To all our customers Regarding the change of names mentioned in the document, such as Mitsubishi Electric and Mitsubishi XX, to Renesas Technology Corp. The semiconductor operations of Hitachi and Mitsubishi Electric were transferred to Renesas Technology Corporation on April 1st 2003. These operations include microcomputer, logic, analog and discrete devices, and memory chips other than DRAMs (flash memory, SRAMs etc.) Accordingly, although Mitsubishi Electric, Mitsubishi Electric Corporation, Mitsubishi Semiconductors, and other Mitsubishi brand names are mentioned in the document, these names have in fact all been changed to Renesas Technology Corp. Thank you for your understanding. Except for our corporate trademark, logo and corporate statement, no changes whatsoever have been made to the contents of the document, and these changes do not constitute any alteration to the contents of the document itself. Note : Mitsubishi Electric will continue the business operations of high frequency & optical devices and power devices. Renesas Technology Corp. Customer Support Dept. April 1, 2003 I MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a u fin s ot a its are is n m This etric li : e m ic Not e para Som P IM REL 16-BIT CMOS MICROCOMPUTER DESCRIPTION These are single-chip 16-bit microcomputers designed with high-performance CMOS silicon gate technology, being packaged in 64-pin plastic molded QFP or shrink plastic molded SDIP. These microcomputers support the 7900 Series instruction set, which are enhanced and expanded instruction set and are upper-compatible with the 7700/7751 Series instruction set. The CPU of these microcomputers is a 16-bit parallel processor that can also be switched to perform 8-bit parallel processing. Also, the bus interface unit of these microcomputers enhances the memory access efficiency to execute instructions fast. Therefore, these microcomputers are suitable for office, business, and industrial equipment controller that require high-speed processing of large data. Also, they are suitable for motor-control equipment since each of them includes the motor control circuit. • • • • • • • • • [M37905M8C-XXXFP, M37905M8C-XXXSP] ROM .............................................................................. 60 Kbytes RAM ............................................................................. 3072 bytes Instruction execution time The fastest instruction at 20 MHz frequency ........................ 50 ns Single power supply .................................................... 5 V ± 0.5 V Interrupts ........... 8 external sources, 23 internal sources, 7 levels Multi-functional 16-bit timer ................................................. 10 + 3 (Three-phase motor drive waveform and Pulse motor drive waveform output are available.) Serial I/O (UART or Clock synchronous) ..................................... 3 10-bit A-D converter .......................................... 12-channel inputs 8-bit D-A converter ............................................ 2-channel outputs 12-bit watchdog timer Programmable input/output (ports P1, P2, P4, P5, P6, P7, P8) .. 50 DISTINCTIVE FEATURES APPLICATION • • Control devices for office equipment such as copiers and facsimiles Control devices for industrial equipment such as communication and measuring instruments Control devices for equipment, requiring motor control, such as inverter air conditioners and general-purpose inverters Number of basic machine instructions .................................... 203 Memory [M37905M4C-XXXFP, M37905M4C-XXXSP] ROM .............................................................................. 32 Kbytes RAM ............................................................................. 1024 bytes [M37905M6C-XXXFP, M37905M6C-XXXSP] ROM .............................................................................. 48 Kbytes RAM ............................................................................. 3072 bytes 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 P13/TxD0 P14/CTS1/RTS1 P15/CTS1/CLK1 P16/RxD1 P17/TxD1 P20/TA4OUT P21/TA4IN P22/TA9OUT P23/TA9IN P24(/TB0IN) P25(/TB1IN) Note P26(/TB2IN) P27 MD1 P40/TA5OUT/RTP20 P41/TA5IN/RTP21 M37905MxC-XXXFP PIN CONFIGURATION (TOP VIEW) M37905MXC-XXXFP 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 P42/TA6OUT/RTP22 P43/TA6IN/RTP23 P44/TA7OUT/RTP30 P45/TA7IN/RTP31 P46/TA8OUT/RTP32 P47/TA8IN/RTP33 P4OUTCUT/INT0 P51/INT1 P52/INT2/RTPTRG1 P53/INT3/RTPTRG0 VSS VCONT XOUT XIN RESET MD0 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 Outline 64P6N-A Note P73/AN3 P72/AN2 P71/AN1 P70/AN0 P67/TA3IN/RTP13 P66/TA3OUT/RTP12 P65/TA2IN/U/RTP11 P64/TA2OUT/V/RTP10 P63/TA1IN/W/RTP03 P62/TA1OUT/U/RTP02 P61/TA0IN/V/RTP01 P60/TA0OUT/W/RTP00 P57/INT7/TB2IN/IDU P56/INT6/TB1IN/IDV P55/INT5/TB0IN/IDW P6OUTCUT/INT4 P12/RXD0 P11/CTS0/CLK0 P10/CTS0/RTS0 VCC AVCC VREF AVSS VSS P83/AN11/TXD2 P82/AN10/RXD2 P81/AN9/CTS2/CLK2 P80/AN8/CTS2/RTS2/DA1 P77/AN7/DA0 P76/AN6 P75/AN5 P74/AN4 Note : Allocation of pins TB0IN to TB2IN can be switched by software. MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER M37905MxC-XXXSP PIN CONFIGURATION (TOP VIEW) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 M37905MXC-XXXSP P83/AN11/TxD2 P82/AN10/RxD2 P81/AN9/CTS2/CLK2 P80/AN8/CTS2/RTS2/DA1 P77/AN7/DA0 P76/AN6 P75/AN5 P74/AN4 P73/AN3 P72/AN2 P71/AN1 P70/AN0 P67/TA3IN/RTP13 P66/TA3OUT/RTP12 P65/TA2IN/U/RTP11 P64/TA2OUT/V/RTP10 P63/TA1IN/W/RTP03 P62/TA1OUT/U/RTP02 P61/TA0IN/V/RTP01 P60/TA0OUT/W/RTP00 P57/INT7/TB2IN/IDU Note P56/INT6/TB1IN/IDV P55/INT5/TB0IN/IDW P6OUTCUT/INT4 MD0 RESET XIN XOUT VCONT VSS P53/INT3/RTPTRG0 P52/INT2/RTPTRG1 Outline 64P4B 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 VSS AVSS VREF AVCC VCC P10/CTS0/RTS0 P11/CTS0/CLK0 P12/RxD0 P13/TxD0 P14/CTS1/RTS1 P15/CTS1/CLK1 P16/RxD1 P17/TxD1 P20/TA4OUT P21/TA4IN P22/TA9OUT P23/TA9IN P24(/TB0IN) Note P25(/TB1IN) P26(/TB2IN) P27 MD1 P40/TA5OUT/RTP20 P41/TA5IN/RTP21 P42/TA6OUT/RTP22 P43/TA6IN/RTP23 P44/TA7OUT/RTP30 P45/TA7IN/RTP31 P46/TA8OUT/RTP32 P47/TA8IN/RTP33 P4OUTCUT/INT0 P51/INT1 Note : Allocation of pins TB0IN to TB2IN can be switched by software. Outline 64P4B 2 MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Data Bus (Even) Data Bus (Odd) Data Buffer DQ0 (8) P6OUTCUT Data Buffer DQ1 (8) Data Buffer DQ2 (8) Address Bus P4OUTCUT Data Buffer DQ3 (8) Instruction Queue Buffer Q0 (8) Instruction Queue Buffer Q1 (8) Instruction Queue Buffer Q2 (8) Reference Voltage Input VREF Instruction Queue Buffer Q3 (8) Instruction Queue Buffer Q4 (8) Instruction Queue Buffer Q5 (8) MD0 Arithmetic Logic Unit (16) Input/Output P1 P1(8) A-D Converter (12) Input/Output P4 P4(8) Timer TB0 (16) Timer TA5 (16) RAM 1 Kbyte 3 Kbytes 3 Kbytes ROM 32 Kbytes 48 Kbytes 60 Kbytes M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Note: Input/Output P5 Input/Output P6 P5(6) P6(8) Input/Output P7 Accumulator A (16) Input/Output P8 Accumulator B (16) P7(8) Clock Generating Circuit Index Register X (16) P8(4) Stack Pointer S (16) Index Register Y (16) VCONT Timer TA0 (16) Timer TB2 (16) Direct Page Register DPR3 (16) RAM (Note) Reset input RESET Direct Page Register DPR2 (16) ROM (Note) Direct Page Register DPR1 (16) Clock output XOUT Timer TB1 (16) Timer TA2 (16) VCC Direct Page Register DPR0 (16) Central Processing Unit (CPU) Input Buffer Register IB (16) Processor Status Register PS (11) Clock input XIN Timer TA6 (16) Timer TA7 (16) Timer TA3 (16) (0V) VSS Data Bank Register DT (8) Timer TA1 (16) Watchdog Timer Timer TA9 (16) Timer TA8 (16) Timer TA4 (16) Program Counter PC (16) Program Bank Register PG (8) BLOCK DIAGRAM Input/Output P2 Incrementer/Decrementer (24) P2(8) UART2 (9) Data Address Register DA (24) UART1 (9) MD1 Program Address Register PA (24) Bus Interface Unit (BIU) Incrementer (24) UART0 (9) Instruction Queue Buffer Q9 (8) D-A0 Converter (8) D-A1 Converter (8) Instruction Queue Buffer Q7 (8) Instruction Queue Buffer Q8 (8) (0V) AVSS AVCC Instruction Register (8) Instruction Queue Buffer Q6 (8) 3 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER FUNCTIONS Parameter Number of basic machine instructions 203 Functions Instruction execution time 50 ns (the fastest instruction at f(fsys) = 20 MHz) External clock input frequency f(XIN) 20 MHz (Max.) System clock frequency f(fsys) 20 MHz (Max.) ROM (Note 1) RAM (Note 1) Programmable input/output P1, P2, P4, P6, P7 8-bit ✕ 5 ports P5 6-bit ✕ 1 P8 4-bit ✕ 1 TA0–TA9 16-bit ✕ 10 TB0–TB2 16-bit ✕ 3 UART0, UART1, and UART2 (UART or Clock synchronous serial I/O) ✕ 3 Memory size Multi-functional timers Serial I/O A-D converter 10-bit successive approximation method ✕ 1 (12 channels) D-A converter 8-bit ✕ 2 Dead-time timer 8-bit ✕ 3 12-bit ✕ 1 Watchdog timer Interrupts Maskable interrups 8 external sources, 20 internal sources. Each interrupt can be set to a priority level within the range of 0–7 by software. Non-maskable interrups 3 internal sources Clock generating circuit Incorporated (externally connected to a ceramic resonator or quartz-crystal resonator). PLL frequency multiplier The following multiplication ratios are available: ✕2, ✕3, ✕4. Power supply voltage 5 V±0.5 V Power dissipation 125 mW (at f(fsys) = 20 MHz, Typ, ; the PLL frequency multiplier is inactive.) Ports’ input/output nput/Output withstand voltage 5V characteristics Memory expansion utput current 5 mA Not available (single-chip mode only). Operating ambient temperature range –20 to 85 °C Device structure CMOS high-performance silicon gate process Package (Note 2) Notes 1: ROM RAM 2: 4 Packages M37905M4C-XXXFP, M37905M4C-XXXSP 32 Kbytes M37905M6C-XXXFP, M37905M6C-XXXSP 48 Kbytes M37905M8C-XXXFP, M37905M8C-XXXSP M37905M4C-XXXFP, M37905M4C-XXXSP 60 Kbytes M37905M6C-XXXFP, M37905M6C-XXXSP 3072 bytes M37905M8C-XXXFP, M37905M8C-XXXSP 3072 bytes M37905M4C-XXXFP, M37905M6C-XXXFP, M37905M8C-XXXFP M37905M4C-XXXSP, M37905M6C-XXXSP, M37905M8C-XXXSP 1024 bytes 64-pin plastic molded QFP (64P6N-A) 64-pin shrink plastic moldeds DIP (64P4B) MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR 16-BIT CMOS MICROCOMPUTER PIN DESCRIPTION Pin Name Input/ Output — Functions Apply 5 V±0.5 V to Vcc, and 0 V to Vss. Vcc, Vss Power supply input MD0 MD0 Input Connect this pin to VSS. MD1 MD1 Input Connect this pin to Vss. RESET Reset input Input The microcomputer is reset when “L” level is applies to this pin. XIN Clock input Input XOUT Clock output These are input and output pins of the internal clock generating circuit. Connect a ceramic resonator or quartz-crystal oscillator between pins XIN and XOUT. When an external clock is used, the clock source should be connected to pin XIN, and pin XOUT should be left open. VCONT Filter circuit connection — When using the PLL frequency multiplier, connect this pin to the filter circuit. When not using the PLL frequency multiplier, this pin should be left open. AVcc, AVss Analog power supply input — Power supply input pins for the A-D and D-A converters. Connect AVcc to Vcc, and AVss to Vss externally. VREF Reference voltage input P10–P17 I/O port P1 I/O Port P1 is an 8-bit I/O port. This port has an I/O direction register, and each pin can be programmed for input or output. These pins enter the input mode ar reset. These pins also function as I/O pins of UART0, 1. P20–P27 I/O port P2 I/O In addition to having the same functions as port P1, these pins function as I/O pins for timers A4 and A9. Also, they can be programmed to function as input pins for timers B0 to B2. P40–P47 I/O port P4 I/O In addition to having the same functions as port P1, these pins function as I/O pins for timers A5 to A8. Also, they function as output pins for motor drive waveform. P51–P53, P55–P57 I/O port P5 I/O In addition to having the same functions as port P1, these pins function as input pins for INT1 to INT3 and INT5 to INT7. Also, pins P55 to P57 function as input pins for timers B0 to B2 and as input pins for position data in the three-phase waveform mode; and pins P52 and P53 function as trigger-input pins in the pulse output port mode. P60–P67 I/O port P6 I/O In addition to having the same functions as port P1, these pins function as I/O pins for timers A0 to A3. Also, they function as motor drive waveform output pins. P70–P77 I/O port P7 I/O In addition to having the same functions as port P1, these pins function as input pins for the A-D converter. Also, P77 functions as an output pin for the D-A converter. P80–P83 I/O port P8 I/O In addition to having the same functions as port P1, these pins function as input pins for the A-D converter. Also, these pins function as I/O pins for UART2,and pin P80 functions as an output pin for the D-A converter. P4OUTCUT P4OUTCUT input Input This pin has the function to forcibly place port P4 pins in the input mode. Also, this pin functions as an input pin for INT0; and this pin is used to input a signal, which forcibly cuts off a motor drive waveform output. P6OUTCUT P6OUTCUT input Input This pin has the function to forcibly place port P6 pins in the input mode. Also, this pin functions as an input pin for INT4; and this pin is used to input a signal, which forcibly cuts off a motor drive waveform output. Output Input This is the reference voltage input pin for the A-D and D-A converters. 5 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER BASIC FUNCTION BLOCKS These microcomputers contain the following devices in the single chip: ROM, RAM, CPU, bus interface unit, and peripheral devices such as the interrupt control circuit, timers, serial I/O, A-D converter, D-A converter, I/O ports, clock generating circuit, etc. MEMORY Figures 1 (1) through (3) show the memory maps. The address space is 64 Kbytes from addresses 016 through FFFF16. This ad- 00000016 00000016 0000FF16 00010016 000BFF16 000C0016 dress space is called “bank 016”. The internal ROM and RAM are allocated as shown in Figures 1 (1) through (3). Addresses FFB416 through FFFF16 contain the RESET and the interrupt vector addresses, and the interrupt vectors are stored there. For details, refer to the section on interrupts. Allocated to addresses 016 through FF16 are peripheral devices such as I/O ports, A-D converter, D-A converter, serial I/O, timers, interrupt control registers, etc. Figures 2 and 3 show the location of SFRs. Peripheral devices' control registers Internal RAM 1024 bytes 000FFF16 00100016 007FFF16 00800016 Peripheral devices' control registers (See Figures 2 and 3.) Unused area Bank 016 00FFFF16 00000016 0000FF16 Interrupt vector table Unused area 00FFB416 Internal ROM 32 Kbytes UART2 transmit UART2 receive Timer A9 Timer A8 Timer A7 Timer A6 Timer A5 INT7 INT6 INT5 Reserved area Address matching detect Reserved area Reserved area 00FFB416 INT4 INT3 A-D conversion UART1 transmit UART1 receive UART0 transmit UART0 receive Timer B2 Timer B1 Timer B0 Timer A4 Timer A3 Timer A2 Timer A1 Timer A0 00FFFF16 INT2 INT1 INT0 Received area Watchdog timer 00FFFE16 Fig. 1 (1) Memory map of M37905M4C-XXXFP/SP (Single-chip mode) 6 DBC BRK instruction Zero divide RESET MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR 00000016 MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER 00000016 0000FF16 00010016 0003FF16 00040016 Peripheral devices' control registers 00000016 Peripheral devices' control registers (See Figures 2 and 3.) Unused area Bank 016 0000FF16 Internal RAM 3072 bytes 00FFFF16 000FFF16 00100016 003FFF16 00400016 Interrupt vector table Unused area 00FFB416 Internal ROM 48 Kbytes UART2 transmit UART2 receive Timer A9 Timer A8 Timer A7 Timer A6 Timer A5 INT7 INT6 INT5 Reserved area Address matching detect Reserved area Reserved area 00FFB416 INT4 INT3 A-D conversion UART1 transmit UART1 receive UART0 transmit UART0 receive Timer B2 Timer B1 Timer B0 Timer A4 Timer A3 Timer A2 Timer A1 Timer A0 00FFFF16 INT2 INT1 INT0 Reserved area Watchdog timer 00FFFE16 DBC BRK instruction Zero divide RESET Fig. 1 (2) Memory map of M37905M6C-XXXFP/SP (Single-chip mode) 7 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 00000016 MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER 00000016 0000FF16 00010016 0003FF16 00040016 Peripheral devices' control registers 00000016 Peripheral devices' control registers (See Figures 2 and 3.) Unused area Bank 016 0000FF16 Internal RAM 3072 bytes 00FFFF16 000FFF16 00100016 Interrupt vector table 00FFB416 Internal ROM 60 Kbytes UART2 transmit UART2 receive Timer A9 Timer A8 Timer A7 Timer A6 Timer A5 INT7 INT6 INT5 Reserved area Address matching detect Reserved area Reserved area 00FFB416 INT4 INT3 A-D conversion UART1 transmit UART1 receive UART0 transmit UART0 receive Timer B2 Timer B1 Timer B0 Timer A4 Timer A3 Timer A2 Timer A1 Timer A0 00FFFF16 INT2 INT1 INT0 Reserved area Watchdog timer 00FFFE16 Fig. 1 (3) Memory map of M37905M8C-XXXFP/SP (Single-chip mode) 8 DBC BRK instruction Zero divide RESET MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Address (Hexadecimel notation) 00000016 00000116 00000216 00000316 00000416 00000516 00000616 00000716 00000816 00000916 00000A16 00000B16 00000C16 00000D16 00000E16 00000F16 00001016 00001116 00001216 00001316 00001416 00001516 00001616 00001716 00001816 00001916 00001A16 00001B16 00001C16 00001D16 00001E16 00001F16 00002016 00002116 00002216 00002316 00002416 00002516 00002616 00002716 00002816 00002916 00002A16 00002B16 00002C16 00002D16 00002E16 00002F16 00003016 00003116 00003216 00003316 00003416 00003516 00003616 00003716 00003816 00003916 00003A16 00003B16 00003C16 00003D16 00003E16 00003F16 Reserved area (Note) Reserved area (Note) Reserved area (Note) Port P1 register Reserved area (Note) Port P1 direction register Port P2 register Reserved area (Note) Port P2 direction register Reserved area (Note) Port P4 register Port P5 register Port P4 direction register Port P5 direction register Port P6 register Port P7 register Port P6 direction register Port P7 direction register Port P8 register Port P8 direction register Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) A-D control register 0 A-D control register 1 A-D register 0 A-D register 1 A-D register 2 A-D register 3 A-D register 4 A-D register 5 A-D register 6 A-D register 7 UART0 transmit/receive mode register UART0 band rate register (BRG0) UART0 transmit buffer register UART0 transmit/receive control register 0 UART0 transmit/receive control register 1 UART0 receive buffer register UART1 transmit/receive mode register UART1 baud rate register (BRG1) UART1 transmit buffer register UART1 transmit/receive control register 0 UART1 transmit/receive control register 1 UART1 receive buffer register 16-BIT CMOS MICROCOMPUTER Address (Hexadecimel notation) 00004016 00004116 00004216 00004316 00004416 00004516 00004616 00004716 00004816 00004916 00004A16 00004B16 00004C16 00004D16 00004E16 00004F16 00005016 00005116 00005216 00005316 00005416 00005516 00005616 00005716 00005816 00005916 00005A16 00005B16 00005C16 00005D16 00005E16 00005F16 00006016 00006116 00006216 00006316 00006416 00006516 00006616 00006716 00006816 00006916 00006A16 00006B16 00006C16 00006D16 00006E16 00006F16 00007016 00007116 00007216 00007316 00007416 00007516 00007616 00007716 00007816 00007916 00007A16 00007B16 00007C16 00007D16 00007E16 00007F16 Count start register 0 Count start register 1 One-shot start register 0 One-shot start register 1 Up-down register 0 Timer A clock division select register Timer A0 register Timer A1 register Timer A2 register Timer A3 register Timer A4 register Timer B0 register Timer B1 register Timer B2 register Timer A0 mode register Timer A1 mode register Timer A2 mode register Timer A3 mode register Timer A4 mode register Timer B0 mode register Timer B1 mode register Timer B2 mode register Processor mode register 0 Processor mode register 1 Watchdog timer register Watchdog timer frequency select register Particular function select register 0 Particular function select register 1 Particular function select register 2 Reserved area (Note) Debug control register 0 Debug control register 1 Address comparison register 0 Address comparison register 1 INT3 interrupt control register INT4 interrupt control register A-D conversion interrupt control register UART0 transmit interrupt control register UART0 receive interrupt control register UART1 transmit interrupt control register UART1 receive interrupt control register Timer A0 interrupt control register Timer A1 interrupt control register Timer A2 interrupt control register Timer A3 interrupt control register Timer A4 interrupt control register Timer B0 interrupt control register Timer B1 interrupt control register Timer B2 interrupt control register INT0 interrupt control register INT1 interrupt control register INT2 interrupt control register Note: Do not write to this address. Fig. 2 Location of SFRs (1) 9 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Address (Hexadecimel notation) 00008016 00008116 00008216 00008316 00008416 00008516 00008616 00008716 00008816 00008916 00008A16 00008B16 00008C16 00008D16 00008E16 00008F16 00009016 00009116 00009216 00009316 00009416 00009516 00009616 00009716 00009816 00009916 00009A16 00009B16 00009C16 00009D16 00009E16 00009F16 0000A016 0000A116 0000A216 0000A316 0000A416 0000A516 0000A616 0000A716 0000A816 0000A916 0000AA16 0000AB16 0000AC16 0000AD16 0000AE16 0000AF16 0000B016 0000B116 0000B216 0000B316 0000B416 0000B516 0000B616 0000B716 0000B816 0000B916 0000BA16 0000BB16 0000BC16 0000BD16 0000BE16 0000BF16 Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) External interrupt input read-out register D-A control register D-A register 0 D-A register 1 Pulse output control register Pulse output data register 0 Pulse output data register 1 Waveform output mode register Dead-time timer Three-phase output data register 0 Three-phase output data register 1 Position-data-retain function control register Serial I/O pin control register Port P2 pin function control register UART2 transmit/receive mode register UART2 band rate register (BRG2) UART2 transmit buffer register UART2 transmit/receive control register 0 UART2 transmit/receive control register 1 UART2 receive buffer register Reserved area (Note) Reserved area (Note) Reserved area (Note) Clock control register 0 Reserved area (Note) Reserved area (Note) Reserved area (Note) Note: Do not write to this address. Fig. 3 Location of SFRs (2) 10 16-BIT CMOS MICROCOMPUTER Address (Hexadecimel notation) 0000C016 0000C116 0000C216 0000C316 0000C416 0000C516 0000C616 0000C716 0000C816 0000C916 0000CA16 0000CB16 0000CC16 0000CD16 0000CE16 0000CF16 0000D016 0000D116 0000D216 0000D316 0000D416 0000D516 0000D616 0000D716 0000D816 0000D916 0000DA16 0000DB16 0000DC16 0000DD16 0000DE16 0000DF16 0000E016 0000E116 0000E216 0000E316 0000E416 0000E516 0000E616 0000E716 0000E816 0000E916 0000EA16 0000EB16 0000EC16 0000ED16 0000EE16 0000EF16 0000F016 0000F116 0000F216 0000F316 0000F416 0000F516 0000F616 0000F716 0000F816 0000F916 0000FA16 0000FB16 0000FC16 0000FD16 0000FE16 0000FF16 Up-down register 1 Timer A5 register Timer A6 register Timer A7 register Timer A8 register Timer A9 register Timer A01 register Timer A11 register Timer A21 register Timer A5 mode register Timer A6 mode register Timer A7 mode register Timer A8 mode register Timer A9 mode register A-D control register 2 Comparator function select register 0 Comparator function select register 1 Comparator result register 0 Comparator result register 1 A-D register 8 A-D register 9 A-D register 10 A-D register 11 Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) Reserved area (Note) UART2 transmit interrupt control register UART2 receive interrupt control register Timer A5 interrupt control register Timer A6 interrupt control register Timer A7 interrupt control register Timer A8 interrupt control register Timer A9 interrupt control register INT5 interrupt control register INT6 interrupt control register INT7 interrupt control register MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR 16-BIT CMOS MICROCOMPUTER CENTRAL PROCESSING UNIT (CPU) INDEX REGISTER X (X) The CPU has 13 registers and is shown in Figure 4. Each of these registers is described below. Index register X consists of 16 bits and the low-order 8 bits can be used separately. Index register length flag x determines whether the register is used as 16-bit register or as 8-bit register. It is used as a 16-bit register when flag x is “0” and as an 8-bit register when flag x is “1”. Flag x is a part of the processor status register (PS) which is described later. In index addressing modes in which register X is used as the index register, the contents of this address are added to obtain the real address. Index register X functions as a pointer register which indicates an address of data table in instructions MVP, MVN, RMPA (Repeat MultiPly and Accumulate). ACCUMULATOR A (A) Accumulator A is the main register of the microcomputer. It consists of 16 bits and the low-order 8 bits can be used separately. Data length flag m determines whether the register is used as 16-bit register or as 8-bit register. It is used as a 16-bit register when flag m is “0” and as an 8-bit register when flag m is “1”. Flag m is a part of the processor status register (PS) which is described later. Data operations such as calculations, data transfer, input/output, etc., are executed mainly through accumulator A. INDEX REGISTER Y (Y) ACCUMULATOR B (B) Accumulator B has the same functions as accumulator A, but the use of accumulator B requires more instruction bytes and execution cycles than accumulator A. ACCUMULATOR E Accumulator E is a 32-bit register and consists of accumulator A (low-order 16 bits) and accumulator B (high-order 16 bits). It is used for 32-bit data processing. Accumulator B 15 Accumulator A 7 BH Index register Y consists of 16 bits and the low-order 8 bits can be used separately. The index register length flag x determines whether the register is used as 16-bit register or as 8-bit register. It is used as a 16-bit register when flag x is “0” and as an 8-bit register when flag x is “1”. Flag x is a part of the processor status register (PS) which is described later. In index addressing modes in which register Y is used as the index register, the contents of this address are added to obtain the real address. Index register Y functions as a pointer register which indicates an address of data table in instructions MVP, MVN, RMPA (Repeat MultiPly and Accumulate). 0 15 BL 7 AH 0 AL 31 0 Accumulator E 15 7 AH 15 0 AL 7 BH 15 0 BL 0 7 XH 15 XL Index register X 7 YH 0 YL Index register Y 15 7 0 PG 7 Stack pointer S S Program bank register PG 15 0 Program counter PC PC 0 DT 0 Data bank register DT 15 15 0 0 0 0 0 0 DPR0 to DPR3 7 IPL2 IPL1 IPL0 N V m x D I Direct page registers DPR0 to DPR3 0 Z C Processor status register PS Carry flag Zero flag Interrupt disable flag Decimal mode flag Index register length flag Data length flag Overflow flag Negative flag Processor interrupt priority level IPL Fig. 4 Register structure 11 MITSUBISHI MICROCOMPUTERS MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER STACK POINTER (S) PROCESSOR STATUS REGISTER (PS) Stack pointer (S) is a 16-bit register. It is used during a subroutine call or interrupts. It is also used during stack, stack pointer relative, or stack pointer relative indirect indexed Y addressing mode. Processor status register (PS) is an 11-bit register. It consists of flags to indicate the result of operation and CPU interrupt levels. Branch operations can be performed by testing the flags C, Z, V, and N. The details of each bit of the processor status register are described below. PROGRAM COUNTER (PC) Program counter (PC) is a 16-bit counter that indicates the low-order 16 bits of the next program memory address to be executed. There is a bus interface unit between the program memory and the CPU, so that the program memory is accessed through bus interface unit. This is described later. PROGRAM BANK REGISTER (PG) Program bank register is an 8-bit register that indicates the high-order 8 bits of the next program memory address to be executed. When a carry occurs by incrementing the contents of the program counter, the contents of the program bank register (PG) is increased by 1. Also, when a carry or borrow occurs after adding or subtracting the offset value to or from the contents of the program counter (PC) using the branch instruction, the contents of the program bank register (PG) is increased or decreased by 1, so that programs can be written without worrying about bank boundaries. DATA BANK REGISTER (DT) Data bank register (DT) is an 8-bit register. With some addressing modes, the data bank register (DT) is used to specify a part of the memory address. The contents of data bank register (DT) is used as the high-order 8 bits of a 24-bit address. Addressing modes that use the data bank register (DT) are direct indirect, direct indexed X indirect, direct indirect indexed Y, absolute, absolute bit, absolute indexed X, absolute indexed Y, absolute bit relative, and stack pointer relative indirect indexed Y. DIRECT PAGE REGISTERS 0 through 3 (DPR0 through DPR3) The direct page register is a 16-bit register. An addressing mode of which name includes ‘direct’ generates an address of data to be accessed, regarding the contents of this register as the base address. The 7900 Series has been expanded direct page registers up to 4 (DPR0 to DPR3), in comparison to the 7700 Series which has the single direct page register. Accordingly, the 7900 Series’s direct addressing method which uses direct page registers differs from that of the 7700 Series. However, the conventional direct addressing method, using only DPR0, is still be selectable, in order to make use of the 7700 Series software property. For more details, refer to the section on the direct page. 12 1. Carry flag (C) The carry flag contains the carry or borrow generated by the ALU after an arithmetic operation. This flag is also affected by shift and rotate instructions. This flag can be set and reset directly with the SEC and CLC instructions or with the SEP and CLP instructions. 2. Zero flag (Z) The zero flag is set if the result of an arithmetic operation or data transfer is zero and reset if it is not. This flag can be set and reset directly with the SEP and CLP instructions. 3. Interrupt disable flag (I) When the interrupt disable flag is set to “1”, all interrupts except watchdog timer and software interrupts are disabled. This flag is set to “1” automatically when an interrupt is accepted. It can be set and reset directly with the SEI and CLI instructions or SEP and CLP instructions. 