive mode 10: Transmit/receive mode 11: Reserved Selects direction of transfer 0: MSB (Transfer beginning with bit7) 1: LSB (Transfer beginning with bit0) NORMAL1/2 or IDLE1/2 modes SCK Selects serial clock SLOW/SLEEP mode TBTCR = "0" TBTCR = "1" 000 fc/212 fs/24 fs/24 001 fc/28 fc/28 Reserved 010 fc/27 fc/27 Reserved 011 fc/26 fc/26 Reserved 100 fc/25 fc/25 Reserved 101 fc/24 fc/24 Reserved 110 fc/23 fc/23 Reserved 111 R/W External clock (Input from SCK1 pin) Note 1: When SIO1CR is set to “1”, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Note 2: Transfer mode, direction of transfer and serial clock must be select during the transfer is stopping (when SIO1SR "0"). Note 3: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz], *: Don’t care Page 160 TMP86FS49BUG Serial Interface Status Register SIO1SR (0021H) 7 6 5 4 3 2 SIOF SEF TXF RXF TXERR RXERR 1 0 (Initial value: 0010 00**) SIOF Serial transfer operation status monitor 0: Transfer finished 1: Transfer in progress SEF Number of clocks monitor 0: 8 clocks 1: 1 to 7 clocks TXF Transmit buffer empty flag 0: Data exists in transmit buffer 1: No data exists in transmit buffer RXF Receive buffer full flag 0: No data exists in receive buffer 1: Data exists in receive buffer Transfer operation error flag Read 0: – (No error exist) 1: Transmit buffer under run occurs in an external clock mode Write 0: Clear the flag 1: – (A write of "1" to this bit is ignored) Receive operation error flag Read 0: – (No error exist) 1: Receive buffer over run occurs in an external clock mode Write 0: Clear the flag 1: – (A write of "1" to this bit is ignored) TXERR RXERR Read only R/W Note 1: The operation error flag (TXERR and RXERR) are not automatically cleared by stopping transfer with SIO1CR "0". Therefore, set these bits to "0" for clearing these error flag. Or set SIO1CR to "1". Note 2: *: Don't care Receive buffer register SIO1RDB (0022H) 7 6 5 4 3 2 1 0 Read only (Initial value: 0000 0000) Transmit buffer register SIO1TDB (0022H) 7 6 5 4 3 2 1 0 Write only (Initial value: **** ****) Note 1: SIO1TDB is write only register. A bit manipulation should not be performed on the transmit buffer register using a readmodify-write instruction. Note 2: The SIO1TDB should be written after checking SIO1SR "1". When SIO1SR is "0", the writing data can't be transferred to SIO1TDB even if write instruction is executed to SIO1TDB Note 3: *: Don't care Page 161 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG 14.3 Function 14.3.1 Serial clock 14.3.1.1 Clock source The serial clock can be selected by using SIO1CR. When the serial clock is changed, the writing instruction to SIO1CR should be executed while the transfer is stopped (when SIO1SR “0”) (1) Internal clock Setting the SIO1CR to other than “111B” outputs the clock (shown in " Table 14-1 Serial Clock Rate (fc = 16 MHz, fs = 32.768kHz) ") as serial clock outputs from SCK1 pin. At the before beginning or finishing of a transfer, SCK1 pin is kept in high level. When writing (in the transmit mode) or reading (in the receive mode) data can not follow the serial clock rate, an automatic-wait function is executed to stop the serial clock automatically and hold the next shift operation until reading or writing is completed (shown in " Figure 14-2 Automatic-wait Function (Example of transmit mode) "). The maximum time from releasing the automatic-wait function by reading or writing a data is 1 cycle of the selected serial clock until the serial clock comes out from SCK1 pin. SIO1CR Automatically wait SCK1 pin output SO1 pin A7 A6 A5 A4 A3 A2 A1 SIO1TDB B7 B6 B5 B4 B3 B2 B1 B0 A0 A B Automatic wait is released by writing SIO1TDB Figure 14-2 Automatic-wait Function (Example of transmit mode) Table 14-1 Serial Clock Rate (fc = 16 MHz, fs = 32.768kHz) NORMAL1/2, IDLE1/2 Mode TBTCR = "0" SLOW1/2, SLEEP1/2 Mode TBTCR = "1" Serial Clock Baud Rate 2048 bps fs/24 2048 bps fc/28 62.5 kbps Reserved – 125 kbps fc/27 125 kbps Reserved – fc/26 250 kbps fc/26 250 kbps Reserved – 100 fc/25 500 kbps fc/25 500 kbps Reserved – 101 fc/24 1.00 Mbps fc/24 1.00 Mbps Reserved – 110 fc/23 2.00 Mbps fc/23 2.00 Mbps Reserved SCK Serial Clock Baud Rate Serial Clock Baud Rate 000 fc/212 3.906 kbps fs/24 001 fc/28 62.5 kbps 010 fc/27 011 Page 162 TMP86FS49BUG (2) External clock When an external clock is selected by setting SIO1CR to “111B”, the clock via the SCK1 pin from an external source is used as the serial clock. To ensure shift operation, the serial clock pulse width must be 4/fc or more for both “H” and “L” levels. SCK1 pin tSCKL tSCKH tSCKL, tSCKH > 4/fc Figure 14-3 External Clock 14.3.1.2 Shift edge The leading edge is used to transmit data, and the trailing edge is used to receive data. (1) Leading edge shift Data is shifted on the leading edge of the serial clock (falling edge of the SCK1 pin input/output). (2) Trailing edge shift Data is shifted on the trailing edge of the serial clock (rising edge of the SCK1 pin input/output). SIO1CR SCK1 pin Shift register 01234567 *0123456 **012345 ***01234 ****0123 *****012 ******01 *******0 ******** Bit6 Bit5 Bit4 Bit3 Bit2 Bit1 Bit0 Bit1 Bit0 Shift out SO1 pin Bit7 (a) Leading edge shift (Example of MSB transfer) SIO1CR SCK1 pin SI1 pin Shift register Bit7 ******** Bit6 7******* Bit5 67****** Bit4 567***** Bit3 4567**** Bit2 34567*** 234567** (b) Trailing edge shift (Example of MSB transfer) Figure 14-4 Shift Edge Page 163 1234567* 01234567 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG 14.3.2 Transfer bit direction Transfer data direction can be selected by using SIO1CR. The transfer data direction can't be set individually for transmit and receive operations. When the data direction is changed, the writing instruction to SIO1CR should be executed while the transfer is stopped (when SIO1CR= “0”) SIOCR SCK1 pin SIO1TDB A Shift out SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 A4 A5 A6 A7 (a) MSB transfer SIO1CR SCK1 pin SIO1TDB A Shift out SO1 pin A0 A1 A2 A3 (b) LSB transfer Figure 14-5 Transfer Bit Direction (Example of transmit mode) 14.3.2.1 Transmit mode (1) MSB transmit mode MSB transmit mode is selected by setting SIO1CR to “0”, in which case the data is transferred sequentially beginning with the most significant bit (Bit7). (2) LSB transmit mode LSB transmit mode is selected by setting SIO1CR to “1”, in which case the data is transferred sequentially beginning with the least significant bit (Bit0). 14.3.2.2 Receive mode (1) MSB receive mode MSB receive mode is selected by setting SIO1CR to “0”, in which case the data is received sequentially beginning with the most significant bit (Bit7). Page 164 TMP86FS49BUG (2) LSB receive mode LSB receive mode is selected by setting SIO1CR to “1”, in which case the data is received sequentially beginning with the least significant bit (Bit0). 14.3.2.3 Transmit/receive mode (1) MSB transmit/receive mode MSB transmit/receive mode are selected by setting SIO1CR to “0” in which case the data is transferred sequentially beginning with the most significant bit (Bit7) and the data is received sequentially beginning with the most significant (Bit7). (2) LSB transmit/receive mode LSB transmit/receive mode are selected by setting SIO1CR to “1”, in which case the data is transferred sequentially beginning with the least significant bit (Bit0) and the data is received sequentially beginning with the least significant (Bit0). 14.3.3 Transfer modes Transmit, receive and transmit/receive mode are selected by using SIO1CR. 14.3.3.1 Transmit mode Transmit mode is selected by writing “00B” to SIO1CR. (1) Starting the transmit operation Transmit mode is selected by setting “00B” to SIO1CR. Serial clock is selected by using SIO1CR. Transfer direction is selected by using SIO1CR. When a transmit data is written to the transmit buffer register (SIO1TDB), SIO1SR is cleared to “0”. After SIO1CR is set to “1”, SIO1SR is set synchronously to “1” the falling edge of SCK1 pin. The data is transferred sequentially starting from SO1 pin with the direction of the bit specified by SIO1CR, synchronizing with the SCK1 pin's falling edge. SIO1SR is kept in high level, between the first clock falling edge of SCK1 pin and eighth clock falling edge. SIO1SR is set to “1” at the rising edge of pin after the data written to the SIO1TDB is transferred to shift register, then the INTSIO1 interrupt request is generated, synchronizing with the next falling edge on SCK1 pin. Note 1: In internal clock operation, when SIO1CR is set to "1", transfer mode does not start without writing a transmit data to the transmit buffer register (SIO1TDB). Note 2: In internal clock operation, when the SIO1CR is set to "1", SIO1TDB is transferred to shift register after maximum 1-cycle of serial clock frequency, then a serial clock is output from SCK1 pin. Note 3: In external clock operation, when the falling edge is input from SCK1 pin after SIO1CR is set to "1", SIO1TDB is transferred to shift register immediately. Page 165 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG (2) During the transmit operation When data is written to SIO1TDB, SIO1SR is cleared to “0”. In internal clock operation, in case a next transmit data is not written to SIO1TDB, the serial clock stops to “H” level by an automatic-wait function when all of the bit set in the SIO1TDB has been transmitted. Automatic-wait function is released by writing a transmit data to SIO1TDB. Then, transmit operation is restarted after maximum 1-cycle of serial clock. When the next data is written to the SIO1TDB before termination of previous 8-bit data with SIO1SR “1”, the next data is continuously transferred after transmission of previous data. In external clock operation, after SIO1SR is set to “1”, the transmit data must be written to SIO1TDB before the shift operation of the next data begins. If the transmit data is not written to SIO1TDB, transmit error occurs immediately after shift operation is started. Then, INTSIO1 interrupt request is generated after SIO1SR is set to “1”. (3) Stopping the transmit operation There are two ways for stopping transmits operation. • The way of clearing SIO1CR. When SIO1CR is cleared to “0”, transmit operation is stopped after all transfer of the data is finished. When transmit operation is finished, SIO1SR is cleared to “0” and SO1 pin is kept in high level. In external clock operation, SIO1CR must be cleared to “0” before SIO1SR is set to “1” by beginning next transfer. • The way of setting SIO1CR. Transmit operation is stopped immediately after SIO1CR is set to “1”. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Clearing SIOS SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin outout Automatic wait SO1 pin C7 C6 C5 C4 C3 C2 C1 C0 A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 SIO1SR INTSIO1 interrupt request SIO1TDB A C B Writing transmit data C Writing transmit Writing transmit data A data B Figure 14-6 Example of Internal Clock and MSB Transmit Mode Page 166 TMP86FS49BUG Writing transmit data Clearing SIOS SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SIO1SR INTSIO1 interrupt request SIO1TDB A B Writing transmit data A Writing transmit data B C Writing transmit data C Figure 14-7 Exaple of External Clock and MSB Transmit Mode SCK1 pin SIO1SR SO1 pin tSODH 4/fc < tSODH < 8/fc Figure 14-8 Hold Time of the End of Transmit Mode (4) Transmit error processing Transmit errors occur on the following situation. • Shift operation starts before writing next transmit data to SIO1TDB in external clock operation. If transmit errors occur during transmit operation, SIO1SR is set to “1” immediately after starting shift operation. Synchronizing with the next serial clock falling edge, INTSIO1 interrupt request is generated. If shift operation starts before writing data to SIO1TDB after SIO1CR is set to “1”, SIO1SR is set to “1” immediately after shift operation is started and then INTSIO1 interrupt request is generated. SIO1 pin is kept in high level when SIO1SR is set to “1”. When transmit error occurs, transmit operation must be forcibly stop by writing SIO1CR to “1”. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Page 167 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 SIO1SR SIO1SR INTSIO1 interrupt request SIO1TDB SIO1CR A Writing transmit data A B Unknown Writing transmit data B Figure 14-9 Example of Transmit Error Processingme 14.3.3.2 Receive mode The receive mode is selected by writing “01B” to SIO1CR. (1) Starting the receive operation Receive mode is selected by setting “01” to SIO1CR. Serial clock is selected by using SIO1CR. Transfer direction is selected by using SIO1CR. After SIO1CR is set to “1”, SIO1SR is set synchronously to “1” the falling edge of SCK1 pin. Synchronizing with the SCK1 pin's rising edge, the data is received sequentially from SI1 pin with the direction of the bit specified by SBI1DIR. SIO1SR is kept in high level, between the first clock falling edge of SCK1 pin and eighth clock falling edge. When 8-bit data is received, the data is transferred to SIO1RDB from shift register. INTSIO1 interrupt request is generated and SIO1SR is set to “1” Note: In internal clock operation, when the SIO1CR is set to "1", the serial clock is generated from SCK1 pin after maximum 1-cycle of serial clock frequency. (2) During the receive operation The SIO1SR is cleared to “0” by reading a data from SIO1RDB. In the internal clock operation, the serial clock stops to “H” level by an automatic-wait function when the all of the 8-bit data has been received. Automatic-wait function is released by reading a received data from SIO1RDB. Then, receive operation is restarted after maximum 1-cycle of serial clock. In external clock operation, after SIO1SR is set to “1”, the received data must be read from SIO1RDB, before the next data shift-in operation is finished. Page 168 TMP86FS49BUG If received data is not read out from SIO1RDB receive error occurs immediately after shift operation is finished. Then INTSIO1 interrupt request is generated after SIO1SR is set to “1”. (3) Stopping the receive operation There are two ways for stopping the receive operation. • The way of clearing SIO1CR. When SIO1CR is cleared to “0”, receive operation is stopped after all of the data is finished to receive. When receive operation is finished, SIO1SR is cleared to “0”. In external clock operation, SIO1CR must be cleared to “0” before SIO1SR is set to “1” by starting the next shift operation. • The way of setting SIO1CR. Receive operation is stopped immediately after SIO1CR is set to “1”. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Clearing SIOS SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin SI1 pin Automatic wait A7 A6 A5 A4 A3 A2 A1 A0 C7 C6 C5 C4 C3 C2 C1 C0 B7 B6 B5 B4 B3 B2 B1 B0 SIO1SR INTSIO1 interrupt request SIO1RDB A B Writing transmit data A Writing transmit data B Figure 14-10 Example of Internal Clock and MSB Receive Mode Page 169 C Writing transmit data C 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG Reading received data Clearing SIOS SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin SI1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SIO1SR INTSIO1 interrupt request SIO1RDB A Writing transmit data A B C Writing transmit data B Writing transmit data C Figure 14-11 Example of External Clock and MSB Receive Mode (4) Receive error processing Receive errors occur on the following situation. To protect SIO1RDB and the shift register contents, the received data is ignored while the SIO1SR is “1”. • Shift operation is finished before reading out received data from SIO1RDB at SIO1SR is “1” in an external clock operation. If receive error occurs, set the SIO1CR to “0” for reading the data that received immediately before error occurence. And read the data from SIO1RDB. Data in shift register (at errors occur) can be read by reading the SIO1RDB again. When SIO1SR is cleared to “0” after reading the received data, SIO1SR is cleared to “0”. After clearing SIO1CR to “0”, when 8-bit serial clock is input to SCK1 pin, receive operation is stopped. To restart the receive operation, confirm that SIO1SR is cleared to “0”. If the receive error occurs, set the SIO1CR to “1” for stopping the receive operation immediately. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Page 170 TMP86FS49BUG SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin SI1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SIO1SR SIO1SR Write a "0" after reading the received data when a receive error occurs. INTSIO1 interrupt request SIO1RDB A B Writing transmit data A Writing transmit data B Figure 14-12 Example of Receive Error Processing Note: If receive error is not corrected, an interrupt request does not generate after the error occurs. 14.3.3.3 Transmit/receive mode The transmit/receive mode are selected by writing “10” to SIO1CR. (1) Starting the transmit/receive operation Transmit/receive mode is selected by writing “10B” to SIO1CR. Serial clock is selected by using SIO1CR. Transfer direction is selected by using SIO1CR. When a transmit data is written to the transmit buffer register (SIO1TDB), SIO1SR is cleared to “0”. After SIO1CR is set to “1”, SIO1SR is set synchronously to the falling edge of SCK1 pin. The data is transferred sequentially starting from SO1 pin with the direction of the bit specified by SIO1CR, synchronizing with the SCK1 pin's falling edge. And receiving operation also starts with the direction of the bit specified by SIO1CR, synchronizing with the SCK1 pin's rising edge. SIO1SR is kept in high level between the first clock falling edge of SCK1 pin and eighth clock falling edge. SIO1SR is set to “1” at the rising edge of SCK1 pin after the data written to the SIO1TDB is transferred to shift register. When 8-bit data has been received, the received data is transferred to SIO1RDB from shift register, then the INTSIO1 interrupt request occurs, synchronizing with setting SIO1SR to “1”. Note 1: In internal clock operation, when the SIO1CR is set to "1", SIO1TDB is transferred to shift register after maximum 1-cycle of serial clock frequency, then a serial clock is output from SCK1 pin. Note 2: In external clock operation, when the falling edge is input from SCK1 pin after SIO1CR is set to "1", SIO1TDB is transferred to shift register immediately. When the rising edge is input from SCK1 pin, receive operation also starts. Page 171 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG (2) During the transmit/receive operation When data is written to SIO1TDB, SIO1SR is cleared to “0” and when a data is read from SIO1RDB, SIO1SR is cleared to “0”. In internal clock operation, in case of the condition described below, the serial clock stops to “H” level by an automatic-wait function when all of the bit set in the data has been transmitted. • Next transmit data is not written to SIO1TDB after reading a received data from SIO1RDB. • Received data is not read from SIO1RDB after writing a next transmit data to SIO1TDB. • Neither SIO1TDB nor SIO1RDB is accessed after transmission. The automatic wait function is released by writing the next transmit data to SIO1TDB after reading the received data from SIO1RDB, or reading the received data from SIO1RDB after writing the next data to SIO1TDB. Then, transmit/receive operation is restarted after maximum 1 cycle of serial clock. In external clock operation, reading the received data from SIO1RDB and writing the next data to SIO1TDB must be finished before the shift operation of the next data begins. If the transmit data is not written to SIO1TDB after SIO1SR is set to “1”, transmit error occurs immediately after shift operation is started. When the transmit error occurred, SIO1SR is set to “1”. If received data is not read out from SIO1RDB before next shift operation starts after setting SIO1SR to “1”, receive error occurs immediately after shift operation is finished. When the receive error has occurred, SIO1SR is set to “1”. (3) Stopping the transmit/receive operation There are two ways for stopping the transmit/receive operation. • The way of clearing SIO1CR. When SIO1CR is cleared to “0”, transmit/receive operation is stopped after all transfer of the data is finished. When transmit/receive operation is finished, SIO1SR is cleared to “0” and SO1 pin is kept in high level. In external clock operation, SIO1CR must be cleared to “0” before SIO1SR is set to “1” by beginning next transfer. • The way of setting SIO1CR. Transmit/receive operation is stopped immediately after SIO1CR is set to “1”. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Page 172 TMP86FS49BUG Clearing SIOS SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin output Automatic wait Automatic wait SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SI1 pin INTSIO1 interrupt request D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 SIO1SR SIO1TDB A Writing transmit data A B C Writing transmit data C Writing transmit data B SIO1SR SIO1RDB D Reading received data D F E Reading received data E Reading received data F Figure 14-13 Example of Internal Clock and MSB Transmit/Receive Mode Page 173 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG Reading received data Writing transmit data Clearing SIOS SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin output SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SI1 pin D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 INTSIO1 interrupt request SIO1SR SIO1TDB A B Writing transmit data A Writing transmit data B C Writing transmit data C SIO1SR SIO1RDB D E F Reading received data D Reading received data E Reading received data F Figure 14-14 Example of External Clock and MSB Transmit/Receive Mode (4) Transmit/receive error processing Transmit/receive errors occur on the following situation. Corrective action is different, which errors occur transmits or receives. (a) Transmit errors Transmit errors occur on the following situation. • Shift operation starts before writing next transmit data to SIO1TDB in external clock operation. If transmit errors occur during transmit operation, SIO1SR is set to “1” immediately after starting shift operation. And INTSIO1 interrupt request is generated after all of the 8-bit data has been received. If shift operation starts before writing data to SIO1TDB after SIO1CR is set to “1”, SIO1SR is set immediately after starting shift operation. And INTSIO1 interrupt request is generated after all of the 8-bit data has been received. SO1 pin is kept in high level when SIO1SR is set to “1”. When transmit error occurs, transmit operation must be forcibly stop by writing SIO1CR to “1” after the received data is read from SIO1RDB. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Page 174 TMP86FS49BUG SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin output SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 SI1 pin D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 INTSIO1 interrupt request SIO1SR SIO1SR SIO1TDB A B Writing transmit data A Unknown Writing transmit data B SIO1SR SIO1RDB D Reading received data D E Reading received data E F Reading received data F SIO1CR Figure 14-15 Example of Transmit/Receive (Transmit) Error Processing (b) Receive errors Receive errors occur on the following situation. To protect SIO1RDB and the shift register contents, the received data is ignored while the SIO1SR is “1”. • Shift operation is finished before reading out received data from SIO1RDB at SIO1SR is “1” in an external clock operation. If receive error occurs, set the SIO1CR to “0” for reading the data that received immediately before error occurence. And read the data from SIO1RDB. Data in shift register (at errors occur) can be read by reading the SIO1RDB again. When SIO1SR is cleared to “0” after reading the received data, SIO1SR is cleared to “0”. After clearing SIO1CR to “0”, when 8-bit serial clock is input to SCK1 pin, receive operation is stopped. To restart the receive operation, confirm that SIO1SR is cleared to “0”. If the received error occurs, set the SIO1CR to “1” for stopping the receive operation immediately. In this case, SIO1CR, SIO1SR register, SIO1RDB register and SIO1TDB register are initialized. Page 175 14. Synchronous Serial Interface (SIO1) 14.3 Function TMP86FS49BUG SIO1CR SIO1SR Start shift operation Start shift operation Start shift operation SIO1SR SCK1 pin output SO1 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 SI1 pin INTSIO1 interrupt request D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 SIO1SR SIO1TDB A B Writing transmit data A Writing transmit data B C Unknown Writing transmit data C SIO1SR SIO1SR SIO1RDB D E Reading received data D OOH Reading received data E SIO1CR Figure 14-16 Example of Transmit/Receive (Receive) Error Processing Note: If receive error is not corrected, an interrupt request does not generate after the error occurs. SCK1 pin SIO1SR SO1 pin tSODH 4/fc < tSODH < 8/fc Figure 14-17 Hold Time of the End of Transmit/Receive Mode Page 176 TMP86FS49BUG 15. Synchronous Serial Interface (SIO2) The serial interfaces connect to an external device via SI2, SO2, and SCK2 pins. When these pins are used as serial interface, the output latches for each port should be set to "1". 