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 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER • • DESCRIPTION The 38B4 group is the 8-bit microcomputer based on the 740 family core technology. The 38B4 group has six 8-bit timers, a 16-bit timer, a fluorescent display automatic display circuit, 12-channel 10-bit A-D converter, a serial I/O with automatic transfer function, which are available for controlling musical instruments and household appliances. • FEATURES • • • • • • • • • • • • • • • Basic machine-language instructions ....................................... 71 Minimum instruction execution time ................................. 0.48 µs (at 4.2 MHz oscillation frequency) Memory size ROM ............................................. 48K to 60K bytes RAM .......................................... 1024 to 2048 bytes Programmable input/output ports ............................................. 51 High-breakdown-voltage output ports ...................................... 36 Software pull-up resistors (Ports P5, P61 to P65 , P7, P8 4 to P87 , P9) Interrupts .................................................. 21 sources, 16 vectors Timers ........................................................... 8-bit ✕ 6, 16-bit ✕ 1 Serial I/O1 (Clock-synchronized) ................................... 8-bit ✕ 1 ...................... (max. 256-byte automatic transfer function) Serial I/O2 (UART or Clock-synchronized) .................... 8-bit ✕ 1 PWM ............................................................................ 14-bit ✕ 1 8-bit ✕ 1 (also functions as timer 6) A-D converter .............................................. 10-bit ✕ 12 channels Fluorescent display function ......................... Total 40 control pins Interrupt interval determination function ..................................... 1 Watchdog timer ............................................................ 20-bit ✕ 1 • • Buzzer output ............................................................................. 1 Clock generating circuit ...................................... Built-in 2 circuits (connect to external ceramic resonator or quartz-crystal oscillator) Power source voltage In high-speed mode ................................................... 4.0 to 5.5 V (at 4.2 MHz oscillation frequency) 2.7 to 5.5 V (at 2.0 MHz oscillation frequency) In middle-speed mode ................................................ 2.7 to 5.5 V (at 4.2 MHz oscillation frequency) In low-speed mode ..................................................... 2.7 to 5.5 V (at 32 kHz oscillation frequency) Power dissipation In high-speed mode .......................................................... 35 mW (at 4.2 MHz oscillation frequency) In low-speed mode ............................................................. 60 µW (at 32 kHz oscillation frequency, at 3 V power source voltage) In stop mode ......................................................................... 1 µA (at clock stop) Operating temperature range ................................... –20 to 85 °C APPLICATION Musical instruments, VCR, household appliances, etc. 50 49 48 47 46 45 44 43 42 41 61 60 59 58 57 56 55 54 53 52 51 65 66 67 40 39 38 68 69 37 70 71 35 36 72 M38B4xMxH-XXXXFP 73 74 34 33 32 31 P75/AN5 P74/AN4 P73/AN3 P72/AN2 P71/AN1 P70/AN0 P61/CNTR0/CNTR2 (Note) P60/CNTR1 P47/INT2 RESET P91/XCOUT P90/XCIN VSS XIN XOUT VCC P46/T3OUT P45/T1OUT P44/PWM1 P43/BUZ01 (Note) P42/INT3 P41/INT1 P40/INT0 P87/PWM0/FLD39 21 22 23 24 26 25 13 14 15 16 17 18 19 20 28 27 79 80 11 12 29 77 78 4 5 6 7 8 9 10 30 76 2 3 75 1 P57/SRDY2/SCLK22 P56/SCLK21 P55/TxD P54/RxD P53/SCLK12 P52/SCLK11 P51/SOUT1 P50/SIN1 AVSS VREF P65/SSTB1/AN11 P64/INT4/SBUSY1/AN10 P63/AN9 P62/SRDY1/AN8 P77/AN7 P76/AN6 62 64 63 P20/BUZ02/FLD0 P21/FLD1 P22/FLD2 P23/FLD3 P24/FLD4 P25/FLD5 P26/FLD6 P27/FLD7 P00/FLD8 P01/FLD9 P02/FLD10 P03/FLD11 P04/FLD12 P05/FLD13 P06/FLD14 P07/FLD15 P10/FLD16 P11/FLD17 P12/FLD18 P13/FLD19 P14/FLD20 P15/FLD21 P16/FLD22 P17/FLD23 PIN CONFIGURATION (TOP VIEW) Note: In the mask option type P, INT3 and CNTR1 cannot be used. Package type : 80P6N-A 80-pin plastic-molded QFP Fig. 1 Pin configuration of M38B4xMxH-XXXXFP P30/FLD24 P31/FLD25 P32/FLD26 P33/FLD27 P34/FLD28 P35/FLD29 P36/FLD30 P37/FLD31 P80/FLD32 P81/FLD33 P82/FLD34 P83/FLD35 VEE P84/FLD36 P85/RTP0/FLD37 P86/RTP1/FLD38 2 Port P0(8) 8 Fig. 2 Functional block diagram A-D converter Port P6(6) 6 Port P5(8) 8 (36 high-breakdown voltage ports) 40 control pins FLD display function Buzzer output PWM0(14-bit) PWM1(8-bit) Serial I/O2 (Clock-synchronized or UART) Serial I/O1(Clock-synchronized) (256 byte automatic transfer) Serial I/O (10-bit 5 12 channel) 8 CPU core Timer X(16-bit) Timer 1(8-bit) Timer 2(8-bit) Timer 3(8-bit) Timer 4(8-bit) Timer 5(8-bit) Timer 6(8-bit) Timers 8 Port P2(8) 8 Port P7(8) Interrupt interval determination function Watchdog timer Port P1(8) Build-in peripheral functions I/O ports FUNCTIONAL BLOCK DIAGRAM (Package : 80P6N-A) Port P9(2) 2 8 Port P4(8) 1 Port P8(8) RAM ROM Memory XIN-XOUT (main-clock) XCIN-XCOUT (sub-clock) System clock generation Port P3(8) 8 7 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FUNCTIONAL BLOCK MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PIN DESCRIPTION Table 1 Pin description (1) Pin Name Function Function except a port function VCC, VSS Power source • Apply voltage of 4.0–5.5 V to VCC, and 