4. Decimal mode flag (D) The decimal mode flag determines whether addition and subtraction are performed as binary or decimal. Binary arithmetic is performed when this flag is “0”. If it is “1”, decimal arithmetic is performed with each word treated as 2- or 4- digit decimal. Arithmetic operation is performed using four digits when data length flag m is “0” and with two digits when it is “1”. Decimal adjust is automatically performed. (Decimal operation is possible only with the ADC and SBC instructions.) This flag can be set and reset with the SEP and CLP instructions. MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER 5. Index register length flag (x) The index register length flag determines whether index register X and index register Y are used as 16-bit registers or as 8-bit registers. The registers are used as 16-bit registers when flag x is “0” and as 8bit registers when it is “1”. This flag can be set and reset with the SEP and CLP instructions. 6. Data length flag (m) The data length flag determines whether the data length is 16-bit or 8-bit. The data length is 16 bits when flag m is “0” and 8 bits when it is “1”. This flag can be set and reset with the SEM and CLM instructions or with the SEP and CLP instructions. 7. Overflow flag (V) The overflow flag is valid when addition or subtraction is performed with a word treated as a signed binary number. If data length flag m is “0”, the overflow flag is set when the result of addition or subtraction is outside the range between –32768 and +32767. If data length flag m is “1”, the overflow flag is set when the result of addition or subtraction is outside the range between –128 and +127. It is reset in all other cases. The overflow flag can also be set and reset directly with the SEP, and CLV or CLP instructions. Additionally, the overflow flag is set when a result of unsigned/signed division exceeds the length of the register where the result is to be stored; the flag is also set when the addition result is outside range of –2147483648 to +2147483647 in the RMPA operation. 8. Negative flag (N) The negative flag is set when the result of arithmetic operation or data transfer is negative (If data length flag m is “0”, data’s bit 15 is “1”. If data length flag m is “1”, data’s bit 7 is “1”.) It is reset in all other cases. It can also be set and reset with the SEP and CLP instructions. 9. Processor interrupt priority level (IPL) The processor interrupt priority level (IPL) consists of 3 bits and determines the priority of processor interrupts from level 0 to level 7. Interrupt is enabled when the interrupt priority of the device requesting interrupt (set using the interrupt control register) is higher than the processor interrupt priority. When an interrupt is enabled, the current processor interrupt priority level is saved in a stack and the processor interrupt priority level is replaced by the interrupt priority level of the device requesting the interrupt. Refer to the section on interrupts for more details. Note: Fix bits 11 to 15 of the processor status register (PS) to “0”. 13 MITSUBISHI MICROCOMPUTERS MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP BANK In order to effectively use the integrated hardware on the chip, this CPU core uses an address generating method with a 24-bit address split into high-order 8 bits and low-order 16 bits. In other words, the 64 Kbytes specified by the low-order 16 bits are one unit (referred to as “bank”), and the address space is divided into 256 banks (016 to FF16) specified by the high-order 8 bits. In the program area on the address space, the bank is specified by the program bank register (PG), and the address in the bank is specified by the program counter (PC). As for each bank boundary, when an overflow has occurred in PC, the contents of PG are incremented by 1. When a borrow has occurred in PC, the contents of PG are decremented by 1. Under the normal conditions, therefore, programming without concern for the bank boundaries is possible. Furthermore, as for the data area on the address space, the bank is specified by the data bank register (DT), and the address in the bank is specified by the operation result by using the various addressing modes (Note). Note: Some addressing modes directly specify a bank. DIRECT PAGE The internal memory and control registers for internal peripheral devices, etc. are assigned to bank 016 (addresses 016 to FFFF16). The direct page and direct addressing modes have been provided for the effective access to bank 016. In the 7900 Series, two types of direct addressing modes are available: the conventional direct addressing mode which uses only DPR0, as in the 7700 Series, and the expanded direct addressing mode, which uses up to 4 direct page registers as selected by the user. The addressing mode is selected according to the contents of bit 1 of the processor mode register 1. This bit 1 is cleared to “0” at reset. (In other words, the conventional direct addressing mode is selected.) However, once this bit 1 has been set to “1” by software, this bit cannot be cleared to “0” again, except by reset. That is to say, when one of these two direct addressing modes has been selected just after reset, the selected addressing mode cannot be switched to another one while the program is running. ■ Conventional direct addressing mode The direct page area consists of 256-byte space. Its bank address is “0016”, and the base address of its low-order 16-bit address is specified by the contents of the direct page register 0 (DPR0). In this conventional direct addressing modes, a value (1 byte) just after an instruction code is regarded as an offset value for the DPR0 contents, and the CPU accesses each address in the direct page area. ■ Expanded direct addressing mode The direct page area consists of four 64-byte spaces. Their bank address is “0016”, and the four base addresses of their low-order 16bit addresses are respectively specified by the contents of four direct page registers. In this expanded direct addressing mode, a value (1 byte) just after an instruction code is regarded as follows: • High-order 2 bits: regarded as a selection field for DPR0 to DPR3. • Low-order 6 bits: regarded as an offset value for the selected direct page register. Then, the CPU accesses each address in each direct page area: 14 16-BIT CMOS MICROCOMPUTER Refer to “7900 Series Software Manual” for details concerning the various addressing modes which use the direct page area. Instruction Set The CPU core of the 7900 Series has an expanded instruction set based on the existing 7700/7751 Series’ CPU core. In addition, its source code (mnemonic) has the complete upper compatibility with the 7700 Series instruction set. For details concerning addressing modes and instruction set, refer to “7900 Series Software Manual”. MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER BUS INTERFACE UNIT Data transfer between the central processing unit (CPU) and internal memory, internal peripheral devices is always performed via the bus interface unit (BIU), which is located between the CPU and the internal buses. Figure 5 shows the BIU and the bus structure. The CPU and BIU are connected by a dedicated bus, and any transfer between the CPU and BIU is controlled by this dedicated bus. On the other hand, data transfer between the BIU and internal pe- ripheral devices uses the following internal common buses: 32-bit code bus, 16-bit data bus, 24-bit address bus, and control signals. The bus control method where the code bus and the data bus separate out (hereafter, this method is referred to as the separate code/ data bus method) is employed in order to improve data transfer capabilities. As a result, the internal memory is connected to both the code bus and the data bus, and registers of all other internal peripheral devices are connected only to the data bus. M37905 Internal buses CPU bus Central Processing Unit (CPU) Internal code bus (CB0 to CB31) Bus Interface Unit (BIU) Internal data bus (DB0 to DB15) Internal address bus (AD0 to AD23) Internal memory Internal control signal Internal peripheral devices (SFR) SFR : Special Function Register ❈ The CPU bus and internal bus separate out independently. Fig. 5 BIU and bus structure 15 MITSUBISHI MICROCOMPUTERS MI ELI Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER BIU structure The BIU consists of four registers shown in Figure 6. Table 1 lists the functions of each register. Table 1. Functions of each register Name Program address register Functions Indicates a storage address for an instruction to be next taken into an instruction queue buffer. Instruction queue buffer Temporarily stores an instruction which has been taken from a memory. Consists of 10 bytes. Data address register Indicates an address where data will be next read from or written to. Data buffer Temporarily stores data which has been read from internal memory or internal peripheral devices by the BIU; or temporarily stores data which is to be written to internal memory or internal peripheral devices by the CPU. Consists of 32 bits. b23 b0 PA Program address register b7 b0 Q0 Instruction queue buffer Q9 b23 b0 Data address register DA b31 b0 DQ Fig. 6 Register structure of BIU 16 Data buffer MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP BIU Functions (1) Instruction prefetch The BIU has ten instruction queue buffers; each buffer consists of 1 byte. When there is an opening in the bus and the instruction queue buffer, an instruction code is read from the program memory (in other words, the memory where a program is stored) and prefetched into an instruction queue buffer. The prefetched instruction code is transferred from the BIU to the CPU, in response to a request from the CPU, via a dedicated bus. When a branch occurs as a result of a branch instruction (JMP, BRA, etc.), subroutine call, or interrupt, the contents of the instruction queue buffer are initialized and the BIU reads a new instruction from the branch destination address. Note that the operations of the BIU instruction prefetch also differ depending on the store addresses for instructions. The store addresses for instructions to be prefetched are categorized as listed in Table 2. (2) Data read operation When executing an instruction for reading data from the internal memory or internal peripheral devices, at first, the CPU informs the BIU’s data address register of the address where the data has been located. Next, the BIU reads the above data from the specified address, passes it to the data buffer, and then, transfers it to the CPU. 16-BIT CMOS MICROCOMPUTER Table 2. Store addresses for instructions to be prefetched Low-order 3 bits of store address for instruction AD2 (A2) AD1 (A1) AD0 (A0) X X 0 Even address 4-byte boundary 0 0 X 8-byte boundary 0 0 0 X: 0 or 1 Figures 7 and 8 show the bus cycle waveform examples for instruction prefetch and data access. Access to internal area When branched or at instruction prefetch φBIU Internal address bus Address Internal code bus CB0 to CB31 Code (3) Data write operation When executing an instruction for writing data into the internal memory or internal peripheral devices, at first, the CPU informs the BIU’s data address register of the address where the data has been located. Next, the BIU passes the above data to the data buffer register, and then, writes it into the specified address. Fig. 7 Bus cycle waveform example for instruction prefetch (4) Bus cycle In order for the BIU to execute the above operations (1) through (3), the 24-bit address bus, 32-bit code bus, 16-bit data bus and internal control signals must be appropriately controlled during data transfer between the BIU and internal memory or internal peripheral devices. This operation is called “bus cycle”. The bus cycle is affected by the lengh of data to be transferred (byte, word, or double-word) at data access. 17 MITSUBISHI MICROCOMPUTERS MI ELI Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER Access starting from even address Access starting from odd address φBIU 8-bit data read Internal address bus φBIU Address Internal data bus Internal address bus D0 to D7 DB0 to DB7 φBIU 8-bit data written Internal address bus Internal address bus D0 to D7 DB0 to DB7 DB0 to DB7 DB8 to DB15 DB8 to DB15 Access to internal area Internal address bus D0 to D7 Internal data bus DB0 to DB7 DB8 to DB15 D8 to D15 DB0 to DB7 DB8 to DB15 φ1 16-bit data written A0 to A23 D0 to D7 D0 to D7 D8 to D15 D8 to D15 D8 to D15 φBIU 32-bit data read Internal data bus DB0 to DB7 DB8 to DB15 32-bit data written DB0 to DB7 DB8 to DB15 Internal address bus Address + 2 D0 to D7 D0 to D7 Internal data bus D8 to D15 D8 to D15 DB0 to DB7 DB8 to DB15 D0 to D7 D0 to D7 Internal address bus Internal data bus Invalid D0 to D7 D8 to D15 Invalid Address Address + 1 D0 to D7 D8 to D15 D8 to D15 D8 to D15 Address Address + 1 Address + 3 Invalid D0 to D7 D0 to D7 D8 to D15 D8 to D15 Invalid φBIU Address Address + 2 Address DB8 to DB15 Address + 1 D0 to D7 DB0 to DB7 Fig. 8 Bus cycle waveform example for data access (access to internal area) 18 Address + 1 φBIU Address φBIU Internal address bus Internal data bus Address φ1 Address D0 to D7 Internal address bus D8 to D15 φBIU Address Internal data bus A0 to A23 Address Internal data bus φBIU 16-bit data read D8 to D15 φBIU Address Internal data bus Internal address bus Invalid DB0 to DB7 DB8 to DB15 Invalid DB8 to DB15 Address Internal data bus D8 to D15 D8 to D15 Address + 3 D0 to D7 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR 16-BIT CMOS MICROCOMPUTER ● Number of bus cycles Figure 9 shows the bus cycle waveform at access to the internal area. Bit 7 of the processor mode register 1 (address 5F16), which is shown in Figure 10, selects the number of bus cycles for the internal ROM: 3φ or 2φ. (This bit 7 is the internal ROM bus cycle select bit.) The internal RAM, SFRs (internal peripheral devices’ control registers) are always accessed with 1 bus cycle = 2φ. 1 bus cycle = 3φ (Note) 1 bus cycle = 2φ (Internal ROM bus cycle select bit = 0) (Internal ROM bus cycle select bit = 1) 1 bus cycle = 2φ 1 bus cycle = 3φ φBIU ROM φBIU Internal address bus Internal address bus Address Internal data bus, Internal code bus Internal data bus Internal code bus Data Address Data 1 bus cycle = 2φ RAM φBIU Internal address bus SFR Internal data bus, Internal code bus Address Data Note: When reprogramming the internal flash memory in the CPU reprogramming mode, select the bus cycle = 3φ. Fig. 9 Bus cycle waveform at access to internal area 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 Processor mode register 1 Address 5F16 Fix these bits to “00000002”. Internal ROM bus cycle select bit 0 : 1 bus cycle = 3φ 1 : 1 bus cycle = 2φ Fig. 10 Bit configuration of processor mode register 1 19 MITSUBISHI MICROCOMPUTERS MI ELI Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER PROCESSOR MODES This microcomputer is dedicated to the single-chip mode. Therefore, be sure to connect pin MD0 to Vss, and be sure to fix the processor mode bits (bits 1 and 0 of the processor mode register 0, address 5E16), which is shown in Figure 11, to “002”. 7 0 6 5 4 3 2 1 0 0 0 0 0 Processor mode register 0 Address 5E16 Processor mode bits 0 0 : Single-chip mode 0 1 : Do not select. 1 0 : Do not select. 1 1 : Do not select. Fix these bits to “002”. Interrupt priority detection time select bits 0 0 : 7 cycles of fsys 0 1 : 4 cycles of fsys 1 0 : 2 cycles of fsys 1 1 : Do not select. Software reset bit By a write of “1” to this bit, the microcomputer will be reset, and then, restarted. Fix this bit to “0”. Fig. 11 Bit configuration of processor mode register 0 20 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP INTERRUPTS Table 3 shows the interrupt sources and the corresponding interrupt vector addresses. Reset is also handled as an interrupt source in this section, too. DBC and BRK instruction are interrupts used only for debugging. Therefore, do not use these interrupts. Interrupts other than reset, watchdog timer, zero divide, and address matching detection all have interrupt control registers. Table 4 shows the addresses of the interrupt control registers and Figure 13 shows the bit configuration of the interrupt control register. The interrupt request bit is automatically cleared by the hardware during reset or when processing an interrupt. Also, interrupt request bits except for that of a watchdog timer interrupt can be cleared by software. An INTi (i = 0 to 7) interrupt request is generated by an external input. INTi is an external interrupt; whether to cause an interrupt at the input level (level sense) or at the edge (edge sense) can be selected with the level/edge select bit. Furthermore, the polarity of the interrupt input can be selected with the polarity select bit. When using the following pins as external interrupt input pins, be sure to clear the direction registers of the corresponding multiplexed ports to “0”: pins P51/INT1, P52/INT2, P53/INT3, P55/INT5, P56/INT6, and P57/INT7. When the external interrupt input read register (address 9516), which is shown in Figure 12, is read out, the status of pins INT0 through INT7 can directly be read. Timer and UART interrupts are described in the respective section. The priority of interrupts when multiple interrupt requests are caused simultaneously is partially fixed by hardware, but, it can also be adjusted by software as shown in Figure 14. The hardware priority is fixed as the following: reset > watchdog timer > other interrupts 16-BIT CMOS MICROCOMPUTER Table 3. Interrupt sources and interrupt vector addresses Interrupts Vector addresses UART2 transmit 00FFB416 00FFB516 UART2 receive 00FFB616 00FFB716 Timer A9 00FFB816 00FFB916 Timer A8 00FFBA16 00FFBB16 Timer A7 00FFBC16 00FFBD16 Timer A6 00FFBE16 00FFBF16 Timer A5 00FFC016 00FFC116 INT7 external interrupt 00FFC216 00FFC316 INT6 external interrupt 00FFC416 00FFC516 INT5 external interrupt 00FFC616 00FFC716 Address matching detection interrupt 00FFCA16 00FFCB16 INT4 external interrupt 00FFD016 00FFD116 INT3 external interrupt 00FFD216 00FFD316 A-D conversion 00FFD416 00FFD516 UART1 transmit 00FFD616 00FFD716 UART1 receive 00FFD816 00FFD916 UART0 transmit 00FFDA16 00FFDB16 UART0 receive 00FFDC16 00FFDD16 Timer B2 00FFDE16 00FFDF16 Timer B1 00FFE016 00FFE116 Timer B0 00FFE216 00FFE316 Timer A4 00FFE416 00FFE516 Timer A3 00FFE616 00FFE716 Timer A2 00FFE816 00FFE916 Timer A1 00FFEA16 00FFEB16 Timer A0 00FFEC16 00FFED16 INT2 external interrupt 00FFEE16 00FFEF16 INT1 external interrupt 00FFF016 00FFF116 INT0 external interrupt 00FFF216 00FFF316 Watchdog timer 00FFF616 00FFF716 DBC (Do not select.) 00FFF816 00FFF916 Break instruction (Do not select.) 00FFFA16 00FFFB16 Zero divide 00FFFC16 00FFFD16 Reset 00FFFE16 00FFFF16 7 6 5 4 3 2 1 0 External interrupt input read register Address 9516 INT0 read bit INT1 read bit INT2 read bit INT3 read bit INT4 read bit INT5 read bit INT6 read bit INT7 read bit Fig. 12 Bit configuration of external interrupt input read register 21 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 7 6 5 4 16-BIT CMOS MICROCOMPUTER 3 2 1 0 Interrupt priority level select bits (Note 1) Interrupt request bit 0 : No interrupt requested 1 : Interrupt requested Interrupt control register bit configuration for A-D converter, UART0, UART1, UART2, timer A0 to timer A9, and timer B0 to timer B2. 7 6 5 4 3 2 1 0 Interrupt priority level select bits (Note 1) Interrupt request bit (Note 2) 0 : No interrupt requested 1 : Interrupt requested Polarity select bit 0 : Interrupt request bit is set to “1” at “H” level when level sense is selected; this bit is set to “1” at falling edge when edge sense is selected. 1 : Interrupt request bit is set to “1” at “L” level when level sense is selected; this bit is set to “1” at rising edge when edge sense is selected. Level/Edge select bit 0 : Edge sense 1 : Level sense Interrupt control register bit configuration for INT0– INT7 Notes 1: Use the MOVM (MOVMB) instruction or the STA (STAB, STAD) instruction for writing to this bit. 2: Interrupt request bits of INT0 to INT7 are invalid when the level sense is selected. Fig. 13 Bit configuration of interrupt control register 22 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Addresses 00006E16 00006F16 00007016 00007116 00007216 00007316 00007416 00007516 00007616 00007716 00007816 00007916 00007A16 00007B16 00007C16 00007D16 00007E16 00007F16 0000F116 0000F216 0000F516 0000F616 0000F716 0000F816 0000F916 0000FD16 0000FE16 0000FF16 Interrupts caused by the address matching detection and when dividing by zero are software interrupts and are not included in Figure 14. Other interrupts previously mentioned are A-D converter, UART, etc. interrupts. The priority of these interrupts can be changed by changing the priority level in the corresponding interrupt control register by software. Figure 15 shows a diagram of the interrupt priority detection circuit. When an interrupt is caused, each interrupt device compares its own priority with the priority from above and if its own priority is higher, then it sends the priority below and requests the interrupt. If the priorities are the same, the one above has priority. This comparison is repeated to select the interrupt with the highest priority among the interrupts that are being requested. Finally the selected interrupt is compared with the processor interrupt priority level (IPL) contained in the processor status register (PS) and the request is accepted if it is higher than IPL and the interrupt disable flag I is “0”. The request is not accepted if flag I is “1”. The reset and watchdog timer interrupts are not affected by the interrupt disable flag I. When an interrupt is accepted, the contents of the processor status register (PS) is saved to the stack and the interrupt disable flag I is set to “1”. Furthermore, the interrupt request bit of the accepted interrupt is cleared to “0” and the processor interrupt priority level (IPL) in the Priority is determined by hardware Table 4. Addresses of interrupt control registers Interrupt control registers INT3 interrupt control register INT4 interrupt control register A-D interrupt control register UART0 transmit interrupt control register UART0 receive interrupt control register UART1 transmit interrupt control register UART1 receive interrupt control register Timer A0 interrupt control register Timer A1 interrupt control register Timer A2 interrupt control register Timer A3 interrupt control register Timer A4 interrupt control register Timer B0 interrupt control register Timer B1 interrupt control register Timer B2 interrupt control register INT0 interrupt control register INT1 interrupt control register INT2 interrupt control register UART2 transmit interrupt control register UART2 receive interrupt control register Timer A5 interrupt control register Timer A6 interrupt control register Timer A7 receive control register Timer A8 interrupt control register Timer A9 interrupt control register INT5 interrupt control register INT6 interrupt control register INT7 interrupt control register MITSUBISHI MICROCOMPUTERS ➂ ➁ ➀ Watchdog timer Reset A-D converter, UART, etc. interrupts Priority can be changed by software inside ➂. Fig. 14 Interrupt priority Level 0 UART2 transmit UART2 receive Timer A9 Timer A8 Timer A7 Timer A6 Timer A5 INT7 INT6 INT5 I N T4 INT3 A-D UART1 transmit UART1 receive UART0 transmit Interrupt request UART0 receive Timer B2 Timer B1 Reset Timer B0 Timer A4 Timer A3 Watchdog timer Timer A2 Timer A1 Timer A0 I N T2 Interrupt disable flag I I N T1 IPL I N T0 Fig. 15 Interrupt priority detection 23 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER processor status register (PS) is replaced by the priority level of the accepted interrupt. Therefore, multi-level priority interrupts are possible by resetting the interrupt disable flag I to “0” and enable further interrupts. For reset, watchdog timer, zero divide, and address match detection interrupts, which do not have an interrupt control register, the processor interrupt level (IPL) is set as shown in Table 5. The interrupt request bit and the interrupt priority level of each interrupt source are sampled and latched at each operation code fetch cycle while fsys is “H”. However, no sampling pulse is generated until the cycles whose number is selected by software has passed, even if the next operation code fetch cycle is generated. The detection of an interrupt which has the highest priority is performed during that time. As shown in Figure 16, there are three different interrupt priority detection time from which one is selected by software. After the selected time has elapsed, the highest priority is determined and is processed after the currently executing instruction has been completed. The time is selected with bits 4 and 5 of the processor mode register 0 (address 5E16) shown in Figure 11. Table 6 shows the relationship between these bits and the number of cycles. After a reset, the processor mode register 0 is initialized to “0016.” Therefore, the longest time is automatically set, however, the shortest time must be selected by software. Table 5. Value loaded in processor interrupt level (IPL) during an interrupt Interrupt types Reset Watchdog timer Zero divide Address matching detection Table 6. Relationship between interrupt priority detection time select bit and number of cycles Priority detection time select bit Bit 5 Bit 4 0 0 0 1 1 0 Operation code fetch cycle (Note) b5 b4 Priority detection time Select one between 00 to 10 with bits 4 and 5 of processor mode register 0 00 01 10 Note: This pulse resides when 2 cycles of fsys is selected. Fig. 16 Interrupt priority detection time 24 Number of cycles (Note) 7 cycles of f sys 4 cycles of f sys 2 cycles of f sys Note: For system clock fsys, refer to the section on the clock generating circuit. fsys Sampling pulse Setting value 0 7 Not change value of IPL. Not change value of IPL. MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 7 6 5 16-BIT CMOS MICROCOMPUTER 4 3 2 1 0 Port P2 pin function control register Address AE16 Pin TB0IN select bit 0: Allocate pin TB0IN to P55. 1: Allocate pin TB0IN to P24. Pin TB1IN select bit 0: Allocate pin TB1IN to P56. 1: Allocate pin TB1IN to P25. Pin TB2IN select bit 0: Allocate pin TB2IN to P57. 1: Allocate pin TB2IN to P26. Fig. 17 Bit configuration of port P2 pin function control register 25 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER TIMER (1) Timer mode [00] There are eight 16-bit timers. They are divided by type into timer A (10) and timer B (3). The timer I/O pins are multiplexed with I/O pins for ports P2, P4, P5 and P6. To use these pins as timer input pins, the port direction register bit corresponding to the pin must be cleared to “0” to specify input mode. Figure 20 shows the bit configuration of the timer Ai mode register in the timer mode. Bits 0, 1 and 5 of the timer Ai mode register must be “0” in timer mode. The timer A’s count source is selected by bits 6 and 7 of the timer Ai mode register and the contents of the timer A clock division select register. (See Table 7.) The counting of the selected clock starts when the count start bit is “1” and stops when it is “0”. Figure 21 shows the bit configuration of the count start bit. The counter is decremented, an interrupt is caused and the interrupt request bit in the timer Ai interrupt control register is set when the contents becomes 000016. At the same time, the contents of the reload register is transferred to the counter and count is continued. TIMER A Figure 18 shows a block diagram of timer A. Timer A has four modes: timer mode, event counter mode, one-shot pulse mode, and pulse width modulation mode. The mode is selected with bits 0 and 1 of the timer Ai mode register (i = 0 to 9). Each of these modes is described below. Figure 19 shows the bit configuration of the timer A clock division select register. Timers A0 to A9 use the count source which has been selected by bits 0 and 1 of this register. Timer A clock division select bit f2 Count source select bits f1 f16 f64 Data bus (odd) f512 Data bus (even) f4096 (Low-order 8 bits) • Timer • One-shot pulse • Pulse width (High-order 8 bits) Reload register(16) Timer (gate function) Counter (16) Polarity selection Event counter Count start registers 0, 1 TAiIN (i = 0–9) (Addresses 4016, 4116) External trigger Countdown Up-down registers 0, 1 (Addresses 4416, C416) Pulse output Toggle flip-flop TAiOUT (i = 0–9) Fig. 18 Block diagram of timer A 26 Countup/Countdown switching “Countdown” is always selected when not in the event counter mode. Addresses Addresses Timer A0 Timer A1 Timer A2 Timer A3 Timer A4 4716 4916 4B16 4D16 4F16 4616 4816 4A16 4C16 4E16 Timer A5 Timer A6 Timer A7 Timer A8 Timer A9 C716 C916 CB16 CD16 CF16 C616 C816 CA16 CC16 CE16 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER When bit 2 of the timer Ai mode register is “1”, the output is generated from TAiOUT pin. The output is toggled each time the contents of the counter reaches to 000016. When the contents of the count start bit is “0”, “L” is output from TAiOUT pin. When bit 2 is “0”, TAiOUT can be used as a normal port pin. When bit 4 is “0”, TAiIN can be used as a normal port pin. When bit 4 is “1”, counting is performed only while the input signal from the TAiIN pin is “H” or “L” as shown in Figure 22. Therefore, this can be used to measure the pulse width of the TAiIN input signal. Whether to count while the input signal is “H” or while it is “L” is determined by bit 3. If bit 3 is “1”, counting is performed while the TAiIN pin input signal is “H” and if bit 3 is “0”, counting is performed while it is “L”. Note that, the duration of “H” or “L” on the TAiIN pin must be 2 or more cycles of the timer count source. When data is written to timer Ai register with timer Ai halted, the same data is also written to the reload register and the counter. When data is written to timer Ai which is busy, the data is written to the reload register, but not to the counter. The new data is reloaded from the reload register to the counter at the next reload time and counting continues. The contents of the counter can be read at any time. When the value set in the timer Ai register is n, the timer frequency division ratio is 1/(n+1). 7 6 5 0 4 3 2 1 0 0 0 7 6 5 4 3 2 1 0 Timer A clock division select register Address 4516 Timer A clock division select bit (See Table 7.) Fig. 19 Bit configuration of timer A clock division select register Table 7. Relationship between timer A clock division select bits, clock source select bits, and count source Clock source select bits (bits 7 and 6 at addresses 5616 to 5A16) (bits 7 and 6 at addresses D616 to DA16) 00 01 10 11 Timer A clock division select bits (bits 1 and 0 at address 4516) 00 f2 f16 f64 f512 01 f1 f16 f64 f4096 10 f1 f64 f512 f4096 11 Do not select. Note: Timers A0 to A9 use the same clock, which is selected by the timer A clock division select bits. Timer A0 mode register Timer A1 mode register Timer A2 mode register Timer A3 mode register Timer A4 mode register Addresses 5616 5716 5816 5916 5A16 Timer A5 mode register Timer A6 mode register Timer A7 mode register Timer A8 mode register Timer A9 mode register Addresses D616 D716 D816 D916 DA16 0 0 : Always “00” in timer mode 0 : No pulse output (TAiOUT is normal port pin.) 1 : Pulse output (TAiOUT is pulse output pin.) 0 × : No gate function (TAiIN is normal port pin.) 1 0 : Count only while TAiIN input is “L”. 