15.1 Configuration Internal data bus SIO2CR SIO2SR SIO2TDB Shift register on transmitter Shift clock Port (Note) Control circuit SO2 pin (Serial data output) MSB/LSB selection Port (Note) Shift register on receiver SI2 pin (Serial data input) SIO2RDB To BUS Port (Note) INTSIO2 interrupt SCK2 pin (Serial data output) Internal clock input Note: Set the register of port correctly for the port assigned as serial interface pins. For details, see the description of the input/output port control register. Figure 15-1 Synchronous Serial Interface (SIO) Page 177 15. Synchronous Serial Interface (SIO2) 15.2 Control TMP86FS49BUG 15.2 Control The SIO is controlled using the serial interface control register (SIO2CR). The operating status of the serial interface can be inspected by reading the status register (SIO2CR). Serial Interface Control Register SIO2CR (0031H) 7 6 SIOS SIOINH SIOS SIOINH SIOM SIODIR 5 4 SIOM 3 2 SIODIR 1 0 SCK (Initial value: 0000 0000) Specify start/stop of transfer 0: Stop 1: Start Forcibly stops transfer (Note 1) 0: – 1: Forcibly stop (Automatically cleared to "0" after stopping) Selects transfer mode 00: Transmit mode 01: Receive mode 10: Transmit/receive mode 11: Reserved Selects direction of transfer 0: MSB (Transfer beginning with bit7) 1: LSB (Transfer beginning with bit0) NORMAL1/2 or IDLE1/2 modes SCK Selects serial clock SLOW/SLEEP mode TBTCR = "0" TBTCR = "1" 000 fc/212 fs/24 fs/24 001 fc/28 fc/28 Reserved 010 fc/2 7 7 Reserved 011 fc/26 fc/26 Reserved 100 fc/2 5 5 Reserved 101 fc/24 fc/24 Reserved 110 3 3 Reserved 111 fc/2 fc/2 fc/2 fc/2 R/W External clock (Input from SCK2 pin) Note 1: When SIO2CR is set to “1”, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Note 2: Transfer mode, direction of transfer and serial clock must be select during the transfer is stopping (when SIO2SR "0"). Note 3: fc: High-frequency clock [Hz], fs: Low-frequency clock [Hz], *: Don’t care Page 178 TMP86FS49BUG Serial Interface Status Register SIO2SR (0032H) 7 6 5 4 3 2 SIOF SEF TXF RXF TXERR RXERR 1 0 (Initial value: 0010 00**) SIOF Serial transfer operation status monitor 0: Transfer finished 1: Transfer in progress SEF Number of clocks monitor 0: 8 clocks 1: 1 to 7 clocks TXF Transmit buffer empty flag 0: Data exists in transmit buffer 1: No data exists in transmit buffer RXF Receive buffer full flag 0: No data exists in receive buffer 1: Data exists in receive buffer Transfer operation error flag Read 0: – (No error exist) 1: Transmit buffer under run occurs in an external clock mode Write 0: Clear the flag 1: – (A write of "1" to this bit is ignored) Receive operation error flag Read 0: – (No error exist) 1: Receive buffer over run occurs in an external clock mode Write 0: Clear the flag 1: – (A write of "1" to this bit is ignored) TXERR RXERR Read only R/W Note 1: The operation error flag (TXERR and RXERR) are not automatically cleared by stopping transfer with SIO2CR "0". Therefore, set these bits to "0" for clearing these error flag. Or set SIO2CR to "1". Note 2: *: Don't care Receive buffer register SIO2RDB (002BH) 7 6 5 4 3 2 1 0 Read only (Initial value: 0000 0000) Transmit buffer register SIO2TDB (002BH) 7 6 5 4 3 2 1 0 Write only (Initial value: **** ****) Note 1: SIO2TDB is write only register. A bit manipulation should not be performed on the transmit buffer register using a readmodify-write instruction. Note 2: The SIO2TDB should be written after checking SIO2SR "1". When SIO2SR is "0", the writing data can't be transferred to SIO2TDB even if write instruction is executed to SIO2TDB . Note 3: *: Don't care Page 179 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG 15.3 Function 15.3.1 Serial clock 15.3.1.1 Clock source The serial clock can be selected by using SIO2CR. When the serial clock is changed, the writing instruction to SIO2CR should be executed while the transfer is stopped (when SIO2SR “0”) (1) Internal clock Setting the SIO2CR to other than “111B” outputs the clock (shown in " Table 15-1 Serial Clock Rate (fc = 16 MHz, fs = 32.768kHz) ") as serial clock outputs from SCK2 pin. At the before beginning or finishing of a transfer, SCK2 pin is kept in high level. When writing (in the transmit mode) or reading (in the receive mode) data can not follow the serial clock rate, an automatic-wait function is executed to stop the serial clock automatically and hold the next shift operation until reading or writing is completed (shown in " Figure 15-2 Automatic-wait Function (Example of transmit mode) "). The maximum time from releasing the automatic-wait function by reading or writing a data is 1 cycle of the selected serial clock until the serial clock comes out from SCK2 pin. SIO2CR Automatically wait SCK2 pin output SO2 pin A7 A6 A5 A4 A3 A2 A1 SIO2TDB B7 B6 B5 B4 B3 B2 B1 B0 A0 A B Automatic wait is released by writing SIO2TDB Figure 15-2 Automatic-wait Function (Example of transmit mode) Table 15-1 Serial Clock Rate (fc = 16 MHz, fs = 32.768kHz) NORMAL1/2, IDLE1/2 Mode TBTCR = "0" SLOW1/2, SLEEP1/2 Mode TBTCR = "1" Serial Clock Baud Rate 2048 bps fs/24 2048 bps fc/28 62.5 kbps Reserved – 125 kbps fc/27 125 kbps Reserved – fc/26 250 kbps fc/26 250 kbps Reserved – 100 fc/25 500 kbps fc/25 500 kbps Reserved – 101 fc/24 1.00 Mbps fc/24 1.00 Mbps Reserved – 110 fc/23 2.00 Mbps fc/23 2.00 Mbps Reserved SCK Serial Clock Baud Rate Serial Clock Baud Rate 000 fc/212 3.906 kbps fs/24 001 fc/28 62.5 kbps 010 fc/27 011 Page 180 TMP86FS49BUG (2) External clock When an external clock is selected by setting SIO2CR to “111B”, the clock via the SCK2 pin from an external source is used as the serial clock. To ensure shift operation, the serial clock pulse width must be 4/fc or more for both “H” and “L” levels. SCK2 pin tSCKL tSCKH tSCKL, tSCKH > 4/fc Figure 15-3 External Clock 15.3.1.2 Shift edge The leading edge is used to transmit data, and the trailing edge is used to receive data. (1) Leading edge shift Data is shifted on the leading edge of the serial clock (falling edge of the SCK2 pin input/output). (2) Trailing edge shift Data is shifted on the trailing edge of the serial clock (rising edge of the SCK2 pin input/output). SIO2CR SCK2 pin Shift register 01234567 *0123456 **012345 ***01234 ****0123 *****012 ******01 *******0 ******** Bit6 Bit5 Bit4 Bit3 Bit2 Bit1 Bit0 Bit1 Bit0 Shift out SO2 pin Bit7 (a) Leading edge shift (Example of MSB transfer) SIO2CR SCK2 pin SI2 pin Shift register Bit7 ******** Bit6 7******* Bit5 67****** Bit4 567***** Bit3 4567**** Bit2 34567*** 234567** (b) Trailing edge shift (Example of MSB transfer) Figure 15-4 Shift Edge Page 181 1234567* 01234567 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG 15.3.2 Transfer bit direction Transfer data direction can be selected by using SIO2CR. The transfer data direction can't be set individually for transmit and receive operations. When the data direction is changed, the writing instruction to SIO2CR should be executed while the transfer is stopped (when SIO2CR= “0”) SIO2CR SCK2 pin SIO2TDB A Shift out SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 A4 A5 A6 A7 (a) MSB transfer SIO2CR SCK2 pin SIO2TDB A Shift out SO2 pin A0 A1 A2 A3 (b) LSB transfer Figure 15-5 Transfer Bit Direction (Example of transmit mode) 15.3.2.1 Transmit mode (1) MSB transmit mode MSB transmit mode is selected by setting SIO2CR to “0”, in which case the data is transferred sequentially beginning with the most significant bit (Bit7). (2) LSB transmit mode LSB transmit mode is selected by setting SIO2CR to “1”, in which case the data is transferred sequentially beginning with the least significant bit (Bit0). 15.3.2.2 Receive mode (1) MSB receive mode MSB receive mode is selected by setting SIO2CR to “0”, in which case the data is received sequentially beginning with the most significant bit (Bit7). Page 182 TMP86FS49BUG (2) LSB receive mode LSB receive mode is selected by setting SIO2CR to “1”, in which case the data is received sequentially beginning with the least significant bit (Bit0). 15.3.2.3 Transmit/receive mode (1) MSB transmit/receive mode MSB transmit/receive mode are selected by setting SIO2CR to “0” in which case the data is transferred sequentially beginning with the most significant bit (Bit7) and the data is received sequentially beginning with the most significant (Bit7). (2) LSB transmit/receive mode LSB transmit/receive mode are selected by setting SIO2CR to “1”, in which case the data is transferred sequentially beginning with the least significant bit (Bit0) and the data is received sequentially beginning with the least significant (Bit0). 15.3.3 Transfer modes Transmit, receive and transmit/receive mode are selected by using SIO2CR. 15.3.3.1 Transmit mode Transmit mode is selected by writing “00B” to SIO2CR. (1) Starting the transmit operation Transmit mode is selected by setting “00B” to SIO2CR. Serial clock is selected by using SIO2CR. Transfer direction is selected by using SIO2CR. When a transmit data is written to the transmit buffer register (SIO2TDB), SIO2SR is cleared to “0”. After SIO2CR is set to “1”, SIO2SR is set synchronously to “1” the falling edge of SCK2 pin. The data is transferred sequentially starting from SO2 pin with the direction of the bit specified by SIO2CR, synchronizing with the SCK2 pin's falling edge. SIO2SR is kept in high level, between the first clock falling edge of SCK2 pin and eighth clock falling edge. SIO2SR is set to “1” at the rising edge of pin after the data written to the SIO2TDB is transferred to shift register, then the INTSIO2 interrupt request is generated, synchronizing with the next falling edge on SCK2 pin. Note 1: In internal clock operation, when SIO2CR is set to "1", transfer mode does not start without writing a transmit data to the transmit buffer register (SIO2TDB). Note 2: In internal clock operation, when the SIO2CR is set to "1", SIO2TDB is transferred to shift register after maximum 1-cycle of serial clock frequency, then a serial clock is output from SCK2 pin. Note 3: In external clock operation, when the falling edge is input from SCK2 pin after SIO2CR is set to "1", SIO2TDB is transferred to shift register immediately. Page 183 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG (2) During the transmit operation When data is written to SIO2TDB, SIO2SR is cleared to “0”. In internal clock operation, in case a next transmit data is not written to SIO2TDB, the serial clock stops to “H” level by an automatic-wait function when all of the bit set in the SIO2TDB has been transmitted. Automatic-wait function is released by writing a transmit data to SIO2TDB. Then, transmit operation is restarted after maximum 1-cycle of serial clock. When the next data is written to the SIO2TDB before termination of previous 8-bit data with SIO2SR “1”, the next data is continuously transferred after transmission of previous data. In external clock operation, after SIO2SR is set to “1”, the transmit data must be written to SIO2TDB before the shift operation of the next data begins. If the transmit data is not written to SIO2TDB, transmit error occurs immediately after shift operation is started. Then, INTSIO2 interrupt request is generated after SIO2SR is set to “1”. (3) Stopping the transmit operation There are two ways for stopping transmits operation. • The way of clearing SIO2CR. When SIO2CR is cleared to “0”, transmit operation is stopped after all transfer of the data is finished. When transmit operation is finished, SIO2SR is cleared to “0” and SO2 pin is kept in high level. In external clock operation, SIO2CR must be cleared to “0” before SIO2SR is set to “1” by beginning next transfer. • The way of setting SIO2CR. Transmit operation is stopped immediately after SIO2CR is set to “1”. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Clearing SIOS SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin outout Automatic wait SO2 pin C7 C6 C5 C4 C3 C2 C1 C0 A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 SIO2SR INTSIO2 interrupt request SIO2TDB A C B Writing transmit data C Writing transmit Writing transmit data A data B Figure 15-6 Example of Internal Clock and MSB Transmit Mode Page 184 TMP86FS49BUG Writing transmit data Clearing SIOS SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SIO2SR INTSIO2 interrupt request SIO2TDB A B Writing transmit data A Writing transmit data B C Writing transmit data C Figure 15-7 Exaple of External Clock and MSB Transmit Mode SCK2 pin SIO2SR SO2 pin tSODH 4/fc < tSODH < 8/fc Figure 15-8 Hold Time of the End of Transmit Mode (4) Transmit error processing Transmit errors occur on the following situation. • Shift operation starts before writing next transmit data to SIO2TDB in external clock operation. If transmit errors occur during transmit operation, SIO2SR is set to “1” immediately after starting shift operation. Synchronizing with the next serial clock falling edge, INTSIO2 interrupt request is generated. If shift operation starts before writing data to SIO2TDB after SIO2CR is set to “1”, SIO2SR is set to “1” immediately after shift operation is started and then INTSIO2 interrupt request is generated. SIO2 pin is kept in high level when SIO2SR is set to “1”. When transmit error occurs, transmit operation must be forcibly stop by writing SIO2CR to “1”. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Page 185 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 SIO2SR SIO2SR INTSIO2 interrupt request SIO2TDB SIO2CR A Writing transmit data A B Unknown Writing transmit data B Figure 15-9 Example of Transmit Error Processingme 15.3.3.2 Receive mode The receive mode is selected by writing “01B” to SIO2CR. (1) Starting the receive operation Receive mode is selected by setting “01” to SIO2CR. Serial clock is selected by using SIO2CR. Transfer direction is selected by using SIO2CR. After SIO2CR is set to “1”, SIO2SR is set synchronously to “1” the falling edge of SCK2 pin. Synchronizing with the SCK2 pin's rising edge, the data is received sequentially from SI2 pin with the direction of the bit specified by SBI2DIR. SIO2SR is kept in high level, between the first clock falling edge of SCK2 pin and eighth clock falling edge. When 8-bit data is received, the data is transferred to SIO2RDB from shift register. INTSIO2 interrupt request is generated and SIO2SR is set to “1” Note: In internal clock operation, when the SIO2CR is set to "1", the serial clock is generated from SCK2 pin after maximum 1-cycle of serial clock frequency. (2) During the receive operation The SIO2SR is cleared to “0” by reading a data from SIO2RDB. In the internal clock operation, the serial clock stops to “H” level by an automatic-wait function when the all of the 8-bit data has been received. Automatic-wait function is released by reading a received data from SIO2RDB. Then, receive operation is restarted after maximum 1-cycle of serial clock. In external clock operation, after SIO2SR is set to “1”, the received data must be read from SIO2RDB, before the next data shift-in operation is finished. Page 186 TMP86FS49BUG If received data is not read out from SIO2RDB receive error occurs immediately after shift operation is finished. Then INTSIO2 interrupt request is generated after SIO2SR is set to “1”. (3) Stopping the receive operation There are two ways for stopping the receive operation. • The way of clearing SIO2CR. When SIO2CR is cleared to “0”, receive operation is stopped after all of the data is finished to receive. When receive operation is finished, SIO2SR is cleared to “0”. In external clock operation, SIO2CR must be cleared to “0” before SIO2SR is set to “1” by starting the next shift operation. • The way of setting SIO2CR. Receive operation is stopped immediately after SIO2CR is set to “1”. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Clearing SIOS SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin SI2 pin Automatic wait A7 A6 A5 A4 A3 A2 A1 A0 C7 C6 C5 C4 C3 C2 C1 C0 B7 B6 B5 B4 B3 B2 B1 B0 SIO2SR INTSIO2 interrupt request SIO2RDB A B Writing transmit data A Writing transmit data B Figure 15-10 Example of Internal Clock and MSB Receive Mode Page 187 C Writing transmit data C 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG Reading received data Clearing SIOS SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin SI2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SIO2SR INTSIO2 interrupt request SIO2RDB A Writing transmit data A B C Writing transmit data B Writing transmit data C Figure 15-11 Example of External Clock and MSB Receive Mode (4) Receive error processing Receive errors occur on the following situation. To protect SIO2RDB and the shift register contents, the received data is ignored while the SIO2SR is “1”. • Shift operation is finished before reading out received data from SIO2RDB at SIO2SR is “1” in an external clock operation. If receive error occurs, set the SIO2CR to “0” for reading the data that received immediately before error occurence. And read the data from SIO2RDB. Data in shift register (at errors occur) can be read by reading the SIO2RDB again. When SIO2SR is cleared to “0” after reading the received data, SIO2SR is cleared to “0”. After clearing SIO2CR to “0”, when 8-bit serial clock is input to SCK2 pin, receive operation is stopped. To restart the receive operation, confirm that SIO2SR is cleared to “0”. If the receive error occurs, set the SIO2CR to “1” for stopping the receive operation immediately. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Page 188 TMP86FS49BUG SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin SI2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SIO2SR SIO2SR Write a "0" after reading the received data when a receive error occurs. INTSIO2 interrupt request SIO2RDB A B Writing transmit data A Writing transmit data B Figure 15-12 Example of Receive Error Processing Note: If receive error is not corrected, an interrupt request does not generate after the error occurs. 15.3.3.3 Transmit/receive mode The transmit/receive mode are selected by writing “10” to SIO2CR. (1) Starting the transmit/receive operation Transmit/receive mode is selected by writing “10B” to SIO2CR. Serial clock is selected by using SIO2CR. Transfer direction is selected by using SIO2CR. When a transmit data is written to the transmit buffer register (SIO2TDB), SIO2SR is cleared to “0”. After SIO2CR is set to “1”, SIO2SR is set synchronously to the falling edge of SCK2 pin. The data is transferred sequentially starting from SO2 pin with the direction of the bit specified by SIO2CR, synchronizing with the SCK2 pin's falling edge. And receiving operation also starts with the direction of the bit specified by SIO2CR, synchronizing with the SCK2 pin's rising edge. SIO2SR is kept in high level between the first clock falling edge of SCK2 pin and eighth clock falling edge. SIO2SR is set to “1” at the rising edge of SCK2 pin after the data written to the SIO2TDB is transferred to shift register. When 8-bit data has been received, the received data is transferred to SIO2RDB from shift register, then the INTSIO2 interrupt request occurs, synchronizing with setting SIO2SR to “1”. Note 1: In internal clock operation, when the SIO2CR is set to "1", SIO2TDB is transferred to shift register after maximum 1-cycle of serial clock frequency, then a serial clock is output from SCK2 pin. Note 2: In external clock operation, when the falling edge is input from SCK2 pin after SIO2CR is set to "1", SIO2TDB is transferred to shift register immediately. When the rising edge is input from SCK2 pin, receive operation also starts. Page 189 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG (2) During the transmit/receive operation When data is written to SIO2TDB, SIO2SR is cleared to “0” and when a data is read from SIO2RDB, SIO2SR is cleared to “0”. In internal clock operation, in case of the condition described below, the serial clock stops to “H” level by an automatic-wait function when all of the bit set in the data has been transmitted. • Next transmit data is not written to SIO2TDB after reading a received data from SIO2RDB. • Received data is not read from SIO2RDB after writing a next transmit data to SIO2TDB. • Neither SIO2TDB nor SIO2RDB is accessed after transmission. The automatic wait function is released by writing the next transmit data to SIO2TDB after reading the received data from SIO2RDB, or reading the received data from SIO2RDB after writing the next data to SIO2TDB. Then, transmit/receive operation is restarted after maximum 1 cycle of serial clock. In external clock operation, reading the received data from SIO2RDB and writing the next data to SIO2TDB must be finished before the shift operation of the next data begins. If the transmit data is not written to SIO2TDB after SIO2SR is set to “1”, transmit error occurs immediately after shift operation is started. When the transmit error occurred, SIO2SR is set to “1”. If received data is not read out from SIO2RDB before next shift operation starts after setting SIO2SR to “1”, receive error occurs immediately after shift operation is finished. When the receive error has occurred, SIO2SR is set to “1”. (3) Stopping the transmit/receive operation There are two ways for stopping the transmit/receive operation. • The way of clearing SIO2CR. When SIO2CR is cleared to “0”, transmit/receive operation is stopped after all transfer of the data is finished. When transmit/receive operation is finished, SIO2SR is cleared to “0” and SO2 pin is kept in high level. In external clock operation, SIO2CR must be cleared to “0” before SIO2SR is set to “1” by beginning next transfer. • The way of setting SIO2CR. Transmit/receive operation is stopped immediately after SIO2CR is set to “1”. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Page 190 TMP86FS49BUG Clearing SIOS SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin output Automatic wait Automatic wait SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SI2 pin INTSIO2 interrupt request D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 SIO2SR SIO2TDB A Writing transmit data A B C Writing transmit data C Writing transmit data B SIO2SR SIO2RDB D Reading received data D F E Reading received data E Reading received data F Figure 15-13 Example of Internal Clock and MSB Transmit/Receive Mode Page 191 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG Reading received data Writing transmit data Clearing SIOS SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin output SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 C2 C1 C0 SI2 pin D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 INTSIO2 interrupt request SIO2SR SIO2TDB A B Writing transmit data A Writing transmit data B C Writing transmit data C SIO2SR SIO2RDB D E F Reading received data D Reading received data E Reading received data F Figure 15-14 Example of External Clock and MSB Transmit/Receive Mode (4) Transmit/receive error processing Transmit/receive errors occur on the following situation. Corrective action is different, which errors occur transmits or receives. (a) Transmit errors Transmit errors occur on the following situation. • Shift operation starts before writing next transmit data to SIO2TDB in external clock operation. If transmit errors occur during transmit operation, SIO2SR is set to “1” immediately after starting shift operation. And INTSIO2 interrupt request is generated after all of the 8-bit data has been received. If shift operation starts before writing data to SIO2TDB after SIO2CR is set to “1”, SIO2SR is set immediately after starting shift operation. And INTSIO2 interrupt request is generated after all of the 8-bit data has been received. SO2 pin is kept in high level when SIO2SR is set to “1”. When transmit error occurs, transmit operation must be forcibly stop by writing SIO2CR to “1” after the received data is read from SIO2RDB. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Page 192 TMP86FS49BUG SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin output SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 SI2 pin D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 INTSIO2 interrupt request SIO2SR SIO2SR SIO2TDB A B Writing transmit data A Unknown Writing transmit data B SIO2SR SIO2RDB D Reading received data D E Reading received data E F Reading received data F SIO2CR Figure 15-15 Example of Transmit/Receive (Transmit) Error Processing (b) Receive errors Receive errors occur on the following situation. To protect SIO2RDB and the shift register contents, the received data is ignored while the SIO2SR is “1”. • Shift operation is finished before reading out received data from SIO2RDB at SIO2SR is “1” in an external clock operation. If receive error occurs, set the SIO2CR to “0” for reading the data that received immediately before error occurence. And read the data from SIO2RDB. Data in shift register (at errors occur) can be read by reading the SIO2RDB again. When SIO2SR is cleared to “0” after reading the received data, SIO2SR is cleared to “0”. After clearing SIO2CR to “0”, when 8-bit serial clock is input to SCK2 pin, receive operation is stopped. To restart the receive operation, confirm that SIO2SR is cleared to “0”. If the received error occurs, set the SIO2CR to “1” for stopping the receive operation immediately. In this case, SIO2CR, SIO2SR register, SIO2RDB register and SIO2TDB register are initialized. Page 193 15. Synchronous Serial Interface (SIO2) 15.3 Function TMP86FS49BUG SIO2CR SIO2SR Start shift operation Start shift operation Start shift operation SIO2SR SCK2 pin output SO2 pin A7 A6 A5 A4 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 C7 C6 C5 C4 C3 SI2 pin INTSIO2 interrupt request D7 D6 D5 D4 D3 D2 D1 D0 E7 E6 E5 E4 E3 E2 E1 E0 F7 F6 F5 F4 F3 F2 F1 F0 SIO2SR SIO2TDB A B Writing transmit data A Writing transmit data B C Unknown Writing transmit data C SIO2SR SIO2SR SIO2RDB D E Reading received data D OOH Reading received data E SIO2CR Figure 15-16 Example of Transmit/Receive (Receive) Error Processing Note: If receive error is not corrected, an interrupt request does not generate after the error occurs. SCK2 pin SIO2SR SO2 pin tSODH 4/fc < tSODH < 8/fc Figure 15-17 Hold Time of the End of Transmit/Receive Mode Page 194 TMP86FS49BUG 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) The TMP86FS49BUG has a serial bus interface which employs an I2C bus. The serial interface is connected to an external devices through SDA and SCL. The serial bus interface pins are also used as the port. When used as serial bus interface pins, set the output latches of these pins to "1". When not used as serial bus interface pins, the port is used as a normal I/O port. Note 1: The serial bus interface can be used only in NORMAL1/2 and IDLE1/2 mode. It can not be used in IDLE0, SLOW1/2 and SLEEP0/1/2 mode. Note 2: The serial bus interface can be used only in the Standard mode of I2C. The fast mode and the high-speed mode can not be used. Note 3: Please refer to the I/O port section about the detail of setting port. 16.1 Configuration INTSBI interrupt request SCL fc/4 Noise canceller Input/ output control Divider Transfer control circuit I2C bus clock sysn. Control Shift register SBICRB/ SBISRB SBI control register B/ SBI status register B I C bus address register I2C bus data control SBI data buffer register Noise canceller SDA SDA SBICRA/ SBISRA SBIDBR I2CAR 2 SCL SBI control register A/ SBI status register A Figure 16-1 Serial Bus Interface (SBI) 16.2 Control The following registers are used for control the serial bus interface and monitor the operation status. • Serial bus interface control register A (SBICRA) • Serial bus interface control register B (SBICRB) • Serial bus interface data buffer register (SBIDBR) • I2C bus address register (I2CAR) • Serial bus interface status register A (SBISRA) • Serial bus interface status register B (SBISRB) 16.3 Software Reset A serial bus interface circuit has a software reset function, when a serial bus interface circuit is locked by an external noise, etc. To reset the serial bus interface circuit, write “10”, “01” into the SWRST (Bit1, 0 in SBICRB). And a status of software reset canbe read from SWRMON (Bit0 in SBISRA). Page 195 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.4 The Data Format in the I2C Bus Mode TMP86FS49BUG 16.4 The Data Format in the I2C Bus Mode The data format of the I2C bus is shown below. (a) Addressing format 8 bits 1 RA S Slave address / C WK 1 to 8 bits 1 1 to 8 bits Data A C K Data 1 1 A CP K 1 or more (b) Addressing format (with restart) 8 bits 1 RA S Slave address / C WK 1 1 to 8 bits 1 8 bits 1 A RA C S Slave address / C K WK Data 1 or more 1 S 1 1 to 8 bits 1 1 to 8 bits Data A C K Data A C K Data 1 S R/W ACK P 1 A CP K 1 or more : Start condition : Direction bit : Acknowledge bit : Stop condition Figure 16-2 Data Format in of I2C Bus Page 196 Data 1 or more (c) Free data format 8 bits 1 to 8 bits 1 A CP K TMP86FS49BUG 16.5 I2C Bus Control The following registers are used to control the serial bus interface and monitor the operation status of the I2C bus. Serial Bus Interface Control Register A 7 SBICRA (0F90H) 6 5 4 BC 3 2 1 ACK 0 SCK (Initial value: 0000 *000) ACK = 0 BC Number of transferred bits BC Number of Clock 000: Bits Bits 8 8 9 8 001: 1 1 2 1 010: 2 2 3 2 011: 3 3 4 3 100: 4 4 5 4 101: 5 5 6 5 110: 6 6 7 6 111: 7 7 8 ACK ACK SCK Acknowledgement mode specification ACK = 1 Number of Clock Master mode Write only 7 Slave mode 0: Not generate a clock pulse for an acknowledgement. Not count a clock pulse for an acknowledgement. 1: Generate a clock pulse for an acknowledgement. Count a clock pulse for an acknowledgement. SCK n At fc = 16 MHz At fc = 8 MHz At fc = 4 MHz 000: 4 Reserved Reserved 100.0 kHz 001: 5 Reserved Reserved 55.6 kHz Serial clock (fscl) selection (Output on SCL pin) 010: 6 Reserved 58.8 kHz 29.4 kHz 011: 7 60.6 kHz 30.3 kHz 15.2 kHz [fscl = 1/(2n+1/fc + 8/fc)] 100: 8 30.8 kHz 15.4 kHz 7.7 kHz 101: 9 15.5 kHz 7.8 kHz 3.9 kHz 110: 10 7.8 kHz 3.9 kHz 1.9 kHz 111: R/W Write only Reserved Note 1: fc: High-frequency clock [Hz], *: Don't care Note 2: SBICRA cannot be used with any of read-modify-write instructions such as bit manipulation, etc. Note 3: Do not set SCK as the frequency that is over 100 kHz. Serial Bus Interface Data Buffer Register SBIDBR (0F91H) 7 6 5 4 3 2 1 0 (Initial value: **** ****) R/W Note 1: For writing transmitted data, start from the MSB (Bit7). Note 2: The data which was written into SBIDBR can not be read, since a write data buffer and a read buffer are independent in SBIDBR. Therefore, SBIDBR cannot be used with any of read-modify-write instructions such as bit manipulation, etc. Note 3: *: Don't care Page 197 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.5 I2C Bus Control TMP86FS49BUG I2C bus Address Register I2CAR (0F92H) 7 6 5 SA6 SA5 SA4 4 3 2 1 SA2 SA1 SA0 0 Slave address SA Slave address selection ALS Address recognition mode specification SA3 ALS (Initial value: 0000 0000) Write only 0: Slave address recognition 1: Non slave address recognition Note 1: I2CAR is write-only register, which cannot be used with any of read-modify-write instruction such as bit manipulation, etc. Note 2: Do not set I2CAR to "00H" to avoid the incorrect response of acknowledgment in slave mode. ( If "00H" is set to I2CAR as the Slave Address and a START Byte "01H" in I2C bus standard is recived, the device detects slave address match.) Serial Bus Interface Control Register B SBICRB (0F93H) MST TRX BB PIN SBIM SWRST1 SWRST0 7 6 5 4 3 MST TRX BB PIN SBIM 0: Master/slave selection Transmitter/receiver selection Start/stop generation Cancel interrupt service request Serial bus interface operating mode selection Software reset start bit 2 1 0 SWRST1 SWRST0 (Initial value: 0001 0000) Slave 1: Master 0: Receiver 1: Transmitter 0: Generate a stop condition when MST, TRX and PIN are "1" 1: Generate a start condition when MST, TRX and PIN are "1" 0: – (Can not clear this bit by a software) 1: Cancel interrupt service request Write only 00: Port mode (Serial bus interface output disable) 01: Reserved 10: I2C bus mode 11: Reserved Software reset starts by first writing "10" and next writing "01" Note 1: Switch a mode to port after confirming that the bus is free. Note 2: Switch a mode to I2C bus mode after confiming that the port is high level. Note 3: SBICRB has write-only register and must not be used with any of read-modify-write instructions such as bit manipulation, etc. Note 4: When the SWRST (Bit1, 0 in SBICRB) is written to "10", "01" in I2C bus mode, software reset is occurred. In this case, the SBICRA, I2CAR, SBISRA and SBISRB registers are initialized and the bits of SBICRB except the SBIM (Bit3, 2 in SBICRB) are also initialized. Serial Bus Interface Status Register A 7 SBISRA (0F90H) 6 5 4 3 2 1 0 SWRMON SWRMON Software reset monitor 0: During software reset 1: – (Initial value) (Initial value: **** ***1) Read only Serial Bus Interface Status Register B SBISRB (0F93H) 7 6 5 4 3 2 1 0 MST TRX BB PIN AL AAS AD0 LRB Page 198 (Initial value: 0001 0000) TMP86FS49BUG MST TRX BB Master/slave selection status monitor 0: 1: Master Transmitter/receiver selection status monitor 0: Receiver Bus status monitor AL AD0 LRB Transmitter 0: Bus free Bus busy 0: Requesting interrupt service 1: Releasing interrupt service request 0: – 1: Arbitration lost detected Slave address match detection monitor 0: - 1: Detect slave address match or "GENERAL CALL" "GENERAL CALL" detection monitor 0: - Arbitration lost detection monitor AAS 1: 1: Interrupt service requests status monitor PIN Slave Last received bit monitor 1: Detect "GENERAL CALL" 0: Last receive bit is "0" 1: Last receiv bit is "1" Read only 16.5.1 Acknowledgement mode specification 16.5.1.1 Acknowledgment mode (ACK = “1”) To set the device as an acknowledgment mode, the ACK (Bit4 in SBICRA) should be set to “1”. When a serial bus interface circuit is a master mode, an additional clock pulse is generated for an acknowledge signal. In a slave mode, a clock is counted for the acknowledge signal. In the master transmitter mode, the SDA pin is released in order to receive an acknowledge signal from the receiver during additional clock pulse cycle. In the master receiver mode, the SDA pin is set to low level generation an acknowledge signal during additional clock pulse cycle. In a slave mode, when a received slave address matches to a slave address which is set to the I2CAR or when a “GENERAL CALL” is received, the SDA pin is set to low level generating an acknowledge signal. After the matching of slave address or the detection of “GENERAL CALL”, in the transmitter, the SDA pin is released in order to receive an acknowledge signal from the receiver during additional clock pulse cycle. In a receiver, the SDA pin is set to low level generation an acknowledge signal during additional clock pulse cycle after the matching of slave address or the detection of “GENERAL CALL” The Table 16-1 shows the SCL and SDA pins status in acknowledgment mode. Table 16-1 SCL and SDA Pins Status in Acknowledgement Mode Mode Pin Transmitter SCL An additional clock pulse is generated. Master Released in order to receive an acknowledge signal. SDA SCL Set to low level generating an acknowledge signal A clock is counted for the acknowledge signal. When slave address matches or a general call is detected Slave Receiver – Set to low level generating an acknowledge signal. SDA After matching of slave address or general call Released in order to receive an acknowledge signal. Set to low level generating an acknowledge signal. 16.5.1.2 Non-acknowledgment mode (ACK = “0”) To set the device as a non-acknowledgement mode, the ACK (Bit4 in SBICRA) should be cleared to “0”. Page 199 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.5 I2C Bus Control TMP86FS49BUG In the master mode, a clock pulse for an acknowledge signal is not generated. In the slave mode, a clock for a acknowledge signal is not counted. 16.5.2 Number of transfer bits The BC (Bits7 to 5 in SBICRA) is used to select a number of bits for next transmitting and receiving data. Since the BC is cleared to “000” by a start condition, a slave address and direction bit transmissions are always executed in 8 bits. Other than these, the BC retains a specified value. 16.5.3 Serial clock 16.5.3.1 Clock source The SCK (Bits2 to 0 in SBICRA) is used to select a maximum transfer frequency output from the SCL pin in the master mode. Four or more machine cycles are required for both high and low levels of pulse width in the external clock which is input from SCL pin. Note: Since the serial bus interface can not be used as the fast mode and the high-speed mode, do not set SCK as the frequency that is over 100 kHz. tHIGH tLOW 1/fscl SCK (Bits2 to 0 in the SBICRA) n 000 001 010 011 100 101 110 tLOW = 2 /fc n tHIGH = 2 /fc + 8/fc fscl = 1/(tLOW + tHIGH) tSCKL n 4 5 6 7 8 9 10 tSCKH tSCKL, tSCKH > 4 tcyc Note 1: fc = High-frequency clock Note 2: tcyc = 4/fc (in NORMAL mode, IDLE mode) Figure 16-3 Clock Source 16.5.3.2 Clock synchronization In the I2C bus, in order to drive a bus with a wired AND, a master device which pulls down a clock pulse to low will, in the first place, invalidate a clock pulse of another master device which generates a high-level clock pulse. Page 200 TMP86FS49BUG The serial bus interface circuit has a clock synchronization function. This function ensures normal transfer even if there are two or more masters on the same bus. The example explains clock synchronization procedures when two masters simultaneously exist on a bus. Count start Wait SCL pin (Master 1) Count restart SCL pin (Master 2) Count reset SCL (Bus) a b c Figure 16-4 Clock Synchronization As Master 1 pulls down the SCL pin to the low level at point “a”, the SCL line of the bus becomes the low level. After detecting this situation, Master 2 resets counting a clock pulse in the high level and sets the SCL pin to the low level. Master 1 finishes counting a clock pulse in the low level at point “b” and sets the SCL pin to the high level. Since Master 2 holds the SCL line of the bus at the low level, Master 1 waits for counting a clock pulse in the high level. After Master 2 sets a clock pulse to the high level at point “c” and detects the SCL line of the bus at the high level, Master 1 starts counting a clock pulse in the high level. Then, the master, which has finished the counting a clock pulse in the high level, pulls down the SCL pin to the low level. The clock pulse on the bus is determined by the master device with the shortest high-level period and the master device with the longest low-level period from among those master devices connected to the bus. 16.5.4 Slave address and address recognition mode specification When the serial bus interface circuit is used with an addressing format to recognize the slave address, clear the ALS (Bit0 in I2CAR) to “0”, and set the SA (Bits7 to 1 in I2CAR) to the slave address. When the serial bus interface circuit is used with a free data format not to recognize the slave address, set the ALS to “1”. With a free data format, the slave address and the direction bit are not recognized, and they are processed as data from immediately after start condition. 16.5.5 Master/slave selection To set a master device, the MST (Bit7 in SBICRB) should be set to “1”. To set a slave device, the MST should be cleared to “0”. When a stop condition on the bus or an arbitration lost is detected, the MST is cleared to “0” by the hardware. 16.5.6 Transmitter/receiver selection To set the device as a transmitter, the TRX (Bit6 in SBICRB) should be set to "1". To set the device as a receiver, the TRX should be cleared to “0”. When data with an addressing format is transferred in the slave mode, the TRX is set to "1" by a hardware if the direction bit (R/W) sent from the master device is “1”, and is cleared to “0” by a hardware if the bit is “0”. In the master mode, after an acknowledge signal is returned from the slave device, the TRX is cleared to “0” by a hardware if a transmitted direction bit is “1”, and is set to "1" by a hardware if it is “0”. When an acknowledge signal is not returned, the current condition is maintained. Page 201 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.5 I2C Bus Control TMP86FS49BUG When a stop condition on the bus or an arbitration lost is detected, the TRX is cleared to “0” by the hardware. " Table 16-2 TRX changing conditions in each mode " shows TRX changing conditions in each mode and TRX value after changing Table 16-2 TRX changing conditions in each mode Mode Direction Bit Conditions TRX after Changing Slave Mode "0" A received slave address is the same value set to I2CAR "0" "1" "1" "0" Master Mode "1" ACK signal is returned "1" "0" When a serial bus interface circuit operates in the free data format, a slave address and a direction bit are not recognized. They are handled as data just after generating a start condition. The TRX is not changed by a hardware. 16.5.7 Start/stop condition generation When the BB (Bit5 in SBISRB) is “0”, a slave address and a direction bit which are set to the SBIDBR are output on a bus after generating a start condition by writing “1” to the MST, TRX, BB and PIN. It is necessary to set ACK to “1” beforehand. SCL pin 1 2 3 4 5 6 7 8 SDA pin A6 A5 A4 A3 A2 A1 A0 R/W Slave address and the direction bit Start condition 9 Acknowledge signal Figure 16-5 Start Condition Generation and Slave Address Generation When the BB is “1”, sequence of generating a stop condition is started by writing “1” to the MST, TRX and PIN, and “0” to the BB. Do not modify the contents of MST, TRX, BB and PIN until a stop condition is generated on a bus. When a stop condition is generated and the SCL line on a bus is pulled-down to low level by another device, a stop condition is generated after releasing the SCL line. SCL pin SDA pin Stop condition Figure 16-6 Stop Condition Generation The bus condition can be indicated by reading the contents of the BB (Bit5 in SBISRB). The BB is set to “1” when a start condition on a bus is detected (Bus Busy State) and is cleared to “0” when a stop condition is detected (Bus Free State). 16.5.8 Interrupt service request and cancel When a serial bus interface circuit is in the master mode and transferring a number of clocks set by the BC and the ACK is complete, a serial bus interface interrupt request (INTSBI) is generated. Page 202 TMP86FS49BUG In the slave mode, the conditions of generating INTSBI interrupt request are follows: • At the end of acknowledge signal when the received slave address matches to the value set by the I2CAR • At the end of acknowledge signal when a “GENERAL CALL” is received • At the end of transferring or receiving after matching of slave address or receiving of “GENERAL CALL” When a serial bus interface interrupt request occurs, the PIN (Bit4 in SBISRB) is cleared to “0”. During the time that the PIN is “0”, the SCL pin is pulled-down to low level. Either writing data to SBIDBR or reading data from the SBIDBR sets the PIN to “1”. The time from the PIN being set to “1” until the SCL pin is released takes tLOW. Although the PIN (Bit4 in SBICRB) can be set to “1” by the softrware, the PIN can not be cleared to “0” by the softrware. Note:When the arbitration lost occurs, if the slave address sent from the other master devices is not match, the INTSBI interrupt request is generated. But the PIN is not cleared. 16.5.9 Setting of I2C bus mode The SBIM (Bit3 and 2 in SBICRB) is used to set I2C bus mode. Set the SBIM to “10” in order to set I2C bus mode. Before setting of I2C bus mode, confirm serial bus interface pins in a high level, and then, write “10” to SBIM. And switch a port mode after confirming that a bus is free. 16.5.10Arbitration lost detection monitor Since more than one master device can exist simultaneously on a bus, a bus arbitration procedure is implemented in order to guarantee the contents of transferred data. Data on the SDA line is used for bus arbitration of the I2C bus. The following shows an example of a bus arbitration procedure when two master devices exist simultaneously on a bus. Master 1 and Master 2 output the same data until point “a”. After that, when Master 1 outputs “1” and Master 2 outputs “0”, since the SDA line of a bus is wired AND, the SDA line is pulled-down to the low level by Master 2. When the SCL line of a bus is pulled-up at point “b”, the slave device reads data on the SDA line, that is data in Master 2. Data transmitted from Master 1 becomes invalid. The state in Master 1 is called “arbitration lost”. A master device which loses arbitration releases the SDA pin and the SCL pin in order not to effect data transmitted from other masters with arbitration. When more than one master sends the same data at the first word, arbitration occurs continuously after the second word. SCL (Bus) SDA pin (Master 1) SDA pin becomes "1" after losing arbitration. SDA pin (Master 2) SDA (Bus) a b Figure 16-7 Arbitration Lost The serial bus interface circuit compares levels of a SDA line of a bus with its SDA pin at the rising edge of the SCL line. If the levels are unmatched, arbitration is lost and the AL (Bit3 in SBISRB) is set to “1”. Page 203 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.5 I2C Bus Control TMP86FS49BUG When the AL is set to “1”, the MST and TRX are cleared to “0” and the mode is switched to a slave receiver mode. Thus, the serial bus interface circuit stops output of clock pulses during data transfer after the AL is set to “1”. The AL is cleared to “0” by writing data to the SBIDBR, reading data from the SBIDBR or writing data to the SBICRB. SCL pin 1 2 3 4 5 6 7 8 9 1 2 3 Master A SDA pin SCL pin D7A D6A D5A D4A D3A D2A D1A D0A 1 2 3 4 5 6 7 8 D7A’ D6A’ D5A’ 9 Stop clock output Master B SDA pin D7B D6B Releasing SDA pin and SCL pin to high level as losing arbitration. AL MST TRX Accessed to SBIDBR or SBICRB INTSBI Figure 16-8 Example of when a Serial Bus Interface Circuit is a Master B 16.5.11Slave address match detection monitor In the slave mode, the AAS (Bit2 in SBISRB) is set to “1” when the received data is “GENERAL CALL” or the received data matches the slave address setting by I2CAR with an address recognition mode (ALS = 0). When a serial bus interface circuit operates in the free data format (ALS = 1), the AAS is set to “1” after receiving the first 1-word of data. The AAS is cleared to “0” by writing data to the SBIDBR or reading data from the SBIDBR. 16.5.12GENERAL CALL detection monitor The AD0 (Bit1 in SBISRB) is set to “1” when all 8-bit received data is “0” immediately after a start condition in a slave mode. The AD0 is cleared to “0” when a start or stop condition is detected on a bus. 16.5.13Last received bit monitor The SDA line value stored at the rising edge of the SCL line is set to the LRB (Bit0 in SBISRB). In the acknowledge mode, immediately after an INTSBI interrupt request is generated, an acknowledge signal is read by reading the contents of the LRB. Page 204 TMP86FS49BUG 16.6 Data Transfer of I2C Bus 16.6.1 Device initialization For initialization of device, set the ACK in SBICRA to “1” and the BC to “000”. Specify the data length to 8 bits to count clocks for an acknowledge signal. Set a transfer frequency to the SCK in SBICRA. Next, set the slave address to the SA in I2CAR and clear the ALS to “0” to set an addressing format. After confirming that the serial bus interface pin is high level, for specifying the default setting to a slave receiver mode, clear “0” to the MST, TRX and BB in SBICRB, set “1” to the PIN, “10” to the SBIM, and “00” to bits SWRST1 and SWRST0. Note:The initialization of a serial bus interface circuit must be complete within the time from all devices which are connected to a bus have initialized to and device does not generate a start condition. If not, the data can not be received correctly because the other device starts transferring before an end of the initialization of a serial bus interface circuit. 