0 V to VSS. VEE • Apply voltage supplied to pull-down resistors of ports P0, P1, and P3. AVSS Pull-down power source Reference voltage Analog power RESET XIN source Reset input Clock input XOUT Clock output • Connect to VSS. • Reset input pin for active “L”. • Input and output pins for the main clock generating circuit. • Feedback resistor is built in between XIN pin and XOUT pin. • Connect a ceramic resonator or quartz-crystal oscillator between the XIN and XOUT pins to set the P00/FLD8– P07/FLD15 I/O port P0 VREF • Reference voltage input pin for A-D converter. • Analog power source input pin for A-D converter. oscillation frequency. • When an external clock is used, connect the clock source to the XIN pin and leave the XOUT pin open. • The clock is used as the oscillating source of system clock. • 8-bit I/O port. • FLD automatic display • I/O direction register allows each pin to be individually programmed as either pins input or output. • At reset, this port is set to input mode. • A pull-down resistor is built in between port P0 and the VEE pin. • CMOS compatible input level. • High-breakdown-voltage P-channel open-drain output structure. • At reset, this port is set to VEE level. P10/FLD16– Output port P1 P17/FLD23 P20/BUZ02 / I/O port P2 FLD0– P27/FLD7 P30/FLD24– Output port P3 P37/FLD31 P40/INT 0, P41/INT 1, P42/INT 3 P43/BUZ01 P44/PWM1 P45/T 1OUT, P46/T 3OUT P47/INT2 I/O port P4 • 8-bit output port. • A pull-down resistor is built in between port P1 and the VEE pin. • High-breakdown-voltage P-channel open-drain output structure. • At reset, this port is set to VEE level. • 8-bit I/O port with the same function as port P0. • FLD automatic display pins • Low-voltage input level. • High-breakdown-voltage P-channel open-drain output structure. • 8-bit output port. • A pull-down resistor is built in between port P3 and the VEE pin. • High-breakdown-voltage P-channel open-drain output structure. pins • Buzzer output pin (P20) • FLD automatic display pins • At reset, this port is set to VEE level. • 7-bit I/O port with the same function as port P0. • CMOS compatible input level • N-channel open-drain output structure. • FLD automatic display • Interrupt input pins In the mask option type P, INT3 cannot be used. • Buzzer output pin • PWM output pin (Timer output pin) • Timer output pin Input port P4 • 1-bit input port. • CMOS compatible input level. • Interrupt input pin 3 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 2 Pin description (2) Pin P50/SIN1, Name I/O port P5 P51/SOUT1, P52/SCLK11, P53/SCLK12 P54/RXD, P55/TXD, P56/SCLK21, Function • 8-bit CMOS I/O port with the same function as port P0. • CMOS compatible input level. • CMOS 3-state output structure. • Serial I/O2 function pins P57/SRDY2/ SCLK22 P60/CNTR1 I/O port P6 P61/CNTR0/ CNTR2 P62/SRDY1/ AN 8 P63/AN9 • 1-bit I/O port with the same function as port P0. • CMOS compatible input level. • N-channel open-drain output structure. • Timer input pin In the mask option type P, CNTR 1 cannot be used. • 5-bit CMOS I/O port with the same function as port P0. • CMOS compatible input level. • CMOS 3-state output structure. • Timer I/O pin P64/INT4/ SBUSY1 /AN10, P65/SSTB1/ AN11 P70/AN0– P77/AN7 I/O port P7 P84/FLD36 P85/RTP0/ FLD 37, P86/RTP1/ FLD38 P87/PWM0/ FLD 39 4 • Serial I/O1 function pin • A-D conversion input pin • A-D conversion input pin • Dimmer signal output pin • Serial I/O1 function pin • A-D conversion input pin • Interrupt input pin (P64) P80/FLD32 – I/O port P8 P83/FLD35 P90/XCIN, P91/XCOUT Function except a port function • Serial I/O1 function pins • 8-bit CMOS I/O port with the same function as port P0. • CMOS compatible input level. • CMOS 3-state output structure. • A-D conversion input pin • 4-bit I/O port with the same function as port P0. • Low-voltage input level. • High-breakdown-voltage P-channel open-drain output structure. • 4-bit CMOS I/O port with the same function as port P0. • Low-voltage input level. • CMOS 3-state output structure • FLD automatic display pins • FLD automatic display pins • Real time port output • FLD automatic display pins • 14-bit PWM output I/O port P9 • 2-bit CMOS I/O port with the same function as port P0. • CMOS compatible input level. • CMOS 3-state output structure. • I/O pins for sub-clock generating circuit (connect a ceramic resonator or a quarts-crystal oscillator) MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PART NUMBERING Product M38B4 9 M F H - XXXX FP Package type FP : 80P6N-A package ROM number High-breakdown voltage pull-down option Regarding option contents, refer to section “MASK OPTION OF PULL-DOWN RESISTOR”. ROM size 1 : 4096 bytes 2 : 8192 bytes 3 : 12288 bytes 4 : 16384 bytes 5 : 20480 bytes 6 : 24576 bytes 7 : 28672 bytes 8 : 32768 bytes 9 : 36864 bytes A : 40960 bytes B : 45056 bytes C : 49152 bytes D : 53248 bytes E : 57344 bytes F : 61440 bytes The first 128 bytes and the last 2 bytes of ROM are reserved areas ; they cannot be used for users. Memory type M : Mask ROM version E : EPROM or One Time PROM version RAM size 0 : 192 bytes 1 : 256 bytes 2 : 384 bytes 3 : 512 bytes 4 : 640 bytes 5 : 768 bytes 6 : 896 bytes 7 : 1024 bytes 8 : 1536 bytes 9 : 2048 bytes Fig. 3 Part numbering 5 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER GROUP EXPANSION Mitsubishi plans to expand the 38B4 group as follows: Memory Type Support for Mask ROM version. Memory Size Mask ROM size ..................................................... 