1 1 : Count only while TAiIN input is “H”. 0 : Always “0” in timer mode. Clock source select bits See Table 7. Fig. 20 Bit configuration of timer Ai mode register in timer mode 27 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 7 6 5 4 3 2 1 16-BIT CMOS MICROCOMPUTER 0 7 Count start register 0 Address (Stopped at “0”, Started at “1”) 4016 Timer A8 count start bit Timer A4 count start bit Timer A9 count start bit Timer mode register 1 Fig. 22 Count waveform when gate function is available 28 Count start register 1 Address (Stopped at “0”, Started at “1”) 4116 Timer A7 count start bit Timer mode register 1 0 Timer A3 count start bit TAiIN Bit 3 1 Timer A2 count start bit Selected clock source fi Bit 4 2 Timer A6 count start bit Fig. 21 Bit configuration of count start register 0 3 Timer A5 count start bit Timer B2 count start bit 1 4 Timer A1 count start bit Timer B1 count start bit Bit 3 5 Timer A0 count start bit Timer B0 count start bit Bit 4 6 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER (2) Event counter mode [01] count) or FFFF16 (increment count), the waveform’s polarity is reversed and is output from TAiOUT pin. If bit 2 is “0”, TAiOUT pin can be used as a normal port pin. However, if bit 4 is “1” and the TAiOUT pin is used as an output pin, the output from the pin changes the count direction. Therefore, bit 4 must be “0” unless the output from the TAiOUT pin is to be used to select the count direction. Data write and data read are performed in the same way as for timer mode. That is, when data is written to timer Ai halted, it is also written to the reload register and the counter. When data is written to timer Ai which is busy, the data is written to the reload register, but not to the counter. The counter is reloaded with new data from the reload register at the next reload time. The counter can be read at any time. In event counter mode, whether to increment or decrement the counter can also be determined by supplying two kinds of pulses of which phases differ by 90° to timer A2, A3, A4, A7, A8 or A9. There are two types of two-phase pulse processing operations. One uses timers A2, A3, A7, and A8 and the other uses timers A4 and A9. In both processing operations, two pulses described above are input to the TAjOUT (j = 2 to 4, 7 to 9) pin and TAjIN pin respectively. When timers A2, A3, A7, and A8 are used, as shown in Figure 25, the count is incremented when a rising edge is input to the TAkIN (k=2, 3, 7, 8) pin after the level of TAkOUT pin changes from “L” to “H”, and when the falling edge is input, the count is decremented. For timers A4 and A9, as shown in Figure 26, when a phase-related pulse with a rising edge input to the TAlIN (l = 4, 9) pin is input after the level of TAlOUT pin changes from “L” to “H”, the count is incremented at the respective rising edge and falling edge of the TAlOUT pin and TAlIN pin. Figure 23 shows the bit configuration of the timer Ai mode register in the event counter mode. In event counter mode, bit 0 of the timer Ai mode register must be “1” and bits 1 and 5 must be “0”. The input signal from the TAiIN pin is counted when the count start bit shown in Figure 21 is “1” and counting is stopped when it is “0”. Count is performed at the fall of the input signal when bit 3 is “0” and at the rise of the signal when it is “1”. In event counter mode, whether to increment or decrement the count can be selected with the up-down bit or the input signal from the TAiOUT pin. When bit 4 of the timer Ai mode register is “0”, the up-down bit is used to determine whether to increment or decrement the count (decrement when the bit is “0” and increment when it is “1”). Figure 24 shows the bit configuration of the up-down register. When bit 4 of the timer Ai mode register is “1”, the input signal from the TAiOUT pin is used to determine whether to increment or decrement the count. However, note that bit 2 must be “0” if bit 4 is “1”. It is because if bit 2 is “1”, TAiOUT pin becomes an output pin to output pulses. The count is decremented when the input signal from the TAiOUT pin is “L” and incremented when it is “H”. Determine the level of the input signal from the TAiOUT pin before a valid edge is input to the TAiIN pin. An interrupt request signal is generated and the interrupt request bit in the timer Ai interrupt control register is set when the counter reaches 000016 (decrement count) or FFFF16 (increment count). At the same time, the contents of the reload register is transferred to the counter and the count is continued. When bit 2 is “1”, each time the counter reaches 000016 (decrement 7 × 6 × 5 0 4 3 2 1 0 0 1 Timer A0 mode register Timer A1 mode register Timer A2 mode register Timer A3 mode register Timer A4 mode register Addresses 5616 5716 5816 5916 5A16 Timer A5 mode register Timer A6 mode register Timer A7 mode register Timer A8 mode register Timer A9 mode register Addresses D616 D716 D816 D916 DA16 0 1 : Always “01” in event counter mode 0 : No pulse output 1 : Pulse output 0 : Count at the falling edge of input signal 1 : Count at the rising edge of input signal 0 : Increment or decrement according to up/down bit 1 : Increment or decrement according to TAiOUT pin input signal level 0 : Always “0” in event counter mode × × : Not used in event counter mode Fig. 23 Bit configuration of timer Ai mode register in event counter mode 29 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 7 6 5 4 3 2 1 16-BIT CMOS MICROCOMPUTER 0 Up-down register 0 Address 4416 7 6 5 4 3 2 1 0 Address C416 Up-down register 1 Timer A0 up-down bit Timer A5 up-down bit Timer A1 up-down bit Timer A6 up-down bit Timer A2 up-down bit Timer A7 up-down bit Timer A3 up-down bit Timer A8 up-down bit Timer A4 up-down bit Timer A9 up-down bit Timer A2 two-phase pulse signal processing select bit 0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing mode Timer A7 two-phase pulse signal processing select bit 0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing mode Timer A3 two-phase pulse signal processing select bit 0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing mode Timer A8 two-phase pulse signal processing select bit 0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing mode Timer A4 two-phase pulse signal processing select bit 0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing mode Timer A9 two-phase pulse signal processing select bit 0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing mode Fig. 24 Bit configuration of up-down register TAkOUT TAkIN (k = 2, 3, 7, 8) Incrementcount Incrementcount Incrementcount Decrementcount Decrementcount Decrementcount Fig. 25 Two-phase pulse processing operation of timer A2, A3, A7, A8 TAlOUT Increment-count at each edge Increment-count at each edge Decrement-count at each edge TAlIN (l = 4, 9) When a phase-related pulse with a falling edge input to the TAkOUT pin is input after the level of TAlIN pin changes from “H” to “L”, the count is decremented at the respective rising edge and falling edge of the TAlIN pin and TAlOUT pin. When performing this two-phase pulse signal processing, bits 0 and 4 of timer Aj mode register must be set to “1” and bits 1, 2, 3, and 5 must be “0”. Bits 6 and 7 are ignored. (See Figure 27.) Note that bits 5, 6, and 7 of the up-down register 0 (address 4416) are the two-phase pulse signal processing select bits for timers A2, A3, and A4, respectively. Also, bits 5, 6, and 7 of the up-down register 1 (address C416) are the two-phase pulse signal processing select bits for timers A7, A8, and A9, respectively. Each timer operates in normal event counter mode when the corresponding bit is “0” and performs two-phase pulse signal processing when it is “1”. Count is started by setting the count start bit to “1”. Data write and read are performed in the same way as for normal event counter mode. Note that the direction register of the input port must be set to input mode because two kinds of pulse signals, described above, are input. Also, there can be no pulse output in this mode. Decrement-count at each edge Fig. 26 Two-phase pulse processing operation of timers A4 and A9 7 × 6 × 5 0 4 1 3 0 2 0 1 0 0 1 Addresses 5816 Timer A2 mode register 5916 Timer A3 mode register 5A16 Timer A4 mode register C816 Timer A7 mode register C916 Timer A8 mode register CA16 Timer A9 mode register 0 1 : Always “01” in event counter mode 0 1 0 0 : Always “0100” when processing two-phase pulse signal × × : Not used in event counter mode Fig. 27 Bit configuration of timer Aj mode register when performing two-phase pulse signal processing in event counter mode 30 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER (3) One-shot pulse mode [10] The output pulse width is Figure 28 shows the bit configuration of the timer Ai mode register in the one-shot pulse mode. In one-shot pulse mode, bit 0 and bit 5 must be “0” and bit 1 and bit 2 must be “1”. The trigger is enabled when the count start bit is “1”. The trigger can be generated by software or it can be input from the TAiIN pin. Software trigger is selected when bit 4 is “0” and the input signal from the TAiIN pin is used as the trigger when it is “1“. Bit 3 is used to determine whether to trigger at the fall of the trigger signal or at the rise. The trigger is at the fall of the trigger signal when bit 3 is “0” and at the rise of the trigger signal when it is “1”. Software trigger is generated by setting “1” to a bit in the one-shot start register. Each bit corresponds to each timer. Figure 29 shows the bit configuration of the one-shot start register. As shown in Figure 30, when a trigger signal is received, the counter counts the clock selected by bits 6 and 7 and the contents of the timer A clock division select register. (Set Table 7.) If the contents of the counter is not 000016, the TAiOUT pin goes “H” when a trigger signal is received. The count direction is decrement. When the counter reaches 000116, the TAiOUT pin goes “L” and count is stopped. The contents of the reload register is transferred to the counter. At the same time, an interrupt request signal is generated and the interrupt request bit in the timer Ai interrupt control register is set. This is repeated each time a trigger signal is received. 7 6 5 0 4 3 2 1 1 1 0 0 1 pulse frequency of the selected clock × (counter’s value at the time of trigger). If the count start flag is “0”, TAiOUT goes “L”. Therefore, the value corresponding to the desired pulse width must be written to timer Ai before setting the timer Ai count start bit. As shown in Figure 31, a trigger signal can be received before the operation for the previous trigger signal is completed. In this case, the contents of the reload register is transferred to the counter by the trigger and then that value is decremented. Except when retriggering while operating, the contents of the reload register are not transferred to the counter by triggering. When retriggering, there must be at least one timer count source cycle before a new trigger can be issued. Data write is performed in the same way as for timer mode. When data is written in timer Ai halted, it is also written to the reload register and the counter. When data is written to timer Ai which is busy, the data is written to the reload register, but not to the counter. The counter is reloaded with new data from the reload register at the next reload time. Undefined data is read when timer Ai is read. Timer A0 mode register Timer A1 mode register Timer A2 mode register Timer A3 mode register Timer A4 mode register Address 5616 5716 5816 5916 5A16 Timer A5 mode register Timer A6 mode register Timer A7 mode register Timer A8 mode register Timer A9 mode register Address D616 D716 D816 D916 DA16 1 0 : Always “10” in one-shot pulse mode 1 : Always “1” in one-shot pulse mode 0 × : Software trigger 1 0 : Trigger at the falling edge of TAiIN input 1 1 : Trigger at the rising edge of TAiIN input 0 : Always “0” in one-shot pulse mode Clock source select bits (See Table 7.) Fig. 28 Bit configuration of timer Ai mode register in one-shot pulse mode 31 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 7 6 0 5 4 3 2 1 16-BIT CMOS MICROCOMPUTER 0 One-shot start register 0 Address 4216 7 6 0 5 4 Timer A0 one-shot start bit Timer A1 one-shot start bit Timer A2 one-shot start bit Timer A3 one-shot start bit Timer A4 one-shot start bit Fix this bit to “0”. Fig. 29 Bit configuration of one-shot start register Selected clock source fi TAiIN (rising edge) TAiOUT Example when the contents of the reload register is 000316 Fig. 30 Pulse output example when external rising edge is selected Selected clock source fi TAiIN (rising edge) TAiOUT Example when the contents of the reload register is 000416 Fig. 31 Example when trigger is re-issued during pulse output 32 3 2 1 0 One-shot start register 1 Timer A5 one-shot start bit Timer A6 one-shot start bit Timer A7 one-shot start bit Timer A8 one-shot start bit Timer A9 one-shot start bit Fix this bit to “0”. Address 4316 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER (4) Pulse width modulation mode [11] Figure 32 shows the bit configuration of the timer Ai mode register in the pulse width modulation mode. In pulse width modulation mode, bits 0, 1, and 2 must be set to “1”. Bit 5 is used to determine whether to perform 16-bit length pulse width modulator or 8-bit length pulse width modulator. 16-bit length pulse width modulator is selected when bit 5 is “0” and 8-bit length pulse width modulator is selected when it is “1”. The 16-bit length pulse width modulator is described first. The pulse width modulator can be started with a software trigger or with an input signal from a TAiIN pin (external trigger). The software trigger mode is selected when bit 4 is “0”. Pulse width modulator is started and a pulse is output from TAiOUT when the count start bit is set to “1”. The external trigger mode is selected when bit 4 is “1”. Pulse width modulation starts when a trigger signal is input from the TAiIN pin when the count start bit is “1”. Whether to trigger at the fall or rise of the trigger signal is determined by bit 3. The trigger is at the fall of the trigger signal when bit 3 is “0” and at the rise when it is “1”. When data is written to timer Ai with the pulse width modulator halted, it is written to the reload register and the counter. Then when the count start bit is set to “1” and a software trigger or an external trigger is issued to start modulation, the waveform shown in Figure 33 is output continuously. Once modulation is started, triggers are not accepted. If the value in the reload register is m, the duration “H” of pulse is 1 ×m selected clock frequency The width of the output pulse is changed by updating timer data. The update can be performed at any time. The output pulse width is changed at the rise of the pulse after data is written to the timer. The contents of the reload register are transferred to the counter just before the rise of the next pulse so that the pulse width is changed from the next output pulse. Undefined data is read when timer Ai is read. The 8-bit length pulse width modulator is described next. The 8-bit length pulse width modulator is selected when the timer Ai mode register bit 5 is “1”. The reload register and the counter are both divided into 8-bit halves. The low-order 8 bits function as a prescaler and the high-order 8 bits function as the 8-bit length pulse width modulator. The prescaler counts the clock selected by bits 6, 7, and the contents of the timer A clock division select register. (See Table 7.) A pulse is generated when the counter reaches 000016 as shown in Figure 34. At the same time, the contents of the reload register is transferred to the counter and count is continued. Therefore, if the low-order 8 bits of the reload register are n, the period of the generated pulse is 1 selected clock frequency The high-order 8 bits function as an 8-bit length pulse width modulator using this pulse as input. The operation is the same as for 16-bit length pulse width modulator except that the length is 8 bits. If the high-order 8 bits of the reload register are m, the duration “H” of pulse is and the output pulse period is 1 × (n + 1) × m. selected clock frequency 1 × (216 – 1). selected clock frequency And the output pulse period is An interrupt request signal is generated and the interrupt request bit in the timer Ai interrupt control register is set at each fall of the output pulse. 7 6 5 4 3 2 1 1 0 1 1 × (n + 1). Timer A0 mode register Timer A1 mode register Timer A2 mode register Timer A3 mode register Timer A4 mode register 1 × (n + 1) × (28 – 1). selected clock frequency Address 5616 5716 5816 5916 5A16 Timer A5 mode register Timer A6 mode register Timer A7 mode register Timer A8 mode register Timer A9 mode register Address D616 D716 D816 D916 DA16 1 1 : Always “11” in pulse width modulation mode 1 : Always “1” in pulse width modulation mode 0 × : Software trigger 1 0 : Trigger at the falling of TAiIN input 1 1 : Trigger at the rising of TAiIN input 0 : 16-bit pulse width modulator 1 : 8-bit pulse width modulator Clock source select bits (See Table 7.) Fig. 32 Bit configuration of timer Ai mode register in pulse width modulation mode 33 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER 1/fi × (216 – 1) Selected clock source fi TAiIN (rising edge) This trigger is not accepted 1/fi × (m) TAiOUT Example when the contents of the reload register is 000316 Fig. 33 16-bit length pulse width modulator output pulse example 1/fi × (n + 1) × (28 – 1) Selected clock source fi TAiIN (falling edge) 1/fi × (n + 1) Prescaler output (when n = 2) 1/fi × (n + 1) × (m) 8-bit length pulse width modulator output (when m = 2) Fig. 34 8-bit length pulse width modulator output pulse example 34 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR 16-BIT CMOS MICROCOMPUTER TIMER B the same address to which some of the timer Ai’s count start bits are allocated. (In other words, they are allocated in the count start register 0.) The count is decremented, an interrupt occurs, and the interrupt request bit in the timer Bi interrupt control register is set when the contents becomes 000016. At the same time, the contents of the reload register is stored in the counter and count is continued. Timer Bi does not have a pulse output function or a gate function like timer A. When data is written to timer Bi halted, it is written to the reload register and the counter. When data is written to timer Bi which is busy, the data is written to the reload register, but not to the counter. The new data is reloaded from the reload register to the counter at the next reload time and counting continues. The contents of the counter can be read at any time. Figure 35 shows a block diagram of timer B. Timer B has three modes: timer mode, event counter mode, and pulse period measurement/pulse width measurement mode. The mode is selected with bits 0 and 1 of the timer Bi mode register (i=0 to 2). Each of these modes is described below. (1) Timer mode [00] Figure 36 shows the bit configuration of the timer Bi mode register in the timer mode. Bits 0 and 1 of the timer Bi mode register must always be “0” in timer mode. Bits 6 and 7 are used to select the clock source. The counting of the selected clock starts when the count start bit is “1” and stops when “0”. As shown in Figure 21, the timer Bi’s count start bits are allocated at Data bus (odd) Count source select bits f2 f16 f64 Data bus (even) f512 (Low-order 8 bits) • Timer mode • Pulse period measurement/Pulse width measurement mode TBiIN Polarity selection and edge pulse generator (High-order 8 bits) Reload register (16) • Event counter mode Counter (16) fx32 Timer B2 clock source select bit (Note 2) Count start register 0 Addresses Timer B0 5116 5016 Timer B1 5316 5216 Timer B2 5516 5416 (Address 4016) Counter reset circuit Timer B2 clock source select bit : Bit 6 at address 6316 Notes 1: Perform a write and read to/from timer Bi register in the condition of 16-bit data length : data length flag (m) = “0”. 2: Only for timer B2, a count source in the event counter mode can be selected. Fig. 35 Block diagram of timer B 35 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER (2) Event counter mode [01] Figure 37 shows the bit configuration of the timer Bi mode register in the event counter mode. In event counter mode, bit 0 in the timer Bi mode register must be “1” and bit 1 must be “0”. The input signal from the TBiIN pin is counted when the count start bit is “1” and counting is stopped when it is “0”. Count is performed at the fall of the input signal when bits 2 and 3 are “0” and at the rise of the input signal when bit 3 is “0” and bit 2 is “1”. When bit 3 is “1” and bit 2 is “0”, count is performed at the rise and fall of the input signal. Only for timer B2, when the timer B2 clock source select bit of the particular function select register 1 (bit 6 at address 6316) = “1” in the event counter mode, fx32 can be selected. (When this bit is “0”, an input signal from pin TB2IN becomes the count source as described above.) For the bit configuration of the particular function select register 1, refer to the section on the standby function. Also, the pin position where pin TBiIN is to be allocated can be selected by the pin TBiIN select bit (bit 0, 1, or 2 at address AE16; the port P2 pin function control register). 7 6 5 4 3 2 1 0 × × × × 0 0 36 Address 5B16 5C16 5D16 0 0 : Always “00” in timer mode × × × : Not used in timer mode and may be any Not used in timer mode Clock source select bits 0 0 : Select f2 0 1 : Select f16 1 0 : Select f64 1 1 : Select f512 Fig. 36 Bit configuration of timer Bi mode register in timer mode 7 6 5 4 3 2 1 0 × × × × 0 1 Timer B0 mode register Timer B1 mode register Timer B2 mode register Address 5B16 5C16 5D16 0 1 : Always “01” in event counter mode 0 0 : Count at the falling edge of input signal 0 1 : Count at the rising edge of input signal 1 0 : Count at the both falling edge and rising edge of input signal (3) Pulse period measurement/Pulse width measurement mode [10] Figure 38 shows the bit configuration of the timer Bi mode register in the pulse period measurement/pulse width measurement mode. In the pulse period measurement/pulse width measurement mode, bit 0 must be “0” and bit 1 must be “1”. Bits 6 and 7 are used to select the clock source. The selected clock is counted when the count start bit is “1” and counting stops when it is “0”. The pulse period measurement mode is selected when bit 3 is “0”. In the pulse period measurement mode, the selected clock is counted during the interval starting at the fall of the input signal from the TBiIN pin to the next fall or at the rise of the input signal to the next rise; the result is stored in the reload register. In this case, the reload register acts as a buffer register. When bit 2 is “0”, the clock is counted from the fall of the input signal to the next fall. When bit 2 is “1”, the clock is counted from the rise of the input signal to the next rise. In the case of counting from the fall of the input signal to the next fall, counting is performed as follows. As shown in Figure 39, when the fall of the input signal from TBiIN pin is detected, the contents of the counter is transferred to the reload register. Next, the counter is cleared and count is started from the next clock. When the fall of the next input signal is detected, the contents of the counter is transferred to the reload register once more, the counter is cleared, and the count is started. The period from the fall of the input signal to the next fall is measured in this way. After the contents of the counter is transferred to the reload register, an interrupt request signal is generated and the interrupt request bit in the timer Bi interrupt control register is set. However, no interrupt request signal is generated when the contents of the counter is transferred first to the reload register after the count start bit is set to “1”. When bit 3 is “1”, the pulse width measurement mode is selected. The pulse width measurement mode is the same as the pulse period measurement mode except that the clock is counted from the fall of the TBiIN pin input signal to the next rise or from the rise of the input signal to the next fall as shown in Figure 40. Timer B0 mode register Timer B1 mode register Timer B2 mode register × × × × : Not used in event counter mode Fig. 37 Bit configuration of timer Bi mode register in event counter mode 7 6 5 4 3 2 1 0 1 0 Timer B0 mode register Timer B1 mode register Timer B2 mode register Address 5B16 5C16 5D16 1 0 : Always “10” in pulse period measurement/pulse width measurement mode 0 0 : Count from the falling edge of input signal to the next falling one 0 1 : Count from the rising edge of input signal to the next rising one 1 0 : Count from the falling edge of input signal to the next rising one and from the rising edge to the next falling one Conut-type select bit 0 : Counter-clear type 1 : Free-run type Timer Bi overflow flag Clock source select bits 0 0 : Select f2 0 1 : Select f16 1 0 : Select f64 1 1 : Select f512 Fig. 38 Bit configuration of timer Bi mode register in pulse period measurement/pulse width measurement mode MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T met ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP When timer Bi is read, the contents of the reload register is read. Note that in this mode, the interval between the fall of the TBiIN pin input signal to the next rise or from the rise to the next fall must be at least two cycles of the timer count source. Timer Bi overflow flag which is bit 5 of timer Bi mode register is set to “1” when the timer Bi counter reaches 000016, which indicates that a pulse width or pulse period is longer than that which can be measured by a 16-bit length. 16-BIT CMOS MICROCOMPUTER This flag is cleared by writing data to the corresponding timer Bi mode register. This flag is set to “1”at reset. In these modes, the count type can be selected by the count-type select bit (bit 4 of the timer Bi mode register). When this bit = “1”, the free-run type is selected; in this case, even when a valid edge is input to pin TBiIN, the contents of the counter will not be cleared to “000016”, and counting will continue. However, when a valid edge is input, an interrupt-requesting signal will be generated. Selected clock source fi TBiIN Reload register ← Counter Counter ← 0 Count start bit Interrupt request signal Fig. 39 Pulse period measurement mode operation (example of measuring the interval between the falling edge to next falling one) Selected clock source fi TBiIN Reload register ← Counter Counter ← 0 Count start bit Interrupt request signal Fig. 40 Pulse width measurement mode operation 37 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP TIMER FUNCTION FOR MOTOR CONTROL 16-BIT CMOS MICROCOMPUTER 7 6 Three-phase motor drive waveform or pulse motor drive waveform can be output by using plural internal timers As. These modes are explained bellow. 5 × 4 3 2 1 1 0 0 0 Waveform output mode register Waveform output select bits 100 : Fix to “100” in three-phase waveform mode Three-phase motor drive waveform output mode (three-phase waveform mode) Three-phase waveform mode using timers A0, A1, A2 and A3 is selected by setting the waveform output select bits of the waveform output mode register (bits 2 through 0 at address A616, Figure 41) to “1002”. There are two types of the three-phase waveform mode: threephase mode 0 and three-phase mode 1. Bit 4 of the waveform output mode register selects either mode. In the three-phase waveform mode, set the corresponding timer mode registers of timers A0, A1, and A2 to select the one-shot pulse mode with the rising edge of an external trigger valid; set the timer mode register of timer A3 to select the timer mode. Figure 43 shows the block diagram in the three-phase waveform mode. The three-phase waveform mode outputs six waveforms, positive waveforms (U, V, W phases) and negative waveforms (U, V, W phases), from the respective ports with “L” level active. Timer A2 controls U and U phases; timer A1 does V and V phases and timer A0 does W and W phases. Timer A3 controls these oneshot pulses’ periods of timers A2, A1 and A0. In the waveform output, a short circuit prevention time can be set to prevent “L” level of positive waveform outputs (U, V, W phases) from overlapping with “L” level of their negative waveform outputs (U, V, W phases). The short circuit prevention time can be set with three 8bit dead-time timers, sharing one reload register. The dead-time timer operates as a one-shot timer. It’s start trigger is selected from the following two types: both the rising and falling edges of timers A0 to A2’s one-shot pulses or their falling edges. Additionally, bit 6 of the waveform output mode register (address A616) controls this selection. When that bit is “0”, both the rising and falling edges are selected; when that bit is “1”, the falling edges are selected. Address A616 (Valid in three-phase mode 1) Three-phase output polarity set buffer 0 : “H” output 1 : “L” output Three-phase mode select bit 0 : Three-phase mode 0 1 : Three-phase mode 1 Not used in three-phase waveform mode Dead-time timer trigger select bit 0 : Both edge of one-shot pulse with timers A2 to A0 1 : Only the falling edge of one-shot pulse with timers A2 to A0 Waveform output control bit 0 : Waveform output disabled 1 : Waveform output enabled Fig. 41 Bit configuration of waveform output mode register in threephase waveform mode 7 6 5 0 4 1 3 1 2 0 1 1 0 0 Timer A0 mode register Timer A1 mode register Timer A2 mode register Address 5616 5716 5816 Fix to “10” in three-phase waveform mode Fix to “0110” in three-phase waveform mode Clock source select bits (See Table 7.) 