16.6.2 Start condition and slave address generation Confirm a bus free status (BB = 0). Set the ACK to “1” and specify a slave address and a direction bit to be transmitted to the SBIDBR. By writing “1” to the MST, TRX, BB and PIN, the start condition is generated on a bus and then, the slave address and the direction bit which are set to the SBIDBR are output. The time from generating the START condition until the falling SCL pin takes tLOW. An INTSBI interrupt request occurs at the 9th falling edge of a SCL clock cycle, and the PIN is cleared to “0”. The SCL pin is pulled-down to the low level while the PIN is “0”. When an interrupt request occurs, the TRX changes by the hardware according to the direction bit only when an acknowledge signal is returned from the slave device. Note 1: Do not write a slave address to be output to the SBIDBR while data is transferred. If data is written to the SBIDBR, data to been outputting may be destroyed. Note 2: The bus free must be confirmed by software within 98.0 µs (The shortest transmitting time according to the I2C bus standard) after setting of the slave address to be output. Only when the bus free is confirmed, set "1" to the MST, TRX, BB, and PIN to generate the start conditions. If the writing of slave address and setting of MST, TRX, BB and PIN doesn't finish within 98.0 µs, the other masters may start the transferring and the slave address data written in SBIDBR may be broken. SCL pin 1 2 3 4 5 6 7 8 SDA pin A6 A5 A4 A3 A2 A1 A0 R/W Start condition 9 Slave address + Direction bit Acknowledge signal from a slave device PIN INTSBI interrupt request Figure 16-9 Start Condition Generation and Slave Address Transfer 16.6.3 1-word data transfer Check the MST by the INTSBI interrupt process after an 1-word data transfer is completed, and determine whether the mode is a master or slave. Page 205 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.6 Data Transfer of I2C Bus TMP86FS49BUG 16.6.3.1 When the MST is “1” (Master mode) Check the TRX and determine whether the mode is a transmitter or receiver. (1) When the TRX is “1” (Transmitter mode) Test the LRB. When the LRB is “1”, a receiver does not request data. Implement the process to generate a stop condition (Described later) and terminate data transfer. When the LRB is “0”, the receiver requests next data. When the next transmitted data is other than 8 bits, set the BC, set the ACK to “1”, and write the transmitted data to the SBIDBR. After writing the data, the PIN becomes “1”, a serial clock pulse is generated for transferring a next 1 word of data from the SCL pin, and then the 1 word of data is transmitted. After the data is transmitted, and an INTSBI interrupt request occurs. The PIN become “0” and the SCL pin is set to low level. If the data to be transferred is more than one word in length, repeat the procedure from the LRB test above. SCL pin 1 2 3 4 5 6 7 8 D7 D6 D5 D4 D3 D2 D1 D0 9 Write to SBIDBR SDA pin Acknowledge signal from a receiver PIN INTSBI interrupt request Figure 16-10 Example of when BC = “000”, ACK = “1” (2) When the TRX is “0” (Receiver mode) When the next transmitted data is other than of 8 bits, set the BC again. Set the ACK to “1” and read the received data from the SBIDBR (Reading data is undefined immediately after a slave address is sent). After the data is read, the PIN becomes “1”. A serial bus interface circuit outputs a serial clock pulse to the SCL pin to transfer next 1-word of data and sets the SDA pin to “0” at the acknowledge signal timing. An INTSBI interrupt request occurs and the PIN becomes “0”. Then a serial bus interface circuit outputs a clock pulse for 1-word of data transfer and the acknowledge signal each time that received data is read from the SBIDBR. Read SBIDBR SCL pin 1 2 3 4 5 6 7 8 SDA pin D7 D6 D5 D4 D3 D2 D1 D0 9 New D7 Acknowledge signal to a transmitter PIN INTSBI interrupt request Figure 16-11 Example of when BC = “000”, ACK = “1” Page 206 TMP86FS49BUG To make the transmitter terminate transmit, clear the ACK to “0” before reading data which is 1word before the last data to be received. A serial bus interface circuit does not generate a clock pulse for the acknowledge signal by clearing ACK. In the interrupt routine of end of transmission, when the BC is set to “001” and read the data, PIN is set to “1” and generates a clock pulse for a 1-bit data transfer. In this case, since the master device is a receiver, the SDA line on a bus keeps the high-level. The transmitter receives the high-level signal as an ACK signal. The receiver indicates to the transmitter that data transfer is complete. After 1-bit data is received and an interrupt request has occurred, generate the stop condition to terminate data transfer. SCL pin 1 2 3 4 5 6 7 8 SDA pin D7 D6 D5 D4 D3 D2 D1 D0 1 Acknowledge signal sent to a transmitter PIN INTSBI interrupt request Clear ACK to "0" before reading SBIDBR Set BC to "001" before reading SBIDBR Figure 16-12 Termination of Data Transfer in Master Receiver Mode 16.6.3.2 When the MST is “0” (Slave mode) In the slave mode, a serial bus interface circuit operates either in normal slave mode or in slave mode after losing arbitration. In the slave mode, the conditions of generating INTSBI interrupt request are follows: • At the end of acknowledge signal when the received slave address matches to the value set by the I2CAR • At the end of acknowledge signal when a “GENERAL CALL” is received • At the end of transferring or receiving after matching of slave address or receiving of “GENERAL CALL” A serial bus interface circuit changes to a slave mode if arbitration is lost in the master mode. And an INTSBI interrupt request occurs when word data transfer terminates after losing arbitration. The behavior of INTSBI interrupt request and PIN after losing arbitration are shown in Table 16-3. Table 16-3 The Behavior of INTSBI interrupt request and PIN after Losing Arbitration When the Arbitration Lost Occurs during Transmission of Slave Address as a Master INTSBI interrupt request PIN When the Arbitration Lost Occurs during Transmission of Data as a Master Transmit Mode INTSBI interrupt request is generated at the termination of word data. When the slave address matches the value set by I2CAR, the PIN is cleared to "0" by generating of INTSBI interrupt request. When the slave address doesn't match the value set by I2CAR, the PIN keeps "1". PIN keeps "1" (PIN is not cleared to "0"). When an INTSBI interrupt request occurs, the PIN (bit 4 in the SBICRB) is reset, and the SCL pin is set to low level. Either reading or writing from or to the SBIDBR or setting the PIN to “1” releases the SCL pin after taking tLOW. Page 207 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.6 Data Transfer of I2C Bus TMP86FS49BUG Check the AL (Bit3 in the SBISRB), the TRX (Bit6 in the SBISRB), the AAS (Bit2 in the SBISRB), and the AD0 (Bit1 in the SBISRB) and implements processes according to conditions listed in " Table 164 Operation in the Slave Mode ". Table 16-4 Operation in the Slave Mode TRX AL 1 AAS 1 1 AD0 Conditions 0 A serial bus interface circuit loses arbitration when transmitting a slave address. And receives a slave address of which the value of the direction bit sent from another master is "1". 0 1 Process Set the number of bits in 1 word to the BC and write transmitted data to the SBIDBR. In the slave receiver mode, a serial bus interface circuit receives a slave address of which the value of the direction bit sent from the master is "1". 0 In the slave transmitter mode, 1-word data is transmitted. Test the LRB. If the LRB is set to "1", set the PIN to "1" since the receiver does not request next data. Then, clear the TRX to "0" to release the bus. If the LRB is set to "0", set the number of bits in 1 word to the BC and write transmitted data to the SBIDBR since the receiver requests next data. 1/0 A serial bus interface circuit loses arbitration when transmitting a slave address. And receives a slave address of which the value of the direction bit sent from another master is "0" or receives a "GENERAL CALL". Read the SBIDBR for setting the PIN to "1" (Reading dummy data) or write "1" to the PIN. 0 A serial bus interface circuit loses arbitration when transmitting a slave address or data. And terminates transferring word data. A serial bus interface circuit is changed to slave mode. To clear AL to "0", read the SBIDBR or write the data to SBIDBR. 1 1/0 In the slave receiver mode, a serial bus interface circuit receives a slave address of which the value of the direction bit sent from the master is "0" or receives "GENERAL CALL". Read the SBIDBR for setting the PIN to "1" (Reading dummy data) or write "1" to the PIN. 0 1/0 In the slave receiver mode, a serial bus interface circuit terminates receiving of 1word data. Set the number of bits in 1-word to the BC and read received data from the SBIDBR. 0 0 1 1 0 0 0 Note: In the slave mode, if the slave address set in I2CAR is "00H", a START Byte "01H" in I2C bus standard is recived, the device detects slave address match and the TRX is set to "1". 16.6.4 Stop condition generation When the BB is “1”, a sequence of generating a stop condition is started by setting “1” to the MST, TRX and PIN, and clear “0” to the BB. Do not modify the contents of the MST, TRX, BB, PIN until a stop condition is generated on a bus. When a SCL line on a bus is pulled-down by other devices, a serial bus interface circuit generates a stop condition after they release a SCL line. The time from the releasing SCL line until the generating the STOP condition takes tLOW. Page 208 TMP86FS49BUG "1" "1" "0" "1" MST TRX BB PIN Stop condition SCL pin SDA pin PIN BB (Read) Figure 16-13 Stop Condition Generation 16.6.5 Restart Restart is used to change the direction of data transfer between a master device and a slave device during transferring data. The following explains how to restart a serial bus interface circuit. Clear “0” to the MST, TRX and BB and set “1” to the PIN. The SDA pin retains the high-level and the SCL pin is released. Since a stop condition is not generated on a bus, a bus is assumed to be in a busy state from other devices. Test the BB until it becomes “0” to check that the SCL pin of a serial bus interface circuit is released. Test the LRB until it becomes “1” to check that the SCL line on a bus is not pulled-down to the low level by other devices. After confirming that a bus stays in a free state, generate a start condition with procedure " 16.6.2 Start condition and slave address generation ". In order to meet setup time when restarting, take at least 4.7 µs of waiting time by software from the time of restarting to confirm that a bus is free until the time to generate a start condition. Note:When the master is in the receiver mode, it is necessary to stop the data transmission from the slave devcie before the STOP condtion is generated. To stop the transmission, the master device make the slave device receiving a negative acknowledge. Therefore, the LRB is "1" before generating the Restart and it can not be confirmed that SCL line is not pulled-down by other devices. Please confirm the SCL line state by reading the port. "0" "0" "0" "1" "1" "1" "1" "1" MST TRX BB PIN MST TRX BB PIN 4.7µs (Min) SCL (Bus) SCL pin SDA pin LRB BB PIN Figure 16-14 Timing Diagram when Restarting Page 209 Start condition 16. Serial Bus Interface(I2C Bus) Ver.-D (SBI) 16.6 Data Transfer of I2C Bus TMP86FS49BUG Page 210 TMP86FS49BUG 17. 10-bit AD Converter (ADC) The TMP86FS49BUG have a 10-bit successive approximation type AD converter. 17.1 Configuration The circuit configuration of the 10-bit AD converter is shown in Figure 17-1. It consists of control register ADCCR1 and ADCCR2, converted value register ADCDR1 and ADCDR2, a DA converter, a sample-hold circuit, a comparator, and a successive comparison circuit. DA converter VAREF VSS R/2 R R/2 AVDD Analog input multiplexer AIN0 A Sample hold circuit Reference voltage Y  10 Analog comparator n S EN Successive approximate circuit Shift clock AINDS ADRS SAIN INTADC Control circuit 4 ADCCR1 2 AMD IREFON AIN15 3 ACK ADCCR2 AD converter control register 1, 2 8 ADCDR1 2 EOCF ADBF ADCDR2 AD conversion result register 1, 2 Note: Before using AD converter, set appropriate value to I/O port register conbining a analog input port. For details, see the section on "I/O ports". Figure 17-1 10-bit AD Converter Page 211 17. 10-bit AD Converter (ADC) 17.2 Register configuration TMP86FS49BUG 17.2 Register configuration The AD converter consists of the following four registers: 1. AD converter control register 1 (ADCCR1) This register selects the analog channels and operation mode (Software start or repeat) in which to perform AD conversion and controls the AD converter as it starts operating. 2. AD converter control register 2 (ADCCR2) This register selects the AD conversion time and controls the connection of the DA converter (Ladder resistor network). 3. AD converted value register 1 (ADCDR1) This register used to store the digital value fter being converted by the AD converter. 4. AD converted value register 2 (ADCDR2) This register monitors the operating status of the AD converter. AD Converter Control Register 1 ADCCR1 (001CH) 7 ADRS 6 5 AMD 4 3 2 AINDS 1 SAIN AD conversion start 0: 1: AD conversion start AMD AD operating mode 00: 01: 10: 11: AD operation disable Software start mode Reserved Repeat mode AINDS Analog input control 0: 1: Analog input enable Analog input disable Analog input channel select 0000: 0001: 0010: 0011: 0100: 0101: 0110: 0111: 1000: 1001: 1010: 1011: 1100: 1101: 1110: 1111: AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 AIN8 AIN9 AIN10 AIN11 AIN12 AIN13 AIN14 AIN15 ADRS SAIN 0 (Initial value: 0001 0000) R/W Note 1: Select analog input channel during AD converter stops (ADCDR2 = "0"). Note 2: When the analog input channel is all use disabling, the ADCCR1 should be set to "1". Note 3: During conversion, Do not perform port output instruction to maintain a precision for all of the pins because analog input port use as general input port. And for port near to analog input, Do not input intense signaling of change. Note 4: The ADCCR1 is automatically cleared to "0" after starting conversion. Note 5: Do not set ADCCR1 newly again during AD conversion. Before setting ADCCR1 newly again, check ADCDR2 to see that the conversion is completed or wait until the interrupt signal (INTADC) is generated (e.g., interrupt handling routine). Note 6: After STOP or SLOW/SLEEP mode are started, AD converter control register1 (ADCCR1) is all initialized and no data can be written in this register. Therfore, to use AD converter again, set the ADCCR1 newly after returning to NORMAL1 or NORMAL2 mode. Page 212 TMP86FS49BUG AD Converter Control Register 2 7 ADCCR2 (001DH) 6 IREFON ACK 5 4 3 IREFON "1" 2 1 ACK 0 "0" (Initial value: **0* 000*) DA converter (Ladder resistor) connection control 0: 1: Connected only during AD conversion Always connected AD conversion time select (Refer to the following table about the conversion time) 000: 001: 010: 011: 100: 101: 110: 111: 39/fc Reserved 78/fc 156/fc 312/fc 624/fc 1248/fc Reserved R/W Note 1: Always set bit0 in ADCCR2 to "0" and set bit4 in ADCCR2 to "1". Note 2: When a read instruction for ADCCR2, bit6 to 7 in ADCCR2 read in as undefined data. Note 3: After STOP or SLOW/SLEEP mode are started, AD converter control register2 (ADCCR2) is all initialized and no data can be written in this register. Therfore, to use AD converter again, set the ADCCR2 newly after returning to NORMAL1 or NORMAL2 mode. Table 17-1 ACK setting and Conversion time Condition ACK 000 Conversion time 16 MHz 8 MHz 4 MHz 2 MHz 10 MHz 5 MHz 2.5 MHz 39/fc - - - 19.5 µs - - 15.6 µs 001 Reserved 010 78/fc - - 19.5 µs 39.0 µs - 15.6 µs 31.2 µs 011 156/fc - 19.5 µs 39.0 µs 78.0 µs 15.6 µs 31.2 µs 62.4 µs 100 312/fc 19.5 µs 39.0 µs 78.0 µs 156.0 µs 31.2 µs 62.4 µs 124.8 µs 101 624/fc 39.0 µs 78.0 µs 156.0 µs - 62.4 µs 124.8 µs - 110 1248/fc 78.0 µs 156.0 µs - - 124.8 µs - - 111 Reserved Note 1: Setting for "−" in the above table are inhibited. fc: High Frequency oscillation clock [Hz] Note 2: Set conversion time setting should be kept more than the following time by Analog reference voltage (VAREF) . - VAREF = 4.5 to 5.5 V 15.6 µs and more - VAREF = 2.7 to 5.5 V 31.2 µs and more AD Converted value Register 1 ADCDR1 (001FH) 7 6 5 4 3 2 1 0 AD09 AD08 AD07 AD06 AD05 AD04 AD03 AD02 3 2 1 0 (Initial value: 0000 0000) AD Converted value Register 2 ADCDR2 (001EH) 7 6 5 4 AD01 AD00 EOCF ADBF (Initial value: 0000 ****) Page 213 17. 10-bit AD Converter (ADC) 17.2 Register configuration TMP86FS49BUG EOCF ADBF AD conversion end flag 0: 1: Before or during conversion Conversion completed AD conversion BUSY flag 0: 1: During stop of AD conversion During AD conversion Read only Note 1: The ADCDR2 is cleared to "0" when reading the ADCDR1. Therfore, the AD conversion result should be read to ADCDR2 more first than ADCDR1. Note 2: The ADCDR2 is set to "1" when AD conversion starts, and cleared to "0" when AD conversion finished. It also is cleared upon entering STOP mode or SLOW mode . Note 3: If a read instruction is executed for ADCDR2, read data of bit3 to bit0 are unstable. Page 214 TMP86FS49BUG 17.3 Function 17.3.1 Software Start Mode After setting ADCCR1 to “01” (software start mode), set ADCCR1 to “1”. AD conversion of the voltage at the analog input pin specified by ADCCR1 is thereby started. After completion of the AD conversion, the conversion result is stored in AD converted value registers (ADCDR1, ADCDR2) and at the same time ADCDR2 is set to 1, the AD conversion finished interrupt (INTADC) is generated. ADRS is automatically cleared after AD conversion has started. Do not set ADCCR1 newly again (Restart) during AD conversion. Before setting ADRS newly again, check ADCDR2 to see that the conversion is completed or wait until the interrupt signal (INTADC) is generated (e.g., interrupt handling routine). AD conversion start AD conversion start ADCCR1 ADCDR2 ADCDR1 status Indeterminate 1st conversion result 2nd conversion result EOCF cleared by reading conversion result ADCDR2 INTADC interrupt request ADCDR1 ADCDR2 Conversion result read Conversion result read Conversion result read Conversion result read Figure 17-2 Software Start Mode 17.3.2 Repeat Mode AD conversion of the voltage at the analog input pin specified by ADCCR1 is performed repeatedly. In this mode, AD conversion is started by setting ADCCR1 to “1” after setting ADCCR1 to “11” (Repeat mode). After completion of the AD conversion, the conversion result is stored in AD converted value registers (ADCDR1, ADCDR2) and at the same time ADCDR2 is set to 1, the AD conversion finished interrupt (INTADC) is generated. In repeat mode, each time one AD conversion is completed, the next AD conversion is started. To stop AD conversion, set ADCCR1 to “00” (Disable mode) by writing 0s. The AD convert operation is stopped immediately. The converted value at this time is not stored in the AD converted value register. Page 215 17. 10-bit AD Converter (ADC) 17.3 Function TMP86FS49BUG ADCCR1 “11” “00” AD conversion start ADCCR1 1st conversion result Conversion operation Indeterminate ADCDR1,ADCDR2 2nd conversion result 3rd conversion result 1st conversion result 2nd conversion result AD convert operation suspended. Conversion result is not stored. 3rd conversion result ADCDR2 EOCF cleared by reading conversion result INTADC interrupt request ADCDR1 Conversion result read ADCDR2 Conversion result read Conversion result read Conversion result read Conversion result read Conversion result read Figure 17-3 Repeat Mode 17.3.3 Register Setting 1. Set up the AD converter control register 1 (ADCCR1) as follows: • Choose the channel to AD convert using AD input channel select (SAIN). • Specify analog input enable for analog input control (AINDS). • Specify AMD for the AD converter control operation mode (software or repeat mode). 2. Set up the AD converter control register 2 (ADCCR2) as follows: • Set the AD conversion time using AD conversion time (ACK). For details on how to set the conversion time, refer to Figure 17-1 and AD converter control register 2. • Choose IREFON for DA converter control. 3. After setting up (1) and (2) above, set AD conversion start (ADRS) of AD converter control register 1 (ADCCR1) to “1”. If software start mode has been selected, AD conversion starts immediately. 4. After an elapse of the specified AD conversion time, the AD converted value is stored in AD converted value register 1 (ADCDR1) and the AD conversion finished flag (EOCF) of AD converted value register 2 (ADCDR2) is set to “1”, upon which time AD conversion interrupt INTADC is generated. 5. EOCF is cleared to “0” by a read of the conversion result. However, if reconverted before a register read, although EOCF is cleared the previous conversion result is retained until the next conversion is completed. Page 216 TMP86FS49BUG Example :After selecting the conversion time 19.5 µs at 16 MHz and the analog input channel AIN3 pin, perform AD conversion once. After checking EOCF, read the converted value, store the lower 2 bits in address 0009EH nd store the upper 8 bits in address 0009FH in RAM. The operation mode is software start mode. SLOOP : : (port setting) : ;Set port register approrriately before setting AD converter registers. : : (Refer to section I/O port in details) LD (ADCCR1) , 00100011B ; Select AIN3 LD (ADCCR2) , 11011000B ;Select conversion time(312/fc) and operation mode SET (ADCCR1) . 7 ; ADRS = 1(AD conversion start) TEST (ADCDR2) . 5 ; EOCF= 1 ? JRS T, SLOOP LD A , (ADCDR2) LD (9EH) , A LD A , (ADCDR1) LD (9FH), A ; Read result data ; Read result data 17.4 STOP/SLOW Modes during AD Conversion When standby mode (STOP or SLOW mode) is entered forcibly during AD conversion, the AD convert operation is suspended and the AD converter is initialized (ADCCR1 and ADCCR2 are initialized to initial value). Also, the conversion result is indeterminate. (Conversion results up to the previous operation are cleared, so be sure to read the conversion results before entering standby mode (STOP or SLOW mode).) When restored from standby mode (STOP or SLOW mode), AD conversion is not automatically restarted, so it is necessary to restart AD conversion. Note that since the analog reference voltage is automatically disconnected, there is no possibility of current flowing into the analog reference voltage. Page 217 17. 10-bit AD Converter (ADC) 17.5 Analog Input Voltage and AD Conversion Result TMP86FS49BUG 17.5 Analog Input Voltage and AD Conversion Result The analog input voltage is corresponded to the 10-bit digital value converted by the AD as shown in Figure 17-4. 