48K to 60K bytes RAM size ............................................................ 1024 to 2048 bytes Package 80P6N-A ..................................... 0.8 mm-pitch plastic molded QFP ROM size (bytes) Under development 60K M38B49MFH 56K 52K Under development 48K M38B47MC 44K 40K 36K 32K 28K 24K 20K 16K 12K 8K 4K 256 512 768 1,024 1,536 2,048 RAM size (bytes) Note : Products under development or planning : the development schedule and specifications may be revised without notice. Fig. 4 Memory expansion plan Currently supported products are listed below. Table 3 List of supported products Product M38B49MFH-XXXXFP M38B47MCH-XXXXFP 6 ROM size (bytes) ROM size for User ( ) 61440 (61310) 49152 (49022) As of Mar. 2000 Remarks RAM size (bytes) Package 2048 80P6N-A Mask ROM version 1024 80P6N-A Mask ROM version MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FUNCTIONAL DESCRIPTION Central Processing Unit (CPU) [Stack Pointer (S)] The stack pointer is an 8-bit register used during subroutine calls and interrupts. This register indicates start address of stored area (stack) for storing registers during subroutine calls and interrupts. The low-order 8 bits of the stack address are determined by the contents of the stack pointer. The high-order 8 bits of the stack address are determined by the stack page selection bit. If the stack page selection bit is “0” , the high-order 8 bits becomes “0016 ”. If the stack page selection bit is “1”, the high-order 8 bits becomes “0116”. The operations of pushing register contents onto the stack and popping them from the stack are shown in Figure 6. Store registers other than those described in Figure 6 with program when the user needs them during interrupts or subroutine calls (see Table 4). The 38B4 group uses the standard 740 Family instruction set. Refer to the table of 740 Family addressing modes and machine instructions or the 740 Family Software Manual for details on the instruction set. Machine-resident 740 Family instructions are as follows: The FST and SLW instructions cannot be used. The STP, WIT, MUL, and DIV instructions can be used. [Accumulator (A)] The accumulator is an 8-bit register. Data operations such as data transfer, etc., are executed mainly through the accumulator. [Index Register X (X)] The index register X is an 8-bit register. In the index addressing modes, the value of the OPERAND is added to the contents of register X and specifies the real address. [Program Counter (PC)] The program counter is a 16-bit counter consisting of two 8-bit registers PCH and PC L. It is used to indicate the address of the next instruction to be executed. [Index Register Y (Y)] The index register Y is an 8-bit register. In partial instruction, the value of the OPERAND is added to the contents of register Y and specifies the real address. b0 b7 A Accumulator b0 b7 X Index register X b0 b7 Y b7 Index register Y b0 S b15 b7 Stack pointer b0 PCL PCH b7 Program counter b0 N V T B D I Z C Processor status register (PS) Carry flag Zero flag Interrupt disable flag Decimal mode flag Break flag Index X mode flag Overflow flag Negative flag Fig. 5 740 Family CPU register structure 7 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER On-going Routine Interrupt request (Note) M (S) Execute JSR Push return address on stack M (S) (PCH) (S) (S) – 1 M (S) (PCL) (S) (S)– 1 (S) M (S) (S) M (S) (S) Subroutine POP return address from stack (S) + 1 (PCL) M (S) (S) (S) + 1 (PCH) M (S) (S) – 1 (PCL) Push return address on stack (S) – 1 (PS) Push contents of processor status register on stack (S) – 1 Interrupt Service Routine Execute RTS (S) (PCH) I Flag is set from “0” to “1” Fetch the jump vector Execute RTI Note: Condition for acceptance of an interrupt (S) (S) + 1 (PS) M (S) (S) (S) + 1 (PCL) M (S) (S) (S) + 1 (PCH) M (S) POP contents of processor status register from stack POP return address from stack Interrupt enable flag is “1” Interrupt disable flag is “0” Fig. 6 Register push and pop at interrupt generation and subroutine call Table 4 Push and pop instructions of accumulator or processor status register Accumulator Processor status register 8 Push instruction to stack Pop instruction from stack PHA PHP PLA PLP MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [Processor Status Register (PS)] The processor status register is an 8-bit register consisting of 5 flags which indicate the status of the processor after an arithmetic operation and 3 flags which decide MCU operation. Branch operations can be performed by testing the Carry (C) flag , Zero (Z) flag, Overflow (V) flag, or the Negative (N) flag. In decimal mode, the Z, V, N flags are not valid. •Bit 0: Carry flag (C) The C flag contains a carry or borrow generated by the arithmetic logic unit (ALU) immediately after an arithmetic operation. It can also be changed by a shift or rotate instruction. •Bit 1: Zero flag (Z) The Z flag is set if the result of an immediate arithmetic operation or a data transfer is “0”, and cleared if the result is anything other than “0”. •Bit 2: Interrupt disable flag (I) The I flag disables all interrupts except for the interrupt generated by the BRK instruction. Interrupts are disabled when the I flag is “1”. •Bit 3: Decimal mode flag (D) The D flag determines whether additions and subtractions are executed in binary or decimal. Binary arithmetic is