7 6 5 0 4 0 3 0 2 0 1 0 0 0 Timer A3 mode register Address 5916 Fix to “000000” in three-phase waveform mode Clock source select bits (See Table 7.) Fig. 42 Bit configuration of timer A0, A1, A2, mode register and timer A3 mode register in three-phase waveform mode 38 Timer A3 (16) (Timer mode) T Timer A21 Timer A11 Timer A01 W-phase output polarity set buffer (bit 3 at address A816) Timer A0 counter (16) (One-shot pulse mode) Reload V-phase output polarity set buffer (bit 4 at address A916) Timer A1 counter (16) (One-shot pulse mode) Reload U-phase output polarity set buffer (bit 5 at address A916) (One-shot pulse mode) Timer A0 T Reload Timer A2 counter (16) Timer A1 T Timer A2 Three-phase output polarity set buffer (bit 3 at address A616) DQ DQ DQ TR Reset R DQ DQ Interrupt validity output select bit (bit 5 at address A916) “1” “0” “1” “0” “1” “0” R SQ T RQ SQ T RQ Q D Three-phase mode select bit R (bit 4 at address A616) Output polarity set toggle flip-flop 0 Output polarity set toggle flip-flop 1 SQ T RQ Interval control circuit Output polarity set toggle flip-flop 2 Reset Reset f2 1/2 1/2 Trigger generating circuit W-phase W-phase output fix polarity set bit output control (bit 0 at address D Q circuit A916) W-phase output fix bit (bit 0 at address A816) DQ T Trigger generating circuit V-phase output fix bit (bit 1 at address A816) DQ T V-phase V-phase output fix polarity set bit output (bit 1 at address D Q control A916) circuit f8 f4 Dead-time timer (8) Dead-time timer (8) T T T Reset T DQ T DQ T DQ T DQ T DQ T DQ b0 b1 b2 P6OUTCUT Bits 2 through 0 of positiondata-retain function control register (address AA16) Dead-time timer (8) Clock-source-of-dead-time-timer select bits (bits 7, 6 at address A816) Reload register Timer A3 interrupt request signal Trigger generating circuit U-phase output fix bit (bit 2 at address DQ A816) T U-phase U-phase output fix polarity set bit output control (bit 2 at address DQ circuit A916) “0” “1” Q D T T Q D Q D T R DQ IDW IDV IDU W W V V U U Waveform output control bit (bit 7 at address A616) PR Data bus (even-numbered) Interrupt request interval set bit (bit 4 at address A916) DQ . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som MI ELI Y NAR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Fig. 43 Block diagram in three-phase waveform mode 39 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER When writing data to the dead-time timer (address A716), the data is written to the reload register shared by three dead-time timers. When the dead-time timers catch the start trigger from the respective timers, the reload register contents are transferred to its counter and the dead-time timer decrements with the clock source selected by bits 6 and 7 of three-phase output data register 0 (address A816). Additionally, this timer can accept another trigger before completion of the preceding trigger operation. In this case, after transferring the reload register contents to the dead-time timer at acceptance of the trigger, the value is decremented. The dead-time timer operates as a one-shot pulse timer. Accordingly, this timer starts pulse output when the trigger is caught, and finishes pulse output and stops operation when its contents become “0016”, and waits next trigger. 7 6 5 × 4 × 3 2 1 0 Three-phase output data register 0 Address A816 In the three-phase waveform mode, setting bit 7 of the waveform output mode register (address A616) to “1” makes positive waveforms (U, V, W phases) and their negative waveforms (U, V, W phases) output from the respective ports. When this bit is “0”, their ports are floating. This bit is cleared to “0” by inputting a falling edge to pin P6OUTCUT, by reset, or by executing instructions. Additionally, setting bits 2 through 0 of the three-phase output data register 0 (address A816) to “1” makes the corresponding waveform outputs fixed. Whether the outputs are fixed to “H” or “L” is selected by bits 2 through 0 of the three-phase output data register 1 (address A916). Clearing these bits to “0” makes the corresponding waveform outputs fixed to “H”; setting these bits to “1” makes the outputs fixed to “L”. 7 × 6 × 5 4 3 2 × 1 0 Three-phase output data register 1 Address A916 W-phase output fix bit 0 : Released from output fixation 1 : Output fixed W-phase fixed output’s polarity set bit 0 : “H” output fixed 1 : “L” output fixed V-phase output fix bit 0 : Released from output fixation 1 : Output fixed V-phase fixed output’s polarity set bit 0 : “H” output fixed 1 : “L” output fixed U-phase output fix bit 0 : Released from output fixation 1 : Output fixed U-phase fixed output’s polarity set bit 0 : “H” output fixed 1 : “L” output fixed When three-phase mode 0 is selected: W-phase output polarity set buffer 0 : “H” output 1 : “L” output When three-phase mode 1 is selected: It may be either “0” or “1”. In three-phase waveform mode, this bit is invalid. It may be either “0” or “1”. In three-phase waveform mode, these bits are invalid. Any of them may be either “0” or “1”. Clock-source-of-dead-time-timer select bits 0 0 : f2 0 1 : f4 1 0 : f8 1 1 : Do not select. When three-phase mode 0 is selected: V-phase output polarity set buffer 0 : “H” output 1 : “L” output When three-phase mode 1 is selected: Interrupt request interval set bit 0 : Every second time 1 : Every fourth time When three-phase mode 0 is selected: U-phase output polarity set buffer 0 : “H” output 1 : “L” output When three-phase mode 1 is selected: Interrupt validity output select bit 0 : An interrupt request occurs at each even-numbered underflow of timer A3. 1 : An interrupt request occurs at each odd-numbered underflow of timer A3. In three-phase waveform mode, these bits are invalid. Any of them may be either “0” or “1”. Fig. 44 Bit configuration of three-phase output data registers 1 and 0 in three-phase waveform mode 40 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Three-phase mode 0 In selecting three-phase waveform mode, three-phase mode 0 is selected by setting bit 4 of the waveform output mode register (address A616) to “0”. The output polarity of three-phase waveform depends on the output polarity set toggle flip-flop. The positive waveform of the three-phase waveform is “H” output when the toggle flip-flop is “0”; it is “L” output when the toggle flip-flop is “1”. (Three-phase waveform is output as a negative waveform.) Each output polarity set toggle flip-flop has the output polarity set buffer shown in Figure 44. When the timer A3’s counter contents become 000016, the contents of output polarity set buffer are set into the output polarity set toggle flip-flop. After that, the polarity of the contents of output polarity set toggle flip-flop are reversed each time completion of one-shot pulse of timer (timers A2 to A0) corresponding to each phase. Figure 45 shows an example of U-phase waveform and the output operation is explained. Three-phase mode 0 becomes valid when writing “0” to the U-phase output polarity set buffer (bit 5 at address A916) and actuating the timer A3. When the counter of timer A3 becomes 000016, the timer A3 interrupt request signal occurs and the timer A2 simultaneously starts one-shot pulse output. At this time, the contents of U-phase output polarity set buffer, “0” in this case, are set into the output polarity set toggle flip-flop 2. When the one-shot pulse output of timer A2 is completed, the contents of output polarity set toggle flip-flop 2 is reversed from “0” to “1”. Simultaneously, the one-shot pulse of the 8-bit dead-time timer is output for ensuring time not to overlap “L” levels of U phase waveform and its negative U phase waveform. The U-phase waveform output keeps “H” level from the start until the one-shot pulse output of the dead-time timer is completed, even if the contents of output polarity set toggle flip-flop 2 are reversed from “0” to “1” owing to the timer A2’s one-shot pulse output. When the one-shot pulse output of the dead-time timer is completed, “1” of output polarity set toggle flip-flop 2 which has been reversed becomes valid and the U phase waveform changes to “L” level. 16-BIT CMOS MICROCOMPUTER Then, write “1” to the U-phase output polarity set buffer (bit 5 at address A916) before the counter of timer A3 becomes 000016. After that, when the counter of timer A3 becomes 000016, the timer A2 starts one-shot pulse output. Simultaneously, the contents of Uphase output polarity set buffer, “1” in this case, are set into the output polarity set toggle flip-flop 2 and the U phase waveform remains “L” level. When the one-shot pulse output of timer A2 is completed, the contents of output polarity set toggle flip-flop 2 is reversed from “1” to “0”. Simultaneously, the one-shot pulse output of the dead-time timer starts. When the contents of output polarity set toggle flip-flop 2 are reversed from “1” to “0”, the U-phase waveform changes its output level from “L” to “H” without waiting for completion of the one-shot pulse output of the dead-time timer. U-phase waveform is generated by repeating the operation above. The way to generate U-phase waveform, which is the negative phase of U-phase, is the same as that for U-phase waveform except that the contents of output polarity set toggle flip-flop 2 are treated as the reversed signal from the case of U-phase waveform. In this way, U-phase waveform and U-phase waveform, having the negative phase of U-phase, are output from the pins so that their “L” levels do not overlap each other. The width of “L” level can be also modified by changing the value of timer A2 or A3. V-, W-phase waveform and V-, W-phase waveform, having their negative phase, are similarly output according to the corresponding timer operation. The explanation above is an example of three-phase waveform generating due to an triangular wave modulation. Three-phase waveform due to a saw-tooth-wave modulation can also be generated by fixing each beginning level of phases. Signal output each time Timer A3 becomes 000016 One-shot pulse output with timer A2 Contents of output polarity set toggle flip-flop 2 Reversed pulse output signal with dead-time timer U-phase waveform output U-phase waveform output Fig. 45 U-phase waveform output example in three-phase mode 0 (triangular wave modulation) 41 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Three-phase mode 1 In selecting three-phase waveform mode, three-phase mode 1 is selected by setting bit 4 of the waveform output mode register (address A616) to “1”. In this mode, each of timers A0 to A2 can have two timer registers and the contents of those registers are alternately reloaded into the counter each time the counter of timer A3 becomes 000016. The interrupt request normally occurs when the counter of timer A3 becomes 000016. However, this occurrence interval can be switched between “every second time” and “every fourth time.” Bit 4 of the pulse output data register 1 (address A916) selects that. Additionally, an even-numbered or odd-numbered timer A3’s underflow can be used as the occurrence factor of timer A3 interrupt request. Bit 5 of the three-phase output data register 1 (address A916) selects that. When the timer A3’s counter contents become 000016, the contents of three-phase output polarity set buffer are set into the output polarity set toggle flip-flop on which the output polarity of three-phase waveform depends. The contents of three-phase output polarity set buffer are reversed after that operation. The polarity of the contents of output polarity set toggle flip-flop is reversed each time completion of one-shot pulse of timer (timers A2 to A0) corresponding to each phase. Figure 46 shows an example of U-phase waveform and the output operation is explained. Write “0” to the three-phase-output-polarity set buffer (bit 3 at address A616). Clear the interrupt request interval set bit (bit 4 at address A916) to “0” so that the timer A3 interrupt request occurs at every second time. Additionally, clear the interrupt validity output select bit (bit 5 at address A916) so that the timer A3 interrupt request occurs at an each even-numbered underflow of timer A3. After the procedure above, three-phase mode 1 starts operation when actuating timer A3. When the counter of timer A3 becomes 000016, the timer A3 interrupt request occurs and timer A2 simultaneously starts one-shot pulse output. At this time, the contents of three-phase output polarity set buffer, “0” in this case, are set into the output polarity set toggle flipflop 2. The contents of three-phase output polarity set buffer are reversed from “0” to “1” after that operation. When the timer A2 counter counts the value written into the timer A2 and the one-shot pulse output of timer A2 is completed, the contents of output polarity set toggle flip-flop 2 are reversed from “0” to “1”. Simultaneously, the one-shot pulse of the 8-bit dead-time timer is output for ensuring time, so that “L” levels of U- and U-phase waveforms do not overlap. The U-phase waveform output keeps “H” level from the start until the one-shot pulse output of the dead-time timer is completed, even if the contents of output polarity set toggle flip-flop 2 are reversed from “0” to “1” owing to the timer A2’s one-shot pulse output. When the one-shot pulse output of the dead-time timer is completed, “1” of output polarity set toggle flip-flop 2 which has been reversed becomes valid and the U-phase waveform changes to “L” level. Then, when the counter of timer A3 becomes 000016, the timer A2 counter counts the value written into timer A2 and timer A2 starts one-shot pulse output. Simultaneously, the contents of three-phase output polarity set buffer are set into the output polarity set toggle flip-flop 2. However, the U-phase waveform remains “L” level, be- 42 16-BIT CMOS MICROCOMPUTER cause the value is the same (“1”). The contents of three-phase output polarity set buffer are reversed from “1” to “0” after that operation. When the one-shot pulse output of timer A2 is completed, the contents of output polarity set toggle flip-flop 2 is reversed from “1” to “0”. Simultaneously, the one-shot pulse output of the dead-time timer starts. When the contents of output polarity set toggle flip-flop 2 is reversed from “1” to “0”, the U-phase waveform changes its output level from “L” to “H” without waiting for completion of the one-shot pulse output of the dead-time timer. U-phase waveform is generated by repeating the operation above. The way to generate U-phase waveform, which is the negative phase of U-phase, is the same as that for U-phase waveform except that the contents of output polarity set toggle flip-flop 2 is treated as the reversed signal from the case of U-phase waveform. In this way, U-phase waveform and U-phase waveform, having the negative phase of U-phase, are output from the pins so that their “L” levels do not overlap each other. The width of “L” level can be also modified by changing the value of timers A2, A21, or A3. V-, W-phase waveform and V-, W-phase waveform, having their negative phase, are similarly output according to the corresponding timer operation. MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER Timer A3 interrupt request signal Signal output each time Timer A3 becomes 000016 One-shot pulse output with timer A2 n1 n2 n3 n4 n5 n6 Timer A2 n1 n3 n5 n7 Timer A21 n2 n4 n6 n8 Contents of output polarity set toggle flip-flop 2 Reversed pulse output signal with dead-time timer U-phase waveform output U-phase waveform output Fig. 46 U-phase waveform output example in three-phase mode 1 (triangular wave modulation) Position-data-retain function The three-phase waveform mode has the function to retain the input data of the corresponding pin (IDU, IDV, IDW) at an edge of a positive waveform (U, V, or W phase). Whether to retain the data at a falling edge or rising one is selected by bit 3 of the position-data-retain function control register (address AA16). Retain data can be read out by bits 2 through 0 of the position-dataretain function control register (address AA16). 7 6 5 4 3 2 1 0 Position-data-retain function control register Address AA16 W-phase position data retain bit (pin IDW) V-phase position data retain bit (pin IDV) U-phase position data retain bit (pin IDU) Retain-trigger polarity select bit 0 : Falling edge of each phase’s positive waveform 1 : Rising edge of each phase’s positive waveform Fig. 47 Bit configuration of position-data-retain function control register 43 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 16-BIT CMOS MICROCOMPUTER PULSE OUTPUT PORT MODE 0 Figure 48 shows the block diagram in the pulse output port mode 0. This mode has an 8-bit pulse output port. The waveform output select bits (bits 0 to 2) of waveform output mode register (address A616) select use of pulse output port. The 8-bit pulse output port can also be divided into “4 bits and 4 bits” or “6 bits and 2 bits”, with the pulse output mode select bit (bit 3) of waveform output mode register (address A616); each of them can be individually controlled. Set timers A3 and A0 to the timer mode because they are used in the pulse output port mode 0. Figure 50 shows the bit configuration of timer A3 and A0 mode registers in the pulse output port mode 0. Timers A3 and A0 start count when setting the corresponding timer count start bit to “1”, and they stop it when clearing that bit to “0”. Each bit using timer A0 as a trigger can also be controlled by an input trigger from pin RTPTRG0. This control is selected by the pulse output trigger select bits of the three-phase output data register 0 (bits 7 and 6 at address A816). Also, this externally-input trigger can be selected from the following three types: falling edges, rising edges, and falling and rising edges. The reversed content of the pulse output data bit can be output to each pulse output port by the pulse output polarity select bit of the three-phase output data register 1 (bit 3 at address A916). When the pulse output polarity select bit = “0”, the content of the pulse output data bit is output as it is; when the pulse output polarity select bit = “1”, the reversed content is output. Pulse width modulation timer select bits (bits 5, 4 at address A616) Pulse width modulation output of timer A1 Pulse output trigger select bits Pulse width modulation (bits 7, 6 at address A816) output of timer A2 Pulse width modulation circuit Pulse width modulation output of timer A4 RTP TRG1 Timer A0 Pulse width modulation enable bits 0 through 2 (bits 0 through 2 at address A916) b0 T D Q b1 D Q b2 D Q Bits 0 through 3 of threephase output data register 0 (address A816) b0 Data bus (odd-numbered) Data bus (even-numbered) b1 Pulse output mode select bit (bit 3 at address A616) Waveform output control bit 1 (bit 7 at address A616) D Q R P6OUTCUT Reset T D Q RTP00 D Q RTP01 b2 D Q RTP02 b3 D Q RTP03 b4 T D Q RTP10 b5 D Q RTP11 Bits 4, 5 of three-phase output data register 0 (address A816) or Bits 4, 5 of three-phase output data register 1 (address A916) D Q b6 b7 Bits 6, 7 of three-phase output data register 1 (address A916) RTP12 D Q T RTP13 Pulse output polarity select bit (bit 3 at address A916) Waveform output control bit 0 (bit 6 at address A616) D Q Timer A3 R Reset Fig. 48 Block diagram in pulse output port mode 0 44 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 7 6 5 4 3 16-BIT CMOS MICROCOMPUTER 2 1 0 Waveform output mode register Address A616 Waveform output select bits 000 : Parallel ports 001 : When pulse mode 0 is selected, RTP0 is selected. When pulse mode 1 is selected, RTP0, RTP11, RTP10 are selected. 010 : When pulse mode 0 is selected, RTP1 is selected. When pulse mode 1 is selected, RTP13 and RTP12 are selected. 011 : When pulse mode 0 is selected, RTP0 and RTP1 are selected. When pulse mode 1 is selected, RTP0, RTP11, RTP10 and RTP13, RTP12 are selected. Pulse output mode select bit 0 : Pulse mode 0 1 : Pulse mode 1 Pulse width modulation timer select bits 0 0 : When pulse mode 0 is selected (valid only for RTP0), Pulse width modulation by timer A1 When pulse mode 1 is selected (valid only for RTP0, RTP11, RTP10), Pulse width modulation by timer A1 0 1 : When pulse mode 0 is selected, Do not set. When pulse mode 1 is selected (valid only for RTP0, RTP11, RTP10), Pulse width modulation by timer A1 ; RTP02, RTP01, RTP00 Pulse width modulation by timer A2 ; RTP03, RTP11, RTP10 1 0 : When pulse mode 0 is selected, Do not set. When pulse mode 1 is selected (valid only for RTP0, RTP11, RTP10), Pulse width modulation by timer A1 ; RTP01, RTP00 Pulse width modulation by timer A2 ; RTP03, RTP02 Pulse width modulation by timer A4 ; RTP11, RTP10 1 1 : Do not select. Waveform output control bit 0 When pulse mode 0 is selected, 0 : RTP1 waveform outputs is disabled. 1 : RTP1 waveform outputs is enabled. When pulse mode 1 is selected, 0 : RTP13, RTP12 waveform outputs are disabled. 1 : RTP13, RTP12 waveform outputs are enabled. Waveform output control bit 1 When pulse mode 0 is selected, 0 : RTP0 waveform output is disabled. 1 : RTP0 waveform output is enabled. When pulse mode 1 is selected, 0 : RTP0, RTP11, RTP10 waveform outputs are disabled. 1 : RTP0, RTP11, RTP10 waveform outputs are enabled. Fig. 49 Bit configuration of waveform output mode register in pulse output port mode 0 7 6 5 0 4 0 3 0 2 0 1 0 0 0 Timer A0 mode register Timer A3 mode register Address 5616 5916 Fix these bits to 000000 in pulse output port mode. Clock source select bits (See Table 7.) Fig. 50 Bit configuration of timer A3 and A0 mode registers in pulse output port mode 0 45 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 7 6 5 4 3 2 1 0 MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Address Three-phase output data register 0 A816 RTP00 pulse output data bit RTP01 pulse output data bit RTP02 pulse output data bit RTP03 pulse output data bit RTP10 pulse output data bit; Valid when pulse mode 1 is selected. RTP11 pulse output data bit; Valid when pulse mode 1 is selected. Pulse output trigger select bits 0 0 : Underflow of timer A0 0 1 : Falling edge of input signal to pin RTPTRG0 1 0 : Rising edge of input signal to pin RTPTRG0 1 1 : Falling and rising edges of input signal to pin RTPTRG0 7 6 5 4 3 2 1 0 Three-phase output data register 1 Address A916 Pulse width modulation enable bit 0 0 : No pulse width modulation by timer A1 1 : Pulse width modulation by timer A1 Pulse width modulation enable bit 1 0 : No pulse width modulation by timer A2 1 : Pulse width modulation by timer A2 Pulse width modulation enable bit 2 0 : No pulse width modulation by timer A4 1 : Pulse width modulation by timer A4 Pulse output polarity select bit 0 : Positive 1 : Negative RTP10 pulse output data bit; Valid when pulse mode 0 is selected. RTP11 pulse output data bit; Valid when pulse mode 0 is selected. RTP12 pulse output data bit RTP13 pulse output data bit Fig. 51 Bit configuration of three-phase output data registers 1 and 0 in pulse output port mode 0 46 Pulse mode 0 This mode divides a pulse output port into 4 bits and 4 bits and individually controls them. When setting the pulse output mode select bit to “0”, and setting bits 2 and 1 to “0” and bit 0 to “1” of the waveform output select bits, four of RTP03, RTP02, RTP01, and RTP00 become the pulse output ports (RTP0 selected). When setting the pulse output mode select bit to “0”, and setting bits 2 and 0 to “0” and bit 1 to “1” of the waveform output select bits, four of RTP13, RTP12, RTP11, RTP10 become the pulse output ports (RTP1 selected). When setting the pulse output mode select bit to “0”, and setting bit 2 to “0” and bits 1 and 0 to “1” of the waveform output select bits, the following two groups become the pulse output ports: •Four of RTP13, RTP12, RTP11, RTP10 •Four of RTP03, RTP02, RTP01, RTP00. Each time the contents of timer A3 counter become 000016, the contents of three-phase output data register 1 (address A916)’s high order 4 bits, (bits 7 to 4), which corresponding to RTP13, RTP12, RTP11, RTP10, are output from ports. Each time the contents of timer A0 counter become 000016, the contents of three-phase output data register 0 (address A816)’s low order 4 bits (bits 3 to 0), which corresponding to RTP03, RTP02, RTP01, RTP00, are output from ports. When writing “0” to the specified one of the pulse output data bits, “L” level is output from the pulse output port when the contents of the corresponding timer counter become 000016; when writing “1” to it, “H” level is output from the pulse output port. In the case that an input trigger of pin RTPTRG0 is selected, the data written to the pulse output data bit is output from the corresponding pulse output port by this selected trigger. Additionally, pulse width modulation can be applied for RTP03, RTP02, RTP01, and RTP0 0. Because timer A1 is used for pulse width modulation, actuate timer A1 in the pulse width modulation mode. When any of pulse output data bits is “1”, the pulse to which pulse width modulation has been applied is output from the pulse output port when the contents of timer A0 counter become 000016. The pulse width modulation using timer A1 can be applied by setting the pulse width modulation enable bit 0 of the three-phase output data register 1 (bit 0 at address A916) to “1” and the pulse width modulation timer select bits of the waveform output mode register (bits 5 and 4 at address A616) to “00”. Figure 52 shows example waveforms in pulse mode 0. In ports selecting pulse mode 0, output of RTP13, RTP12, of RTP11 and RTP10 is controlled by the waveform output control bit 0 (bit 6) of waveform output mode register; output of RTP03, RTP02, RTP01 and RTP00 is done by the waveform output control bit 1 (bit 7). When setting the waveform output control bit to “1”, waveform is output from the corresponding port. When clearing that bit to “0”, waveform output from the corresponding port stops, and the port becomes floating. The waveform output control bits are cleared to “0” by reset or by executing instructions. Also, the waveform output control bit 1 can be cleared to “0” by inputting a falling edge to pin P6OUTCUT. MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Pulse mode 1 This mode divides a pules output port into 6 bits and 2bits and individually control them. When setting the pulse output mode select bit to “1”, and setting bits 2 and 1 to “0” and bit 0 to “1” of the waveform output select bits, the following become the pulse output ports: •Six of RTP11, RTP10, RTP03, RTP02, RTP01, RTP00 When setting the pulse output mode select bit to “1”, and setting bits 2 and 0 to “0” and bit 1 to “1” of the waveform output select bits, two of RTP13, RTP12 become the pulse output ports. When setting the pulse output mode select bit to “1”, and setting bit 2 to “0” and bits 1 and 0 to “1” of the waveform output select bits, the following two groups become the pulse output ports: •Two of RTP13, RTP12 •Six of RTP11, RTP10, RTP03, RTP02, RTP01, RTP00. 16-BIT CMOS MICROCOMPUTER trolled by the waveform output control bit 0 (bit 6) of the waveform output mode register; output of RTP11, RTP10, RTP03, RTP02, RTP01 and RTP00 is done by the waveform output control bit 1 (bit 7). When setting the waveform output control bit to “1”, waveform is output from the corresponding port. When clearing that bit to “0”, waveform output from the corresponding port stops, and the port becomes floating. These waveform output control bits 0, 1 are cleared to “0” by reset, by inputting a falling edge to pin P6OUTCUT, or by executing instructions. Each time the contents of timer A3 counter become 000016, the contents of three-phase output data register 1 (address A916)’s bits 7 and 6, which corresponding to RTP13 and RTP12, are output from ports. Each time the contents of timer A0 counter become 000016, the contents of three-phase output data register 0 (address A816)s’ low order 6 bits (bits 5 to 0), which corresponding to RTP11 , RTP10, RTP03, RTP02, RTP01, RTP00, are output from ports. Whether to control these pulse output ports by an underflow of timer A0 or an input edge to pin RTPTRG0 is selected by the pulse output trigger select bits of the three-phase output data register 0 (bits 7 and 6 at address A816). Additionally, pulse width modulation can be applied to RTP1 1, RTP10, RTP03, RTP02, RTP01, and RTP00. The pulse width modulation timer select bits of the waveform output mode register (bits 5 and 4 at address A616) select the type of pulse width modulation from the following: (1) When the pulse width modulation timer select bits = “00”, the common modulation to six of RTP11, RTP10, RTP03, RTP02, RTP01, RTP00 is selected. For this modulation, since timer A1 is necessary, be sure to actuate this timer in the pulse width modulation mode. (2) When the pulse width modulation timer select bits = “01”, the modulation to the following two groups is selected; one consists of RTP11, RTP10, RTP03, and the other consists of RTP02, RTP01, RTP00. For this modulation, since timers A1 and A2 are necessary, be sure to actuate these timers in the pulse width modulation mode. (3) When the pulse width modulation timer select bits = “10”, the modulation to the following three groups is selected; one consists of RTP1 1, RTP10, and another consists of RTP03 , RTP02, and the other consists of RTP01, RTP00. For this modulation, since timers A1, A2, and A4 are necessary, be sure to actuate these timers in the pulse width modulation mode. Additionally, at this time, be sure to set the corresponding pulse width modulation enable bit of the three-phase output data register 1 (bits 2 through 0 at address A916) to “1” in order to enable the pulse width modulation. The other operations are the same as that of pulse mode 0. Figure 53 shows example waveforms in pulse mode 1. In ports selecting pulse mode 1, output of RTP13 and RTP12 is con- 47 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Pulse output port example Signal output each time timer A0 becames 000016 RTP03 RTP02 RTP01 RTP00 Example of pulse width modulation for above pulse output port using timer A1 Signal output each time timer A0 becames 000016 RTP03 RTP02 RTP01 RTP00 Pulse output port example in the case of pulse output polarity select bit = “1” Signal output each time timer A3 becames 000016 RTP11 RTP10 Fig. 52 Example waveforms in pulse mode 0 Pulse output port example Signal output each time timer A0 becames 000016 RTP11 RTP10 RTP03 RTP02 RTP01 RTP00 Example of pulse width modulation for above pulse output port using timer A1 Signal output each time timer A0 becames 000016 RTP11 RTP10 RTP03 RTP02 RTP01 RTP00 Fig. 53 Example waveforms in pulse mode 1 48 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 16-BIT CMOS MICROCOMPUTER PULSE OUTPUT PORT MODE 1 Figure 54 shows the block diagram in the pulse output port mode 1. This mode has an 8-bit pulse output port. The waveform output select bits (bits 0 to 2) of the pulse output control register (address A016) select use of pulse output the port. The 8-bit pulse output port can also be divided into “4 bits and 4 bits” or “6 bits and 2 bits”, with the pulse output mode select bit (bit 3) of the pulse output control register (address A016); each of them can be individually controlled. Set timers A8 and A5 to the timer mode because they are used in the pulse output port mode 1. Figure 56 shows the bit configuration of timer A8 and A5 mode registers in the pulse output port mode 1. Timers A8 and A5 start count when setting the corresponding timer count start bit to “1”, and they stop it when clearing that bit to “0”. Each bit using timer A5 as a trigger can also be controlled by an input trigger from pin RTPTRG1. This control is selected by the pulse output trigger select bits of the pulse output data register 0 (bits 7 and 6 at address A216). Also, this externally-input trigger can be selected from the following three types: falling edges, rising edges, and falling and rising edges. The reversed content of the pulse output data bit can be output to each pulse output port by the pulse output polarity select bit of the pulse output data register 1 (bit 3 at address A416). When the pulse output polarity select bit = “0”, the content of the pulse output data bit is output as it is; when the pulse output polarity select bit = “1”, the reversed content is output. Pulse width modulation timer select bits (bits 5, 4 at address A016) Pulse width modulation output of timer A6 Pulse output trigger select bits Pulse width modulation (bits 7, 6 at address A216) output of timer A7 Pulse width modulation output of timer A9 Pulse width modulation circuit RTP TRG1 Timer A5 Pulse width modulation enable bits 0 through 2 (bits 0 through 2 at address A416) b0 T D Q b1 D Q Data bus (even-numbered) b2 D Q Waveform output control bit 1 (bit 7 at address A016) D Q R P4OUTCUT Bits 0 through 3 of pulse output data register 0 (address A216) b0 T D Q RTP2 0 b1 D Q RTP21 b2 D Q RTP22 b3 D Q RTP23 b4 T D Q RTP30 b5 D Q RTP31 Pulse output mode select bit (bit 3 at address A016) Reset Bits 4, 5 of three-phase output data register 0 (address A216) or Bits 4, 5 of three-phase output data register 1 (address A416) D Q b6 b7 Bits 6, 7 of pulse output data register 1 (address A416) RTP32 D Q T RTP33 Pulse output polarity select bit (bit 3 at address A416) Waveform output control bit 0 (bit 6 at address A016) D Q Timer A8 R Reset Fig. 54 Block diagram in pulse output port mode 1 49 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 7 6 5 4 3 16-BIT CMOS MICROCOMPUTER 2 1 0 Pulse output control register Address A016 Waveform output select bits 000 : Parallel ports 001 : When pulse mode 0 is selected, RTP2 is selected. When pulse mode 1 is selected, RTP2, RTP31, RTP30 are selected. 