3FFH 3FEH 3FDH AD conversion result 03H 02H 01H VAREF 0 1 2 3 1021 1022 1023 1024 Analog input voltage VSS 1024 Figure 17-4 Analog Input Voltage and AD Conversion Result (Typ.) Page 218 TMP86FS49BUG 17.6 Precautions about AD Converter 17.6.1 Restrictions for AD Conversion interrupt (INTADC) usage When an AD interrupt is used, it may not be processed depending on program composition. For example, if an INTADC interrupt request is generated while an interrupt with priority lower than the interrupt latch IL15 (INTADC) is being accepted, the INTADC interrupt latch may be cleared without the INTADC interrupt being processed. The completion of AD conversion can be detected by the following methods: (1) Method not using the AD conversion end interrupt Whether or not AD conversion is completed can be detected by monitoring the AD conversion end flag (EOCF) by software. This can be done by polling EOCF or monitoring EOCF at regular intervals after start of AD conversion. (2) Method for detecting AD conversion end while a lower-priority interrupt is being processed While an interrupt with priority lower than INTADC is being processed, check the AD conversion end flag (EOCF) and interrupt latch IL15. If IL15 = 0 and EOCF = 1, call the AD conversion end interrupt processing routine with consideration given to PUSH/POP operations. At this time, if an interrupt request with priority higher than INTADC has been set, the AD conversion end interrupt processing routine will be executed first against the specified priority. If necessary, we recommend that the AD conversion end interrupt processing routine be called after checking whether or not an interrupt request with priority higher than INTADC has been set. 17.6.2 Analog input pin voltage range Make sure the analog input pins (AIN0 to AIN15) are used at voltages within VAREF to VSS. If any voltage outside this range is applied to one of the analog input pins, the converted value on that pin becomes uncertain. The other analog input pins also are affected by that. 17.6.3 Analog input shared pins The analog input pins (AIN0 to AIN15) are shared with input/output ports. When using any of the analog inputs to execute AD conversion, do not execute input/output instructions for all other ports. This is necessary to prevent the accuracy of AD conversion from degrading. Not only these analog input shared pins, some other pins may also be affected by noise arising from input/output to and from adjacent pins. 17.6.4 Noise Countermeasure The internal equivalent circuit of the analog input pins is shown in Figure 17-5. The higher the output impedance of the analog input source, more easily they are susceptible to noise. Therefore, make sure the output impedance of the signal source in your design is 5 kΩ or less. Toshiba also recommends attaching a capacitor external to the chip. Internal resistance AINi Permissible signal source impedance 5 kΩ (typ) Analog comparator Internal capacitance C = 12 pF (typ.) 5 kΩ (max) DA converter Note) i = 15 to 0 Figure 17-5 Analog Input Equivalent Circuit and Example of Input Pin Processing Page 219 17. 10-bit AD Converter (ADC) 17.6 Precautions about AD Converter TMP86FS49BUG Page 220 TMP86FS49BUG 18. Key-on Wakeup (KWU) In the TMP86FS49BUG, the STOP mode is released by not only P20(INT5/STOP) pin but also four (STOP0 to STOP3) pins. When the STOP mode is released by STOP0 to STOP3 pins, the STOP pin needs to be used. In details, refer to the following section " 18.2 Control ". 18.1 Configuration INT5 STOP STOP mode release signal (1: Release) STOP0 STOP1 STOP2 STOPCR (0F9FH) STOP3 STOP2 STOP1 STOP0 STOP3 Figure 18-1 Key-on Wakeup Circuit 18.2 Control STOP0 to STOP3 pins can controlled by Key-on Wakeup Control Register (STOPCR). It can be configured as enable/disable in 1-bit unit. When those pins are used for STOP mode release, configure corresponding I/O pins to input mode by I/O port register beforehand. Key-on Wakeup Control Register STOPCR 7 6 5 4 (0F9FH) STOP3 STOP2 STOP1 STOP0 3 2 1 0 (Initial value: 0000 ****) STOP3 STOP mode released by STOP3 0:Disable 1:Enable Write only STOP2 STOP mode released by STOP2 0:Disable 1:Enable Write only STOP1 STOP mode released by STOP1 0:Disable 1:Enable Write only STOP0 STOP mode released by STOP0 0:Disable 1:Enable Write only 18.3 Function Stop mode can be entered by setting up the System Control Register (SYSCR1), and can be exited by detecting the "L" level on STOP0 to STOP3 pins, which are enabled by STOPCR, for releasing STOP mode (Note1). Page 221 18. Key-on Wakeup (KWU) 18.3 Function TMP86FS49BUG Also, each level of the STOP0 to STOP3 pins can be confirmed by reading corresponding I/O port data register, check all STOP0 to STOP3 pins "H" that is enabled by STOPCR before the STOP mode is started (Note2,3). Note 1: When the STOP mode released by the edge release mode (SYSCR1 = “0”), inhibit input from STOP0 to STOP3 pins by Key-on Wakeup Control Register (STOPCR) or must be set "H" level into STOP0 to STOP3 pins that are available input during STOP mode. Note 2: When the STOP pin input is high or STOP0 to STOP3 pins input which is enabled by STOPCR is low, executing an instruction which starts STOP mode will not place in STOP mode but instead will immediately start the release sequence (Warm up). Note 3: The input circuit of Key-on Wakeup input and Port input is separated, so each input voltage threshold value is different. Therefore, a value comes from port input before STOP mode start may be different from a value which is detected by Key-on Wakeup input (Figure 18-2). Note 4: STOP pin doesn’t have the control register such as STOPCR, so when STOP mode is released by STOP0 to STOP3 pins, STOP pin also should be used as STOP mode release function. Note 5: In STOP mode, Key-on Wakeup pin which is enabled as input mode (for releasing STOP mode) by Key-on Wakeup Control Register (STOPCR) may generate the penetration current, so the said pin must be disabled AD conversion input (analog voltage input). Note 6: When the STOP mode is released by STOP0 to STOP3 pins, the level of STOP pin should hold "L" level (Figure 18-3). External pin Port input Key-on wakeup input Figure 18-2 Key-on Wakeup Input and Port Input b) In case of STOP0 to STOP3 a) STOP STOP pin STOP pin "L" STOP mode Release STOP mode STOP0 pin STOP mode Release STOP mode Figure 18-3 Priority of STOP pin and STOP0 to STOP3 pins Table 18-1 Release level (edge) of STOP mode Release level (edge) Pin name SYSCR1="1" (Note2) SYSCR1="0" STOP "H" level Rising edge STOP0 "L" level Don’t use (Note1) STOP1 "L" level Don’t use (Note1) STOP2 "L" level Don’t use (Note1) STOP3 "L" level Don’t use (Note1) Page 222 TMP86FS49BUG 19. Flash Memory TMP86FS49BUG has 61440byte flash memory (address: 1000H to FFFFH). The write and erase operations to the flash memory are controlled in the following three types of mode. - MCU mode The flash memory is accessed by the CPU control in the MCU mode. This mode is used for software bug correction and firmware change after shipment of the device since the write operation to the flash memory is available by retaining the application behavior. - Serial PROM mode The flash memory is accessed by the CPU control in the serial PROM mode. Use of the serial interface (UART) enables the flash memory to be controlled by the small number of pins. TMP86FS49BUG in the serial PROM mode supports on-board programming which enables users to program flash memory after the microcontroller is mounted on a user board. - Parallel PROM mode The parallel PROM mode allows the flash memory to be accessed as a stand-alone flash memory by the program writer provided by the third party. High-speed access to the flash memory is available by controlling address and data signals directly. For the support of the program writer, please ask Toshiba sales representative. In the MCU and serial PROM modes, the flash memory control register (FLSCR) is used for flash memory control. This chapter describes how to access the flash memory using the flash memory control register (FLSCR) in the MCU and serial PROM modes. Note 1: The 'Read Protect' described by data sheet of old edition was changed into 'Security Program'. Page 223 19. Flash Memory 19.1 Flash Memory Control TMP86FS49BUG 19.1 Flash Memory Control The flash memory is controlled via the flash memory control register (FLSCR) . Flash Memory Control Register FLSCR 7 6 (0FFFH) 5 4 FLSMD FLSMD BANKSEL 3 2 1 0 BANKSEL (Initial value : 1100 1***) Flash memory command sequence execution control 1100: Disable command sequence execution 0011: Enable command sequence execution Others: Reserved R/W Flash memory bank select control (Serial PROM mode only) 0: Select BANK0 1: Select BANK1 R/W Note 1: The command sequence of the flash memory can be executed only when FLSMD="0011B". In other cases, any attempts to execute the command sequence are ineffective. Note 2: FLSMD must be set to either "1100B" or "0011B". Note 3: BANKSEL is effective only in the serial PROM mode. In the MCU mode, the flash memory is always accessed with actual addresses (1000-FFFFH) regardless of BANKSEL. Note 4: Bits 2 through 0 in FLSCR are always read as don’t care. 19.1.1 Flash Memory Command Sequence Execution Control (FLSCR) The flash memory can be protected from inadvertent write due to program error or microcontroller misoperation. This write protection feature is realized by disabling flash memory command sequence execution via the flash memory control register (write protect). To enable command sequence execution, set FLSCR to “0011B”. To disable command sequence execution, set FLSCR to “1100B”. After reset, FLSCR is initialized to “1100B” to disable command sequence execution. Normally, FLSCR should be set to “1100B” except when the flash memory needs to be written or erased. 19.1.2 Flash Memory Bank Select Control (FLSCR) In the serial PROM mode, a 2-kbyte BOOTROM is mapped to addresses 7800H-7FFFH and the flash memory is mapped to 2 banks at 8000H-FFFFH. Flash memory addresses 1000H-7FFFH are mapped to 9000HFFFFH as BANK0, and flash memory addresses 8000H-FFFFH are mapped to 8000H-FFFFH as BANK1. FLSCR is used to switch between these banks. For example, to access the flash memory address 7000H, set FLSCR to “0” and then access F000H. To access the flash memory address 9000H, set FLSCR to “1" and then access 9000H. In the MCU mode, the flash memory is accessed with actual addresses at 1000H-FFFFH. In this case, FLSCR is ineffective (i.e., its value has no effect on other operations). Table 19-1 Flash Memory Access Operating Mode FLSCR MCU mode Don’t care 0 (BANK0) Access Area Specified Address 1000H-FFFFH 1000H-7FFFH 9000H-FFFFH Serial PROM mode 1 (BANK1) 8000H-FFFFH Page 224 TMP86FS49BUG 19.2 Command Sequence The command sequence in the MCU and the serial PROM modes consists of six commands (JEDEC compatible), as shown in Table 19-2. Addresses specified in the command sequence are recognized with the lower 12 bits (excluding BA, SA, and FF7FH used for security program). The upper 4 bits are used to specify the flash memory area, as shown in Table 19-3. Table 19-2 Command Sequence Command Sequence 1st Bus Write Cycle 2nd Bus Write Cycle 3rd Bus Write Cycle 4th Bus Write Cycle 5th Bus Write Cycle 6th Bus Write Cycle Address Data Address Data Address Data Address Data Address Data Address Data 1 Byte program 555H AAH AAAH 55H 555H A0H BA (Note 1) Data (Note 1) - - - - 2 Sector Erase (4-kbyte Erase) 555H AAH AAAH 55H 555H 80H 555H AAH AAAH 55H SA (Note 2) 30H 3 Chip Erase (All Erase) 555H AAH AAAH 55H 555H 80H 555H AAH AAAH 55H 555H 10H 4 Product ID Entry 555H AAH AAAH 55H 555H 90H - - - - - - Product ID Exit XXH F0H - - - - - - - - - - Product ID Exit 555H AAH AAAH 55H 555H F0H - - - - - - Security Program 555H AAH AAAH 55H 555H A5H FF7FH 00H - - - - 5 6 Note 1: Set the address and data to be written. Note 2: The area to be erased is specified with the upper 4 bits of the address. Table 19-3 Address Specification in the Command Sequence Operating Mode FLSCR Specified Address MCU mode Don’t care 1***H-F***H 0 (BANK0) 9***H-F***H 1 (BANK1) 8***H-F***H Serial PROM mode 19.2.1 Byte Program This command writes the flash memory for each byte unit. The addresses and data to be written are specified in the 4th bus write cycle. Each byte can be programmed in a maximum of 40 µs. The next command sequence cannot be executed until the write operation is completed. To check the completion of the write operation, perform read operations repeatedly until the same data is read twice from the same address in the flash memory. During the write operation, any consecutive attempts to read from the same address is reversed bit 6 of the data (toggling between 0 and 1). Note:To rewrite data to Flash memory addresses at which data (including FFH) is already written, make sure to erase the existing data by "sector erase" or "chip erase" before rewriting data. 19.2.2 Sector Erase (4-kbyte Erase) This command erases the flash memory in units of 4 kbytes. The flash memory area to be erased is specified by the upper 4 bits of the 6th bus write cycle address. For example, in the MCU mode, to erase 4 kbytes from 7000H to 7FFFH, specify one of the addresses in 7000H-7FFFH as the 6th bus write cycle. In the serial PROM mode, to erase 4 kbytes from 7000H to 7FFFH, set FLSCR to "0" and then specify one of the addresses in F000H-FFFFH as the 6th bus write cycle. The sector erase command is effective only in the MCU and serial PROM modes, and it cannot be used in the parallel PROM mode. Page 225 19. Flash Memory 19.2 Command Sequence TMP86FS49BUG A maximum of 30 ms is required to erase 4 kbytes. The next command sequence cannot be executed until the erase operation is completed. To check the completion of the erase operation, perform read operations repeatedly for data polling until the same data is read twice from the same address in the flash memory. During the erase operation, any consecutive attempts to read from the same address is reversed bit 6 of the data (toggling between 0 and 1). 19.2.3 Chip Erase (All Erase) This command erases the entire flash memory in approximately 30 ms. The next command sequence cannot be executed until the erase operation is completed. To check the completion of the erase operation, perform read operations repeatedly for data polling until the same data is read twice from the same address in the flash memory. During the erase operation, any consecutive attempts to read from the same address is reversed bit 6 of the data (toggling between 0 and 1). After the chip is erased, all bytes contain FFH. 19.2.4 Product ID Entry This command activates the Product ID mode. In the Product ID mode, the vendor ID, the flash ID, and the security program status can be read from the flash memory. Table 19-4 Values To Be Read in the Product ID Mode Address Meaning F000H Vendor ID 98H F001H Flash macro ID 41H F002H FF7FH Read Value Flash size 0EH: 60 kbytes 0BH: 48 kbytes 07H: 32 kbytes 05H: 24 kbytes 03H: 16 kbytes 01H: 8 kbytes 00H: 4 kbytes FFH: Security program disabled Security program status Other than FFH: Security program enabled Note: The value at address F002H (flash size) depends on the size of flash memory incorporated in each product. For example, if the product has 60-kbyte flash memory, "0EH" is read from address F002H. 19.2.5 Product ID Exit This command is used to exit the Product ID mode. 19.2.6 Security Program This command enables the read protection or write protection setting in the flash memory. When the security program is enabled, the flash memory cannot be read in the parallel PROM mode. In the serial PROM mode, the flash write and RAM loader commands cannot be executed. To enable the security program setting in the serial PROM mode, set FLSCR to "1" before executing the security program command sequence. To disable the security program setting, it is necessary to execute the chip erase command sequence. Whether or not the security program is enabled can be checked by reading FF7FH in the Product ID mode. For details, see Table 19-4. Page 226 TMP86FS49BUG It takes a maximum of 40 µs to set security program in the flash memory. The next command sequence cannot be executed until this operation is completed. To check the completion of the security program operation, perform read operations repeatedly for data polling until the same data is read twice from the same address in the flash memory. During the security program operation, any attempts to read from the same address is reversed bit 6 of the data (toggling between 0 and 1). 19.3 Toggle Bit (D6) After the byte program, chip erase, and security program command sequence is executed, any consecutive attempts to read from the same address is reversed bit 6 (D6) of the data (toggling between 0 and 1) until the operation is completed. Therefore, this toggle bit provides a software mechanism to check the completion of each operation. Usually perform read operations repeatedly for data polling until the same data is read twice from the same address in the flash memory. After the byte program, chip erase, or security program command sequence is executed, the initial read of the toggle bit always produces a "1". Page 227 19. Flash Memory 19.4 Access to the Flash Memory Area TMP86FS49BUG 19.4 Access to the Flash Memory Area When the write, erase and security program are set in the flash memory, read and fetch operations cannot be performed in the entire flash memory area. Therefore, to perform these operations in the entire flash memory area, access to the flash memory area by the control program in the BOOTROM or RAM area. (The flash memory program cannot write to the flash memory.) The serial PROM or MCU mode is used to run the control program in the BOOTROM or RAM area. Note 1: The flash memory can be written or read for each byte unit. Erase operations can be performed either in the entire area or in units of 4 kbytes, whereas read operations can be performed by an one transfer instruction. However, the command sequence method is adopted for write and erase operations, requiring several-byte transfer instructions for each operation. Note 2: To rewrite data to Flash memory addresses at which data (including FFH) is already written, make sure to erase the existing data by "sector erase" or "chip erase" before rewriting data. 19.4.1 Flash Memory Control in the Serial PROM Mode The serial PROM mode is used to access to the flash memory by the control program provided in the BOOTROM area. Since almost of all operations relating to access to the flash memory can be controlled simply by the communication data of the serial interface (UART), these functions are transparent to the user. For the details of the serial PROM mode, see “Serial PROM Mode.” To access to the flash memory by using peripheral functions in the serial PROM mode, run the RAM loader command to execute the control program in the RAM area. The procedures to execute the control program in the RAM area is shown in " 19.4.1.1 How to write to the flash memory by executing the control program in the RAM area (in the RAM loader mode within the serial PROM mode) ". 19.4.1.1 How to write to the flash memory by executing the control program in the RAM area (in the RAM loader mode within the serial PROM mode) (Steps 1 and 2 are controlled by the BOOTROM, and steps 3 through 10 are controlled by the control program executed in the RAM area.) 1. Transfer the write control program to the RAM area in the RAM loader mode. 2. Jump to the RAM area. 3. Disable (DI) the interrupt master enable flag (IMF←"0"). 4. Set FLSCR to "0011B" (to enable command sequence execution). 5. Execute the erase command sequence. 6. Read the same flash memory address twice. (Repeat step 6 until the same data is read by two consecutive reads operations.) 7. Specify the bank to be written in FLSCR. 8. Execute the write command sequence. 9. Read the same flash memory address twice. (Repeat step 9 until the same data is read by two consecutive reads operations.) 10. Set FLSCR to "1100B" (to disable command sequence execution). Note 1: Before writing to the flash memory in the RAM area, disable interrupts by setting the interrupt master enable flag (IMF) to "0". Usually disable interrupts by executing the DI instruction at the head of the write control program in the RAM area. Note 2: Since the watchdog timer is disabled by the BOOTROM in the RAM loader mode, it is not required to disable the watchdog timer by the RAM loader program. Page 228 TMP86FS49BUG Example :After chip erasure, the program in the RAM area writes data 3FH to address F000H. DI : Disable interrupts (IMF←"0") LD (FLSCR),00111000B LD IX,0F555H LD IY,0FAAAH LD HL,0F000H : Enable command sequence execution. ; #### Flash Memory Chip erase Process #### sLOOP1: LD (IX),0AAH : 1st bus write cycle LD (IY),55H : 2nd bus write cycle LD (IX),80H : 3rd bus write cycle LD (IX),0AAH : 4th bus write cycle LD (IY),55H : 5th bus write cycle LD (IX),10H : 6th bus write cycle LD W,(HL) CMP W,(HL) JR NZ,sLOOP1 : Loop until the same value is read. SET (FLSCR).3 : Set BANK1. ; #### Flash Memory Write Process #### sLOOP2: sLOOP3: LD (IX),0AAH : 1st bus write cycle LD (IY),55H : 2nd bus write cycle LD (IX),0A0H : 3rd bus write cycle LD (HL),3FH : 4th bus write cycle, (F000H)=3FH LD W,(HL) CMP W,(HL) JR NZ,sLOOP2 : Loop until the same value is read. LD (FLSCR),11001000B : Disable command sequence execution. JP sLOOP3 Page 229 19. Flash Memory 19.4 Access to the Flash Memory Area TMP86FS49BUG 19.4.2 Flash Memory Control in the MCU mode In the MCU mode, write operations are performed by executing the control program in the RAM area. Before execution of the control program, copy the control program into the RAM area or obtain it from the external using the communication pin. The procedures to execute the control program in the RAM area in the MCU mode are described below. 19.4.2.1 How to write to the flash memory by executing a user write control program in the RAM area (in the MCU mode) (Steps 1 and 2 are controlled by the program in the flash memory, and steps 3 through 11 are controlled by the control program in the RAM area.) 1. Transfer the write control program to the RAM area. 2. Jump to the RAM area. 3. Disable (DI) the interrupt master enable flag (IMF←"0"). 4. Disable the watchdog timer, if it is used. 5. Set FLSCR to "0011B" (to enable command sequence execution). 6. Execute the erase command sequence. 7. Read the same flash memory address twice. (Repeat step 7 until the same data is read by two consecutive read operations.) 8. Execute the write command sequence. (It is not required to specify the bank to be written.) 9. Read the same flash memory address twice. (Repeat step 9 until the same data is read by two consecutive read operations.) 10. Set FLSCR to "1100B" (to disable command sequence execution). 11. Jump to the flash memory area. Note 1: Before writing to the flash memory in the RAM area, disable interrupts by setting the interrupt master enable flag (IMF) to "0". Usually disable interrupts by executing the DI instruction at the head of the write control program in the RAM area. Note 2: When writing to the flash memory, do not intentionally use non-maskable interrupts (the watchdog timer must be disabled if it is used). If a non-maskable interrupt occurs while the flash memory is being written, unexpected data is read from the flash memory (interrupt vector), resulting in malfunction of the microcontroller. Page 230 TMP86FS49BUG Example :After sector erasure (E000H-EFFFH), the program in the RAM area writes data 3FH to address E000H. DI : Disable interrupts (IMF←"0") LD (WDTCR2),4EH : Clear the WDT binary counter. LDW (WDTCR1),0B101H : Disable the WDT. LD (FLSCR),00111000B : Enable command sequence execution. LD IX,0F555H LD IY,0FAAAH LD HL,0E000H ; #### Flash Memory Sector Erase Process #### sLOOP1: LD (IX),0AAH : 1st bus write cycle LD (IY),55H : 2nd bus write cycle LD (IX),80H : 3rd bus write cycle LD (IX),0AAH : 4th bus write cycle LD (IY),55H : 5th bus write cycle LD (HL),30H : 6th bus write cycle LD W,(HL) CMP W,(HL) JR NZ,sLOOP1 : Loop until the same value is read. ; #### Flash Memory Write Process #### sLOOP2: LD (IX),0AAH : 1st bus write cycle LD (IY),55H : 2nd bus write cycle LD (IX),0A0H : 3rd bus write cycle LD (HL),3FH : 4th bus write cycle, (1000H)=3FH LD W,(HL) CMP W,(HL) JR NZ,sLOOP2 : Loop until the same value is read. LD (FLSCR),11001000B : Disable command sequence execution. JP XXXXH : Jump to the flash memory area. Example :This write control program reads data from address F000H and stores it to 98H in the RAM area. LD A,(0F000H) : Read data from address F000H. LD (98H),A : Store data to address 98H. Page 231 19. Flash Memory 19.4 Access to the Flash Memory Area TMP86FS49BUG Page 232 TMP86FS49BUG 20. Serial PROM Mode 20.1 Outline The TMP86FS49BUG has a 2048 byte BOOTROM (Mask ROM) for programming to flash memory. The BOOTROM is available in the serial PROM mode, and controlled by TEST, BOOT and RESET pins. Communication is performed via UART. The serial PROM mode has seven types of operating mode: Flash memory writing, RAM loader, Flash memory SUM output, Product ID code output, Flash memory status output, Flash memory erasing and Flash memory security program setting. Memory address mapping in the serial PROM mode differs from that in the MCU mode. Figure 20-1 shows memory address mapping in the serial PROM mode. Table 20-1 Operating Range in the Serial PROM Mode Parameter Power supply High frequency (Note) Min Max Unit 4.5 5.5 V 2 16 MHz Note: Though included in above operating range, some of high frequencies are not supported in the serial PROM mode. For details, refer to “Table 20-5”. 