executed when this flag is “0”; decimal arithmetic is executed when it is “1”. Decimal correction is automatic in decimal mode. Only the ADC and SBC instructions can be used for decimal arithmetic. •Bit 4: Break flag (B) The B flag is used to indicate that the current interrupt was generated by the BRK instruction. The BRK flag in the processor status register is always “0”. When the BRK instruction is used to generate an interrupt, the processor status register is pushed onto the stack with the break flag set to “1”. •Bit 5: Index X mode flag (T) When the T flag is “0”, arithmetic operations are performed between accumulator and memory. When the T flag is “1”, direct arithmetic operations and direct data transfers are enabled between memory locations. •Bit 6: Overflow flag (V) The V flag is used during the addition or subtraction of one byte of signed data. It is set if the result exceeds +127 to -128. When the BIT instruction is executed, bit 6 of the memory location operated on by the BIT instruction is stored in the overflow flag. •Bit 7: Negative flag (N) The N flag is set if the result of an arithmetic operation or data transfer is negative. When the BIT instruction is executed, bit 7 of the memory location operated on by the BIT instruction is stored in the negative flag. Table 5 Set and clear instructions of each bit of processor status register C flag Set instruction Clear instruction SEC CLC Z flag _ _ I flag D flag SEI CLI SED CLD B flag _ _ T flag V flag SET CLT _ CLV N flag _ _ 9 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [CPU Mode Register (CPUM)] 003B 16 The CPU mode register contains the stack page selection bit and the internal system clock selection bit etc. The CPU mode register is allocated at address 003B 16 . b7 b0 CPU mode register (CPUM: address 003B16) Processor mode bits b1 b0 0 0 : Single-chip mode 0 1: 1 0 : Not available 1 1: Stack page selection bit 0: Page 0 1: Page 1 Not available Port XC switch bit 0: I/O port function 1: XCIN–XCOUT oscillating function Main clock (XIN–XOUT) stop bit 0: Oscillating 1: Stopped Main clock division ratio selection bit 0: f(XIN) (high-speed mode) 1: f(XIN)/4 (middle-speed mode) Internal system clock selection bit 0: XIN-XOUT selection (middle-/high-speed mode) 1: XCIN-XCOUT selection (low-speed mode) Fig. 7 Structure of CPU mode register 10 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER MEMORY Special Function Register (SFR) Area The special function register (SFR) area in the zero page contains control registers such as I/O ports and timers. RAM RAM is used for data storage and for stack area of subroutine calls and interrupts. Zero Page The 256 bytes from addresses 000016 to 00FF16 are called the zero page area. The internal RAM and the special function registers (SFR) are allocated to this area. The zero page addressing mode can be used to specify memory and register addresses in the zero page area. Access to this area with only 2 bytes is possible in the zero page addressing mode. Special Page ROM The first 128 bytes and the last 2 bytes of ROM are reserved for device testing, and the other areas are user areas for storing programs. The 256 bytes from addresses FF0016 to FFFF 16 are called the special page area. The special page addressing mode can be used to specify memory addresses in the special page area. Access to this area with only 2 bytes is possible in the special page addressing mode. Interrupt Vector Area The interrupt vector area contains reset and interrupt vectors. RAM area RAM size (byte) 192 256 384 512 640 768 896 1024 1536 2048 Address XXXX16 000016 RAM 00FF16 013F16 01BF16 023F16 02BF16 033F16 03BF16 043F16 063F16 083F16 SFR area 1 Zero page 004016 010016 XXXX16 Reserved area 044016 Not used (Note) 0EF016 0EFF16 0F0016 ROM area ROM size (byte) Address YYYY16 Address ZZZZ16 4096 8192 12288 16384 20480 24576 28672 32768 36864 40960 45056 49152 53248 57344 61440 F00016 E00016 D00016 C00016 B00016 A00016 900016 800016 700016 600016 500016 400016 300016 200016 100016 F08016 E08016 D08016 C08016 B08016 A08016 908016 808016 708016 608016 508016 408016 308016 208016 108016 ROM 0FFF16 YYYY16 SFR area 2 RAM area for Serial I/O automatic transfer RAM area for FLD automatic display Reserved ROM area (common ROM area,128 byte) ZZZZ16 FF0016 FFDC16 FFFE16 FFFF16 Special page Interrupt vector area Reserved ROM area Note: When 1024 bytes or more are used as RAM area, this area can be used. Fig. 8 Memory map diagram 11 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER 000016 Port P0 (P0) 002016 Timer 1 (T1) 000116 Port P0 direction register (P0D) 002116 Timer 2 (T2) 000216 Port P1 (P1) 002216 Timer 3 (T3) 002316 Timer 4 (T4) 000416 Port P2 (P2) 002416 Timer 5 (T5) 000516 Port P2 direction register (P2D) 002516 Timer 6 (T6) 000616 Port P3 (P3) 002616 PWM control register (PWMCON) 000316 002716 Timer 6 PWM register (T6PWM) 000816 Port P4 (P4) 002816 Timer 12 mode register (T12M) 000916 Port P4 direction register (P4D) 002916 Timer 34 mode register (T34M) 000A16 Port P5 (P5) 002A16 Timer 56 mode register (T56M) 000B16 Port P5 direction register (P5D) 002B16 Watchdog timer control register (WDTCON) 000C16 Port P6 (P6) 002C16 Timer X (low-order) (TXL) 000D16 Port P6 direction register (P6D) 002D16 Timer X (high-order) (TXH) 000E16 Port P7 (P7) 002E16 Timer X mode register 1 (TXM1) 000F16 Port P7 direction register (P7D) 002F16 Timer