010 : When pulse mode 0 is selected, RTP3 is selected. When pulse mode 1 is selected, RTP33 and RTP32 are selected. 011 : When pulse mode 0 is selected, RTP2 and RTP3 are selected. When pulse mode 1 is selected, RTP2, RTP31, RTP30 and RTP33, RTP32 are selected. Pulse output mode select bit 0 : Pulse mode 0 1 : Pulse mode 1 Pulse width modulation timer select bits 0 0 : When pulse mode 0 is selected (valid only for RTP2), Pulse width modulation by timer A6 When pulse mode 1 is selected (valid only for RTP2, RTP31, RTP30), Pulse width modulation by timer A6 0 1 : When pulse mode 0 is selected, Do not set. When pulse mode 1 is selected (valid only for RTP2, RTP31, RTP30), Pulse width modulation by timer A6 ; RTP22, RTP21, RTP20 Pulse width modulation by timer A7 ; RTP23, RTP31, RTP30 1 0 : When pulse mode 0 is selected, Do not set. When pulse mode 1 is selected (valid only for RTP2, RTP31, RTP30), Pulse width modulation by timer A6 ; RTP21, RTP20 Pulse width modulation by timer A7 ; RTP23, RTP22 Pulse width modulation by timer A9 ; RTP31, RTP30 1 1 : Do not select. Waveform output control bit 0 When pulse mode 0 is selected, 0 : RTP3 waveform outputs is disabled. 1 : RTP3 waveform outputs is enabled. When pulse mode 1 is selected, 0 : RTP33, RTP32 waveform outputs are disabled. 1 : RTP33, RTP32 waveform outputs are enabled. Waveform output control bit 1 When pulse mode 0 is selected, 0 : RTP2 waveform output is disabled. 1 : RTP2 waveform output is enabled. When pulse mode 1 is selected, 0 : RTP2, RTP31, RTP30 waveform outputs are disabled. 1 : RTP2, RTP31, RTP30 waveform outputs are enabled. Fig. 55 Bit configuration of pulse output control register in pulse output port mode 1 7 6 5 0 4 0 3 0 2 0 1 0 0 0 Timer A5 mode register Timer A8 mode register Address D616 D916 Fix these bits to “000000” in pulse output port mode. Clock source select bits (See Table 7.) Fig. 56 Bit configuration of timer A8 and A5 mode registers in pulse output port mode 1 50 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR 7 6 5 4 3 2 1 0 Pulse output data register 0 MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Address A216 RTP20 pulse output data bit RTP21 pulse output data bit RTP22 pulse output data bit RTP23 pulse output data bit RTP30 pulse output data bit; Valid when pulse mode 1 is selected. RTP31 pulse output data bit; Valid when pulse mode 1 is selected. Pulse output trigger select bits 0 0 : Underflow of timer A5 0 1 : Falling edge of input signal to pin RTPTRG1 1 0 : Rising edge of input signal to pin RTPTRG1 1 1 : Falling and rising edges of input signal to pin RTPTRG1 7 6 5 4 3 2 1 0 Pulse output data register 1 Address A416 Pulse width modulation enable bit 0 0 : No pulse width modulation by timer A6 1 : Pulse width modulation by timer A6 Pulse width modulation enable bit 1 0 : No pulse width modulation by timer A7 1 : Pulse width modulation by timer A7 Pulse width modulation enable bit 2 0 : No pulse width modulation by timer A9 1 : Pulse width modulation by timer A9 Pulse output polarity select bit 0 : Positive 1 : Negative RTP30 pulse output data bit; Valid when pulse mode 0 is selected. RTP31 pulse output data bit; Valid when pulse mode 0 is selected. RTP32 pulse output data bit RTP33 pulse output data bit Fig. 57 Bit configuration of pulse output data registers 1 and 0 in pulse output port mode 1 Pulse mode 0 This mode divides a pulse output port into 4 bits and 4 bits and individually controls them. When setting the pulse output mode select bit to “0”, and setting bits 2 and 1 to “0” and bit 0 to “1” of the waveform output select bits, four of RTP23, RTP22, RTP21, and RTP20 become the pulse output ports (RTP2 selected). When setting the pulse output mode select bit to “0”, and setting bits 2 and 0 to “0” and bit 1 to “1” of the waveform output select bits, four of RTP33, RTP32, RTP31, RTP30 become the pulse output ports (RTP3 selected). When setting the pulse output mode select bit to “0”, and setting bit 2 to “0” and bits 1 and 0 to “1” of the waveform output select bits, the following two groups become the pulse output ports: •Four of RTP33, RTP32, RTP31, RTP30 •Four of RTP23, RTP22, RTP21, RTP20. Each time the contents of timer A8 counter become 000016, the contents of the pulse output data register 1 (address A416)’s high-order 4 bits (bits 7 to 4), which corresponding to RTP33, RTP32, RTP31, RTP30, are output from ports. Each time the contents of timer A5 counter become 000016, the contents of pulse output data register 0 (address A216)’s low-order 4 bits (bits 3 to 0), which corresponding to RTP23, RTP22, RTP21, RTP20, are output from ports. When writing “0” to the specified one of the pulse output data bits, “L” level is output from the pulse output port when the contents of the corresponding timer counter become 000016; when writing “1” to it, “H” level is output from the pulse output port. In the case that an input trigger of pin RTPTRG1 is selected, the data written to the pulse output data bit is output from the corresponding pulse output port by this selected trigger. Additionally, pulse width modulation can be applied for RTP23 , RTP22, RTP21, and RTP20. Because timer A6 is used for pulse width modulation, actuate timer A6 in the pulse width modulation mode. When any of pulse output data bits is “1”, the pulse to which pulse width modulation has been applied is output from the pulse output port when the contents of timer A5 counter become 000016. The pulse width modulation using timer A6 can be applied by setting the pulse width modulation enable bit 0 of the pulse output data register 1 (bit 0 at address A416) to “1” and the pulse width modulation timer select bits of the pulse output control register (bits 5 and 4 at address A016) to “00”. Figure 58 shows example waveforms in pulse mode 0. In ports selecting pulse mode 0, output of RTP33, RTP32, RTP31 and RTP30 is controlled by the waveform output control bit 0 (bit 6) of pulse output control register; output of RTP23, RTP22, RTP21 and RTP20 is done by the waveform output control bit 1 (bit 7). When setting the waveform output control bit to “1”, waveform is output from the corresponding port. When clearing that bit to “0”, waveform output from the corresponding port stops, and the port becomes floating. The waveform output control bits are cleared to “0” by reset or by executing instructions. Also, the waveform output control bit 1 can be cleared to “0” by inputting a falling edge to pin P4OUTCUT. 51 MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Pulse mode 1 This mode divides a pules output port into 6 bits and 2 bits and individually control them. When setting the pulse output mode select bit to “1”, and setting bits 2 and 1 to “0” and bit 0 to “1” of the waveform output select bits, the following become the pulse output ports: •Six of RTP31, RTP30, RTP23, RTP22, RTP21, RTP20 When setting the pulse output mode select bit to “1”, and setting bits 2 and 0 to “0” and bits 1 to “1” of the waveform output select bits, two of RTP33, RTP32 become the pulse output ports. When setting the pulse output mode select bit to “1”, and setting bit 2 to “0” and bits 1 and 0 to “1” of the waveform output select bits, the following two groups become the pulse output ports: •Two of RTP33, RTP32 •Six of RTP31, RTP30, RTP23, RTP22, RTP21, RTP20 Each time the contents of timer A8 counter become 000016, the contents of pulse output data register 1 (address A416)’s bits 7 and 6, which corresponding to RTP33 and RTP32, are output from ports. Each time the contents of timer A5 counter become 000016, the contents of pulse output data register 0 (address A216)’s low-order 6 bits (bits 5 to 0), which corresponding to RTP31, RTP30, RTP23, RTP22, RTP21, RTP20, are output from ports. Whether to control these pulse output ports by an underflow of timer A5 or an input edge to pin RTPTRG1 is selected by the pulse output trigger select bit of the pulse output data register 0 (bits 7 and 6 at address A216). Additionally, pulse width modulation can be applied to RTP3 1, RTP30, RTP23, RTP22, RTP21, and RTP20. The pulse width modulation timer select bits of the pulse output control register (bits 5 and 4 at address A016) select the type of pulse width modulation from the following: (1) When the pulse width modulation timer select bits = “00”, the common modulation to six of RTP31, RTP30, RTP23, RTP22, RTP21, RTP20 is selected. For this modulation, since timer A6 is necessary, be sure to actuate this timer in the pulse width modulation mode. (2) When the pulse width modulation timer select bits = “01”, the modulation to the following two groups is selected; one consists of RTP31, RTP30, RTP23, and the other consists of RTP22, RTP21, RTP20. For this modulation, since timers A6 and A7 are necessary, be sure to actuate these timers in the pulse width modulation mode. (3) When the pulse width modulation timer select bits = “10”, the modulation to the following three groups is selected; one consists of RTP31, RTP30, and another consists of RTP2 3, RTP22 , and the other consists of RTP21, RTP20. For this modulation, since timers A6, A7, and A9 are necessary, be sure to actuate these timers in the pulse width modulation mode. Additionally, at this time, be sure to set the corresponding pulse width modulation enable bit of the pulse output data register 1 (bits 2 through 0 at address A416) to “1” in order to enable the pulse width modulation. The other operations are the same as that of pulse mode 0. Figure 59 shows example waveforms in pulse mode 1. In ports selecting pulse mode 1, output of RTP33 and RTP32 is controlled by the waveform output control bit 0 (bit 6) of the pulse output 52 16-BIT CMOS MICROCOMPUTER control register; output of RTP31, RTP30, RTP23, RTP22, RTP21, and RTP20 is done by the waveform output control bit 1 (bit 7). When setting the waveform output control bit to “1”, waveform is output from the corresponding port. When clearing that bit to “0”, waveform output from the corresponding port stops, and the port becomes floating. These waveform output control bits 0, 1 are cleared to “0” by reset, by inputting a falling edge to pin P4OUTCUT, or by executing instructions. MI ELI Y NAR . . nge tion ifica t to cha pec al s subjec in f are ot a is n limits his e: T ametric ic t No e par Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Pulse output port example Signal output each time timer A5 becames 000016 RTP23 RTP22 RTP21 RTP20 Example of pulse width modulation for above pulse output port using timer A6 Signal output each time timer A5 becames 000016 RTP23 RTP22 RTP21 RTP20 Pulse output port example in the case of pulse output polarity select bit = “1” Signal output each time timer A8 becames 000016 RTP31 RTP30 Fig. 58 Example waveforms in pulse mode 0 Pulse output port example Signal output each time timer A5 becames 000016 RTP31 RTP30 RTP23 RTP22 RTP21 RTP20 Example of pulse width modulation for above pulse output port using timer A6 Signal output each time timer A5 becames 000016 RTP31 RTP30 RTP23 RTP22 RTP21 RTP20 Fig. 59 Example waveforms in pulse mode 1 53 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in f s are ot a is n limits his e: T ametric ic t No e par Som PR 16-BIT CMOS MICROCOMPUTER SERIAL I/O PORTS Two independent serial I/O ports are provided. Figure 60 shows a block diagram of the serial I/O ports. Bits 0 through 2 of the UARTi(i = 0, 1, 2) transmit/receive mode register shown in Figure 61 are used to determine whether to use ports P1 and P8 as programmable I/O ports, clock synchronous serial I/O ports, or asynchronous (UART) serial I/O ports which use start and stop bits. Figures 62 and 63 show the block diagrams of the receiver/transmitter. Figure 64 shows the bit configuration of the UARTi transmit/receive control register. Each communication method is described below. Data bus (odd) Data bus (even) Bit converter UARTi D7 D6 D5 D4 D3 D2 D1 D0 receive buffer register UART0 (Addresses 3716, 3616) UART1 (Addresses 3F16, 3E16) UART2 (Addresses B716, B616) 0 0 0 0 0 0 0 D8 RXDi UARTi receive register BRG count source select bits f2 f16 BRGi f64 1/(n + 1) divider f512 1/16 divider UART Clock synchronous 1/16 divider UART Clock synchronous Receive control circuit Transmit control circuit Transfer clock Transfer clock Clock synchronous (Internal clock) 1/2 divider UARTi transmit register Clock synchronous (External clock) TXDi Clock synchronous (when internal clock selected) D8 UARTi transmit buffer register UART0 (Addresses 3316, 3216) UART1 (Addresses 3B16, 3A16) UART2 (Addresses B316, B216) D7 D6 D5 D4 D3 D2 D1 D0 CLKi CTSi/CLKi CTSi Bit converter CTSi/RTSi Data bus (odd) n = a value set into the UARTi baud rate register (BRGi) Data bus (even) Fig. 60 Block diagram of serial I/O port 7 6 5 4 3 2 1 0 Addresses 3016 UART 0 Transmit/Receive mode register 3816 UART 1 Transmit/Receive mode register B016 UART 2 Transmit/Receive mode register Serial I/O mode select bits 0 0 0 : Serial I/O is invalid. (Ports P1 and P8 function as programmable I/O ports.) 0 0 1 : Clock synchronous 1 0 0 : 7-bit UART 1 0 1 : 8-bit UART 1 1 0 : 9-bit UART Internal/External clock select bit 0 : Internal clock 1 : External clock Stop bit length select bit (Valid in UART mode.) 0 : 1 stop bit 1 : 2 stop bits Odd/Even parity select bit (Valid in UART mode with the parity enable bit = “1”.) (Note) 0 : Odd parity 1 : Even parity Parity enable bit (Valid in UART mode) (Note) 0 : No parity 1 : With parity Sleep select bit (Valid in UART mode) (Note) 0 : No sleep 1 : Sleep Note: In the clock synchronous serial I/O mode, bits 4 to 6 are invalid. (Each of them may be “0” or “1”.) Furthermore, fix bit 7 to “0”. Fig. 61 Bit configuration of UARTi transmit/receive mode register 54 MI I L E MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . tion hange c ifica pec ject to s l fina sub ot a its are is n his tric lim T : me ice Not e para Som PR 16-BIT CMOS MICROCOMPUTER Data bus (odd) Data bus (even) UARTi receive buffer register 0 0 0 0 0 2SP R XD i PAR D7 D6 D5 D4 D3 D2 D1 D0 8-bit UART 9-bit UART Synchronous UART No parity 1SP D8 0 9-bit UART Parity SP SP 0 7-bit UART 7-bit UART 8-bit UART Synchronous UARTi receive register Synchronous SP : Stop bit PAR : Parity bit Fig. 62 Block diagram of receiver Data bus (odd) Data bus (even) UARTi receive transmit register D8 2SP SP SP D6 D5 D4 D3 D2 D0 TXDi UART 8-bit UART No parity D1 8-bit UART 7-bit UART 9-bit UART 9-bit UART Synchronous Synchronous Parity PAR 1SP D7 7-bit UART UARTi transmit register Synchronous “0” SP : Stop bit PAR : Parity bit Fig. 63 Block diagram of transmitter 55 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR 7 6 5 4 MSB CPL /LSB 7 6 3 16-BIT CMOS MICROCOMPUTER 2 TX R/C EPTY 5 4 SUM PER FER OER 1 0 CS1 CS0 3 2 1 0 RI RE TI TE Address UART0 transmit/receive control register 0 34 16 3C16 UART1 transmit/receive control register 0 B416 UART2 transmit/receive control register 0 BRG count source select bits 0 0 : f2 0 1 : f16 1 0 : f64 1 1 : f512 CTS/RTS function select bit (Note 1) 0 : CTS function is selected. 1 : RTS function is selected. Transmit register empty flag 0 : Data is present in the transmit register. (Transmission is in progress.) 1 : No data is present in the transmit register. (Transmission is completed.) CTS/RTS enable bit 0 : CTS, RTS function is enabled. 1 : CTS, RTS function is disabled. UARTi receive interrupt mode select bit 0 : Reception interrupt 1 : Reception error interrupt CLK polarity select bit (This bit is used in the clock synchronous serial I/O mode.) (Note 2) 0 : At the falling edge of a transfer clock, transmit data is output; at the rising edge, receive data is input. When not in transfer, pin CLK’s level is “H”. 1 : At the rising edge of a transfer clock, transmit data is output; at the falling edge, receive data is input. When not in transfer, pin CLK’s level is “L”. Transfer format select bit (This bit is used in the clock synchronous serial I/O mode.) (Note 2) 0 : LSB (Least Significant Bit) first 1 : MSB (Most Significant Bit) first UART0 transmit/receive control register 1 UART1 transmit/receive control register 1 UART2 transmit/receive control register 1 Transmit enable bit Transmit buffer empty flag Receive enable bit Receive complete flag Overrun error flag Framing error flag (Note 3) Parity error flag (Note 3) Error sum flag (Note 3) Notes 1: Valid when the CTS/RTS enable bit (bit 4) = “0”. 2: Fix these bits to “0” in UART mode or when serial I/O is invalid. 3: Valid in UART mode. Fig. 64 Bit configuration of UARTi transmit/receive control register 56 Address 3516 3D16 B516 MI I L E MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . tion hange c ifica pec ject to s l fina sub ot a its are is n his tric lim T : me ice Not e para Som PR 16-BIT CMOS MICROCOMPUTER CLOCK SYNCHRONOUS SERIAL COMMUNICATION A case where communication is performed between two clock synchronous serial I/O ports as shown in Figure 65 will be described. (The transmission side will be denoted by subscript j and the receiving side will be denoted by subscript k.) Bit 0 of the UARTj transmit/receive mode register and UARTk transmit/receive mode register must be set to “1” and bits 1 and 2 must be “0”. The length of the transmission data is fixed at 8 bits. Bit 3 of the UARTj transmit/receive mode register of the clock sending side is cleared to “0” to select the internal clock. Bit 3 of the UARTk transmit/receive mode register of the clock receiving side is set to “1” to select the external clock. Bits 4, 5 and 6 are ignored in clock synchronous mode. Bit 7 must always be “0”. The clock source is selected by bit 0 (CS0) and bit 1 (CS1) of the clock-sending-side UARTj transmit/receive control register 0. As shown in Figure 60, the selected clock is divided by (n + 1), then by 2, is passed through a transmission control circuit, and is output as transmission clock CLKj. Therefore, when the selected clock is fi, On the clock receiving side, the CS0 and CS1 bits of the UARTk transmit/receive control register 0 are ignored because an external clock is selected. Both of UART0 and UART1 can use CTS and RTS functions. Bit 4 of the UARTi transmit/receive control register 0 is used to determine whether to use CTS or RTS signal. Bit 4 must be “0” when CTS or RTS signal is used. Bit 4 must be “1” when CTS and RTS signals are not used. When CTS and RTS signals are not used, CTS/ RTS pin can be used as a normal port pin. When using pin CTS/RTS, : • If bit 2 of the UARTi transmit/receive control register 0 is cleared to “0”, CTS input is selected. • If bit 2 is set to “1”, RTS output is selected. The case using CTS and RTS signals are explained below. As shown in Figure 72, bits 2, 3 and 5 of the serial I/O pin control register can determine whether port pins P13, P17 and P83 are used as pins TxDi or as port pins. When bits 2, 3 and 5 are “0”, P13, P17 and P83 function as pins TxDi; when bits 2, 3 and 5 are “1”, P13, P17 and P83 function as port pins. Therefore, in the input-only system where pins TxDi are not used, pins TxDi can function as port pins. Bit Rate = fi/ {(n + 1) × 2} TxDj TxDk UARTj transmit register UARTk transmit register UARTj transmit buffer register UARTk transmit buffer register UARTj receive buffer register UARTk receive buffer register RxDj RxDk UARTj receive register UARTk receive register UARTj Transmit/Receive mode register 0 0 0 0 UARTk Transmit/Receive mode register 0 1 CLKj RI RE TI 0 1 UARTk Transmit/Receive control register 0 TX MSB CPL /LSB EPTY 1 CTSj SUM PER FER OER 0 CLKk UARTj Transmit/Receive control register 0 TX MSB CS1 CS0 CPL /LSB EPTY 0 UARTj Transmit/Receive control register 1 1 RTSk UARTk Transmit/Receive control register 1 TE SUM PER FER OER RI RE TI TE Fig. 65 Clock synchronous serial communication 57 MI ELI Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Transmission Transmission is started when bit 0 (TEj flag: transmit enable bit) of UARTj transmit/receive control register 1 is “1”, bit 1 (TIj flag) of one is “0”, and CTSj input is “L”. The TIj flag indicates whether the transmit buffer register is empty or not. It is cleared to “0” when data is written in the transmit buffer register; it is set to “1” when the contents of the transmit buffer register is transferred to the transmit register and the transmit buffer register becomes empty. When all of the transmit conditions are satisfied, the transmit data in the transmit buffer register are transferred to the transmit register, and transmission starts. As shown in Figure 66, data is output from TxDj pin each time when transmission clock CLKj changes from “H” to “L”. (In the clock synchronous serial I/O mode, the polarity of a transfer clock can be changed. For details, refer to the section on the selection of the transfer clock polarity.) The data is output from the least significant bit. When the transmit register becomes empty after the contents has been transmitted, data is transferred automatically from the transmit buffer register to the transmit register if the next transmission start condition is satisfied. The next transmission is performed succeedingly. Once transmission has started, the TEj flag, TIj flag, and CTSj signals are ignored until data transmission completes. Therefore, transmission is not interrupted when CTS j input is changed to “H” during transmission. The transmission start condition indicated by TEj flag, TIj flag, and CTSj is checked while the TENDj signal (shown in Figure 66) is “H”. Therefore, data can be transmitted continuously if the next transmission data is written in the transmit buffer register and TIj flag is cleared to “0” before theTENDj signal goes “H”. Bit 3 (TXEPTYj flag) of UARTj transmit/receive control register 0 changes to “1” at the next cycle just after the TENDj signal goes “H” and changes to “0” when transmission starts. Therefore, this flag can be used to determine whether data transmission has completed. When the TIj flag changes from “0” to “1”, the interrupt request bit in the UARTj transmit interrupt control register is set to “1”. Receive When bit 2 (REk flag) of the UARTk transmit/receive control register 1 is set to “1”, reception becomes enabled. In this case, when the CLKk signal is input, the receive operation starts simultaneously with this signal. The RTSk output is “H” when the REk flag is “0”. When the REk flag is set to “1”, the RTSk output becomes “L”. This informs the transmitter side that reception becomes enabled. When the receive operation starts, the RTSk output automatically becomes “H”. When the receive operation starts, the receiver takes data from pin RxDk each time when the transmit clock (CLKj) turns from “L” to “H”. Simultaneously with reception, the contents of the receiver register is shifted bit by bit. (Note that, in the clock synchronous serial communication, the polarity of a transfer clock can be inverted. For details, refer to the section on the polarity of the transfer clock.) When an 8-bit data is received, the contents of the receive register is transferred to the receive buffer register and bit 3 (RIk flag) of UARTk transmit/receive control register 1 is set to “1”. In other words, the setting “1” to the RIk flag indicates that the receive buffer register contains the received data. At this time, if the low-order byte of the UARTk receive buffer register is 58 16-BIT CMOS MICROCOMPUTER read out, the RTSk output turns back to “L”. This indicates that the next data reception becomes enabled. Bit 4 (OERk flag) of UARTk transmit/receive control register 1 is set to “1” when the next data is transferred from the receive register to the receive buffer register while RIk flag is “1”, and indicates that the next data was transferred to the receive register before the contents of the receive buffer register was read. (In other words, this indicates that an overrun error has occurred.) RIk flag is automatically cleared to “0” when the low-order byte of the receive buffer register is read or when the REk flag is cleared to “0”. The OERk flag is cleared when the REk flag is cleared. Bit 5 (FERk flag), bit 6 (PERk flag), and bit 7 (SUMk flag) are ignored in clock synchronous mode. As shown in Figure 60, with clock synchronous serial communication, data cannot be received unless the transmitter is operating because the receive clock is created from the transmission clock. Therefore, the transmitter must be operating even when there is no need to sent data from UARTk to UARTj. MI I L E MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . tion hange c ifica pec ject to s l fina sub ot a its are is n his tric lim T : me ice Not e para Som PR 16-BIT CMOS MICROCOMPUTER 1/fi × (n + 1) × 2 Transmission clock TEj TIj Write in transmit buffer register Transmit register ←Transmit buffer register CTSj 1/fi × (n + 1) × 2 Stopped because TEj = “0” CLKj TENDj TXDj D0 D1 D2 D3 D4 D5 D6 D7 D0 D1 D2 D3 D4 D5 D6 D7 D0 D1 D2 D3 D4 D5 D6 D7 TXEPTYj Fig. 66 Clock synchronous serial I/O timing Interrupt request at completion of reception When the RIk flag changes from “0” to “1”, in other words, when the receive operation is completed, the interrupt request bit of the UARTk receive interrupt control register can be set to “1”. The timing when this interrupt request bit is to be set to “1” can be selected from the following: • Each reception • When an error occurs at reception If bit 5 of the UARTk transmit/receive control register 0 (UART receive interrupt mode select bit) is cleared to “0”, the interrupt request bit is set to “1” at each reception. If bit 5 is set to “1”, the interrupt request bit is set to “1” only when an error occurs. (In the clock synchronous serial communication, only when an overrun error occurs, the interrupt request bit is set to “1”.) Polarity of transfer clock In the clock synchronous serial communication, by bit 6 of the UARTj transmit/receive control register 0 (CPL), the polarity of a transfer clock can be selected. As shown in Figure 67, when bit 6 = “0”, the polarity is as follows: • In transmission, transmit data is output at the falling edge of CLKj. • In reception, receive data is input at the rising edge of CLKk. • When not in transfer, CLKi is at “H” level. When bit 6 = “1”, the polarity is as follows: • In transmission, transmit data is output at the rising edge of CLKj. • In reception, receive data is input at the rising edge of CLKk. • When not in transfer, CLKi is at “L” level. 59 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR 16-BIT CMOS MICROCOMPUTER ■ CLK polarity select bit = 0 CLKi TxDi D0 D1 D2 D3 D4 D5 D6 D7 RxDi D0 D1 D2 D3 D4 D5 D6 D7 ❇ Transmit data is output to pin TxDi at the falling edge of transfer clock, and receive data is input from pin RxDi at the rising edge of transfer clock. When not in transfer, pin CLKi’s level is “H”. ■ CLK polarity select bit = 1 CLKi TxDi D0 D1 D2 D3 D4 D5 D6 D7 RxDi D0 D1 D2 D3 D4 D5 D6 D7 ❇ Transmit data is output to pin TxDi at the rising edge of transfer clock, and receive data is input from pin RxDi at the falling edge of transfer clock. When not in transfer, pin CLKi’s level is “L”. Fig. 67 Polarity of transfer clock 60 MI I L E MITSUBISHI MICROCOMPUTERS Y NAR . . tion hange c ifica pec ject to s l fina sub ot a its are is n his tric lim T : me ice Not e para Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Selection of transfer format the transmit buffer register and the receive buffer register when writing transmit data to the transmit buffer register or reading receive data from the receive buffer register. Accordingly, the transmitter’s operation is the same in both transfer formats. Figure 68 shows the connection relation. In clock synchronous serial communication, transfer format can be selected by bit 7 of the transmit/receive control register 0. When bit 7 is “0”, transfer format is LSB first. When bit 7 is “1”, transfer format is MSB first. This function is realized by changing connection relation between Bit 7 in transmit/receive control register 0 Write to transmit buffer register Data bus 0 (LSB first) Transmit buffer register Data bus Receive buffer register DB7 D7 DB7 D7 DB6 D6 DB6 D6 DB5 D5 DB5 D5 DB4 D4 DB4 D4 DB3 D3 DB3 D3 DB2 D2 DB2 D2 DB1 D1 DB1 D1 DB0 D0 DB0 D0 Data bus 1 (MSB first) Read from receive buffer register Transmit buffer register Data bus Receive buffer register DB7 D7 DB7 D7 DB6 D6 DB6 D6 DB5 D5 DB5 D5 DB4 D4 DB4 D4 DB3 D3 DB3 D3 DB2 D2 DB2 D2 DB1 D1 DB1 D1 DB0 D0 DB0 D0 Fig. 68 Connection relation between transmit buffer register, receive buffer register, and data bus Precautions for clock synchronous serial communication In the clock synchronous serial communication, the separate function for CTSi/RTSi cannot be selected. Furthermore, when an internal clock is selected, RTS output is undefined. Therefore, do not use the RTS function. Before transmit operation is performed, be sure to clear bits 2, 3 and 5 of the serial I/O pin control register (address AC16) to “00”. 