20.2 Memory Mapping The Figure 20-1 shows memory mapping in the Serial PROM mode and MCU mode. In the serial PROM mode, the BOOTROM (Mask ROM) is mapped in addresses from 7800H to 7FFFH. The flash memory is divided into two banks for mapping. Therefore, when the RAM loader mode (60H) is used, it is required to specify the flash memory address according to Figure 20-1 (For detail of banks and control register, refer to the chapter of “Flash Memory Control Register”.) To use the Flash memory writing command (30H), specify the flash memory addresses from 1000H to FFFFH, that is the same addresses in the MCU mode, because the BOOTROM changes the flash memory address. 0000H SFR 003FH 0040H RAM 0000H 64 bytes SFR 2048 bytes RAM 083FH 64 bytes 2048 bytes 083FH 0F80H DBR 003FH 0040H 0F80H DBR 128 bytes 0FFFH 128 bytes 0FFFH 1000H 7800H BOOTROM 7FFFH 8000H 9000H Flash memory 2048 bytes Flash memory 28672 bytes (BANK0) 7FFFH 8000H 61440 bytes 32768 bytes (BANK1) FFFFH FFFFH Serial PROM mode MCU mode Figure 20-1 Memory Address Maps Page 233 20. Serial PROM Mode 20.3 Serial PROM Mode Setting TMP86FS49BUG 20.3 Serial PROM Mode Setting 20.3.1 Serial PROM Mode Control Pins To execute on-board programming, activate the serial PROM mode. Table 20-2 shows pin setting to activate the serial PROM mode. Table 20-2 Serial PROM Mode Setting Pin Setting TEST pin High BOOT/RXD1 pin High RESET pin Note: The BOOT pin is shared with the UART communication pin (RXD1 pin) in the serial PROM mode. This pin is used as UART communication pin after activating serial PROM mode 20.3.2 Pin Function In the serial PROM mode, TXD1 (P02) and RXD1 (P01) are used as a serial interface pin. Table 20-3 Pin Function in the Serial PROM Mode Pin Name (Serial PROM Mode) Input/ Output Pin Name (MCU Mode) Function TXD1 Output Serial data output BOOT/RXD1 Input/Input Serial PROM mode control/Serial data input RESET Input Serial PROM mode control RESET TEST Input Fixed to high TEST VDD, AVDD Power supply 4.5 to 5.5 V VSS Power supply 0V VAREF Power supply Leave open or apply input reference voltage. I/O ports except P02, P01 I/O XIN Input XOUT Output P02 (Note 1) P01 These ports are in the high-impedance state in the serial PROM mode. Self-oscillate with an oscillator. (Note 2) Note 1: During on-board programming with other parts mounted on a user board, be careful no to affect these communication control pins. Note 2: Operating range of high frequency in serial PROM mode is 2 MHz to 16 MHz. Page 234 TMP86FS49BUG TMP86FS49BUG VDD(4.5 V to 5.5 V) VDD Serial PROM mode TEST MCU mode XIN pull-up BOOT / RXD1 (P01) TXD1 (P02) XOUT External control RESET VSS GND Figure 20-2 Serial PROM Mode Pin Setting Note 1: For connection of other pins, refer to " Table 20-3 Pin Function in the Serial PROM Mode ". 20.3.3 Example Connection for On-Board Writing Figure 20-3 shows an example connection to perform on-board wring. VDD(4.5 V to 5.5 V) VDD Serial PROM mode TEST Pull-up MCU mode BOOT / RXD1 (P01) Level converter TXD1 (P02) PC control (Note 2) Other parts RESET control (Note 1) RC power-on reset circuit RESET XIN XOUT VSS GND Application board External control board Figure 20-3 Example Connection for On-Board Writing Note 1: When other parts on the application board effect the UART communication in the serial PROM mode, isolate these pins by a jumper or switch. Note 2: When the reset control circuit on the application board effects activation of the serial PROM mode, isolate the pin by a jumper or switch. Note 3: For connection of other pins, refer to " Table 20-3 Pin Function in the Serial PROM Mode ". Page 235 20. Serial PROM Mode 20.3 Serial PROM Mode Setting TMP86FS49BUG 20.3.4 Activating the Serial PROM Mode The following is a procedure to activate the serial PROM mode. " Figure 20-4 Serial PROM Mode Timing " shows a serial PROM mode timing. 1. Supply power to the VDD pin. 2. Set the RESET pin to low. 3. Set the TEST pin and BOOT/RXD1 pins to high. 4. Wait until the power supply and clock oscillation stabilize. 5. Set the RESET pin to high. 6. Input the matching data (5AH) to the BOOT/RXD1 pin after setup sequence. For details of the setup timing, refer to " 20.15 UART Timing ". VDD TEST(Input) RESET(Input) PROGRAM BOOT/RXD1 (Input) don't care Reset mode High level setting Serial PROM mode Setup time for serial PROM mode (Rxsup) Matching data input Figure 20-4 Serial PROM Mode Timing Page 236 TMP86FS49BUG 20.4 Interface Specifications for UART The following shows the UART communication format used in the serial PROM mode. To perform on-board programming, the communication format of the write controller must also be set in the same manner. The default baud rate is 9600 bps regardless of operating frequency of the microcontroller. The baud rate can be modified by transmitting the baud rate modification data shown in Table 1-4 to TMP86FS49BUG. The Table 20-5 shows an operating frequency and baud rate. The frequencies which are not described in Table 20-5 can not be used. - Baud rate (Default): 9600 bps - Data length: 8 bits - Parity addition: None - Stop bit: 1 bit Table 20-4 Baud Rate Modification Data Baud rate modification data 04H 05H 06H 07H 0AH 18H 28H Baud rate (bps) 76800 62500 57600 38400 31250 19200 9600 Page 237 20. Serial PROM Mode 20.4 Interface Specifications for UART TMP86FS49BUG Table 20-5 Operating Frequency and Baud Rate in the Serial PROM Mode (Note 3) 1 2 3 4 5 6 7 8 Reference Baud Rate (bps) 76800 62500 57600 38400 31250 19200 9600 Baud Rate Modification Data 04H 05H 06H 07H 0AH 18H 28H Ref. Frequency (MHz) Rating (MHz) Baud rate (bps) (%) (bps) (%) (bps) (%) (bps) (%) 2 1.91 to 2.10 - - - - - - - - - - - - 9615 +0.16 4 3.82 to 4.19 - - - - - - - - 31250 0.00 19231 +0.16 9615 +0.16 (bps) (%) (bps) (%) (bps) (%) 4.19 3.82 to 4.19 - - - - - - - - 32734 +4.75 20144 +4.92 10072 +4.92 4.9152 4.70 to 5.16 - - - - - - 38400 0.00 - - 19200 0.00 9600 0.00 5 4.70 to 5.16 - - - - - - 39063 +1.73 - - 19531 +1.73 9766 +1.73 6 5.87 to 6.45 - - - - - - - - - - - - 9375 -2.34 - 6.144 5.87 to 6.45 - - 7.3728 7.05 to 7.74 - - - - - - - - - - - 9600 0.00 - 57600 0.00 - - - - 19200 0.00 9600 0.00 8 7.64 to 8.39 - - 62500 0.00 - - 38462 +0.16 31250 0.00 19231 +0.16 9615 +0.16 9.8304 9.40 to 10.32 76800 0.00 - - - - 38400 0.00 - - 19200 0.00 9600 0.00 10 9.40 to 10.32 78125 +1.73 - - - - 39063 +1.73 - - 19531 +1.73 9766 +1.73 12 11.75 to 12.90 - - - - 57692 +0.16 - - 31250 0.00 18750 -2.34 9375 -2.34 12.288 11.75 to 12.90 - - - - 59077 +2.56 - - 32000 +2.40 19200 0.00 9600 0.00 12.5 11.75 to 12.90 - - 60096 -3.85 60096 +4.33 - - 30048 -3.85 19531 +1.73 9766 +1.73 9 14.7456 14.10 to 15.48 - - - - 57600 0.00 38400 0.00 - - 19200 0.00 9600 0.00 10 16 15.27 to 16.77 76923 +0.16 62500 0.00 - - 38462 +0.16 31250 0.00 19231 +0.16 9615 +0.16 Note 1: “Ref. Frequency” and “Rating” show frequencies available in the serial PROM mode. Though the frequency is supported in the serial PROM mode, the serial PROM mode may not be activated correctly due to the frequency difference in the external controller (such as personal computer) and oscillator, and load capacitance of communication pins. Note 2: It is recommended that the total frequency difference is within ±3% so that auto detection is performed correctly by the reference frequency. Note 3: The external controller must transmit the matching data (5AH) repeatedly till the auto detection of baud rate is performed. This number indicates the number of times the matching data is transmitted for each frequency. Page 238 TMP86FS49BUG 20.5 Operation Command The eight commands shown in Table 20-6 are used in the serial PROM mode. After reset release, the TMP86FS49BUG waits for the matching data (5AH). Table 20-6 Operation Command in the Serial PROM Mode Command Data Operating Mode Description 5AH Setup Matching data. Execute this command after releasing the reset. F0H Flash memory erasing Erases the flash memory area (address 1000H to FFFFH). 30H Flash memory writing Writes to the flash memory area (address 1000H to FFFFH). 60H RAM loader Writes to the specified RAM area (address 0050H to 083FH). 90H Flash memory SUM output Outputs the 2-byte checksum upper byte and lower byte in this order for the entire area of the flash memory (address 1000H to FFFFH). C0H Product ID code output Outputs the product ID code (13-byte data). C3H Flash memory status output Outputs the status code (7-byte data) such as the security program condition. FAH Flash memory security program setting Enables the security program. 20.6 Operation Mode The serial PROM mode has seven types of modes, that are (1) Flash memory erasing, (2) Flash memory writing, (3) RAM loader, (4) Flash memory SUM output, (5) Product ID code output, (6) Flash memory status output and (7) Flash memory security program setting modes. Description of each mode is shown below. 1. Flash memory erasing mode The flash memory is erased by the chip erase (erasing an entire flash area) or sector erase (erasing sectors in 4-kbyte units). The erased area is filled with FFH. When the security program is enabled, the sector erase in the flash erasing mode can not be performed. To disable the security program, perform the chip erase. Before erasing the flash memory, TMP86FS49BUG checks the passwords except a blank product. If the password is not matched, the flash memory erasing mode is not activated. 2. Flash memory writing mode Data is written to the specified flash memory address for each byte unit. The external controller must transmit the write data in the Intel Hex format (Binary). If no error is encountered till the end record, TMP86FS49BUG calculates the checksum for the entire flash memory area (1000H to FFFFH), and returns the obtained result to the external controller. When the security program is enabled, the flash memory writing mode is not activated. In this case, perform the chip erase command beforehand in the flash memory erasing mode. Before activating the flash memory writing mode, TMP86FS49BUG checks the password except a blank product. If the password is not matched, flash memory writing mode is not activated. 3. RAM loader mode The RAM loader transfers the data in Intel Hex format sent from the external controller to the internal RAM. When the transfer is completed normally, the RAM loader calculates the checksum. After transmitting the results, the RAM loader jumps to the RAM address specified with the first data record in order to execute the user program. When the security program is enabled, the RAM loader mode is not activated. In this case, perform the chip erase beforehand in the flash memory erasing mode. Before activating the RAM loader mode, TMP86FS49BUG checks the password except a blank product. If the password is not matched, flash RAM loader mode is not activated. 4. Flash memory SUM output mode The checksum is calculated for the entire flash memory area (1000H to FFFFH), and the result is returned to the external controller. Since the BOOTROM does not support the operation command to read the flash memory, use this checksum to identify programs when managing revisions of application programs. 5. Product ID code output The code used to identify the product is output. The code to be output consists of 13-byte data, which includes the information indicating the area of the ROM incorporated in the product. The external controller reads this code, and recognizes the product to write. (In the case of TMP86FS49BUG, the addresses from 1000H to FFFFH become the ROM area.) Page 239 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG 6. Flash memory status output mode The status of the area from FFE0H to FFFFH, and the security program condition are output as 7-byte code. The external controller reads this code to recognize the flash memory status. 7. Flash memory security program setting mode This mode disables reading and writing the flash memory data in parallel PROM mode. In the serial PROM mode, the flash memory writing and RAM loader modes are disabled. To disable the flash memory security program, perform the chip erase in the flash memory erasing mode. Page 240 TMP86FS49BUG 20.6.1 Flash Memory Erasing Mode (Operating command: F0H) Table 20-7 shows the flash memory erasing mode. Table 20-7 Flash Memory Erasing Mode Transfer Data from the External Controller to TMP86FS49BUG Transfer Byte BOOT ROM Transfer Data from TMP86FS49BUG to the External Controller Baud Rate 1st byte 2nd byte Matching data (5AH) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: No data transmitted 3rd byte 4th byte Baud rate change data (Table 20-4) - 9600 bps 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (F0H) - Modified baud rate Modified baud rate OK: Echo back data (F0H) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte 8th byte Password count storage address bit 15 to 08 (Note 4, 5) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 9th byte 10th byte Password count storage address bit 07 to 00 (Note 4, 5) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 11th byte 12th byte Password comparison start address bit 15 to 08 (Note 4, 5) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 13th byte 14th byte Password comparison start address bit 07 to 00 (Note 4, 5) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted) 15th byte : m’th byte Password string (Note 4, 5) Modified baud rate - - Modified baud rate OK: Nothing transmitted Error: Nothing transmitted n’th - 2 byte Erase area specification (Note 2) Modified baud rate - n’th - 1 byte - Modified baud rate OK: Checksum (Upper byte) (Note 3) Error: Nothing transmitted n’th byte - Modified baud rate OK: Checksum (Lower byte) (Note 3) Error: Nothing transmitted n’th + 1 byte (Wait for the next operation command data) Modified baud rate - Note 1: “xxH × 3” indicates that the device enters the halt condition after transmitting 3 bytes of xxh. Note 2: Refer to " 20.13 Specifying the Erasure Area ". Note 3: Refer to " 20.8 Checksum (SUM) ". Note 4: Refer to " 20.10 Passwords ". Note 5: Do not transmit the password string for a blank product. Note 6: When a password error occurs, TMP86FS49BUG stops UART communication and enters the halt mode. Therefore, when a password error occurs, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Note 7: If an error occurs during transfer of a password address or a password string, TMP86FS49BUG stops UART communication and enters the halt condition. Therefore, when a password error occurs, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Description of the flash memory erasing mode 1. The 1st through 4th bytes of the transmitted and received data contain the same data as in the flash memory writing mode. Page 241 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG 2. The 5th byte of the received data contains the command data in the flash memory erasing mode (F0H). 3. When the 5th byte of the received data contains the operation command data shown in Table 20-6, the device echoes back the value which is the same data in the 6th byte position of the received data (in this case, F0H). If the 5th byte of the received data does not contain the operation command data, the device enters the halt condition after sending 3 bytes of the operation command error code (63H). 4. The 7th thorough m'th bytes of the transmitted and received data contain the same data as in the flash memory writing mode. In the case of a blank product, do not transmit a password string. (Do not transmit a dummy password string.) 5. The n’th - 2 byte contains the erasure area specification data. The upper 4 bits and lower 4 bits specify the start address and end address of the erasure area, respectively. For the detailed description, see “1.13 Specifying the Erasure Area”. 6. The n’th - 1 byte and n’th byte contain the upper and lower bytes of the checksum, respectively. For how to calculate the checksum, refer to “1.8 Checksum (SUM)”. Checksum is calculated unless a receiving error or Intel Hex format error occurs. After sending the end record, the external controller judges whether the transmission is completed correctly by receiving the checksum sent by the device. 7. After sending the checksum, the device waits for the next operation command data. Page 242 TMP86FS49BUG 20.6.2 Flash Memory Writing Mode (Operation command: 30H) Table 20-8 shows flash memory writing mode process. Table 20-8 Flash Memory Writing Mode Process Transfer Byte BOOT ROM Transfer Data from External Controller to TMP86FS49BUG Transfer Data from TMP86FS49BUG to External Controller Baud Rate 1st byte 2nd byte Matching data (5Ah) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: Nothing transmitted 3rd byte 4th byte Baud rate modification data (See Table 20-4) - 9600 bps 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (30H) - Modified baud rate Modified baud rate OK: Echo back data (30H) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte 8th byte Password count storage address bit 15 to 08 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 9th byte 10th byte Password count storage address bit 07 to 00 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 11th byte 12th byte Password comparison start address bit 15 to 08 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 13th byte 14th byte Password comparison start address bit 07 to 00 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted) 15th byte : m’th byte Password string (Note 5) Modified baud rate - m’th + 1 byte : n’th - 2 byte Intel Hex format (binary) (Note 2) n’th - 1 byte - Modified baud rate OK: SUM (Upper byte) (Note 3) Error: Nothing transmitted n’th byte - Modified baud rate OK: SUM (Lower byte) (Note 3) Error: Nothing transmitted n’th + 1 byte (Wait state for the next operation command data) Modified baud rate - - OK: Nothing transmitted Error: Nothing transmitted Modified baud rate - Note 1: “xxH × 3” indicates that the device enters the halt condition after sending 3 bytes of xxH. For details, refer to " 20.7 Error Code ". Note 2: Refer to " 20.9 Intel Hex Format (Binary) ". Note 3: Refer to " 20.8 Checksum (SUM) ". Note 4: Refer to " 20.10 Passwords ". Note 5: If addresses from FFE0H to FFFFH are filled with “FFH”, the passwords are not compared because the device is considered as a blank product. Transmitting a password string is not required. Even in the case of a blank product , it is required to specify the password count storage address and the password comparison start address. Transmit these data from the external controller. If a password error occurs due to incorrect password count storage address or password comparison start address, TMP86FS49BUG stops UART communication and enters the halt condition. Therefore, when a password error occurs, initialize TMP86FS49BUG by the RESET pin and reactivate the serial ROM mode. Note 6: If the security program is enabled or a password error occurs, TMP86FS49BUG stops UART communication and enters the halt confition. In this case, initialize TMP86FS49BUG by the RESET pin and reactivate the serial ROM mode. Note 7: If an error occurs during the reception of a password address or a password string, TMP86FS49BUG stops UART communication and enters the halt condition. In this case, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Page 243 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG Description of the flash memory writing mode 1. The 1st byte of the received data contains the matching data. When the serial PROM mode is activated, TMP86FS49BUG (hereafter called device), waits to receive the matching data (5AH). Upon reception of the matching data, the device automatically adjusts the UART’s initial baud rate to 9600 bps. 2. When receiving the matching data (5AH), the device transmits an echo back data (5AH) as the second byte data to the external controller. If the device can not recognize the matching data, it does not transmit the echo back data and waits for the matching data again with automatic baud rate adjustment. Therefore, the external controller should transmit the matching data repeatedly till the device transmits an echo back data. The transmission repetition count varies depending on the frequency of device. For details, refer to Table 20-5. 3. The 3rd byte of the received data contains the baud rate modification data. The five types of baud rate modification data shown in Table 20-4 are available. Even if baud rate is not modified, the external controller should transmit the initial baud rate data (28H: 9600 bps). 4. Only when the 3rd byte of the received data contains the baud rate modification data corresponding to the device's operating frequency, the device echoes back data the value which is the same data in the 4th byte position of the received data. After the echo back data is transmitted, baud rate modification becomes effective. If the 3rd byte of the received data does not contain the baud rate modification data, the device enters the halts condition after sending 3 bytes of baud rate modification error code (62H). 5. The 5th byte of the received data contains the command data (30H) to write the flash memory. 6. When the 5th byte of the received data contains the operation command data shown in Table 1-6, the device echoes back the value which is the same data in the 6th byte position of the received data (in this case, 30H). If the 5th byte of the received data does not contain the operation command data, the device enters the halt condition after sending 3 bytes of the operation command error code (63H). 7. The 7th byte contains the data for 15 to 8 bits of the password count storage address. When the data received with the 7th byte has no receiving error, the device does not send any data. If a receiving error or password error occurs, the device does not send any data and enters the halt condition. 8. The 9th byte contains the data for 7 to 0 bits of the password count storage address. When the data received with the 9th byte has no receiving error, the device does not send any data. If a receiving error or password error occurs, the device does not send any data and enters the halt condition. 9. The 11th byte contains the data for 15 to 8 bits of the password comparison start address. When the data received with the 11th byte has no receiving error, the device does not send any data. If a receiving error or password error occurs, the device does not send any data and enters the halt condition. 10. The 13th byte contains the data for 7 to 0 bits of the password comparison start address. When the data received with the 13th byte has no receiving error, the device does not send any data. If a receiving error or password error occurs, the device does not send any data and enters the halt condition. 11. The 15th through m’th bytes contain the password data. The number of passwords becomes the data (N) stored in the password count storage address. The external password data is compared with Nbyte data from the address specified by the password comparison start address. The external controller should send N-byte password data to the device. If the passwords do not match, the device enters the halt condition without returning an error code to the external controller. If the addresses from FFE0H to FFFFH are filled with “FFH”, the passwords are not conpared because the device is considered as a blank product. 