X mode register 2 (TXM2) 001016 Port P8 (P8) 003016 Interrupt interval determination register (IID) 001116 Port P8 direction register (P8D) 003116 Interrupt interval determination control register (IIDCON) 001216 Port P9 (P9) 003216 A-D control register (ADCON) 001316 Port P9 direction register (P9D) 003316 A-D conversion register (low-order) (ADL) 001416 PWM register (high-order) (PWMH) 003416 A-D conversion register (high-order) (ADH) 001516 PWM register (low-order) (PWM L) 003516 001616 Baud rate generator (BRG) 003616 001716 UART control register (UARTCON) 003716 001816 Serial I/O1 automatic transfer data pointer (SIO1DP) 003816 001916 Serial I/O1 control register 1 (SIO1CON1) 003916 Interrupt source switch register (IFR) 001A16 Serial I/O1 control register 2 (SIO1CON2) 003A16 Interrupt edge selection register (INTEDGE) 001B16 Serial I/O1 register/Transfer counter (SIO1) 003B16 CPU mode register (CPUM) 001C16 Serial I/O1 control register 3 (SIO1CON3) 003C16 Interrupt request register 1(IREQ1) 001D16 Serial I/O2 control register (SIO2CON) 003D16 Interrupt request register 2(IREQ2) 001E16 Serial I/O2 status register (SIO2STS) 003E16 Interrupt control register 1(ICON1) 001F16 Serial I/O2 transmit/receive buffer register (TB/RB) 003F16 Interrupt control register 2(ICON2) 0EF016 Pull-up control register 1 (PULL1) 0EF816 FLD data pointer (FLDDP) 0EF116 Pull-up control register 2 (PULL2) 0EF916 Port P0FLD/port switch register (P0FPR) 0EF216 0EFA16 Port P2FLD/port switch register (P2FPR) 0EF316 0EFB16 Port P8FLD/port switch register (P8FPR) 000716 0EF416 FLDC mode register (FLDM) 0EFC16 Port P8FLD output control register (P8FLDCON) 0EF516 Tdisp time set register (TDISP) 0EFD16 Buzzer output control register (BUZCON) 0EF616 Toff1 time set register (TOFF1) 0EFE16 0EF716 Toff2 time set register (TOFF2) 0EFF16 Fig. 9 Memory map of special function register (SFR) 12 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER I/O PORTS [Direction Registers] PiD The 38B4 group has 51 programmable I/O pins arranged in eight individual I/O ports (P0, P2, P40–P4 6, and P5–P9). The I/O ports have direction registers which determine the input/output direction of each individual pin. Each bit in a direction register corresponds to one pin, and each pin can be set to be input port or output port. When “0” is written to the bit corresponding to a pin, that pin becomes an input pin. When “1” is written to that pin, that pin becomes an output pin. If data is read from a pin set to output, the value of the port output latch is read, not the value of the pin itself. Pins set to input (the bit corresponding to that pin must be set to “0”) are floating and the value of that pin can be read. If a pin set to input is written to, only the port output latch is written to and the pin remains floating. b7 b0 Pull-up control register 1 (PULL1 : address 0EF016) P50, P51 pull-up control bit P52, P53 pull-up control bit P54, P55 pull-up control bit P56, P57 pull-up control bit P61 pull-up control bit 0: No pull-up 1: Pull-up P62, P63 pull-up control bit P64, P65 pull-up control bit Not used (returns “0” when read) [High-Breakdown-Voltage Output Ports] The 38B4 group has 5 ports with high-breakdown-voltage pins (ports P0–P3 and P8 0–P83). The high-breakdown-voltage ports have Pchannel open-drain output with Vcc- 45 V of breakdown voltage. Each pin in ports P0, P1, and P3 has an internal pull-down resistor connected to V EE. At reset, the P-channel output transistor of each port latch is turned off, so that it goes to VEE level (“L”) by the pull-down resistor. Writing “1” (weak drivability) to bit 7 of the FLDC mode register (address 0EF416 ) shows the rising transition of the output transistors for reducing transient noise. At reset, bit 7 of the FLDC mode register is set to “0” (strong drivability). [Pull-up Control Register] PULL Ports P5, P61–P65, P7, P84–P87 and P9 have built-in programmable pull-up resistors. The pull-up resistors are valid only in the case that the each control bit is set to “1” and the corresponding port direction registers are set to input mode. b7 b0 Pull-up control register 2 (PULL2 : address 0EF116) P70, P71 pull-up control bit P72, P73 pull-up control bit P74, P75 pull-up control bit P76, P77 pull-up control bit P84, P85 pull-up control bit 0: No pull-up 1: Pull-up P86, P87 pull-up control bit P90, P91 pull-up control bit Not used (returns “0” when read) Fig. 10 Structure of pull-up control registers (PULL1 and PULL2) 13 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 6 List of I/O port functions (1) zPin Name Input/Output Port P0 Input/output, individual bits CMOS compatible input level FLD automatic display function FLDC mode register High-breakdown voltage PPort P0FLD/port switch register P10/FLD16– Port P1 P17/FLD23 Output channel open-drain output with pull-down resistor High-breakdown voltage Pchannel open-drain output with pull-down resistor P20/BUZ02/ Port P2 FLD0 P21/FLD1– P27/FLD7 P30/FLD24– Port P3 Input/output, individual bits P00/FLD8– P07/FLD15 Output P37/FLD31 P40/INT0, P41/INT1 P42/INT3 Port P4 P43/BUZ01 P44/PWM1 P45/T1OUT P46/T3OUT P47/INT2 Input P50/SIN1 Port P5 P51/SOUT1, P52/SCLK11, P53/SCLK12 P54/RXD P55/TXD, P56/SCLK21 P57/SRDY2/ SCLK22 P60/CNTR1 Port P6 P61/CNTR0/ CNTR2 P62/SRDY1/ AN8 P63/AN9 P64/INT4/ SBUSY1/AN10 P65/SSTB1/ AN11 P70/AN0– P77/AN7 14 Input/output, individual bits Port P7 Input/output, individual