61 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER ASYNCHRONOUS SERIAL COMMUNICATION Bit 4 is the stop bit length select bit to select 1 stop bit or 2 stop bits. Bit 5 is a select bit of odd parity or even parity. In the odd parity mode, the parity bit is adjusted so that the sum of 1s in the data and parity bit is always odd. In the even parity mode, the parity bit is adjusted so that the sum of the 1s in the data and parity bit is always even. Bit 6 is the parity bit select bit which indicates whether to add parity bit or not. Bits 4 to 6 must be set or reset according to the data format used in the communicating devices. Bit 7 is the sleep select bit. The sleep mode is described later. Figure 72 shows the bit configuration of the serial I/O pin control register. By bits 0, 1 and 4 of the serial I/O pin control register (CTSi/ RTSi separate select bits), the function of the CTS/RTS pin can be separated into two functions, and each function can be assigned to two different pins. When each of bits 0, 1 and 4 = “1”, the above separation is performed. When each of bits 0, 1 and 4 = “0”, no separation is performed. Table 8 lists the selection methods of the CTS/RTS function. Asynchronous serial communication can be performed using 7-, 8-, or 9-bit length data. The operation is the same for all data lengths. The following is the description for 8-bit asynchronous communication. With 8-bit asynchronous communication, bit 0 of UARTi transmit/receive mode register is “1”, bit 1 is “0”, and bit 2 is “1”. Bit 3 is used to select an internal clock or an external clock. If bit 3 is “0”, an internal clock is selected and if bit 3 is “1”, then external clock is selected. If an internal clock is selected, bit 0 (CS0) and bit 1 (CS1) of UARTi transmit/receive control register 0 are used to select the clock source. When an internal clock is selected for asynchronous serial communication, the CLKi pin can be used as a normal I/O pin. The selected internal or external clock is divided by (n + 1), then by 16, and is passed through a control circuit to create the UART transmission clock or UART receive clock. Therefore, the transmission speed can be changed by changing the contents (n) of the bit rate generator. If the selected clock is an internal clock Pfi or an external clock fEXT, Bit Rate = (fi or fEXT) / {(n+1)×16} (1/fi or 1/fEXT) × (n + 1) × 16 Transmission clock TEi TIi Transmit register ← Transmit buffer register Written in transmit buffer register CTSi TENDi Start bit TXDi Stopped because TEi = “0” Parity bit Stop bit ST D0 D1 D2 D3 D4 D5 D6 D7 P SP ST D0 D1 D2 D3 D4 D5 D6 D7 P SP ST D0 D1 TXEPTYi Fig. 69 Transmit timing example when 8-bit asynchronous communication with parity and 1 stop bit selected (1/fi or 1/fEXT) × (n + 1) × 16 Transmission clock TEi TIi Transmit register ← Transmit buffer register Written in transmit buffer register TENDi Start bit TXDi Stop bit Stop bit Stopped because TEi = “0” ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP SP ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP SP TXEPTYi Fig. 70 Transmit timing example when 9-bit asynchronous communication with no parity and 2 stop bits selected 62 ST D0 D1 D2 MI I L E MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP . . tion hange c ifica pec ject to s l fina sub ot a its are is n his tric lim T : me ice Not e para Som PR 16-BIT CMOS MICROCOMPUTER Transmission Transmission is started when bit 0 (TEi flag transmit enable flag) of UARTi transmit/receive control register 1 is “1”, bit 1 (TIi flag) is “0”, and CTSi input (in other words, transmit enable signal input from receiver) is “L”. The TIi flag indicates whether the transmit buffer is empty or not. It is cleared to “0” when data is written in the transmit buffer; it is set to “1” when the contents of the transmit buffer register is transferred to the transmit register. When all of the transmission conditions are satisfied, transmit data is transferred to the transmit register, and transmit operation starts. As shown in Figures 69 and 70, data is output from the TXDi pin with the stop bit or parity bit specified by bits 4 through 6 of UARTi transmit/receive mode register. The data is output from the least significant bit. When the transmit register becomes empty after the contents has been transmitted, data is transferred automatically from the transmit buffer register to the transmit register if the next transmit start condition is satisfied. Then, the next transmission is performed succeedingly. Once transmission has started, the TEi flag, TIi flag, and CTSi signal are ignored until data transmission is completed. Therefore, transmission does not stop until it completes event if, during transmission, the TEi flag is cleared to “0” or CTSi input is set to “1”. The transmission start condition indicated by TEi flag, TIi flag, and CTSi is checked while the TENDi signal shown in Figure 69 is “H”. Therefore, data can be transmitted continuously if the next transmission data is written in the transmit buffer register and TIi flag is cleared to “0” before the TENDi signal goes “H”. Bit 3 (TXEPTYi flag) of UARTi transmit/receive control register 0 changes to “1” at the next cycle just after the TENDi signal goes “H” and changes to “0” when transmission starts. Therefore, this flag can be used to determine whether data transmission is completed. When the TIi flag changes from “0” to “1”, the interrupt request bit of the UARTi transmit interrupt control register is set to “1”. fi or fEXT REi Stop bit RXDi Start bit Check to be “L” level Receive clock D1 D0 Start bit D7 Data fetched Starting at the falling edge of start bit RIi RTSi Fig. 71 Receive timing example when 8-bit asynchronous communication with no parity and 1 stop bit selected 63 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR . ion. hange icat ecif ct to c p s al bje a fin are su not s is is ric limit h T t me ice: Not e para Som PR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Table 8. Selection methods of CTS/RTS function Functions CTS/RTS CTSi/RTSi CTS/RTS enable bit separate select bit function select bit Pin P10/CTS0/RTS0 Pin P11/CTS0/CLK0 Pin P14/CTS1/RTS1 Pin P15/CTS1/CLK1 Pin P80/CTS2/RTS2 Pin P81/CTS2/CLK2 0 CTS1 CTS2 CTS0 P15 or CLK1 P81 or CLK2 P11 or CLK0 0 1 RTS1 RTS2 RTS0 0 P15 or CLK1 P81 or CLK2 P11 or CLK0 1 CTS1 (Notes 1 and 2) CTS2 (Notes 1, 2) CTS0 (Notes 1, 2) ✕ RTS1 RTS2 RTS0 1 ✕ ✕ P14 P80 P15 or CLK1 P81 or CLK2 P11 or CLK0 P10 ✕: It may be “0” or “1”. Notes 1: When using the CTS function, be sure to clear the corresponding bit of the port P1 and port P8 direction registers to “0”. 2: When CTSi and RTSi has been separated, the CLKi pin cannot be used. Therefore, in the clock synchronous serial communication, CTSi and RTSi cannot be separated. Also, when CTSi and RTSi are separated in UART mode, be sure to select an internal clock. Receive 7 6 5 4 3 2 1 0 Address Serial I/O pin control register AC16 CTS0/RTS0 separate select bit 0 : CTS0/RTS0 are used together. 1 : CTS0/RTS0 are separated. CTS1/RTS1 separate select bit 0 : CTS1/RTS1 are used together. 1 : CTS1/RTS1 are separated. TxD0/P13 switch bit 0 : Functions as TxD0. 1 : Functions as P13. TxD1/P17 switch bit 0 : Functions as TxD1. 1 : Functions as P17. CTS2/RTS2 separate select bit 0 : CTS2/RTS2 are used together. 1 : CTS2/RTS2 are separated. TxD2/P83 switch bit 0 : Functions as TxD2. 1 : Functions as P83. Fig. 72 Bit configuration of serial I/O pin control register 64 Receive is enabled when bit 2 (REi flag) of UARTi transmit/receive control register 1 is set to “1.” As shown in Figure 71, the frequency divider circuit (1/16) at the receiving side begin to work when a start bit arrives and the data is received. If RTSi output is selected by setting bit 2 of UARTi transmit/receive control register 0 to “1”, the RTSi output is “H” when the REi flag is “0”. When the REi flag changes to “1”, the RTSi output goes “L” to inform the receiver that reception has become enabled. When the receive operation starts, the RTSi output automatically becomes “H”. The entire transmission data bits are received when the start bit passes the final bit of the receive block shown in Figure 62. At this point, the contents of the receive register is transferred to the receive buffer register and bit 3 (Rli flag) of UARTi transmit/receive control register 1 is set to “1.” In other words, the RIi flag indicates that the receive buffer register contains data when it is set to “1.” At this time, when the low-order byte of the UARTk receive buffer register is read out, RTSi output goes back to “L” to indicate that the register is ready to receive the next data. Bit 4 (OERi flag) of UARTi transmit/receive control register 1 is set to “1” when the next data is transferred from the receive register to the receive buffer register while the RIi flag is “1”, in other words, when an overrun error occurs. If the OERi flag is “1”, it indicates that the next data has been transferred to the receive buffer register before the contents of the receive buffer register has been read. Bit 5 (FERi flag) is set to “1” when the number of stop bits is less than required (framing error). Bit 6 (PERi flag) is set to “1” when a parity error occurs. Bit 7 (SUMi flag) is set to “1” when either the OERi flag, FERi flag, or the PERi flag is set to “1.” Therefore, the SUMi flag can be used to determine whether there is an error. The setting of the RIi flag, OERi flag, FERi flag, and the PERi flag is performed while transferring the contents of the receive register to the receive buffer register. MI I L E Y NAR . . tion hange c ifica pec ject to s l fina sub ot a its are is n his tric lim T : me ice Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER The FERi, PERi, and SUMi flags are cleared to “0” when reading the low-order byte of the receive buffer register or when writing “0” to the REi flag. The OERi flag is cleared to “0” when writing “0” to the REi flag. Interrupt request at completion of reception When the RIk flag changes from “0” to “1”, in other words, when the receive operation is completed, the interrupt request bit of the UARTk receive interrupt control register can be set to “1”. The timing when this interrupt request bit is to be set to “1” can be selected from the following: • Each reception • When an error occurs at reception If bit 5 of the UARTk transmit/receive control register 0 (UART receive interrupt mode select bit) is cleared to “0”, the interrupt request bit is set to “1” at each reception. If bit 5 is set to “1”, the interrupt request bit is set to “1” only when an error occurs. (In the clock asynchronous serial communication, when an overrun error, framing error, or parity error occurs, the interrupt request bit is set to “1”.) Sleep mode The sleep mode is used to communicate only between certain microcomputers when multiple microcomputers are connected through serial I/O. The microcomputer enters the sleep mode when bit 7 of UARTi transmit/receive mode register is set to “1”. The operation of the sleep mode for an 8-bit asynchronous communication is described below. When sleep mode is selected, the contents of the receive register is not transferred to the receive buffer register if bit 7 (bit 6 if 7-bit asynchronous communication and bit 8 if 9-bit asynchronous communication) of the received data is “0”. Also the RIi, OERi, FERi, PERi, and the SUMi flags are unchanged. Therefore, the interrupt request bit of the UARTi receive interrupt control register is also unchanged. Normal receive operation takes place when bit 7 of the received data is “1”. The following is an example of how the sleep mode can be used. The main microcomputer first sends data: bit 7 is “1” and bits 0 to 6 are set to the address of the subordinate microcomputer to be communicated with. Then all subordinate microcomputers receive this data. Each subordinate microcomputer checks the received data, clears the sleep bit to “0” if bits 0 through 6 are its own address and sets the sleep bit to “1” if not. Next, the main microcomputer sends data with bit 7 cleared. Then the microcomputer which cleared the sleep bit will receive the data, but the microcomputers which set the sleep bit to “1” will not. In this way, the main microcomputer is able to communicate only with the designated microcomputer. Precautions for clock asynchronous (UART) serial communication When CTSi and RTSi are separated, pin CLKi cannot be used. Therefore, when CTSi and RTSi are separated in UART mode, be sure to select an internal clock. Before transmit operation is performed, be sure to clear bits 2, 3 and 5 of the serial I/O pin control register (address AC16) to “00”. 65 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a u fin s ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER A-D CONVERTER The A-D converter is a 10-bit successive approximation converter. The use of A-D converter or the use of comparator can be selected for each A-D input pin. The contents of the comparator function select register specify it. Figure 73 shows a block diagram of the A-D converter. f1 Selection of A-D conversion frequency (1,1) (1,0) V 1/2 VREF connection select bit VREF AVSS (0,1) 1/2 f2 φAD (0,0) A-D conversion frequency (φAD) select bits 1, 0 0 Vref Resistor ladder network 1 A-D control register 2 Comparator function select register 1 Comparator function select register 0 A-D control register 1 Selector 1 Control circuit Successive approximation register A-D control register 0 Selector Comparator result register 1 Comparator result register 0 A-D register 0 A-D register 1 Comparator A-D register 2 A-D register 3 A-D register 4 A-D register 5 Decoder A-D register 6 A-D register 7 A-D register 8 A-D register 9 A-D register 10 A-D register 11 Data bus (odd) Data bus (even) AN0 AN1 AN2 AN3 AN4 AN5 AN6 AN7 AN8 AN9 AN10 AN11 Selector Fig. 73 Block diagram of A-D converter 66 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP Figure 74 shows the bit configuration of the comparator function select register 0 (address DC16), and Figure 75 shows that of the comparator function select register 1 (address DD16). Each of bits 7 to 0 corresponds to its own channel, respectively. Each channel can be selected as either an A-D converter or a comparator. When the bit is “0”, the channel corresponding to it functions as a 10-bit or an 8-bit A-D converter. When the bit is “1”, the channel functions as a comparator. When selecting an A-D converter, an input voltage to a selected analog input pin is A-D converted and the result is stored into one of these A-D registers. When selecting a comparator, D-A conversion is performed to the value of which high-order 8 bits are the value stored in an even address of the A-D converter and of which low-order 2 bits are “102.” Then, this D-A converted value is compared with the voltage supplied to an analog input pin. After the comparison, when the voltage supplied to an analog input pin is higher, “1” is stored into the comparator result register 0 (address DE16) shown in Figure 76, or the comparator result register 1 (Address DF16) shown in Figure 77. When it is lower, “0” is stored into that of these register. Be sure to perform only read to the A-D register of which channel is selected as an A-D converter, and perform only write to the A-D register of which channel is selected as a comparator. Additionally, do not write to the comparator function select registers 0, 1 and the A-D register while an A-D converter or a comparator is operating. Port direction register’s bits corresponding to pins to be A-D converted must be “0” (input mode) because analog input ports are multiplexed with ports P7 and P8. Figure 78 shows the bit configuration of the A-D control register 0 (address 1E16), Figure 79 shows that of the A-D control register 1 (address 1F16), and Figure 80 shows that of the A-D control register 2 (address DB16). The operation clock of the A-D converter, φAD, is selected by the following bits: bit 7 of the A-D control register 0 and bit 4 of the A-D control register 1. When bit 4 of the A-D control register 1 = “0”, φAD is selected as follows: • if bit 7 of the A-D control register 0 = “0”, φAD = f2/4. • if bit 7 of the A-D control register 0 = “1”, φAD = f2/2. When bit 4 of the A-D control register 1 = “1”, φAD is selected as follows: • if bit 7 of the A-D control register 0 = “0”, φAD = f2. • if bit 7 of the A-D control register 0 = “1”, φAD = f1. Note that the highest frequency, φAD = f1, can be selected only in the 8-bit resolution mode. φAD during A-D conversion must be 250 kHz or more because the comparator uses a capacity coupling amplifier. Bit 3 of A-D control register 1 is used to select whether to regard the conversion result as 10-bit or as 8-bit data. The conversion result is regarded as 10-bit data when bit 3 is “1” and as 8-bit data when bit 3 is “0”. When the conversion result is used as 10-bit data, the low-order 8 bits of the conversion result are stored in the even address of the corresponding A-D register and the high-order 2 bits are stored in bits 0 and 1 at the odd address of the corresponding A-D register. Bits 2 to 7 of the A-D register odd address are “0000002” when read. When the conversion result is used as 8-bit data, the high-order 8 16-BIT CMOS MICROCOMPUTER bits of the 10-bit A-D conversion result are stored in even address of the corresponding A-D register. In this case, the value at the A-D register’s odd address is “0016” when read. Whether to connect the reference voltage input (VREF) with the ladder network or not depends on bit 5 of the A-D control register 1. The VREF pin is connected when bit 5 is “0” and is disconnected when bit 5 is “1” (High impedance state). When A-D or D-A conversion is not performed, current from the VREF pin to the ladder network can be cut off by disconnecting ladder network from the VREF pin. Before starting A-D conversion, wait for 1 µs or more after clearing bit 5 to “0”. 67 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 7 6 5 4 3 2 1 16-BIT CMOS MICROCOMPUTER 0 Comparator function select register 0 Address DC16 7 6 5 4 3 2 1 0 Comparator result register 0 AN0 pin comparator result bit AN1 pin comparator result bit AN2 pin comparator result bit AN3 pin comparator result bit AN4 pin comparator result bit AN5 pin comparator result bit AN6 pin comparator result bit AN7 pin comparator result bit AN0 pin comparator function select bit AN1 pin comparator function select bit AN2 pin comparator function select bit AN3 pin comparator function select bit AN4 pin comparator function select bit AN5 pin comparator function select bit AN6 pin comparator function select bit AN7 pin comparator function select bit 0 : A-D converter is selected. 1 : Comparator is selected. Fig. 74 Bit configuration of comparator function select register 0 7 0 6 0 5 0 4 0 3 2 1 0 Comparator function select register 1 Address DC16 AN8 pin comparator function select bit AN9 pin comparator function select bit AN10 pin comparator function select bit AN11 pin comparator function select bit Fix these bits to “0000”. “0” : A-D converter is selected. “1” : Comparator is selected. Fig. 75 Bit configuration of comparator function select register 1 68 Address DE16 0 : ANi input level is lower than set digital value 1 : ANi input level is higher than set digital value Note: Do not access with the ORAM(ORAMB) or ANDM(ANDMB) instruction. Fig. 76 Bit configuration of comparator result register 0 7 6 5 4 3 2 1 0 Comparator result register 1 Address DE16 AN8 pin comparator result bit AN9 pin comparator result bit AN10 pin comparator result bit AN11 pin comparator result bit 0 : ANi input level is lower than set digital value 1 : ANi input level is higher than set digital value Note: Do not access with the ORAM(ORAMB) or ANDM(ANDMB) instruction. Fig. 77 Bit configuration of comparator result register 1 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a u fin s ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER Operation mode The operation mode is selected by bits 3 and 4 of A-D control register 0 and bit 2 of A-D control register 1. The available operation modes are one-shot, repeat, single sweep, repeat sweep 0, and repeat sweap 1. Note that, as for pins AN8 through AN11, only one-shot and repeat modes can be selected. Either an A-D converter or a comparator can be selected respectively for each pin in the following 5 modes. The following description applies to the case where the bit of the comparator function select register 0/1 is “0” and an A-D converter is selected. It also applies to a comparator’s operation except that an A-D conversion is changed to a comparator operation and the result of the comparison is stored into the comparator result register 0/1. (1) One-shot mode One-shot mode is selected when bits 3 and 4 of A-D control register 0 are “0”. The A-D conversion pins are selected with bits 0 to 2 of A-D control register 0 and bits 0 to 3 of A-D control register 2. A-D 7 6 5 0 4 3 2 1 0 A-D control register 0 conversion or comparator operation is started when bit 6 of A-D control register 0 (A-D conversion start bit) is set to “1”. When the ANi (i = 11 through 0) comparator function select bit of the comparator function select register 0/1 = “0” and bit 3 of the A-D control register 1 = “1”, A-D conversion ends 59 φAD cycles after, and the interrupt request bit of the A-D conversion interrupt control register is set to “1”. At the same time, bit 6 of the A-D control register 0 (A-D conversion start bit) is cleared to “0” and this A-D conversion stops. The result of A-D conversion is stored into the A-D register corresponding to the selected pin. When the ANi (i = 11 through 0) comparator function select bit of the comparator function select register 0/1 = “1”, a comparator operation ends 14 φAD cycles after, and the interrupt request bit of the A-D conversion interrupt control register is set to “1”. At the same time, bit 6 of the A-D control register 0 (A-D conversion start bit) is cleared to “0” and the comparator operation stops. The result of the comparison is stored into the bits of the comparator result register corresponding to the selected pin. Address 1E16 Analog input select bits (Note 1) (Valid in the one-shot mode and repeat mode.) 0 0 0 : AN0 0 0 1 : AN1 0 1 0 : AN2 0 1 1 : AN3 1 0 0 : AN4 1 0 1 : AN5 1 1 0 : AN6 1 1 1 : AN7 (Note 2) A-D operation mode select bit 0 0 0 : One-shot mode 0 1 : Repeat mode 1 0 : Single sweep mode 1 1 : Repeat sweep mode 0 or Repeat sweep mode 1 Fix this bit to “0”. A-D conversion start bit (Note 3) 0 : A-D conversion stopped. 1 : A-D conversion started. A-D conversion frequency (φAD) select bit 0 Notes 1: Invalid in the single sweep mode and repeat sweep mode 0. (Each of these bits may be “0” or “1”.) 2: When using pin AN7, make sure that the D-A0 output enable bit (bit 0 at address 9616) = “0” (output disabled). 3: Use the MOVM (MOVMB) or STA (STAB or STAD) instruction for rewriting to this bit. 4: Rewriting to each bit of the A-D control register 0 (except for bit 6) must be performed while A-D conversion is stopped. Fig. 78 Bit configuration of A-D control register 0 69 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 7 6 5 0 4 16-BIT CMOS MICROCOMPUTER 3 2 1 0 A-D control register 1 Address 1F16 A-D sweep pin select bits (Note 1) (Valid in the single sweep mode and repeat sweep mode.) 0 0 : AN0, AN1 (2 pins) 0 1 : AN0–AN3 (4 pins) 1 0 : AN0–AN4 (5 pins) 1 1 : AN0–AN7 (8 pins) (Note 2) A-D operation mode select bit 1 0: Modes other than repeat sweep mode 1 1: Repeat sweep mode 1 Resolution select bit 0: 8-bit resolution mode 1: 10-bit resolution mode A-D conversion frequency (φAD) select bit 1 Fix this bit to “0”. VREF connection select bit (Note 3) 0 : VREF is connected. 1 : VREF is disconnected. “0” at read. A-D conversion frequency (φAD) select bit φAD Bit 1 Bit 0 f2/4 0 0 1 0 f2/2 0 1 f2 f1 (Selectable only in 8-bit resolution mode) 1 1 Notes 1: Invalid in the one-shot mode and repeat mode. (Each of these bits may be “0” or “1”.) 2: When using pin AN7, make sure that the D-A0 output enable bit (bit 0 at address 9616) = “0” (output disabled). 3: Once this bit is cleared from “1” to “0”, it is necessary to wait for 1 µs or more before the A-D conversion starts. 4: Rewriting to each bit of the A-D control register 1 must be performed while A-D conversion is stopped. Fig. 79 Bit configuration of A-D control register 1 7 6 5 4 3 2 1 0 0 0 0 0 A-D control register 2 Address DB16 Analog input select bits (Note 1) (Valid in the one-shot mode and repeat mode) 0xxx : AN0–AN7 1000 : AN8 (Note 2) 1001 : AN9 1010 : AN10 1011 : AN11 1100 : Do not select. 1101 : Do not select. 1110 : Do not select. 1111 : Do not select. Notes 1: Invalid in the single sweep mode and repeat sweep mode 0 (Each of these bits may be “0” or “1”.) 2: When using pin AN8, make sure that the D-A1 output enable bit (bit 1 at address 9616) = “0” (output disabled). 3: Rewriting to each bit of the A-D control register 2 must be performed while A-D conversion is stopped. Fig. 80 Bit configuration of A-D control register 2 70 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP (2) Repeat mode Repeat mode is selected when bit 3 of the A-D control register 0 = “1” and bit 4 = “0”. The operation of this mode is the same as the operation of one-shot mode except that when A-D conversion for the selected pin is complete and the result is stored in the A-D register, conversion does not stop, but is repeated. No interrupt request is generated in this mode. Furthermore, the A-D conversion start bit is not cleared. The contents of the A-D register can be read at any time. Be sure not to write to the A-D register corresponding to the pins selected for a comparator during operation. 16-BIT CMOS MICROCOMPUTER pins selected as repeat sweep pins. No interrupt request is generated. Furthermore, the A-D conversion start bit is not cleared. The contents of the A-D register can be read at any time. Be sure not to write to the A-D register, corresponding to the pins selected for a comparator, during operation. Precaution for A-D conversion interrupts Clear the interrupt request bit of the A-D conversion interrupt control register (bit 3 at address 7016) before using an A-D conversion interrupt. It is because this interrupt request bit is undefined just after reset. (3) Single sweep mode Single sweep mode is selected when bit 3 of the A-D control register 0 = “0” and bit 4 = “1”. In the single sweep mode, the number of analog input pins to be swept can be selected. Analog input pins are selected by bits 1 and 0 of the A-D control register 1 (address 1F16). Two pins, four pins, or five pins can be selected as analog input pins, depending on the contents of these bits. A-D conversion is performed only for selected input pins. After A-D conversion is performed for input of AN0 pin, the conversion result is stored in A-D register 0, and in the same way, A-D conversion is performed for selected pins one after another. After A-D conversion is performed for all selected pins, the sweep is stopped. A-D conversion is started when bit 6 of the A-D control register 0 (A-D conversion start bit) is set to “1”. When A-D conversion for all selected pins end, the interrupt request bit of the A-D conversion interrupt control register is set to “1”. At the same time, A-D conversion start bit is cleared to “0” and A-D conversion stops. (4) Repeat sweep mode 0 Repeat sweep mode 0 is selected when bit 3 of the A-D control register 0 = “1” and bit 4 = “1”. The difference from the single sweep mode is that A-D conversion does not stop after conversion for all selected pins, but repeats again from the AN0 pin. The repeat is performed among the selected pins. Also, no interrupt request is generated. Furthermore, the A-D convension start bit is not cleared. The contents of the A-D register can be read at any time. Be sure not to write to the A-D register corresponding to the pins selected for a comparator during operation. (5) Repeat sweep mode 1 Repeat sweep mode 1 is selected when bit 3 of the A-D control register 0 = “1” and bit 4 = “1”, and bit 2 of the A-D control register 1 =“1”. The differences from the repeat sweap mode 0 are as follows: • the A-D conversion for one unselected pin is performed each time when A-D conversion for selected pins is completed, and the A-D conversion is repeated once again from AN0 pin. • the number of analog input pins to be swept. The analog input pins to be repeatedly swept are selected with bits 1 and 0 of the A-D control register 1. The contents of these pins are used to select one pin, two pins, three pins or four pins. The unselected pins are converted starting from the pin next to the 71 A IMIN MITSUBISHI MICROCOMPUTERS RY e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER D-A CONVERTER Two independent D-A converters are included in this microcomputer, and each D-A converter adopts an 8-bit R-2R method. Figure 81 shows the block diagram of the D-A converter, and Figure 82 shows the bit configuration of the D-A control register (address 9616). D-A conversion is performed by writing a value to the corresponding D-A register i. Whether to output the analog voltage or not is determined by bits 0 and 1 of the D-A control register. When any of bits 0 and 1 = “1”, the corresponding pin (D-A0 or D-A1) outputs the analog voltage. This analog voltage (V) is determined according to value n. (“n” = decimal number. This has been set in the D-A register.) V = VREF ✕ n/256 (n = 0 to 255) VREF : Reference voltage 7 6 5 4 3 2 1 0 D-A control register D-A0 output enable bit (Note) 0: Output is disabled. 1: Output is enabled. D-A1 output enable bit (Note) 0: Output is disabled. 