12. The m’th + 1 through n’th - 2 bytes of the received data contain the binary data in the Intel Hex format. No received data is echoed back to the external controller. After receiving the start mark (3AH for “:”) in the Intel Hex format, the device starts data record reception. Therefore, the received data except 3AH is ignored until the start mark is received. After receiving the start mark, the device receives the data record, that consists of data length, address, record type, write data and checksum. Since the device starts checksum calculation after receiving an end record, the external controller should wait for the checksum after sending the end record. If a receiving error or Intel Hex format error occurs, the device enters the halts condition without returning an error code to the external controller. 13. The n’th - 1 and n’th bytes contain the checksum upper and lower bytes. For details on how to calculate the SUM, refer to " 20.8 Checksum (SUM) ". The checksum is calculated only when the end record is detected and no receiving error or Intel Hex format error occurs. After sending the end Page 244 TMP86FS49BUG record, the external controller judges whether the transmission is completed correctly by receiving the checksum sent by the device. 14. After transmitting the checksum, the device waits for the next operation command data. Note 1: Do not write only the address from FFE0H to FFFFH when all flash memory data is the same. If only these area are written, the subsequent operation can not be executed due to password error. Note 2: To rewrite data to Flash memory addresses at which data (including FFH) is already written, make sure to erase the existing data by "sector erase" or "chip erase" before rewriting data. Page 245 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG 20.6.3 RAM Loader Mode (Operation Command: 60H) Table 20-9 shows RAM loader mode process. Table 20-9 RAM Loader Mode Process Transfer Bytes BOOT ROM RAM Transfer Data from External Controller to TMP86FS49BUG Transfer Data from TMP86FS49BUG to External Controller Baud Rate 1st byte 2nd byte Matching data (5AH) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: Nothing transmitted 3rd byte 9600 bps - 4th byte Baud rate modification data (See Table 20-4) - 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (60H) - Modified baud rate Modified baud rate OK: Echo back data (60H) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte 8th byte Password count storage address bit 15 to 08 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 9th byte 10th byte Password count storage address bit 07 to 00 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 11th byte 12th byte Password comparison start address bit 15 to 08 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 13th byte 14th byte Password comparison start address bit 07 to 00 (Note 4) Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 15th byte : m’th byte Password string (Note 5) Modified baud rate - m’th + 1 byte : n’th - 2 byte Intel Hex format (Binary) (Note 2) n’th - 1 byte - OK: Nothing transmitted Error: Nothing transmitted Modified baud rate - Modified baud rate - - Modified baud rate OK: SUM (Upper byte) (Note 3) Error: Nothing transmitted n’th byte - Modified baud rate OK: SUM (Lower byte) (Note 3) Error: Nothing transmitted - The program jumps to the start address of RAM in which the first transferred data is written. Note 1: “xxH × 3” indicates that the device enters the halt condition after sending 3 bytes of xxH. For details, refer to " 20.7 Error Code ". Note 2: Refer to " 20.9 Intel Hex Format (Binary) ". Note 3: Refer to " 20.8 Checksum (SUM) ". Note 4: Refer to " 20.10 Passwords ". Note 5: If addresses from FFE0H to FFFFH are filled with “FFH”, the passwords are not compared because the device is considered as a blank product. Transmitting a password string is not required. Even in the case of a blank product , it is required to specify the password count storage address and the password comparison start address. Transmit these data from the external controller. If a password error occurs due to incorrect password count storage address or password comparison start address, TMP86FS49BUG stops UART communication and enters the halt condition. Therefore, when a password error occurs, initialize TMP86FS49BUG by the RESET pin and reactivate the serial ROM mode. Note 6: After transmitting a password string, the external controller must not transmit only an end record. If receiving an end record after a password string, the device may not operate correctly. Note 7: If the security program is enabled or a password error occurs, TMP86FS49BUG stops UART communication and enters the halt condition. In this case, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Page 246 TMP86FS49BUG Note 8: If an error occurs during the reception of a password address or a password string, TMP86FS49BUG stops UART communication and enters the halt condition. In this case, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Description of RAM loader mode 1. The 1st through 4th bytes of the transmitted and received data contains the same data as in the flash memory writing mode. 2. In the 5th byte of the received data contains the RAM loader command data (60H). 3. When th 5th byte of the received data contains the operation command data shown in Table 1-6, the device echoes back the value which is the same data in the 6th byte position (in this case, 60H). If the 5th byte does not contain the operation command data, the device enters the halt condition after sending 3 bytes of operation command error code (63H). 4. The 7th through m’th bytes of the transmitted and received data contain the same data as in the flash memory writing mode. 5. The m’th + 1 through n’th - 2 bytes of the received data contain the binary data in the Intel Hex format. No received data is echoed back to the external controller. After receiving the start mark (3AH for “:”) in the Intel Hex format, the device starts data record reception. Therefore, the received data except 3AH is ignored until the start mark is received. After receiving the start mark, the device receives the data record, that consists of data length, address, record type, write data and checksum. The writing data of the data record is written into RAM specified by address. Since the device starts checksum calculation after receiving an end record, the external controller should wait for the checksum after sending the end record. If a receiving error or Intel Hex format error occurs, the device enters the halts condition without returning an error code to the external controller. 6. The n’th - 1 and n’th bytes contain the checksum upper and lower bytes. For details on how to calculate the SUM, refer to " 20.8 Checksum (SUM) ". The checksum is calculated only when the end record is detected and no receiving error or Intel Hex format error occurs. After sending the end record, the external controller judges whether the transmission is completed correctly by receiving the checksum sent by the device. 7. After transmitting the checksum to the external controller, the boot program jumps to the RAM address that is specified by the first received data record. Note 1: To rewrite data to Flash memory addresses at which data (including FFH) is already written, make sure to erase the existing data by "sector erase" or "chip erase" before rewriting data. Page 247 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG 20.6.4 Flash Memory SUM Output Mode (Operation Command: 90H) Table 20-10 shows flash memory SUM output mode process. Table 20-10 Flash Memory SUM Output Process Transfer Bytes BOOT ROM Transfer Data from External Controller to TMP86FS49BUG Transfer Data from TMP86FS49BUG to External Controller Baud Rate 1st byte 2nd byte Matching data (5AH) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: Nothing transmitted 3rd byte 9600 bps - 4th byte Baud rate modification data (See Table 20-4) - 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (90H) - Modified baud rate Modified baud rate OK: Echo back data (90H) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte - Modified baud rate OK: SUM (Upper byte) (Note 2) Error: Nothing transmitted 8th byte - Modified baud rate OK: SUM (Lower byte) (Note 2) Error: Nothing transmitted 9th byte (Wait for the next operation command data) Modified baud rate - Note 1: “xxH × 3” indicates that the device enters the halt condition after sending 3 bytes of xxH. For details, refer to " 20.7 Error Code ". Note 2: Refer to " 20.8 Checksum (SUM) ". Description of the flash memory SUM output mode 1. The 1st through 4th bytes of the transmitted and received data contains the same data as in the flash memory writing mode. 2. The 5th byte of the received data contains the command data in the flash memory SUM output mode (90H). 3. When the 5th byte of the received data contains the operation command data shown in Table 1-6, the device echoes back the value which is the same data in the 6th byte position of the received data (in this case, 90H). If the 5th byte of the received data does not contain the operation command data, the device enters the halt condition after transmitting 3 bytes of operation command error code (63H). 4. The 7th and the 8th bytes contain the upper and lower bits of the checksum, respectively. For how to calculate the checksum, refer to " 20.8 Checksum (SUM) ". 5. After sending the checksum, the device waits for the next operation command data. Page 248 TMP86FS49BUG 20.6.5 Product ID Code Output Mode (Operation Command: C0H) Table 20-11 shows product ID code output mode process. Table 20-11 Product ID Code Output Process Transfer Bytes BOOT ROM Transfer Data from External Controller to TMP86FS49BUG Transfer Data from TMP86FS49BUG to External Controller Baud Rate 1st byte 2nd byte Matching data (5AH) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: Nothing transmitted 3rd byte 9600 bps - 4th byte Baud rate modification data (See Table 20-4) - 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (C0H) - Modified baud rate Modified baud rate OK: Echo back data (C0H) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte Modified baud rate 3AH Start mark 8th byte Modified baud rate 0AH The number of transfer data (from 9th to 18th bytes) 9th byte Modified baud rate 02H Length of address (2 bytes) 10th byte Modified baud rate 1DH Reserved data 11th byte Modified baud rate 00H Reserved data 12th byte Modified baud rate 00H Reserved data 13th byte Modified baud rate 00H Reserved data 14th byte Modified baud rate 01H ROM block count (1 block) 15th byte Modified baud rate 10H First address of ROM (Upper byte) 16th byte Modified baud rate 00H First address of ROM (Lower byte) 17th byte Modified baud rate FFH End address of ROM (Upper byte) 18th byte Modified baud rate FFH End address of ROM (Lower byte) 19th byte Modified baud rate D2H Checksum of transferred data (9th through 18th byte) Modified baud rate - 20th byte (Wait for the next operation command data) Note: “xxH × 3” indicates that the device enters the halt condition after sending 3 bytes of xxH. For details, refer to " 20.7 Error Code ". Description of Product ID code output mode 1. The 1st through 4th bytes of the transmitted and received data contain the same data as in the flash memory writing mode. 2. The 5th byte of the received data contains the product ID code output mode command data (C0H). 3. When the 5th byte contains the operation command data shown in Table 20-6, the device echoes back the value which is the same data in the 6th byte position of the received data (in this case, C0H). If the 5th byte data does not contain the operation command data, the device enters the halt condition after sending 3 bytes of operation command error code (63H). 4. The 9th through 19th bytes contain the product ID code. For details, refer to " 20.11 Product ID Code ". Page 249 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG 5. After sending the checksum, the device waits for the next operation command data. Page 250 TMP86FS49BUG 20.6.6 Flash Memory Status Output Mode (Operation Command: C3H) Table 20-12 shows Flash memory status output mode process. Table 20-12 Flash Memory Status Output Mode Process Transfer Bytes BOOT ROM Transfer Data from External Controller to TMP86FS49BUG Transfer Data from TMP86FS49BUG to External Controller Baud Rate 1st byte 2nd byte Matching data (5AH) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: Nothing transmitted 3rd byte 9600 bps - 4th byte Baud rate modification data (See Table 20-4) - 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (C3H) - Modified baud rate Modified baud rate OK: Echo back data (C3H) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte Modified baud rate 3AH Start mark 8th byte Modified baud rate 04H Byte count (from 9th to 12th byte) 9th byte Modified baud rate 00H to 03H Status code 1 10th byte Modified baud rate 00H Reserved data 11th byte Modified baud rate 00H Reserved data 12th byte Modified baud rate 00H Reserved data 13th byte Modified baud rate Checksum 2’s complement for the sum of 9th through 12th bytes 9th byte Checksum 00H: 00H 01H: FFH 02H: FEH 03H: FDH Modified baud rate - 14th byte (Wait for the next operation command data) Note 1: “xxH × 3” indicates that the device enters the halt condition after sending 3 bytes of xxH. For details, refer to " 20.7 Error Code ". Note 2: For the details on status code 1, refer to " 20.12 Flash Memory Status Code ". Description of Flash memory status output mode 1. The 1st through 4th bytes of the transmitted and received data contain the same data as in the Flash memory writing mode. 2. The 5th byte of the received data contains the flash memory status output mode command data (C3H). 3. When the 5th byte contains the operation command data shown in Table 20-6, the device echoes back the value which is the same data in the 6th byte position of the received data (in this case, C3H). If the 5th byte does not contain the operation command data, the device enters the halt condition after sending 3 bytes of operation command error code (63H). 4. The 9th through 13th bytes contain the status code. For details on the status code, refer to " 20.12 Flash Memory Status Code ". 5. After sending the status code, the device waits for the next operation command data. Page 251 20. Serial PROM Mode 20.6 Operation Mode TMP86FS49BUG 20.6.7 Flash Memory security program Setting Mode (Operation Command: FAH) Table 20-13 shows Flash memory security program setting mode process. Table 20-13 Flash Memory security program Setting Mode Process Transfer Data from External Controller to TMP86FS49BUG Transfer Bytes BOOT ROM Transfer Data from TMP86FS49BUG to External Controller Baud Rate 1st byte 2nd byte Matching data (5AH) - 9600 bps 9600 bps - (Automatic baud rate adjustment) OK: Echo back data (5AH) Error: Nothing transmitted 3rd byte 9600 bps - 4th byte Baud rate modification data (See Table 20-4) - 9600 bps OK: Echo back data Error: A1H × 3, A3H × 3, 62H × 3 (Note 1) 5th byte 6th byte Operation command data (FAH) - Modified baud rate Modified baud rate OK: Echo back data (FAH) Error: A1H × 3, A3H × 3, 63H × 3 (Note 1) 7th byte 8th byte Password count storage address 15 to 08 (Note 2) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 9th byte 10th byte Password count storage address 07 to 00 (Note 2) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 11th byte 12th byte Password comparison start address 15 to 08 (Note 2) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 13th byte 14th byte Password comparison start address 07 to 00 (Note 2) Modified baud rate Modified baud rate OK: Nothing transmitted Error: Nothing transmitted 15th byte : m’th byte Password string (Note 2) Modified baud rate - - Modified baud rate OK: Nothing transmitted Error: Nothing transmitted n’th byte - Modified baud rate OK: FBH (Note 3) Error: Nothing transmitted n’+1th byte (Wait for the next operation command data) Modified baud rate - Note 1: “xxH × 3” indicates that the device enters the halt condition after sending 3 bytes of xxH. For details, refer to " 20.7 Error Code ". Note 2: Refer to " 20.10 Passwords ". Note 3: If the security program is enabled for a blank product or a password error occurs for a non-blank product, TMP86FS49BUG stops UART communication and enters the halt mode. In this case, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Note 4: If an error occurs during reception of a password address or a password string, TMP86FS49BUG stops UART communication and enters the halt mode. In this case, initialize TMP86FS49BUG by the RESET pin and reactivate the serial PROM mode. Description of the Flash memory security program setting mode 1. The 1st through 4th bytes of the transmitted and received data contain the same data as in the Flash memory writing mode. 2. The 5th byte of the received data contains the command data in the flash memory status output mode (FAH). 3. When the 5th byte of the received data contains the operation command data shown in Table 1-6, the device echoes back the value which is the same data in the 6th byte position of the received data (in Page 252 TMP86FS49BUG this case, FAH). If the 5th byte does not contain the operation command data, the device enters the halt condition after transmitting 3 bytes of operation command error code (63H). 4. The 7th through m’th bytes of the transmitted and received data contain the same data as in the flash memory writing mode. 5. The n'th byte contains the status to be transmitted to the external controller in the case of the successful security program. Page 253 20. Serial PROM Mode 20.7 Error Code TMP86FS49BUG 20.7 Error Code When detecting an error, the device transmits the error code to the external controller, as shown in Table 20-14. Table 20-14 Error Code Transmit Data Meaning of Error Data 62H, 62H, 62H Baud rate modification error. 63H, 63H, 63H Operation command error. A1H, A1H, A1H Framing error in the received data. A3H, A3H, A3H Overrun error in the received data. Note: If a password error occurs, TMP86FS49BUG does not transmit an error code. 20.8 Checksum (SUM) 20.8.1 Calculation Method The checksum (SUM) is calculated with the sum of all bytes, and the obtained result is returned as a word. The data is read for each byte unit and the calculated result is returned as a word. Example: A1H B2H C3H D4H If the data to be calculated consists of the four bytes, the checksum of the data is as shown below. A1H + B2H + C3H + D4H = 02EAH SUM (HIGH)= 02H SUM (LOW)= EAH The checksum which is transmitted by executing the flash memory write command, RAM loader command, or flash memory SUM output command is calculated in the manner, as shown above. Page 254 TMP86FS49BUG 20.8.2 Calculation data The data used to calculate the checksum is listed in Table 20-15. Table 20-15 Checksum Calculation Data Operating Mode Calculation Data Description Data in the entire area of the flash memory Even when a part of the flash memory is written, the checksum of the entire flash memory area (1000H to FFFH) is calculated. The data length, address, record type and checksum in Intel Hex format are not included in the checksum. RAM loader mode RAM data written in the first received RAM address through the last received RAM address The length of data, address, record type and checksum in Intel Hex format are not included in the checksum. Product ID Code Output mode 9th through 18th bytes of the transferred data For details, refer to " 20.11 Product ID Code ". Flash Memory Status Output mode 9th through 12th bytes of the transferred data For details, refer to " 20.12 Flash Memory Status Code " Flash Memory Erasing mode All data in the erased area of the flash memory (the whole or part of the flash memory) When the sector erase is executed, only the erased area is used to calculate the checksum. In the case of the chip erase, an entire area of the flash memory is used. Flash memory writing mode Flash memory SUM output mode Page 255 20. Serial PROM Mode 20.9 Intel Hex Format (Binary) TMP86FS49BUG 20.9 Intel Hex Format (Binary) 1. After receiving the checksum of a data record, the device waits for the start mark (3AH “:”) of the next data record. After receiving the checksum of a data record, the device ignores the data except 3AH transmitted by the external controller. 2. After transmitting the checksum of end record, the external controller must transmit nothing, and wait for the 2-byte receive data (upper and lower bytes of the checksum). 3. If a receiving error or Intel Hex format error occurs, the device enters the halt condition without returning an error code to the external controller. The Intel Hex format error occurs in the following case: When the record type is not 00H, 01H, or 02H When a checksum error occurs When the data length of an extended record (record type = 02H) is not 02H When the device receives the data record after receiving an extended record (record type = 02H) with extended address of 1000H or larger. When the data length of the end record (record type = 01H) is not 00H 20.10Passwords The consecutive eight or more-byte data in the flash memory area can be specified to the password. TMP86FS49BUG compares the data string specified to the password with the password string transmitted from the external controller. The area in which passwords can be specified is located at addresses 1000H to FF9FH. The area from FFA0H to FFFFH can not be specified as the passwords area. If addresses from FFE0H through FFFFH are filled with “FFH”, the passwords are not compared because the product is considered as a blank product. Even in this case, the password count storage addresses and password comparison start address must be specified. Table 20-16 shows the password setting in the blank product and nonblank product. Table 20-16 Password Setting in the Blank Product and Non-Blank Product Password Blank Product (Note 1) Non-Blank Product PNSA (Password count storage address) 1000H ≤ PNSA ≤ FF9FH 1000H ≤ PNSA ≤ FF9FH PCSA (Password comparison start address) 1000H ≤ PCSA ≤ FF9FH 1000H ≤ PCSA ≤ FFA0 - N N (Password count) * 8≤N Password string setting Not required (Note 5) Required (Note 2) Note 1: When addresses from FFE0H through FFFFH are filled with “FFH”, the product is recognized as a blank product. Note 2: The data including the same consecutive data (three or more bytes) can not be used as a password. (This causes a password error data. TMP86FS49BUG transmits no data and enters the halt condition.) Note 3: *: Don’t care. Note 4: When the above condition is not met, a password error occurs. If a password error occurs, the device enters the halt condition without returning the error code. Note 5: In the flash memory writing mode or RAM loader mode, the blank product receives the Intel Hex format data immediately after receiving PCSA without receiving password strings. In this case, the subsequent processing is performed correctly because the blank product ignores the data except the start mark (3AH “:”) as the Intel Hex format data, even if the external controller transmits the dummy password string. However, if the dummy password string contains “3AH”, it is detected as the start mark erroneously. The microcontroller enters the halt mode. If this causes the problem, do not transmit the dummy password strings. Note 6: In the flash memory erasing mode, the external controller must not transmit the password string for the blank product. Page 256 TMP86FS49BUG UART RXD pin F0H 12H F1H 07H 01H 02H 03H 04H 05H 06H 07H PNSA 08H Password string PCSA Flash memory F012H 08H F107H 01H F108H 02H F109H 03H F10AH 04H F10BH 05H Example F10CH 06H PNSA = F012H PCSA = F107H Password string = 01H,02H,03H,04H,05H 06H,07H,08H F10DH 07H F10EH "08H" becomes the umber of Compare passwords 8 bytes 08H Figure 20-5 Password Comparison 20.10.1Password String The password string transmitted from the external controller is compared with the specified data in the flash memory. When the password string is not matched to the data in the flash memory, the device enters the halt condition due to the password error. 