bits I/O Format Low-voltage input level High-breakdown voltage Pchannel open-drain output Non-Port Function Related SFRs FLDC mode register Buzzer output (P20) FLDC mode register FLD automatic display function Port P2FLD/port switch register FLD automatic display function Buzzer output control register High-breakdown voltage P- FLDC mode register Ref.No. (1) (2) (3) (1) (2) channel open-drain output with pull-down resistor CMOS compatible input level External interrupt input Interrupt edge selection register (5) N-channel open-drain output In the mask option type P, INT3 cannot be used. (7-1) (7-2) Buzzer output Buzzer output control register (4) PWM output Timer 56 mode register (6) Timer output Timer 12 mode register (8-1) Timer output Timer 34 mode register (8-2) CMOS compatible input level External interrput input Interrupt edge selection register (9) Interrupt interval determination control register CMOS compatible input level Serial I/O1 function I/O CMOS 3-state output Serial I/O2 function I/O Serial I/O1 control register 1, 2 (10) (11) Serial I/O2 control register UART control register (10) (11) (12) CMOS compatible input level External count input N-channel open-drain output In the mask option type P, CMOS compatible input level CNTR1 cannot be used. CMOS 3-state output Serial I/O1 function I/O A-D conversion input A-D conversion input Dimmer signal output Serial I/O1 function I/O A-D conversion input External interrupt input Serial I/O1 function I/O A-D conversion input A-D conversion input Interrupt edge selection register (7-1) (7-2) (13) Serial I/O1 control register 1, 2 A-D control register (14) A-D control register P8FLD output control bit Serial I/O1 control register 1, 2 A-D control register Interrupt edge selection register Serial I/O1 control register 1, 2 A-D control register A-D control register (15) (16) (17) (15) MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 7 List of I/O port functions (2) Name Input/Output I/O Format P80/FLD32 – Port P8 P83/FLD35 Pin Input/output, individual bits Low-voltage input level High-breakdown voltage Pchannel open-drain output Low-voltage input level CMOS 3-state output P84/FLD36 P85/RTP0/ FLD 37, P86/RTP1/ FLD38 P87/PWM0/ FLD 39 P90/XCIN P91/XCOUT Non-Port Function Related SFRs FLD automatic display function FLDC mode register Port P8FLD/port switch register FLD automatic display function FLDC mode register Real time port output (1) (18) (19) Port P8FLD/port switch register Timer X mode register 2 FLD automatic display function FLDC mode register PWM output Port P8FLD/port switch register PWM control register Port P9 Ref.No. CMOS compatible input level Sub-clock generating circuit I/O CPU mode register CMOS 3-state output (20) (21) (22) Notes 1 : Make sure that the input level at each pin is either 0 V or Vcc during execution of the STP instruction. When an input level is at an intermediate potential, a current will flow from Vcc to Vss through the input-stage gate. 2 : How to use double-function ports as function I/O ports, refer to the applicable sections. 15 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) Ports P0, P21–P27, P80–P83 (2) Ports P1, P3 FLD/Port switch register Dimmer signal (Note 1) * Port latch Data bus Dimmer signal (Note 1) Local data bus Direction register Local data bus * Port latch Data bus read VEE (Note 2) VE E (3) Port P20 (4) Port P43 FLD/Port switch register Buzzer control signal Buzzer signal output Buzzer control signal Buzzer signal output Dimmer signal (Note 1) Local data bus Direction register Data bus Port latch Direction register Data bus * # Port latch read read (Note 2) VEE (5) Ports P40, P41 (6) Port P44 Timer 6 output selection bit Direction register Data bus Port latch Direction register Data bus # Port latch read INT0,INT1 interrupt input Timer 6 output * High-breakdown-voltage P-channel transistor # Middle-breakdown-voltage N-channel transistor Notes 1: The dimmer signal sets the Toff timing. 2: A pull-down resistor is not built in to ports P2 and P8. Fig. 11 Port block diagram (1) 16 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (7-2) Ports P42, P60 (mask option type P) (7-1) Ports P42, P60 Direction register Direction register Data bus Port latch # Data bus # Port latch read INT3 interrupt input CNTR1 input (8-2) Ports P45, P46 (mask option type P) (8-1) Ports P45, P46 Timer 1 output bit Timer 3 output bit Timer 1 output bit Timer 3 output bit Direction register Direction register Data bus Port latch # Data bus # Port latch read Timer 1 output Timer 3 output Timer 1 output Timer 3 output (9) Port P47 (10) Ports P50, P54 Pull-up control Data bus INT2 interrupt input Direction register Data bus Port latch Serial I/O input # Middle-breakdown-voltage N-channel transistor Fig. 12 Port block diagram (2) 17 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (11) Ports P51–P53, P55, P56 (12) Port P57 Pull-up control P-channel output disable signal (P51,P55) Output OFF control signal Serial I/O2 mode selection bit Pull-up control SRDY2 output enable bit Direction register Direction register Data bus Port latch Data bus TXD, SOUT or SCLK Port latch Serial ready output Serial clock input Serial clock input P52,P53,P56 (13) Port P61 (14) Port P62 Pull-up control Pull-up control P62/SRDY1•P64/SBUSY1 pin control bit Timer X operating mode bit Direction register Direction register Port latch Data bus Data bus