1: Output is enabled. Note: Pin D-Ai is multiplexed with I/O port pins, analog input pins, and external interrupt input pins. When a D-Ai output enable bit = “1” (in other words, output is enabled.), however, the corresponding pin cannot function as another I/O pin, which is multiplexed with pin D-Ai. Fig. 82 Bit configuration of D-A control register The contents of the corresponding D-A output enable bit and D-A register are cleared to “0” at reset. An external buffer is necessary when connecting a low impedance load with the D-A converter. It is because that a D-A output pin does not include a buffer. Pin D-Ai (i = 0, 1) is multiplexed with I/O port pins, analog input pins, and external interrupt input pins. When a D-Ai output enable bit = “1” (in other words, output is enabled.), however, the corresponding pin cannot function as another I/O pin, which is multiplexed with pin DAi. Also, when not using the D-A converter, be sure to clear the contents of the corresponding D-A output enable bit and D-A register to “0”. Data bus D-A register i (i = 0, 1) (Addresses 9816, 9916) VREF AVSS R-2R ladder resistor network D-Ai output enable bit Pin D-Ai Fig. 81 Block diagram of D-A converter 72 Address 9616 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER WATCHDOG TIMER comes “0” and an interrupt is generated. The microcomputer can generate a reset pulse by writing “1” to bit 6 (software reset bit) of processor mode register 0 in an interrupt routine and can be restarted. The watchdog timer can also be used to return from the STP state, where a clock has stopped its operation owing to the STP instruction execution. For details, refer to the sections on the clock generating circuit and standby function. The watchdog timer stops its operation in the following cases, and at this time, input to the watchdog timer is disabled: • When the external area is accessed in the hold state • In the wait mode • In the stop mode The watchdog timer is used to detect unexpected execution sequence caused by software runaway and others. Figure 83 shows the block diagram of the watchdog timer. The watchdog timer consists of a 12-bit binary counter. The watchdog timer counts clock Wf32, which is obtained by dividing the peripheral devices’ clock f2 by 16; or clock Wf512, which is obtained by doing it by 256. Bit 0 of the watchdog timer frequency select register (watchdog timer frequency select bit) shown in Figure 84 selects which clock is to be counted. Wf512 is selected when this bit 0 is “0”, and Wf32 is selected when bit 0 is “1”. Bit 0 is cleared to “0” after reset. FFF16 is set in the watchdog timer when “L” level voltage is applied to pin RESET, STP instruction is executed, data is written to the watchdog timer register (address 6016), or the most significant bit of the watchdog timer becomes “0”. After FFF16 is set in the watchdog timer, when the watchdog timer counts Wf32 or Wf512 by 2048 counts, the most significant bit of the watchdog timer becomes “0”, the watchdog timer interrupt request bit is set to “1”, and FFF16 is set again in the watchdog timer. In program coding, make sure that data is written in the watchdog timer before the most significant bit of the watchdog timer becomes “0”. If this routine is not executed owing to unexpected program execution or others, the most significant bit of the watchdog timer be- 7 6 5 4 3 2 1 0 Watchdog timer frequency select register Address 6116 Watchdog timer frequency select bit 0 : W f512 1 : W f32 Watchdog timer clock source select bits at STP state termination 0 0 : fX32 0 1 : fX16 1 0 : fX128 1 1 : fX64 Fig. 84 Bit configuration of watchdog timer frequency select register f2 Wait mode Wf32 1 1/16 1/16 Wf512 Divided f(XIN) Watchdog timer frequency select bit 0 fX16 fX32 fX64 fX128 Watchdog timer interrupt request Watchdog timer ❈ Stop mode “FFF16” is set. Disables watchdog timer (Note). Watchdog timer clock source select bits at STP state termination Writing to watchdog timer register RESET STP instruction • Watchdog timer register: address 6016 • Watchdog timer frequency select register: bit 0 at address 6116 • Watchdog timer clock source select bits at STP state termination: bits 6, 7 at address 6116 ❈ When the most significant bit of the watchdog timer becomes “0”, this signal will be generated. Note: During the stop mode and until the stop mode is terminated, setting for disabling the watchdog timer is ignored. Fig. 83 Block diagram of watchdog timer 73 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP How to disable watchdog timer When not using the watchdog timer, it can be disabled. When the watchdog timer is disabled, it’s operation stops and no watchdog timer interrupt has been generated. Setting for disabling the watchdog timer is possible by writing “7916” and “5016” to the particular function select register 2 (address 6416) sequentially with the following instructions: • MOVMB/STAB instruction, or • MOVM/STA instruction (m = 1) If any method other than above has been adopted in order to access (in other words, read/write) the particular function select register 2, the watchdog timer will not be disabled until reset operation is performed. (Also, reset is the only one method to remove the setting for disabling the watchdog timer.) Moreover, this setting for disabling the watchdog timer is ignored at return from the STP mode, and the watchdog timer operates. (For details, refer to the section on the standby function.) 74 16-BIT CMOS MICROCOMPUTER MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER INPUT/OUTPUT PINS Ports P1, P2, and P4 through P8 all have the direction register, and each bit can be programmed for input or output. A pin becomes an output pin when the corresponding bit of direction register is “1”, and an input pin when it is “0”. Also, each bit of the port P6 direction register can be cleared to “0” by inputting a falling edge to pin P6OUTCUT or by executing instructions. Each bit of the port P4 direction register can be cleared to “0” by inputting a falling edge to pin P4OUTCUT or by executing instructions. When a pin is programmed for output, the data is written to its port latch and it is output to the output pin. When a pin is programmed for output, the contents of the port latch is read instead of the value of the pin. Accordingly, a previously output value can be read correctly even when the output “H” voltage is lowered or the output “L” voltage is raised owing to an external load, etc. A pin programmed as an input pin is in the flooting state, and the value input to the pin can be read. When a pin is programmed as an input pin, the data is written only in the port latch and the pin remains floating. Each of Figures 85 and 86 shows the block diagram for each port pin. When using a port pin as an internal peripheral device’s input pin, clear the corresponding port direction register’s bit to “0”. When using a port pin as an internal peripheral device’s output pin, the port direction register’s bit may be “0” or “1”. 75 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER [Inside dotted-line not included] P27 Direction register [Inside dotted-line included] P12/RXD0, P16/RXD1, P21/TA4IN, P2 3/TA9IN, P24(/TB0IN), P25(/TB1IN), P26(/TB2IN), P51/INT1, P52/INT2/RTPTRG1, P53/INT3/RTPTRG0, P55/INT5/TB0IN/IDW, P56/INT6/TB1IN/IDV, P57/INT7/TB2IN/IDU Data bus Direction register [Inside dotted-line not included] P13/TXD0, P17/TXD1 P6 0/TA0OUT/W/RTP00, P6 1/TA0IN/V/RTP01, P6 2/TA1OUT/U/RTP02, P6 3/TA1IN/W/RTP03, P6 4/TA2OUT/V/RTP10, P6 5/TA2IN/U/RTP11, P6 6/TA3OUT/RTP12, P6 7/TA3IN/RTP13 1 Output(Internal peripheral devices) [Inside dotted-line included] P20/TA4OUT, P2 2/TA9OUT P40/TA5OUT/RTP20, P41/TA5IN/RTP21, P42/TA6OUT/RTP22, P43/TA6IN/RTP23, P44/TA7OUT/RTP30, P45/TA7IN/RTP31, P46/TA8OUT/RTP32, P47/TA8IN/RTP33, Port latch Data bus Port latch Direction register R P4OUTCUT Reset 1 Output(Internal peripheral devices) Data bus Port latch Direction register R P6OUTCUT Reset [Inside dotted-line not included] P70/AN0, P71/AN1, P72/AN2, P73/AN3, P74/AN4, P75/AN5, P76/AN6 1 Output(Internal peripheral devices) Data bus Port latch Direction register Data bus Port latch [Inside dotted-line included] P82/AN10/RxD0 Analog input Fig. 85 Block diagram for each port pin (1) 76 MI ELI Y NAR ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER 1 [Inside dotted-line not included] P10/CTS0/RTS0 P11/CTS0/CLK0 P14/CTS1/RTS1 P15/CTS1/CLK1 0 Direction register Output (Internal peripheral devices) Data bus Port latch [Inside dotted-line included] P81/AN9/CTS2/CLK2 Analog input Direction register P77/AN7/DA0 Data bus Port latch Analog input Analog output Enable D-A output 1 0 Direction register P80/AN8/CTS2/RTS2/DA1 Output (Internal peripheral devices) Data bus Port latch Analog input Analog output Enable D-A output Direction register 1 P83/AN11/TXD2 Output (Internal peripheral devices) Data bus Port latch Analog input P4OUTCUT/INT0, P6OUTCUT/INT4 Fig. 86 Block diagram for each port pin (2) 77 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER RESET CIRCUIT While the power source voltage satisfies the recommended operating condition, reset state is removed if pin RESET’s level returns from the stabilized “L” level to the “H” level. As a result, program execution starts from the reset vector address. This reset vector address is expressed as shown below: • A23 to A16 = 0016 • A15 to A8 = Contents at address FFFF16 • A7 to A0 = Contents at address FFFE16 Figures 87 and 88 show the microcomputer internal register’s status at reset, and Figure 89 shows an operation example of the reset circuit. Apply “L” level voltage to pin RESET for a period (10 µs or more) under the following conditions: • Pin Vcc’s level satisfies the recommended operating condition. • Oscillator’s operation has been stabilized. VCC level VCC 0V RESET 0.2VCC level 10 µs 0V XIN 0V Power on Oscillation stabilized Fig. 89 Operation example of reset circuit (Note that proper evaluation is necessary in the system development stage.) Address Address Pulse output control register (A016)··· 0016 Comparator function select register 0 (DC16)··· 0016 Pulse output data register 0 (A216)··· 0016 Comparator function select register 1 (DD16)··· 0016 Pulse output data register 1 (A416)··· 0016 Comparator result register 0 (DE16)··· 0016 Waveform output mode register (A616)··· 0016 Comparator result register 1 (DF16)··· 0016 Three-phase output data register 0 (A816)··· 0016 UART2 transmit interrupt control register (F116)··· 0 0 0 0 Three-phase output data register 1 (A916)··· 0016 UART2 receuve interrupt control register (F216)··· 0 0 0 0 0 0 0 0 Timer A5 interrupt control register (F516)··· 0 0 0 0 (AC16)··· 0 0 0 0 0 0 Timer A6 interrupt control register (F616)··· 0 0 0 0 Port P2 pin function control register (AE16)··· 0 0 0 Timer A7 interrupt control register (F716)··· 0 0 0 0 Timer A8 interrupt control register (F816)··· 0 0 0 0 UART2 transmit/receive control register 0 (B416)··· 0 0 0 0 1 0 0 0 Timer A9 interrupt control register (F916)··· 0 0 0 0 UART2 transmit/receive control register 1 (B516)··· 0 0 0 0 0 0 1 0 INT5 interrupt control register (FD16)··· 0 0 0 0 0 0 Clock control register 0 (BC16)··· 0 0 0 1 0 1 1 1 INT6 interrupt control register (FE16)··· 0 0 0 0 0 0 Up-down register 1 (C416)··· 0016 INT7 interrupt control register (FF16)··· 0 0 0 0 0 0 Timer A5 mode register (D616)··· 0016 Processor status register PS 0 0 0 ? ? 0 0 0 1 ? ? Timer A6 mode register (D716)··· 0016 Program bank register PG Timer A7 mode register (D816)··· 0016 Program counter PCH Contents at address FFFF16 Timer A8 mode register (D916)··· 0016 Program counter PCL Contents at address FFFE16 Timer A9 mode register (DA16)··· 0016 Direct page registers DPR0 to DPR3 A-D control register 2 (DB16)··· Position-data-retain function control register (AA16)··· Serial I/O pin control register UART2 transmit/receive mode register (B016)··· 0016 0 0 0 0016 000016 0016 Data bank register DT Stack pointer FFF16 Note: The contents of the other registers and RAM are undefined at reset and must be initialized by software. Fig. 88 Microcomputer internal register’s status at reset (2) 78 MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER Address Address Port P1 direction register (0516)··· 0016 Processor mode register 0 (5E16)··· 0 0 0 0 1 0 0 0 Port P2 direction register (0816)··· 0016 Processor mode register 1 (5F16)··· 0 0 0 0 0 0 0 1 Port P4 direction register (0C16)··· 0016 Watchdog timer Port P5 direction register (0D16)··· 0 0 0 Port P6 direction register (1016)··· Port P7 direction register (6016)··· FFF16 Watchdog timer frequency select register (6116)··· 0 0 0 0 0 0 0 0 Particular function select register 0 (6216)··· 0 (1116)··· 0 0 0 0 0 Particular function select register 1 (6316)··· Port P8 direction register (1416)··· 0 0 0 0 Debug control register 0 (6616)··· 1 A-D control register 0 (1E16)··· 0 0 0 0 0 ? ? ? Debug control register 1 (6716)··· 0 0 0 A-D control register 1 (1F16)··· INT3 interrupt control register (6E16)··· 0 0 0 0 0 UART 0 transmit/receive mode register (3016)··· 0016 INT4 interrupt control register (6F16)··· 0 0 0 0 0 UART 1 transmit/receive mode register (3816)··· 0016 A-D conversion interrupt control register (7016)··· ? 0 0 0 UART 0 transmit/receive control register 0 (3416)··· 0 0 0 0 1 0 0 0 UART 0 transmit interrupt control register (7116)··· 0 0 0 0 UART 1 transmit/receive control register 0 (3C16)··· 0 0 0 0 1 0 0 0 UART 0 receive interrupt control register (7216)··· 0 0 0 0 UART 0 transmit/receive control register 1 (3516)··· 0 0 0 0 0 0 1 0 UART 1 transmit interrupt control register (7316)··· 0 0 0 0 UART 1 transmit/receive control register 1 (3D16)··· 0 0 0 0 0 0 1 0 UART 1 receive interrupt control register (7416)··· 0 0 0 0 Count start register 0 (4016)··· 0016 Timer A0 interrupt control register (7516)··· 0 0 0 0 Count start register 1 (4116)··· 0 0 0 0 0 Timer A1 interrupt control register (7616)··· 0 0 0 0 One-shot start register 0 (4216)··· 0 0 0 0 0 0 Timer A2 interrupt control register (7716)··· 0 0 0 0 One-shot start register 1 (4316)··· 0 0 0 0 0 0 Timer A3 interrupt control register (7816)··· 0 0 0 0 Up-down register 0 (4416)··· 0016 Timer A4 interrupt control register (7916)··· 0 0 0 0 Timer A clock frequency select register (4516)··· Timer B0 interrupt control register (7A16)··· 0 0 0 0 Timer A0 mode register (5616)··· 0016 Timer B1 interrupt control register (7B16)··· 0 0 0 0 Timer A1 mode register (5716)··· 0016 Timer B2 interrupt control register (7C16)··· 0 0 0 0 Timer A2 mode register (5816)··· 0016 INT0 interrupt control register (7D16)··· 0 0 0 0 0 0 Timer A3 mode register (5916)··· 0016 INT1 interrupt control register (7E16)··· 0 0 0 0 0 0 Timer A4 mode register (5A16)··· 0016 INT2 interrupt control register (7F16)··· 0 0 0 0 0 0 Timer B0 mode register (5B16)··· 0 0 ? 0 0 0 0 0 D-A control register (9616)··· 0 0 Timer B1 mode register (5C16)··· 0 0 ? 0 0 0 0 0 D-A register 0 (9816)··· 0016 Timer B2 mode register (5D16)··· 0 0 ? 0 0 0 0 0 D-A register 1 (9916)··· 0016 0 0 0 0 0 0 0 0 ? ? 0 0 0 0 0 0 0 0 0 0 (Note 2) (Note 2) 0 0 0 (Note 2) Notes 1: The contents of the other registers and RAM are undefined at reset and must be initialized by software. 2: At power-on reset, these bits are clear to “0”. At hardware or software reset, on the other hand, these bits retain the value just before reset. Fig. 87 Microcomputer internal register’s status at reset (1) 79 A IMIN RY e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER OSCILLATION CIRCUIT An oscillation circuit locates between pins XIN and XOUT, and Figure 90 shows a circuit example with an external ceramic resonator or quartz crystal oscillator. The constants such as capacitance etc. depend on a resonator/oscillator. Therefore, for these constants, adopt the resonator/oscillator manufacturer’s recommended values. Figure 91 shows a circuit example with an external clock source. When an external clock is input, be sure to leave pin XOUT open. Also, in this case, when the external clock input select bit (bit 1 of the particular function select register 0; See Figure 95.) is set to “1”, the oscillation circuit stops it’s operation and resumes the current dissipation. Moreover, this bit has another function, which selects the return condition from the stop mode. For details, refer to the section on the standby function. On the other hand, the PLL (Phase Locked Loop) frequency multiplier (hereafter, referred to as PLL circuit.) is included, also. This PLL circuit uses a clock input from pin XIN and generates a multiplicated clock. When using the PLL circuit, be sure to connect pin VCONT with an external filter circuit. (See Figure 92.) When not using the PLL circuit, be sure to leave pin VCONT open. When not using the PLL circuit, be sure to clear the PLL circuit operation enable bit (bit 1 of the clock control register 0; See Figure 94.), so that the PLL circuit will stop its operation. M37905 XIN XOUT Rf Rd COUT CIN Fig. 90 Circuit example with external ceramic resonator or quartz-crystal oscillator M37905 XIN XOUT Left open. External clock source Vcc Vss Fig. 91 Circuit example with external clock source M37905 VCONT 1 kΩ 220 pF 0.1 µF Note: Make the wiring length as short as possible, and shield it with the GND line which surrounds this circuit. Also, for the clock supply to pin XIN, see Figures 90 and 91. Fig. 92 Circuit example of connection with pin VCONT when PLL circuit used 80 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER CLOCK GENERATING CIRCUIT Figure 93 shows the block diagram of the clock generating circuit. The clock generating circuit consists of the clock oscillation circuit, PLL frequency multiplier (PLL circuit), system clock switch circuit, peripheral devices’ clock switch circuit, clock divider, standby control circuit, etc. As control registers for the clock generating circuit, also, the clock control register 0 (address BC16), particular function select register 0 (address 6216) are provided. (See Figures 94 and 95.) As shown in Figure 93, clocks used in the CPU, BIU, peripheral devices, watchdog timer (in other words, clocks φCPU, φBIU, f1 to f4096, Wf32, Wf512) are made from system clock fsys. System clock fsys can be selected between fXIN (in other words, a clock input from pin XIN) and fPLL (in other words, an output clock generated by the PLL circuit. The PLL circuit’s operation, system clock (fsys) selection, and division ratio selection for peripheral devices’ clocks (f1 to f4096) are controlled by the clock control register. The following describes about these control. Bit 1 of the clock control register 0 (the PLL circuit operation enable bit) selects the PLL circuit’s operation (inactive/active). When this bit is set to “1”, pin VCONT will becomes valid, and the PLL circuit will be active. At reset, the PLL circuit operation enable bit becomes “1”. (In this case, the PLL circuit is active.) When not using the PLL circuit, be sure to clear the PLL circuit operation enable bit to “0” (inactive). At the STP instruction execution, the PLL circuit is inactive, and pin VCONT is invalid, regardless of this bit 1’s status. Bits 2 and 3 of the clock control register (the PLL multiplication ratio select bits) select the ratio of fPLL/fXIN. The PLL multiplication ratio must be set so that the frequency of fPLL must be in the range from 10 MHz to 20 MHz. At reset, the PLL multiplication ratio select bits become “0,1” (✕ 2). The change of the PLL multiplication ratio must be performed while input clock fXIN is selected as the system clock. (In this case, bit 5 of the clock control register 0 = “0”.) After that, be sure to wait that the operation-stabilizing time of the PLL circuit has passed, and switch the system clock to fPLL. (In other words, set bit 5 to “1”.) Note that, after reset, the PLL multiplication ratio select bits are allowed to be changed only once. Bit 5 of the clock control register 0 is the system clock select bit, and input clock fXIN is selected as the system clock when bit 5 = “0”. On the other hand, when bit 5 = “1”, fPLL is selected. At reset, the system clock select bit becomes “0”. When selecting fPLL, be sure that the PLL circuit’s operation has fully been stabilized, and then, set the system clock select bit to “1”. Also, when the PLL circuit operation enable bit is cleared to “0” (the PLL circuit is inactive.), the system clock select bit will automatically be cleared to “0”. Note that a value of “1” cannot be written to the system clock select bit while the PLL circuit operation enable bit =“0”. Table 9 lists the fsys selection. Bits 6 and 7 of the clock control register 0 are the peripheral devices’ clock select bits 0, 1, and these bits select the division ratio of (f1 to f4096)/(fsys). Table 10 lists the internal peripheral devices’ operation clock frequency. At reset, these bits become “0, 0”. Table 9. fsys selection System clock select bit PLL circuit operation enable bit PLL multiplication ratio select bits (Bit 5) (Bits 3, 2) (Note) (Bit 1) 0 01 (✕ 2) 1 1 10 (✕ 3) 11 (✕ 4) System clock fsys Clock source Frequency (Note) f(XIN) f(XIN) ✕ 2 f(XIN) ✕ 3 f(XIN) ✕ 4 fXIN fPLL fPLL fPLL Note: The PLL multiplication ratio must be set so that the frequency of fPLL must be in the range from 10 MHz to 20 MHz. f(XIN) means the frequency of the input clock from pin XIN (fXIN). After reset, the PLL multiplication ratio select bits are allowed to be changed only once. Table 10. Internal peripheral devices’ operation clock frequency Internal peripheral devices’ operation clock f1 f2 f16 f64 f512 f4096 Peripheral devices’ clock select bits 1, 0 (bits 7, 6) 00 fsys fsys/2 fsys/16 fsys/64 fsys/512 fsys/4096 0 1 (Note) fsys fsys fsys/8 fsys/32 fsys/256 fsys/2048 10 11 fsys/2 fsys/4 fsys/32 fsys/128 fsys/1024 fsys/8192 Do not select. Note: When selecting the peripheral devices’ clock select bits 1, 0 = “012”, be sure that system clock fsys does not exceed 10 MHz. 81 82 Fig. 93 Block diagram of clock generating circuit R S Q WIT instruction Interrupt request R S Q Wait mode XIN XOUT fXIN f/n STP instruction R S Q 0 1 0 Wait mode fsys CPU wait request Wait mode : bit 0 at address 6116 : bits 6, 7 at address 6116 : bit 1 at address 6216 : bit 3 at address 6316 : bit 1 at address BC16 : bits 2, 3 at address BC16 : bit 5 at address BC16 : bits 6, 7 at address BC16 1/2 1 BIU : Bus Interface Unit CPU : Central Processing Unit ❈ : Signal generated when the watchdog timer’s most significant bit becomes “0” • Watchdog timer frequency select bit • Watchdog timer clock source select bits at stop state termination • External clock input select bit • System clock stop select bit at WIT • PLL circuit operation enable bit • PLL multiplication ratio select bits • System clock select bit • Peripheral device’s clock select bits 0, 1 Reset VCONT fX16 fX32 fX64 fX128 1 System clock select bit 1 0 f4096 1/16 0 1 Wf512 Wf32 Watchdog timer frequency select bit 1/8 fX16 fX32 fX64 fX128 External clock input select bit (Clock for CPU) φ CPU (Clock for BIU) φ BIU 1/8 Watchdog timer clock source select bit at stop state termination 1/16 1/4 System clock frequency select bit 1/8 f1 f2 f16 f64 f512 0 1 ❈ Watchdog timer Interrupt request Operating clock for timer A Operating clock for serial I/O, timer B A-D conversion frequency (φAD) clock source RY External clock input select bit STP instruction Interrupt request PLL frequency fPLL multiplier 1/2 Peripheral device’s clock select bit 0 Peripheral device’s clocks P REL 0 Peripheral device’s clock select bit 1 e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som A IMIN PLL multiplication ratio select bits PLL circuit operation enable bit System clock stop select bit at WIT Wait mode MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 7 6 5 4 16-BIT CMOS MICROCOMPUTER 3 2 1 1 0 Clock control register 0 1 Address BC16 Fix this bit to “1”. PLL circuit operation enable bit (Note 1) 0: PLL frequency multiplier is inactive, and pin VCONT is invalid (floating state). 1: PLL frequency multiplier is active, and pin VCONT is valid. PLL multiplication ratio select bits (Note 2) 00: Do not select. 01: Double 10: Triple 11: Quadruple Fix this bit to “1”. System clock select bit (Note 3) 0: fXIN 1: fPLL Peripheral device’s clock select bits 1, 0 See Table 10. Notes 1: When not using the PLL frequency multiplier, be sure to clear this bit to “0”. In the stop mode, the PLL circuit is inactive regardless of this bit’s content; at this time, pin VCONT is invalid. 2: When rewriting this bit, be sure to clear bit 5 to “0” simultaneously. Also, after this bit is rewritten, insert a waiting time of 2 ms, and then set bit 5 to “1”. 3: When the PLL circuit operation enable bit (bit 1) has been cleared to “0”, this bit will also be cleared to “0”. When bit 1 = “0”, nothing can be written to this bit. (Fixed to be “0”.) Fig. 94 Bit configuration of clock control register 0 7 0 6 5 4 0 0 3 2 1 0 Particular function select register 0 Address 6216 STP instruction invalidity select bit (Note) 0: STP instruction is valid. 1: STP instruction is invalid. External clock input select bit (Note) 0: Oscillation circuit is active. (The oscillator is connected.) Watchdog timer is used at stop mode termination. 1: Oscillation circuit is inactive. (The externally-generated clock is input.) When the system clock select bit = “0”, watchdog timer is not used at stop mode termination. When the system clock select bit = “1”, watchdog timer is used at stop mode termination. Fix this bit to “0”. Note: Writing to these bits requires the following procedure: • Write “5516” to this register. (The bit status does not change only by this writing.) • Succeedingly, write “0” or “1” to each bit. Also, use the MOVM (MOVMB) instruction or STA (STAB, STAD) instruction Fig. 95 Bit configuration of particular function select register 0 83 MITSUBISHI MICROCOMPUTERS A IMIN RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER STANDBY FUNCTION STP mode The standby function provides the stop (hereafter called STP) and the wait (hereafter called WIT) mode. These modes are used to save the power dissipation of the system, by making oscillation or system clock inactive in the case that the CPU needs not be active. The microcomputer enters the STP or WIT mode by executing the STP or WIT instruction, and either mode is terminated by acceptance of an interrupt request or reset. To terminate the STP or WIT mode by an interrupt request, the interrupt to be used for termination of the STP or WIT mode must be enabled in advance to execution of the STP or WIT instruction. The interrupt priority level of this interrupt needs to be higher than the processor interrupt priority level (IPL) of the routine where the STP or WIT instruction will be executed. Figures 95 shows the bit configuration of the particular function select register 0, Figure 96 shows the bit configuration of the particular function select register 1, and Figure 97 shows the bit configuration of the watchdog timer frequency select register. Setting the STP instruction invalidity select bit (bit 0 of the particular function select register 0) to “1” invalidates the STP instruction, and the STP instruction will be ignored. Since the above bit is cleared to “0” after reset is removed, however, the STP instruction is valid. The STP- or the WIT-instruction-execution status bit (bit 0 or 1 of the particular function select register 1) is set to “1” by the execution of the STP or the WIT instruction, and so, after the STP or WIT mode has been terminated, each bit will indicate that the STP or WIT instruction has been executed. Accordingly, each of these bits must be cleared to “0” by software at termination of the STP or the WIT mode. Table 11 explains the microcomputer’s operation in the STP and WIT modes. The execution of the STP instruction makes the oscillation circuit and PLL circuit inactive. It also makes the following inactive: input clock fXIN, system clock fsys, φBIU, φCPU, and peripheral devices’ clocks f1 to f4096, Wf32 and Wf512 with the “L” state, and divide clocks fX16 to fX128 with the “H” state. In the watchdog timer, “FFF16” is automatically set. As shown in Figure 93, any one of divide clocks fX16 to fX128, which is selected by the watchdog timer clock source select bits at STP termination (bits 6 and 7 of the watchdog timer frequency select register), becomes the watchdog timer’s clock source. In the STP mode, the A-D converter and watchdog timer, which uses peripheral devices’ clocks f1 to f4096, Wf32 and Wf512, are inactive. At this time, timers A and B can be active only in the event counter mode, and serial I/O communication is active while an external clock is selected. The STP mode is terminated by acceptance of an interrupt request or reset, and the oscillation circuit and PLL circuit restart their operations. Input clock fXIN, system clock fsys, and peripheral devices’ clocks f1 to f4096, Wf32 and Wf512 are also supplied. When the STP mode is terminated by reset, supply of φBIU and φCPU starts immediately after the oscillation circuit and PLL circuit restart their operations. Therefore, the reset input must be raised “H” after the operation-stabilizing time for these circuits has passed. The following two modes are available in order to terminate the STP mode by an interrupt: (1) The watchdog timer is used in order to measure the period from the operation restart of the oscillation circuit and PLL circuit until the supply start of φBIU and φCPU. (2) The supply of φBIU and φCPU is started immediately after the operation restart of the oscillation circuit and PLL circuit. Table 11. Microcomputer’s operation in STP and WIT modes Mode STP System clock stop select bit at WIT Oscillation PLL circuit circuit Operations of function while WIT, STP modes fsys, φ1, Wf32, Wf512 φBIU, φCPU Peripheral devices using f1 to f4096, Wf32, Wf512 f1 to f4096 — Inactive Inactive Inactive (“L”) Inactive (“L”) Inactive (“L”) “0” Active (Note 1) Active (Note 2) Active Inactive (“L”) Inactive (“L”) WIT “1” Active (Note 1) Active (Note 2) Inactive (“L”) Inactive (“L”) Inactive (“L”) Timers A, B: Operation is enabled only in the event counter mode. Serial I/O: Operation is enabled only while an external clock is selected. A-D converter: Inactive. (Watchdog timer: Inactive) Timers A, B, Serial I/O, A-D converter: Operation is enabled. (Watchdog timer: Inactive) Timers A, B: Operation is enabled only in the event counter mode. Serial I/O: Operation is enabled only while an external clock is selected. A-D converter: Inactive. (Watchdog timer: Inactive) Notes 1: When the external clock input select bit = “1”, the oscillation circuit is inactive. Also, clock input from pin XIN is allowed. 2: When the PLL circuit operation enable bit = “0”, the PLL circuit is inactive. 84 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER When the external clock input select bit (bit 1 of the particular function select register 0) = “0” or the system clock select bit (bit 5 of the clock control register 0) = “1”, the watchdog timer will start counting down with one of the above divide clocks, fX16 to fX128, after the oscillation circuit and PLL circuit have been restarted their operations owing to an interrupt. The most significant bit of the watchdog timer reaching “0”, supply of φBIU and φCPU restarts. On the other hand, when the external clock input select bit = “1 ” and the system clock select bit = “0”, supply of φBIU and φCPU will restart immediately after the oscillation circuit and PLL circuit have been restarted their operations owing to an interrupt. (In actual fact, after the selected one of the above divide clocks, fX16 to fX128, has been changed from “H” to “L”, this supply will restart.) 