20.10.2Handling of Password Error If a password error occurs, the device enters the halt condition. In this case, reset the device to reactivate the serial PROM mode. 20.10.3Password Management during Program Development If a program is modified many times in the development stage, confusion may arise as to the password. Therefore, it is recommended to use a fixed password in the program development stage. Example :Specify PNSA to F000H, and the password string to 8 bytes from address F001H (PCSA becomes F001H.) Password Section code abs = 0F000H DB 08H : PNSA definition DB “CODE1234” : Password string definition Page 257 20. Serial PROM Mode 20.11 Product ID Code TMP86FS49BUG 20.11Product ID Code The product ID code is the 13-byte data containing the start address and the end address of ROM. Table 20-17 shows the product ID code format. Table 20-17 Product ID Code Format Data Description In the Case of TMP86FS49BUG 1st Start Mark (3AH) 3AH 2nd The number of transfer data (10 bytes from 3rd to 12th byte) 0AH 3rd Address length (2 bytes) 02H 4th Reserved data 1DH 5th Reserved data 00H 6th Reserved data 00H 7th Reserved data 00H 8th ROM block count 01H 9th The first address of ROM (Upper byte) 10H 10th The first address of ROM (Lower byte) 00H 11th The end address of ROM (Upper byte) FFH 12th The end address of ROM (Lower byte) FFH 13th Checksum of the transferred data (2’s compliment for the sum of 3rd through 12th bytes) D2H 20.12Flash Memory Status Code The flash memory status code is the 7-byte data including the security program status and the status of the data from FFE0H to FFFFH. Table 20-18 shows the flash memory status code. Table 20-18 Flash Memory Status Code Data Description In the Case of TMP86FS49BUG 1st Start mark 3AH 2nd Transferred data count (3rd through 6th byte) 04H 3rd Status code 00H to 03H (See figure below) 4th Reserved data 00H 5th Reserved data 00H 6th Reserved data 00H 3rd byte 00H 01H 02H 03H Checksum of the transferred data (2’s compliment for the sum of 3rd through 6th data) 7th checksum 00H FFH FEH FDH Status Code 1 7 6 5 4 3 Page 258 2 1 0 RPENA BLANK (Initial Value: 0000 00**) TMP86FS49BUG RPENA Flash memory security program status 0: 1: Security program is disabled. Security program is enabled. BLANK The status from FFE0H to FFFFH. 0: 1: All data is FFH in the area from FFE0H to FFFFH. The value except FFH is included in the area from FFE0H to FFFFH. Some operation commands are limited by the flash memory status code 1. If the security program is enabled, flash memory writing mode command and RAM loader mode command can not be executed. Erase all flash memory before executing these command. Flash Memory Erasing Mode RPENA BLANK Flash Memory Writing Mode RAM Loader Mode Flash memory SUM Output Mode 0 0 m m m m m 0 1 Pass Pass m m m 1 0 × × m m m m × × 1 1 × × m m m Pass × Pass Product ID Code Output Mode Flash Memory Status Output Mode Sector Erase Chip Erase Security program Setting Mode × m Pass Pass Note: m: The command can be executed. Pass: The command can be executed with a password. ×: The command can not be executed. (After echoing the command back to the external controller, TMP86FS49BUG stops UART communication and enters the halt condition.) Page 259 20. Serial PROM Mode 20.13 Specifying the Erasure Area TMP86FS49BUG 20.13Specifying the Erasure Area In the flash memory erasing mode, the erasure area of the flash memory is specified by n−2 byte data. The start address of an erasure area is specified by ERASTA, and the end address is specified by ERAEND. If ERASTA is equal to or smaller than ERAEND, the sector erase (erasure in 4 kbyte units) is executed. Executing the sector erase while the security program is enabled results in an infinite loop. If ERASTA is larger than ERAEND, the chip erase (erasure of an entire flash memory area) is executed and the security program is disabled. Therefore, execute the chip erase (not sector erase) to disable the security program. Erasure Area Specification Data (n−2 byte data) 7 6 5 4 3 2 ERASTA ERASTA ERAEND 1 0 ERAEND The start address of the erasure area 0000: 0001: 0010: 0011: 0100: 0101: 0110: 0111: 1000: 1001: 1010: 1011: 1100: 1101: 1110: 1111: from 0000H from 1000H from 2000H from 3000H from 4000H from 5000H from 6000H from 7000H from 8000H from 9000H from A000H from B000H from C000H from D000H from E000H from F000H The end address of the erasure area 0000: 0001: 0010: 0011: 0100: 0101: 0110: 0111: 1000: 1001: 1010: 1011: 1100: 1101: 1110: 1111: to 0FFFH to 1FFFH to 2FFFH to 3FFFH to 4FFFH to 5FFFH to 6FFFH to 7FFFH to 8FFFH to 9FFFH to AFFFH to BFFFH to CFFFH to DFFFH to EFFFH to FFFFH Note: When the sector erase is executed for the area containing no flash cell, TMP86FS49BUG stops the UART communication and enters the halt condition. Page 260 Page 261 Transmit UART data (Checksum of an entire area) Transmit UART data (Checksum of an entire area) Jump to the start address of RAM program Transmit UART data (Checksum) RAM write process Flash memory write process OK Receive UART data (Intel Hex format) Infinite loop Receive UART data (Intel Hex format) OK Transmit UART data (Product ID code) Infinite loop Transmit UART data (Transmit data = FBH) Blank product Blank product check Security Program check Transmit UART data (Transmit data = C3H) Receive data = C3H (Flash memory status output mode) Transmit UART data (Status of the Security Program and blank product) Infinite loop NG Security Program setting OK Verify the password (Compare the receive data and flash memory data) NG Verify the password (Compare the receive data and flash memory data) Transmit UART data (Echo back the baud rate modification data) NG Verify the password (Compare the receive data and flash memory data) Receive UART data Blank product check Transmit UART data (Transmit data = FAH) Receive data = FAH (Security Program setting mode) Non-blank product Security Enable Transmit UART data (Transmit data = C0H) Receive data = C0H (Product ID code output mode) Blank product check Security disabled Security Program check Transmit UART data (Transmit data = 60H) Receive data = 60H (RAM loader mode) Blank Non-blank product product Security Enable Transmit UART data (Transmit data = 90H) Receive data = 90H (Flash memory sum output mode) Blank product check Security disabled Security Program check Transmit UART data (Transmit data = 30H) Receive data = 30H (Flash memory writing mode) Receive UART data Modify the baud rate based on the receive data Blank Non-blank product product Transmit UART data (Transmit data = 5AH) Yes No Adjust the baud rate (Adjust the source clock to 9600 bps) Receive data = 5AH Receive UART data Setup START Transmit UART data (Checksum of an entire area) Disable Security Program Chip erase (Erase on entire area) Transmit UART data (Checksum of the erased area) Sector erase (Block erase) Upper 4 bits x 1000H to Lower 4 bits x 1000H Security disabled Security Program check Upper 4 bits < Lower 4 bits Infinite loop NG Upper 4 bits > Lower 4 bits Receive data Receive UART data OK Verify the password (Compare the receive data and flash memory data) Blank Non-blank product product Blank product check Transmit UART data (Transmit data = F0H) Receive data = F0H (Flash memory erasing mode) Infinite loop Security enabled TMP86FS49BUG 20.14Flowchart 20. Serial PROM Mode 20.15 UART Timing TMP86FS49BUG 20.15UART Timing Table 20-19 UART Timing-1 (VDD = 4.5 to 5.5 V, fc = 2 to 16 MHz, Topr = -10 to 40°C) Minimum Required Time Parameter Symbol Clock Frequency (fc) At fc = 2 MHz At fc = 16 MHz Time from matching data reception to the echo back CMeb1 Approx. 930 465 µs 58.1 µs Time from baud rate modification data reception to the echo back CMeb2 Approx. 980 490 µs 61.3 µs Time from operation command reception to the echo back CMeb3 Approx. 800 400 µs 50 µs Checksum calculation time CKsm Approx. 7864500 3.93 s 491.5 µs Erasure time of an entire flash memory CEall - 30 ms 30 ms Erasure time for a sector of a flash memory (in 4-kbyte units) CEsec - 15 ms 15 ms Table 20-20 UART Timing-2 (VDD = 4.5 to 5.5 V, fc = 2 to 16 MHz, Topr = -10 to 40°C) Minimum Required Time Parameter Symbol Clock Frequency (fc) At fc = 2 MHz At fc = 16 MHz Time from the reset release to the acceptance of start bit of RXD pin RXsup 2100 1.05 ms 131.3 ms Matching data transmission interval CMtr1 28500 14.2 ms 1.78 ms Time from the echo back of matching data to the acceptance of baud rate modification data CMtr2 380 190 µs 23.8 µs Time from the echo back of baud rate modification data to the acceptance of an operation command CMtr3 650 325 µs 40.6 µs Time from the echo back of operation command to the acceptance of password count storage addresses (Upper byte) CMtr4 800 400 µs 50 µs CMtr3 CMtr2 RXsup CMtr4 RESET pin (5AH) (30H) (28H) RXD pin (5AH) (30H) (28H) TXD pin CMeb1 (5AH) CMeb2 (5AH) RXD pin TXD pin CMtr1 Page 262 CMeb3 (5AH) TMP86FS49BUG 21. Input/Output Circuit 21.1 Control pins The input/output circuitries of the TMP86FS49BUG control pins are shown below. Control Pin I/O Input/Output Circuitry Remarks Osc.enable fc VDD XIN XOUT Input Output Resonator connecting pins (high frequency) VDD Rf RO Rf = 1.2 MΩ (typ.) RO =0.5 kΩ (typ.) XIN XOUT XTEN Osc.enable XTIN XTOUT Input Output fs VDD VDD Rf Resonator connecting pins (Low frequency) Rf = 6 MΩ (typ.) RO RO = 220 kΩ (typ.) XTIN XTOUT VDD R RIN RESET Input Hysteresis input Pull-up resistor RIN = 220 kΩ (typ.) R = 100 Ω (typ.) Address-trap-reset Watchdog-timer-reset System-clock-reset R TEST R = 100 Ω (typ.) Input Note: The TEST pin of the TMP86FS49BUG does not have a pull-down resistor and a protection diode on the VDD side. Therefore, fix the TEST pin at Low-level. Page 263 21. Input/Output Circuit 21.2 Input/Output Ports TMP86FS49BUG 21.2 Input/Output Ports Port I/O Input/Output Circuitry Remarks Initial "High-Z" VDD Data output P1 Tri-state I/O Hysteresis input I/O Disable R = 100 Ω (typ.) R Pin input Initial "High-Z" P3 I/O Sink open drain output High current output Data output R Output latch input R = 100 Ω (typ.) Pin input Initial "High-Z" P2 I/O VDD Sink open drain output Hysteresis input Data output R Output latch input R = 100 Ω (typ.) Pin input Initial "High-Z" P5 I/O Sink open drain output High current output Hysteresis input Data output R Output latch input R = 100 Ω (typ.) Pin input Initial "High-Z" VDD P-ch control Data output P0 P4 I/O Sink open drain output or C-MOS output Hysteresis input Output latch input R Disable Pin input (Control input) Page 264 R = 100 Ω (typ.) TMP86FS49BUG Port I/O Input/Output Circuitry Initial "High-Z" Analog input Remarks VDD Data output P67 P66 P65 P64 I/O Tri-state I/O Output latch input R = 100 Ω (typ.) R Disable Pin input Key-on Wakeup Initial "High-Z" Analog input P63 P62 P61 P60 P7 VDD Data output I/O Tri-state I/O R = 100 Ω (typ.) Output latch input R Disable Pin input Page 265 21. Input/Output Circuit 21.2 Input/Output Ports TMP86FS49BUG Page 266 TMP86FS49BUG 22. Electrical Characteristics 22.1 Absolute Maximum Ratings The absolute maximum ratings are rated values which must not be exceeded during operation, even for an instant. Any one of the ratings must not be exceeded. If any absolute maximum rating is exceeded, a device may break down or its performance may be degraded, causing it to catch fire or explode resulting in injury to the user. Thus, when designing products which include this device, ensure that no absolute maximum rating value will ever be exceeded. (VSS = 0 V) Parameter Symbol Pins Ratings Unit V Supply voltage VDD -0.3 to 6.0 Input voltage VIN -0.3 to VDD + 0.3 V VOUT1 -0.3 to VDD + 0.3 V Output voltage Output current (Per 1 pin) Output current (Total) IOUT1 P0, P1, P4, P6, P7 ports -1.8 IOUT2 P0, P1, P2, P4, P6, P7 ports 3.2 IOUT3 P3, P5 ports 30 Σ IOUT1 P0, P1, P2, P4, P6, P7 ports 60 Σ IOUT2 P3, P5 ports 80 Power dissipation [Topr = 85 °C] PD 250 Soldering temperature (time) Tsld 260 (10 s) Storage temperature Tstg -55 to 125 Operating temperature Topr -40 to 85 Page 267 mA mW °C 22. Electrical Characteristics 22.1 Absolute Maximum Ratings TMP86FS49BUG 22.2 Operating Conditions The Operating Conditions shows the conditions under which the device be used in order for it to operate normally while maitaining its quality. If the device is used outside the range of Operating Conditions (power supply voltage, operating temperature range, or AC/DC rated values), it may operate erratically. Therefore, when designing your application equipment, always make sure its intended working conditions will not exceed the range of Operating Conditions. 22.2.1 MCU mode (Flash Programming or erasing) (VSS = 0 V, Topr = -10 to 40°C) Parameter Symbol Pins Ratings VDD Supply voltage Input high level Input low level Clock frequency NORMAL1, 2 modes VIH1 Except hysteresis input VIH2 Hysteresis input VIL1 Except hysteresis input VIL2 Hysteresis input fc VDD ≥ 4.5 V VDD ≥ 4.5 V XIN, XOUT Min Max 4.5 5.5 VDD × 0.70 Unit VDD VDD × 0.75 V VDD × 0.30 0 VDD × 0.25 1.0 16.0 MHz 22.2.2 MCU mode (Except Flash Programming or erasing) (VSS = 0 V, Topr = -40 to 85°C) Parameter Supply voltage Symbol Pins VDD Ratings fc = 16 MHz NORMAL1, 2 modes IDLE0, 1, 2 modes fc = 8 MHz NORMAL1, 2 modes IDLE0, 1, 2 modes fs = 32.768 KHz SLOW1, 2 modes SLEEP0, 1, 2 modes Min Max Unit 5.5 V 4.5 2.7 STOP mode Input high level VIH1 Except hysteresis input VIH2 Hysteresis input VDD < 4.5 V VIH3 Input low level VIL1 Except hysteresis input VIL2 Hysteresis input VDD ≥ 4.5 V VDD × 0.70 VDD × 0.75 fc XIN, XOUT fs XTIN, XTOUT VDD = 2.7 to 5.5V VDD = 4.5 to 5.5V VDD = 2.7 to 5.5V Page 268 VDD VDD × 0.90 VDD × 0.30 0 V VDD × 0.25 VDD × 0.10 VDD < 4.5 V VIL3 Clock frequency VDD ≥ 4.5 V 1.0 30.0 8.0 16.0 34.0 MHz kHz TMP86FS49BUG 22.2.3 Serial PROM mode (VSS = 0 V, Topr = -10 to 40 °C) Parameter Supply voltage Input high voltage Input low voltage Clock frequency Symbol Pins VDD VIH1 NORMAL1, 2 modes Except hysteresis input VIH2 Hysteresis input VIL1 Except hysteresis input VIL2 Hysteresis input fc Condition VDD ≥ 4.5 V VDD ≥ 4.5 V XIN, XOUT Min Max 4.5 5.5 VDD × 0.70 VDD × 0.75 0 2.0 Page 269 VDD Unit V VDD × 0.30 VDD × 0.25 16.0 MHz 22. Electrical Characteristics 22.1 Absolute Maximum Ratings TMP86FS49BUG 22.3 DC Characteristics (VSS = 0 V, Topr = -40 to 85 °C) Parameter Symbol Pins Condition Min Typ. Max Unit – 0.9 – V – – ±2 µA 100 220 450 kΩ VHS Hysteresis input IIN1 TEST IIN2 Sink open drain, tri–state port IIN3 RESET, STOP RIN2 RESET pull–up VDD = 5.5 V, VIN = 0 V ILO1 Sink open drain port VDD = 5.5 V, VOUT = 5.5 V – – 2 ILO2 Tri–state port VDD = 5.5 V, VOUT = 5.5 V/0 V – – ±2 Output high voltage VOH Tri–state port VDD = 4.5 V, IOH = -0.7 mA 4.1 – – Output low voltage VOL Except XOUT, P3, P5 VDD = 4.5 V, IOL = 1.6 mA – – 0.4 Output low curren IOL High current port (P3, P5 Port) VDD = 4.5 V, VOL = 1.0 V – 20 – – 9 16 Hysteresis voltage Input current Input resistance Output leakage current VDD = 5.5 V, VIN = VTEST = 5.5 V/0 V VDD = 5.5 V Supply current in NORMAL1, 2 modes VIN = 5.3 V/0.2 V VTEST = 5.3 V/0.1 V Supply current in IDLE 0, 1, 2 modes When a program operates on flash memory (Note5,6) fc = 16 MHz fs = 32.768 kHz Supply current in SLOW1 mode IDD VDD = 3.0 V VIN = 2.8 V/0.2 V VTEST = 2.8 V/0.1 V Supply current in SLEEP1 mode 6 8 When a program operates on flash memory (Note5,6) – 27 260 When a program operates on RAM – 10 15 – 6.5 13 – 6 12 – 0.5 10 – 10 – Supply current in SLEEP0 mode V mA mA – fs = 32.768 kHz µA µA VDD = 5.5 V Supply current in STOP mode VIN = 5.3 V/0.2 V VTEST = 5.3 V/0.1 V VDD = 5.5 V Peak current for SLOW1 mode (Note5,6) VIN = 5.3 V/0.2 V, VTEST = 5.3 V/0.1 V IDDP-P Topr = -10 to 40 °C mA VDD = 3.0 V VIN = 2.8 V/0.2 V, VTEST = 2.8 V/0.1 V – 2 – – 26 – Topr = -10 to 40 °C Write / Erase / Security program current for Flash memory (Note7,8) VDD = 5.5 V IDDEW VIN = 5.3 V/0.2 V, VTEST = 5.3 V/0.1 V mA Topr = -10 to 40 °C Note 1: Typical values show those at Topr = 25°C and VDD = 5 V. Note 2: Input current (IIN3): The current through pull-up resistor is not included. Note 3: IDD does not include IREF. Note 4: The supply currents of SLOW2 and SLEEP2 modes are equivalent to those of IDLE0, IDLE1 and IDLE2 modes. Note 5: When a program is executing in the flash memory or when data is being read from the flash memory, the flash memory operates in an intermittent manner, causing peak currents in the operation current, as shown in Figure 22-1. In this case, the supply current IDD (in NORMAL1, NORMAL2 and SLOW1 modes) is defined as the sum of the average peak current and MCU current. Note 6: When designing the power supply, make sure that peak currents can be supplied. The internal supply voltage of this device may be changed by this peak current. Thus, it needs a bypass capacitor (about 0.1µF ) near its power terminal to stabilize its operation. In SLOW1 mode, the difference between the peak current and the average current becomes large. Note 7: If a write or erase is performed on the flash memory or a security program is enabled in the flash memory, an instantaneous peak current flows, as shown in Figure 22-2. Page 270 TMP86FS49BUG Note 8: The circuit of a power supply must be designed such as to enable the supply of a peak current. This peak current causes the supply voltage in the device to fluctuate. Connect a bypass capacitor of about 0.1µF near the power supply of the device to stabilize its operation. Note 9: VIN is supply volage to the terminals except for TEST pin. VTEST: is supply voltage for TEST pin. Note 10:To execute the Program, Erase and Security Program commands on the flash memory, the temperature must be kept within Topr = -10 to 40 degree celsius. If this temperature range is not observed, operation cannot be guaranteed. 1 machine cycle (4/fc or 4/fs) n Program coutner (PC) n+1 n+2 n+3 Momentary flash current I DDP-P [mA] Max. current Typ. current Sum of average momentary flash current and MCU current MCU current Figure 22-1 Intermittent Operation of Flash Memory 1 machine cycle Program counter (PC) Internal data bus Internal write signal Last write cycle of each of the Byte Program, Security Program, Chip Erase and Sector Erase TBD, TSCE I DDEW [mA] Figure 22-2 Current When an Erase or Program is Being Performed on the Flash Memory Page 271 22. Electrical Characteristics 22.1 Absolute Maximum Ratings TMP86FS49BUG 22.4 AD Characteristics (VSS = 0.0 V, 4.5 V ≤ VDD ≤ 5.5 V, Topr = -40 to 85 °C) Paramete Symbol Analog reference voltage VAREF Power supply voltage of analog control circuit AVDD Condition Min Typ. Max AVDD - 1.0 – AVDD VDD V ∆ VAREF 3.5 – – Analog input voltage VAIN VSS – VAREF Power supply current of analog reference voltage IREF – 0.6 1.0 – – ±2 – – ±2 – – ±2 – – ±2 Analog reference voltage range (Note 4) VDD = AVDD = VAREF = 5.5 V VSS = 0.0 V Non linearity error VDD = AVDD = 5.0 V, Zero point error VSS = 0.0 V Full scale error VAREF = 5.0 V Total error Unit mA LSB (VSS = 0 V, 2.7 V ≤ VDD < 4.5 V, Topr = -40 to 85°C) Parameter Symbol Analog reference voltage VAREF Power supply voltage of analog control circuit AVDD Condition Min Typ. Max AVDD - 1.0 – AVDD VDD V ∆ VAREF 2.5 – – Analog input voltage VAIN VSS – VAREF Power supply current of analog reference voltage IREF – 0.5 0.8 – – ±2 – – ±2 – – ±2 – – ±2 Analog reference voltage range (Note 4) VDD = AVDD = VAREF = 4.5 V VSS = 0.0 V Non linearity error Zero point error Full scale error VDD = AVDD = 2.7 V VSS = 0.0 V VAREF = 2.7 V Total error Unit mA LSB Note 1: The total error includes all errors except a quanitization error, and is defined as a maximum deviation from the ideal conversion line. Note 2: Conversion time is defferent in recommended value by power supply voltage. Note 3: The voltage to be input on the AIN input pin must not exceed the range between VAREF and VSS. If a voltage outside this range is input, conversion values will become unstable and conversion values of other channels will also be affected. Note 4: Analog reference voltage range: ∆VAREF = VAREF - VSS Note 5: When AD converter is not used, fix the AVDD and VAREF pin on the VDD level. Page 272 TMP86FS49BUG 22.5 AC Characteristics (VSS = 0 V, 4.5 V ≤ VDD ≤ 5.5 V, Topr = -40 to 85°C) Parameter Symbol Condition Min Typ. Max 0.25 – 4 117.6 – 133.3 For external clock operation (XIN input) fc = 16 MHz – 31.25 – ns For external clock operation (XTIN input) fs = 32.768 kHz – 15.26 – µs NORMAL1, 2 modes Machine cycle time tcy IDLE0, 1, 2 modes µs SLOW1, 2 modes SLEEP0, 1, 2 modes High-level clock pulse width tWCH Low-level clock pulse width tWCL High-level clock pulse width tWSH Low-level clock pulse width tWSL Unit (VSS = 0 V, 2.7 V ≤ VDD < 4.5 V, Topr = -40 to 85°C) Paramete Symbol Condition Min Typ. Max 0.5 – 4 117.6 – 133.3 For external clock operation (XIN input) fc = 8 MHz – 62.5 – ns For external clock operation (XTIN input) fs = 32.768 kHz – 15.26 – µs NORMAL1, 2 modes tcy Machine cycle time IDLE0, 1, 2 modes SLOW1, 2 modes SLEEP0, 1, 2 modes High-level clock pulse width tWCH Low-level clock pulse width tWCL High-level clock pulse width tWSH Low-level clock pulse width tWSL Unit µs 22.6 Flash Characteristics 22.6.1 Write/Retention Characteristics (VSS = 0 V) Paramete Number of guaranteed writes to flash memory Condition VSS = 0 V, Topr = -10 to 40°C Page 273 Min Typ. Max. Unit – – 100 Times 22. Electrical Characteristics 22.8 Handling Precaution TMP86FS49BUG 22.7 Recommended Oscillating Conditions XIN XOUT XTIN C2 C1 (1) High-frequency Oscillation XTOUT C1 C2 (2) Low-frequency Oscillation Note 1: To ensure stable oscillation, the resonator position, load capacitance, etc. must be appropriate. Because these factors are greatly affected by board patterns, please be sure to evaluate operation on the board on which the device will actually be mounted. Note 2: The product numbers and specifications of the resonators by Murata Manufacturing Co., Ltd. are subject to change. For up-to-date information, please refer to the following URL: http://www.murata.com/ 22.8 Handling Precaution - The solderability test conditions for lead-free products (indicated by the suffix G in product name) are shown below. 1. When using the Sn-37Pb solder bath Solder bath temperature = 230 °C Dipping time = 5 seconds Number of times = once R-type flux used 2. When using the Sn-3.0Ag-0.5Cu solder bath Solder bath temperature = 245 °C Dipping time = 5 seconds Number of times = once R-type flux used Note: The pass criteron of the above test is as follows: Solderability rate until forming ≥ 95 % - When using the device (oscillator) in places exposed to high electric fields such as cathode-ray tubes, we recommend electrically shielding the package in order to maintain normal operating condition. Page 274 TMP86FS49BUG 23. Package Dimensions LQFP64-P-1010-0.50D Rev 01 Unit: mm Page 275 23. Package Dimensions TMP86FS49BUG Page 276 This is a technical document that describes the operating functions and electrical specifications of the 8-bit microcontroller series TLCS-870/C (LSI). Toshiba provides a variety of development tools and basic software to enable efficient software development. These development tools have specifications that support advances in microcomputer hardware (LSI) and can be used extensively. Both the hardware and software are supported continuously with version updates. The recent advances in CMOS LSI production technology have been phenomenal and microcomputer systems for LSI design are constantly being improved. The products described in this document may also be revised in the future. Be sure to check the latest specifications before using. Toshiba is developing highly integrated, high-performance microcomputers using advanced MOS production technology and especially well proven CMOS technology. We are prepared to meet the requests for custom packaging for a variety of application areas. We are confident that our products can satisfy your application needs now and in the future.
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