Timer X output CNTR0,CNTR2 input Timer 2, Timer X external clock input (15) Ports P63, P7 Port latch Serial ready output Serial ready input A-D conversion input Analog input pin selection bit (16) Port P64 Pull-up control P62/SRDY1•P64/SBUSY1 pin control bit Pull-up control Dimmer output control bit (P63) Direction register Direction register Data bus Data bus Port latch Port latch SBUSY1 output INT4 interrupt input, SBUSY1 input Dimmer signal output (P63) A-D conversion input Analog input pin selection bit Fig. 13 Port block diagram (3) 18 A-D conversion input Analog input pin selection bit MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (17) Port P65 (18) Port P84 Pull-up control P65/SSTB1 pin control bit Dimmer signal (Note) Direction register Direction register Port latch Data bus Pull-up control FLD/Port switch register Local data bus Port latch Data bus SSTB1 output A-D conversion input (19) Ports P85, P86 (20) Port P87 Dimmer signal (Note) Pull-up control Dimmer signal (Note) FLD/Port switch register FLD/Port switch register Real time port control bit Direction register Local data bus Data bus Local data bus Port latch Direction register Port latch Data bus RTP output PWM0 output (21) Port P90 (22) Port P91 Pull-up control Pull-up control Port Xc switch bit Port Xc switch bit Direction register Data bus Pull-up control P87/PWM output enable bit Port latch Direction register Data bus Port latch Oscillator Port P90 Sub-clock generating circuit input Port Xc switch bit * High-breakdown-voltage P-channel transistor Note: The dimmer signal sets the Toff timing. Fig. 14 Port block diagram (4) 19 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER INTERRUPTS Interrupts occur by twenty one sources: five external, fifteen internal, and one software. Interrupt Control Each interrupt except the BRK instruction interrupt have both an interrupt request bit and an interrupt enable bit, and is controlled by the interrupt disable flag. An interrupt occurs if the corresponding interrupt request and enable bits are “1” and the interrupt disable flag is “0”. Interrupt enable bits can be set or cleared by software. Interrupt request bits can be cleared by software, but cannot be set by software. The BRK instruction interrupt and reset cannot be disabled with any flag or bit. The I flag disables all interrupts except the BRK instruction interrupt and reset. If several interrupts requests occurs at the same time the interrupt with highest priority is accepted first. Interrupt Operation Upon acceptance of an interrupt the following operations are automatically performed: 1. The contents of the program counter and processor status register are automatically pushed onto the stack. 2. The interrupt disable flag is set and the corresponding interrupt request bit is cleared. 3. The interrupt jump destination address is read from the vector table into the program counter. ■Notes on Use When the active edge of an external interrupt (INT0–INT4) is set or when switching interrupt sources in the same vector address, the corresponding interrupt request bit may also be set. Therefore, please take following sequence: (1) Disable the external interrupt which is selected. (2) Change the active edge in interrupt edge selection register (3) Clear the set interrupt request bit to “0”. (4) Enable the external interrupt which is selected. 20 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 8 Interrupt vector addresses and priority Interrupt Source Priority Vector Addresses (Note 1) High Low Reset (Note 2) INT0 1 2 FFFD16 FFFB16 FFFC16 FFFA16 INT1 3 FFF916 FFF816 INT2 4 FFF716 Remote control/ counter overflow Serial I/O1 5 FFF516 Interrupt Request At reset At detection of either rising or falling edge of INT0 input At detection of either rising or falling edge of INT1 input Non-maskable External interrupt (active edge selectable) External interrupt (active edge selectable) FFF616 At detection of either rising or falling edge of INT2 input At 8-bit counter overflow FFF416 At completion of data transfer External interrupt (active edge selectable) Valid when interrupt interval determination is operating Valid when serial I/O ordinary Serial I/O automatic transfer Timer X Timer 1 6 7 FFF316 FFF116 FFF216 FFF016 At timer X underflow At timer 1 underflow Timer 2 Timer 3 Timer 4 Timer 5 Timer 6 8 9 10 11 12 FFEF16 FFED16 FFEB16 FFE916 FFE716 FFEE16 FFEC16 FFEA16 FFE816 FFE616 At timer 2 underflow At timer 3 underflow At timer 4 underflow At timer 5 underflow At timer 6 underflow Serial I/O2 receive INT3 13 14 FFE516 FFE316 FFE416 FFE216 Serial I/O2 transmit INT4 15 FFE116 FFE016 At completion of serial I/O2 data receive At detection of either rising or falling edge of INT3 input At completion of serial I/O2 data transmit At detection of either rising or falling edge of At completion of the last data transfer INT4 input A-D conversion FLD blanking 16 FFDF16 Remarks Generating Conditions FFDE16 At completion of A-D conversion At falling edge of the last timing immediately before blanking period starts mode is selected Valid when serial I/O automatic transfer mode is selected STP release timer underflow (Note 3) External interrupt (Note 4) (active edge selectable) External interrupt (active edge selectable) Valid when INT4 interrupt is selected Valid when A-D conversion is selected Valid when FLD blanking interrupt is selected FLD digit At rising edge of digit (each timing) Valid when FLD digit interrupt is selected BRK instruction 17 FFDD16 FFDC16 At BRK instruction execution Non-maskable software interrupt Notes 1 : Vector addresses contain interrupt jump destination addresses. 