7 6 5 4 3 0 2 1 0 0 Particular function select register 1 Address 6316 STP-instruction-execution status bit (Note 1) 0: Normal operation. 1: STP instruction is under execution. WIT-instruction-execution status bit (Note 1) 0: Normal operation. 1: WIT instruction is under execution. Fix this bit to “0”. System clock stop select bit at WIT (Note 2) 0: In wait mode, system clock fsys is active. 1: In wait mode, system clock fsys is inactive. Fix this bit to “0”. Timer B2 clock source select bit Valid in event counter mode: 0: Clock input from pin TB2IN is counted. 1: fX32 (f(XIN)/32) is counted. Notes 1: At power-on reset, this bit becomes “0”. At hardware reset or software reset, this bit retains the value just before reset. Even when “1” is try to be written, the bit status will not change. 2: Setting this bit to “1” must be performed just before execution of the WIT instruction. Also, after the wait state is terminated, this bit must be cleared to “0” immediately. Fig. 96 Bit configuration of particular function select register 1 7 6 5 4 3 2 1 0 Watchdog timer frequency select register Address 6116 Watchdog timer frequency select bit 0 : Select W f512 1 : Select W f32 Watchdog timer clock source select bits at STP termination 0 0 : fX32 0 1 : fX16 1 0 : fX128 1 1 : fX64 Fig. 97 Bit configuration of watchdog timer frequency select register 85 MITSUBISHI MICROCOMPUTERS A IMIN RY e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP WIT mode When the WIT instruction is executed with the system clock stop select bit at WIT (bit 3 of the particular function select register 1 in Figure 93) being “0”, φBIU, φCPU, and divide clocks Wf32 and Wf512 are inactive with the “L“ state. However, the oscillation circuit, PLL circuit, input clock fXIN, system clock fsys, φ1, and peripheral devices’ clocks f1 to f4096 remain active. Therefore, BIU and CPU are inactive, where as timers A and B, serial I/O, and the A-D converter, which use the peripheral devices’ clocks f1 to f4096, are still active. Note that the watchdog timer is inactive. On the other hand, when the WIT instruction is executed with the system clock stop select bit at WIT being “1”, the oscillation circuit, PLL circuit, and input clock fXIN are active, while system clock fsys, φBIU, φCPU, and peripheral devices’ clocks are inactive. As a result, the A-D converter and watchdog timer, which use peripheral devices’ clocks f1 to f4096, Wf32 and Wf512, become inactive. At this time, timers A and B are active only in the event counter mode, and serial I/O communication is active only while an external clock is selected. If the internal peripheral devices are not used in the WIT mode, the latter is better because the current dissipation is more saved. Note that the system clock stop select bit at WIT needs to be set to “1” immediately before execution of the WIT instruction and cleared to “0” immediately after the WIT mode is terminated. The WIT state is terminated by acceptance of an interrupt request, and then, supply of φBIU and φCPU will restart. Since the oscillation circuit, PLL circuit, and clock input fXIN are active in the WIT mode, an interrupt processing can be executed just after the WIT mode termination. 86 16-BIT CMOS MICROCOMPUTER A IMIN RY e. n. atio chang cific o spe bject t l a u fin s ot a its are is n m This etric li : e m ic Not e para Som P REL MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER POWER SAVING FUNCTION The following functions can save the power dissipation of the whole system. (1) Inactive system clock in wait mode In the wait mode, if the internal peripheral devices need not to operate, when the system clock stop select bit at WIT (bit 3 of the particular function select register 1) = “1”, both of system clock fsys and peripheral devices’ clock are inactive, and the power dissipation can be saved. For details, refer to the section on the standby function. (2) Inactive oscillation circuit When an externally-generated stable clock is input to pin XIN, the power dissipation can be saved if both of the following conditions are met: • the external clock input select bit (bit 1 of the particular function select register 0) = “1”. • the oscillation driver circuit between pins XIN and XOUT is inactive. At this time, the output level at pin XOUT is fixed to “H”. When not using fPLL, also, the supply of φBIU and φCPU restarts just after the microcomputer returns from the stop mode, owing to an interrupt request occurrence. Therefore, an instruction can be executed just after the termination of the stop mode. For details, refer to the section on the clock generating circuit and standby function. (3) Disconnection from pin VREF When not using the A-D converter, by setting the VREF connection select bit (bit 6 of the A-D control register 1) to “1”, the resistor ladder network of the A-D converter will be disconnected from the reference voltage input pin (VREF). In this case, no current flows from pin VREF to the resistor ladder network, and the power dissipation can be saved. Note that, after the VREF connection select bit changes from “1” (VREF disconnected) to “0” (VREF connected), be sure that a waiting time of 1 µs or more has passed before the A-D conversion starts. For details, refer to the section on the A-D converter. 87 A IMIN RY e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER DEBUG FUNCTION When the CPU fetches an instruction code, an interrupt request will be generated if a selected condition is satisfied, as a resultant of comparison between a specified address and the start address where the instruction code is stored (the contents of PG and PC). The decision whether this condition is satisfied or not is called address matching detection, and the interrupt generated by this detection is called an address matching detection interrupt. (For interrupt vector addresses, refer to the section on interrupts.) In the address matching detection, a non-maskable interrupt routine is proceeded without execution of the original instruction which has been allocated to the target address. The debug function provides the following two modes: • the address matching detection mode, which is used to avoid the area where program exists or modify a program. • the out-of-address-area detection mode, which is used to detect a program runaway. Figure 98 shows the block diagram of the debug function. Figures 99 and 100 show the bit configurations of the debug control registers 0, 1, and address compare registers 0,1, respectively. The detect condition select bits of the debug control register 0 can select one condition between the following 4 conditions. When the selected address condition is satisfied, an address matching detection interrupt request will be generated: (1) Address matching detection 0 The contents of PG and PC match with the address which has been set in the address compare register 0. (2) Address matching detection 1 The contents of PG and PC match with the address which has been set in the address compare register 1. (3) Address matching detection 2 The contents of PG and PC match with the address which has been set in either of the address compare register 0 or address compare register 1. (4) Out-of-address-area detection The contents of PG and PC are less than the address which has been set in the address compare register 0 or larger than the address which has been set in the address compare register 1. By setting the detect enable bit of the debug control register 0 to “1”, an address matching detection interrupt request will be generated if any one of the above address conditions is satisfied. Clearing the detect enable bit to “0” generates no interrupt request even if any of the above address conditions is satisfied. The address compare register access enable bit of the debug control register 1 must be set to “1” by the instruction just before the access operation (read/write). Then, this bit must be cleared to “0” (disabled) by the next instruction. While this bit = “0”, the address compare registers 0, 1 cannot be accessed. The address-matching-detection 2 decision bit of the debug control register 1 decides, whether the address which has been set in the address compare register 0 or 1 matches with the contents of PG, PC, when the address matching detection 2 is selected. The contents of this bit is invalid when address matching detection 0 or 1 is selected. In order to use the debug function to avoid the area where program exists or modify a program, perform the necessary processing within an address matching interrupt routine. As a result, the contents of PG, PC, PS at acceptance of an address matching detection interrupt request (i.e. the address at which an address matching detection condition is satisfied) have been pushed onto the stack. If a return destination address after the interrupt processing is to be altered, rewrite the contents of the stack, and then return by the RTI instruction. To use the debug function to detect a program runaway, set an address area where no program exists into the address compare registers 0 and 1 by using the out-of-address-area detection. When the CPU fetches instruction codes from this address area and executes them, an address matching detection interrupt request will be generated. The above debug function cannot be evaluated by a debugger, so that the debug function must not be used while a debugger is running. Internal data bus (DB0 to DB15) Debug control register 0 Address compare register 0 Address compare register 1 Debug control register 1 Matching • Compare register Matching • Compare register CPU bus (Address) Fig. 98 Block diagram of debug function 88 Address matching detect circuit Address matching detection interrupt A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a u fin s ot a its are is n m This etric li : e m ic Not e para Som P REL 7 6 1 0 16-BIT CMOS MICROCOMPUTER 5 4 3 0 0 2 1 0 Debug control register 0 Address 6616 Detect condition select bits (Note 1) 000: Do not select. 001: Address matching detection 0 010: Address matching detection 1 011: Address matching detection 2 100: Do not select. 101: Out-of-address-area detection 110: Do not select. 111: Do not select. Fix this bit to “0” (Note 1). Detect enable bit (Note 1) 0: Detection disabled. 1: Detection enabled. Fix this bit to “0” (Note 1). “1” at read. 7 0 6 5 4 3 1 2 1 0 Debug control register 1 0 Address 6716 Fix this bit to “0” (Note 1). “0” at read (Note 1). Address compare register access enable bit (Note 2) 0: Disabled 1: Enabled Fix this bit to “1” when using the debug function. While debugger is not used, “0” at read. While debugger is used, “1” at read. Address-matching-detection 2 decision bit ❈ Valid when address matching detection 2 is selected. 0: Matches with the contents of the address compare register 0. 1: Matches with the contents of the address compare register 1. “0” at read. Notes 1: At power-on reset, these bits = “0”; at hardware reset or software reset, these bits retain the value just before reset. 2: Set this bit to “1” with the instruction just before the address compare register 0, 1 (addresses 6816 to 6D16) is accessed. And then, clear this bit to “0” with the instruction just after the access. Fig. 99 Bit configuration of debug control register 0, 1 (23) 7 (16) (15) 0 7 (8) 0 7 0 Address compare register 0 Address compare register 1 Address 6816, 6916, 6A16 6B16, 6C16, 6D16 The address to be detected (in other words, the start address of instruction) is set here. Fig. 100 Bit configuration of address compare register 0, 1 89 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER ABSOLUTE MAXIMUM RATINGS Ratings Unit VCC Power source voltage –0.3 to 6.5 V AVCC Analog power source voltage –0.3 to 6.5 V VI Input voltage P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83, P4OUTCUT, P6OUTCUT, VCONT, VREF, XIN, RESET, MD0, MD1 –0.3 to VCC+0.3 V VO Output voltage P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, –0.3 to VCC+0.3 V 300 Parameter Symbol P70–P77, P80–P83, XOUT Pd Topr Tstg Power dissipation Operating ambient temperature –20 to 85 mW °C Storage temperature –40 to 150 °C RECOMMENDED OPERATING CONDITIONS (Vcc = 5 V, Ta = –20 to 85 °C, unless otherwise noted) Limits Symbol Parameter VCC Power source voltage AVCC Analog power source voltage VSS AVSS VIH Min. 4.5 Typ. Max. 5.0 5.5 Unit V VCC V Power source voltage 0 V Analog power source voltage High-level Input voltage P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83, P4OUTCUT, P6OUTCUT, XIN, RESET, MD0, MD1 0 V 0.8 Vcc Vcc V 0 0.2 VCC V VIL Low-level Input voltage P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83, P4OUTCUT, P6OUTCUT, XIN, RESET, MD0, MD1 IOH(peak) High-level peak output current P10–P17, P20–P27, P55–P57, P60–P67, P70–P77 –10 mA IOH(avg) High-level average output current P10–P17, P20–P27, P55–P57, P60–P67, P70–P77 –5 mA IOL(peak) Low-level peak output current P10–P17, P20–P27, P51–P53, P55–P57, P70–P77 10 mA IOL(peak) 20 mA IOL(avg) Low-level peak output current P40–P47, P60–P67 Low-level average output current P10–P17, P20–P27, P51–P53, P55–P57, P70–P77 5 mA IOL(avg) Low-level average output current P40–P47, P60–P67 f(XIN) f(fsys) External clock input frequency (Note 1) 15 20 MHz System clock frequency 20 MHz Notes 1: When using the PLL frequency multiplier, be sure that f(fsys) = 20 MHz or less. 2: The average output current is the average value of an interval of 100 ms. 3: The sum of IOL(peak) must be 110 mA or less, the sum of IOH(peak) must be 80 mA or less. 90 mA A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER DC ELECTRICAL CHARACTERISTICS (Vcc = 5 V, Vss = 0 V, Ta = –20 to 85 °C, f(fsys) = 20 MHz, unless otherwise noted) Symbol VOH VOL Parameter High-level output voltage P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83 Low-level output voltage P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83 VT+ —VT– Hysteresis Test conditions IOH = –10 mA Min. Limits Typ. Max. Unit V 3 IOL = 10 mA 2 V TA0IN–TA9IN, TA0OUT–TA9OUT, TB0IN–TB2IN, INT0–INT7, CTS0, CTS1, CTS2, CLK0, CLK1, CLK2, RxD0, RxD1, RxD2, RTPTRG0, RTPTRG1, P4OUTCUT, P6OUTCUT 0.4 1 V VT+ —VT– Hysteresis RESET VT+ —VT– Hysteresis XIN IIH High-level input current P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83, P4OUTCUT, P6OUTCUT, XIN, RESET, MD0, MD1 0.5 1.5 V 0.1 0.3 IIL Low-level input current P10–P17, P20–P27, P40–P47, P51–P53, P55–P57, P60–P67, P70–P77, P80–P83, P4OUTCUT, P6OUTCUT, XIN, RESET, MD0, MD1 VRAM RAM hold voltage ICC Power source current VI = 5.0 V 5 V µA VI = 0 V –5 µA 50 mA Ta = 25 °C when clock is inactive. 1 µA Ta = 85 °C when clock is inactive. 20 When clock is inactive. Output-only pins are open, and the other pins are connected to Vss or Vcc. An external square-waveform clock is input. (Pin XOUT is open.) The PLL frequency multiplier is inactive. f(fsys) = 20 MHz. CPU is active. V 2 25 91 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER A-D CONVERTER CHARACTERISTICS (VCC = AVCC = 5 V ± 0.5 V, VSS = AVSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol ————— Parameter Resolution Test conditions VREF = VCC ————— Absolute accuracy VREF = VCC RLADDER Ladder resistance VREF = VCC tCONV Conversion time VREF VIA Reference voltage Analog input voltage f(fsys) ≤ 20 MHz Limits Min. Typ. A-D converter Comparator Unit Bits 1 VREF V 256 ±3 LSB ±2 LSB ± 40 mV kΩ 10-bit resolution mode 8-bit resolution mode Comparater 10-bit resolution mode 8-bit resolution mode Comparater Max. 10 5 5.9 2.45 (Note) µs 0.7 (Note) 2.7 0 VCC VREF V V Note: This is applied when A-D conversion freguency (φAD) = f1 (φ). D-A CONVERTER CHARACTERISTICS (VCC = 5 V, VSS = AVSS = 0 V, VREF = 5 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol —— —— tsu RO IVREF Test conditions Parameter Resolution Absolute accuracy Set time Output resistance Reference power source input current Min. 2 Limits Typ. 3.5 (Note) Max. 8 ± 1.0 3 4.5 3.2 Unit Bits % µs kΩ mA Note: The test conditions are as follows: • One D-A converter is used. • The D-A register value of the unused D-A converter is “0016.” • The reference power source input current for the ladder resistance of the A-D converter is excluded. RESET INPUT Reset input timing requirements (VCC = 5 V ± 0.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted) Symbol tw(RESETL) Parameter RESET input low-level pulse width RESET input tw(RESETL) 92 Min. 10 Limits Typ. Max. Unit µs MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER PERIPHERAL DEVICE INPUT/OUTPUT TIMING (VCC = 5 V±0.5 V, VSS = 0 V, Ta = –20 to 85 °C, f(fsys) = 20 MHz unless otherwise noted) For limits depending on f(fsys), their calculation formulas are shown below. Also, the values at f(fsys) = 20 MHz are shown in ( ). ∗ Timer A input (Count input in event counter mode) Symbol tc(TA) tw(TAH) tw(TAL) Limits Parameter Min. 80 40 40 TAiIN input cycle time TAiIN input high-level pulse width TAiIN input low-level pulse width Max. Unit ns ns ns Timer A input (Gating input in timer mode) Symbol Parameter tc(TA) TAiIN input cycle time f(fsys) ≤ 20 MHz tw(TAH) TAiIN input high-level pulse width f(fsys) ≤ 20 MHz tw(TAL) TAiIN input low-level pulse width f(fsys) ≤ 20 MHz Limits Min. 16 × 109 (800) f(fsys) 8 × 109 (400) f(fsys) 9 8 × 10 (400) f(fsys) Max. Unit ns ns ns Note : The TAiIN input cycle time requires 4 or more cycles of a count source. The TAiIN input high-level pulse width and the TAiIN input low-level pulse width respectively require 2 or more cycles of a count source. The limits in this table are applied when the count source = f2 at f(fsys) ≤ 20 MHz. Timer A input (External trigger input in one-shot pulse mode) Symbol Limits Parameter tc(TA) TAiIN input cycle time tw(TAH) tw(TAL) TAiIN input high-level pulse width TAiIN input low-level pulse width Min. f(fsys) ≤ 20 MHz 8 × 109 f(fsys) Max. (400) Unit ns 80 80 ns ns Timer A input (External trigger input in pulse width modulation mode) Symbol tw(TAH) tw(TAL) Parameter TAiIN input high-level pulse width TAiIN input low-level pulse width Limits Min. 80 80 Max. Unit ns ns Timer A input (Up-down input and Count input in event counter mode) Symbol tc(UP) tw(UPH) tw(UPL) tsu(UP-TIN) th(TIN-UP) Parameter TAiOUT input cycle time TAiOUT input high-level pulse width TAiOUT input low-level pulse width TAiOUT input setup time TAiOUT input hold time Limits Min. 2000 1000 1000 400 400 Max. Unit ns ns ns ns ns 93 A IMIN RY e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Timer A input (Two-phase pulse input in event counter mode) Symbol tc(TA) tsu(TAjIN-TAjOUT) tsu(TAjOUT-TAjIN) Limits Parameter Min. 800 200 200 TAjIN input cycle time TAjIN input setup time TAjOUT input setup time • Gating input in timer mode • Count input in event counter mode • External trigger input in one-shot pulse mode • External trigger input in pulse width modulation mode tc(TA) tw(TAH) TAiIN input tw(TAL) • Up-down and Count input in event counter mode tc(UP) tw(UPH) TAiOUT input (Up-down input) tw(UPL) TAiOUT input (Up-down input) TAiIN input (When count by falling) th(TIN-UP) tsu(UP-TIN) TAiIN input (When count by rising) • Two-phase pulse input in event counter mode tc(TA) TAjIN input tsu(TAjIN-TAjOUT) tsu(TAjIN-TAjOUT) tsu(TAjOUT-TAjIN) TAjOUT input tsu(TAjOUT-TAjIN) Test conditions • VCC = 5 V ± 0.5 V, Ta = –20 to 85 °C • Input timing voltage : VIL = 1.0 V, VIH = 4.0 V 94 Max. Unit ns ns ns MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER Timer B input (Count input in event counter mode) Symbol tc(TB) tw(TBH) tw(TBL) tc(TB) tw(TBH) tw(TBL) Limits Parameter Min. 80 40 40 160 80 80 TBiIN input cycle time (one edge count) TBiIN input high-level pulse width (one edge count) TBiIN input low-level pulse width (one edge count) TBiIN input cycle time (both edge count) TBiIN input high-level pulse width (both edge count) TBiIN input low-level pulse width (both edge count) Max. Unit ns ns ns ns ns ns Timer B input (Pulse period measurement mode) Symbol Limits Parameter tc(TB) TBiIN input cycle time f(fsys) ≤ 20 MHz tw(TBH) TBiIN input high-level pulse width f(fsys) ≤ 20 MHz tw(TBL) TBiIN input low-level pulse width f(fsys) ≤ 20 MHz Min. 16 × 109 (800) f(fsys) 9 8 × 10 (400) f(fsys) 8 × 109 (400) f(fsys) Unit Max. ns ns ns Note: The TBiIN input cycle time requires 4 or more cycles of a count source. The TBiIN input high-level pulse width and the TBiIN input low-level pulse width respectively require 2 or more cycles of a count source. The limits in this table are applied when the count source = f2 at f(fsys) ≤ 20 MHz. Timer B input (Pulse width measurement mode) Symbol Parameter tc(TB) TBiIN input cycle time f(fsys) ≤ 20 MHz tw(TBH) TBiIN input high-level pulse width f(fsys) ≤ 20 MHz tw(TBL) TBiIN input low-level pulse width f(fsys) ≤ 20 MHz Limits Min. 16 × 109 (800) f(fsys) 9 8 × 10 (400) f(fsys) 8 × 109 (400) f(fsys) Unit Max. ns ns ns Note: The TBiIN input cycle time requires 4 or more cycles of a count source. The TBiIN input high-level pulse width and the TBiIN input low-level pulse width respectively require 2 or more cycles of a count source. The limits in this table are applied when the count source = f2 at f(fsys) ≤ 20 MHz. Serial I/O Parameter Symbol tc(CK) tw(CKH) tw(CKL) td(C-Q) th(C-Q) tsu(D-C) th(C-D) CLKi input cycle time CLKi input high-level pulse width CLKi input low-level pulse width TXDi output delay time TXDi hold time RXDi input setup time RXDi input hold time Limits Min. 200 100 100 Max. 80 0 20 90 Unit ns ns ns ns ns ns ns 95 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER External interrupt (INTi) input Symbol tw(INH) tw(INL) Limits Parameter Min. 250 250 INTi input high-level pulse width INTi input low-level pulse width tc(TB) tw(TBH) TBiIN input tw(TBL) tc(CK) tw(CKH) CLKi input tw(CKL) th(C-Q) TxDi output td(C-Q) tsu(D-C) RxDi input tw(INL) INTi input tw(INH) Test conditions • Vcc = 5 V ± 0.5 V, Ta = –20 to 85 °C • Input timing voltage : VIL = 1.0 V, VIH = 4.0 V • Output timing voltage : VOL = 0.8 V, VOH = 2.0 V, CL = 50 pF 96 th(C-D) Max. Unit ns ns MI ELI MITSUBISHI MICROCOMPUTERS Y NAR M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP ge. ion. icat to chan ecif l sp ubject a in af es not mits ar li is is : Th metric e ic Not e para Som PR 16-BIT CMOS MICROCOMPUTER External clock input Timing Requirements (VCC = 5 V±0.5 V, VSS = 0 V, Ta = –20 to 85 °C, f(XIN) = 20 MHz, unless otherwise noted) Symbol tc tw(half) tw(H) tw(L) tr tf Limits Parameter Min. 50 0.45 tc 0.5 tc – 8 0.5 tc – 8 External clock input cycle time External clock input pulse width with half input-voltage External clock input high-level pulse width External clock input low-level pulse width External clock input rise time External clock input fall time tw(H) 0.55 tc 8 8 External clock input tw(L) Max. tr tf Unit ns ns ns ns ns ns tc tw(half) XIN Test conditions • Vcc = 5 V ± 0.5 V, Ta = –20 to 85 °C • Input timing voltage : VIL = 1.0 V, VIH = 4.0 V (tw(H), tw(L), tr, tf) • Output timing voltage : 2.5 V (tc, tw(half)) 97 A IMIN MITSUBISHI MICROCOMPUTERS RY M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL 16-BIT CMOS MICROCOMPUTER PACKAGE OUTLINE 64P6N-A Plastic 64pin 14✕14mm body QFP EIAJ Package Code QFP64-P-1414-0.80 Weight(g) 1.11 Lead Material Alloy 42 MD e JEDEC Code – HD 64 b2 ME D 49 1 I2 48 Recommended Mount Pad HE E Symbol A A1 A2 b c D E e HD HE L L1 x y 33 16 A 32 L1 c A2 17 b x A1 F e M y b2 I2 MD ME L Detail F MMP 64P4B JEDEC Code – Plastic 64pin 750mil SDIP Weight(g) 7.9 Lead Material Alloy 42/Cu Alloy 33 1 32 E 64 e1 c EIAJ Package Code SDIP64-P-750-1.78 Dimension in Millimeters Min Nom Max – – 3.05 0.1 0.2 0 – – 2.8 0.3 0.35 0.45 0.13 0.15 0.2 13.8 14.0 14.2 13.8 14.0 14.2 – 0.8 – 16.5 16.8 17.1 16.5 16.8 17.1 0.4 0.6 0.8 1.4 – – – – 0.2 – – 0.1 – 0° 10° 0.5 – – – – 1.3 – – 14.6 14.6 – – Symbol A1 L A A2 D e SEATING PLANE 98 b1 b b2 A A1 A2 b b1 b2 c D E e e1 L Dimension in Millimeters Min Nom Max – – 5.08 0.38 – – – 3.8 – 0.4 0.5 0.59 0.9 1.0 1.3 0.65 0.75 1.05 0.2 0.25 0.32 56.2 56.4 56.6 16.85 17.0 17.15 – 1.778 – – 19.05 – 2.8 – – 0° – 15° A IMIN RY e. n. atio chang cific o spe bject t l a fin su ot a its are is n m This etric li : e m ic Not e para Som P REL MITSUBISHI MICROCOMPUTERS M37905M4C-XXXFP, M37905M4C-XXXSP M37905M6C-XXXFP, M37905M6C-XXXSP M37905M8C-XXXFP, M37905M8C-XXXSP 16-BIT CMOS MICROCOMPUTER Keep safety first in your circuit designs! • Mitsubishi Electric Corporation puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of non-flammable material or (iii) prevention against any malfunction or mishap. • These materials are intended as a reference to assist our customers in the selection of the Mitsubishi semiconductor product best suited to the customer’s application; they do not convey any license under any intellectual property rights, or any other rights, belonging to Mitsubishi Electric Corporation or a third party. Mitsubishi Electric Corporation assumes no responsibility for any damage, or infringement of any third-party’s rights, originating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples contained in these materials. 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When using any or all of the information contained in these materials, including product data, diagrams, charts, programs, and algorithms, please be sure to evaluate all information as a total system before making a final decision on the applicability of the information and products. Mitsubishi Electric Corporation assumes no responsibility for any damage, liability or other loss resulting from the information contained herein. Mitsubishi Electric Corporation semiconductors are not designed or manufactured for use in a device or system that is used under circumstances in which human life is potentially at stake. Please contact Mitsubishi Electric Corporation or an authorized Mitsubishi Semiconductor product distributor when considering the use of a product contained herein for any specific purposes, such as apparatus or systems for transportation, vehicular, medical, aerospace, nuclear, or undersea repeater use. The prior written approval of Mitsubishi Electric Corporation is necessary to reprint or reproduce in whole or in part these materials. If these products or technologies are subject to the Japanese export control restrictions, they must be exported under a license from the Japanese government and cannot be imported into a country other than the approved destination. Any diversion or reexport contrary to the export control laws and regulations of Japan and/or the country of destination is prohibited. Please contact Mitsubishi Electric Corporation or an authorized Mitsubishi Semiconductor product distributor for further details on these materials or the products contained therein. Notes regarding these materials • • • • • • • © 2001 MITSUBISHI ELECTRIC CORP. New publication, effective Jul., 2001. Specifications subject to change without notice. Revision History Rev. M37905MxC-XXXFP/SP Datasheet Revision Description No. Rev. date 1.0 First Edition. The following are released. • DESCRIPTION 000630 2.0 1. Revised Points Refer to “Corrections and Supplementary Explanation for M37905MxC-XXXFP/SP Datasheet (Rev.A)”. 2. Added Sections 010301 BLOCK DIAGRAM, BASIC FUNCTION BLOCKS, MEMORY, CENTRAL PROCESSING UNIT (CPU), BUS INTERFACE UNIT, PROCESSOR MODES, INTERRUPTS, TIMER, TIMER FUNCTION FOR MOTOR CONTROL, PULSE OUTPUT PORT MODE 0/1, SERIAL I/O PORTS, A-D CONVERTER, D-A CONVERTER, WATCHDOG TIMER, INPUT/OUTPUT PINS, RESET CIRCUIT, OSCILLATION CIRCUIT, CLOCK GENERATING CIRCUIT, STANDBY FUNCTION, POWER SAVING FUNCTION, DEBUG FUNCTION, ELECTRICAL CHARACTERISTICS, PACKAGE OUTLINE 3.0 Refer to “Corrections and Explanation for M37905MxC-XXXFP/SP Datasheet (Rev.B)”. Note : ★ represents the new information added in Rev.3.0. (1/1) 010702 Corrections and Supplementary Explanation for M37905MxC-XXXFP/SP Datasheet (Rev.B) No.1 Page Error Correction Page 1, 8-bit A-D converter DISTINCTIVE FEATURES 8-bit D-A converter Page 1, Control devices for equipment required APPLICATION for motor control such as inverter ••••• Control devices for equipment, requiring motor control, such as inverter ••••• Page 1, ● Pin No.23; P53/INT3/RTPTRG0/XCOUT M37905MxC-XXXFP ● Pin No.24; P52/INT2/RTPTRG1/XCIN PIN CONFIGURATION (TOP VIEW) ● Pin No.50; P11/CTS0/CLK0 ● Pin No.23; P53/INT3/RTPTRG0 ● Pin No.24; P52/INT2/RTPTRG1 ● Pin No.50; P11/CTS0/CLK0 Page 2, ● Pin No.28; XONT M37905MxC-XXXSP ● Pin No.31; P53/INT3/RTPTRG0/XCOUT PIN CONFIGURA● Pin No.32; P52/INT2/RTPTRG1/XCIN TION (TOP VIEW) ● Pin No.28; XOUT ● Pin No.31; P53/INT3/RTPTRG0 ● Pin No.32; P52/INT2/RTPTRG1 Page 4, Item 1 External main-clock input frequency f(XIN) External clock input frequency f(XIN) ❈ “External sub-clock input frequency f(XCIN)” is deleted. Item 2 System clock input frequency f(fsys) System clock frequency f(fsys) Item 3: Clock gen- 2 circuits incorporated Incorporated erating circuit Item 4: Power dis- •••• (at f(XIN) = 20 MHz, ••••) •••• (at f(fsys) = 20 MHz, ••••) sipation ★ Page 43, Figure 43 4 5 3 2 1 4 5 0 3 2 1 0 Position-data-retain function control register Position-data-retain function control register Retained trigger’s polarity select bit Retain-trigger polarity select bit •••• •••• ★ Page 70, Figure 79 3: ••••, it is necessary to wait for 1 s or more before •••• 3: ••••, it is necessary to wait for 1 µs or more before •••• ★ Page 78, Figure 88 Comparison result register 0 (DE16)••• Comparison result register 1 (DF16)••• Comparator result register 0 (DE16)••• Comparator result register 1 (DF16)••• ★ ★ ★ Page 81, •••• the clock control register •••• • Left column Line 7 • Right column Lines 5, 10, 21 Page 90, RECOMMENDED OPERATING CONDITIONS Page 91, Symbol VIL Parameter Low-level input voltage •••• Limits Min. Typ. Max. •••• the clock control register 0 •••• Unit 0.2 VCC VmA 0 (VCC = 5V, ••••, f(fsys) = 20 MHz) DC ELECTRICAL CHARACTERISTICS (1/2) Symbol VIL Parameter Low-level input voltage •••• Limits Min. Typ. Max. 0 Unit 0.2 VCC (VCC = 5V, ••••, f(fsys) = 20 MHz, unless otherwise noted) V Corrections and Supplementary Explanation for M37905MxC-XXXFP/SP Datasheet (Rev.B) No.2 Page ★ Page 91, DC ELECTRICAL CHARACTERISTICS Error Symbol Parameter VOL Low-level P10-P17, •••• output •••••••••••••••, P70–P74, ••• voltage Symbol Parameter Test conditions VOL ROM hold When clock •••• voltage Symbol Parameter ICC Power source current Test conditions Output- f(fsys) = only pins 20 MHz. •••••••• •••• Correction Limits Min. Typ. Max. 2 Limits Min. Typ. Max. 2 50 Limits Min. Typ. Max. 25 (2/2) Unit Symbol Parameter V VOL Low-level P10-P17, •••• output •••••••••••••••, P70–P77, ••• voltage Unit V Unit mA Symbol Parameter Test conditions VOL ROM hold When clock •••• voltage Symbol Parameter ICC Power source current Test conditions Output- f(fsys) = only pins 20 MHz. •••• •••••••• Limits Min. Typ. Max. 2 Limits Min. Typ. Max. 2 Unit V Unit V Limits Min. Typ. Max. 25 50 Unit mA