2 : Reset function in the same way as an interrupt with the highest priority. 3 : In the mask option type P, timer 4 interrupt whose count source is CNTR1 input cannot be used. 4 : In the mask option type P, INT3 interrupt cannot be used. 21 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Interrupt request bit Interrupt enable bit Interrupt disable flag I Interrupt request BRK instruction Reset Fig. 15 Interrupt control b7 b0 Interrupt source switch register (IFR : address 003916) INT3/serial I/O2 transmit interrupt switch bit (Note 1) 0 : INT3 interrupt 1 : Serial I/O2 transmit interrupt INT4/AD conversion interrupt switch bit 0 : INT4 interrupt 1 : A-D conversion interrupt Not used (return “0” when read) (Do not write “1” to these bits.) b7 b0 Interrupt edge selection register (INTEDGE : address 003A16) INT0 interrupt edge selection bit INT1 interrupt edge selection bit 0 : Falling edge active INT2 interrupt edge selection bit 1 : Rising edge active INT3 interrupt edge selection bit (Note 1) INT4 interrupt edge selection bit Not used (return “0” when read) 0 : Rising edge count CNTR0 pin edge switch bit 1 : Falling edge count CNTR1 pin edge switch bit (Note 1) b7 b0 Interrupt request register 1 (IREQ1 : address 003C16) b7 INT0 interrupt request bit INT1 interrupt request bit INT2 interrupt request bit Remote controller/counter overflow interrupt request bit Serial I/O1 interrupt request bit Timer 4 interrupt request bit (Note 2) Timer 5 interrupt request bit Timer 6 interrupt request bit Serial I/O2 receive interrupt request bit INT3/serial I/O2 transmit interrupt request bit (Note 2) INT4 interrupt request bit AD conversion interrupt request bit FLD blanking interrupt request bit FLD digit interrupt request bit Not used (returns “0” when read) Serial I/O automatic transfer interrupt request bit Timer X interrupt request bit Timer 1 interrupt request bit Timer 2 interrupt request bit Timer 3 interrupt request bit b7 b0 Interrupt control register 1 (ICON1 : address 003E16) INT0 interrupt enable bit INT1 interrupt enable bit INT2 interrupt enable bit Remote controller/counter overflow interrupt enable bit Serial I/O1 interrupt enable bit Serial I/O automatic transfer interrupt enable bit Timer X interrupt enable bit Timer 1 interrupt enable bit Timer 2 interrupt enable bit Timer 3 interrupt enable bit b0 Interrupt request register 2 (IREQ2 : address 003D16) 0 : No interrupt request issued 1 : Interrupt request issued b7 b0 Interrupt control register 2 (ICON2 : address 003F16) Timer 4 interrupt enable bit (Note 3) Timer 5 interrupt enable bit Timer 6 interrupt enable bit Serial I/O2 receive interrupt enable bit INT3/serial I/O2 transmit interrupt enable bit (Note 3) INT4 interrupt enable bit AD conversion interrupt enable bit FLD blanking interrupt enable bit FLD digit interrupt enable bit Not used (returns “0” when read) (Do not write “1” to this bit.) 0 : Interrupt disabled 1 : Interrupt enabled Notes 1: In the mask option type P, these bits are not available because CNTR1 function and INT3 function cannot be used. 2: In the mask option type P, if timer 4 interrupt whose count source is CNTR1 input and INT3 interrupt are selected, these bits do not become “1”. 3: In the mask option type P, timer 4 interrupt whose count source is CNTR1 input and INT3 interrupt are not available. Fig. 16 Structure of interrupt related registers 22 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER TIMERS 8-Bit Timer b7 b0 Timer 12 mode register (T12M: address 002816) The 38B4 group has six built-in timers : Timer 1, Timer 2, Timer 3, Timer 4, Timer 5, and Timer 6. Each timer has the 8-bit timer latch. All timers are down-counters. When the timer reaches “00 16”, an underflow occurs with the next count pulse. Then the contents of the timer latch is reloaded into the timer and the timer continues down-counting. When a timer underflows, the interrupt request bit corresponding to that timer is set to “1”. The count can be stopped by setting the stop bit of each timer to “1”. The internal system clock can be set to either the high-speed mode or low-speed mode with the CPU mode register. At the same time, timer internal count source is switched to either f(X IN) or f(XCIN). ●Timer 1, Timer 2 The count sources of timer 1 and timer 2 can be selected by setting the timer 12 mode register. A rectangular waveform of timer 1 underflow signal divided by 2 can be output from the P4 5/T1OUT pin. The active edge of the external clock CNTR 0 can be switched with the bit 6 of the interrupt edge selection register. At reset or when executing the STP instruction, all bits of the timer 12 mode register are cleared to “0”, timer 1 is set to “FF 16”, and timer 2 is set to “0116”. Timer 1 count stop bit 0 : Count operation 1 : Count stop Timer 2 count stop bit 0 : Count operation 1 : Count stop Timer 1 count source selection bits 00 : f(XIN)/8 or f(XCIN)/16 01 : f(XCIN) 10 : f(XIN)/16 or f(XCIN)/32 11 : f(XIN)/64 or f(XCIN)/128 Timer 2 count source selection bits 00 : Underflow of Timer 1 01 : f(XCIN) 10 : External count input CNTR0 11 : Not available Timer 1 output selection bit (P45) 0 : I/O port 1 : Timer 1 output Not used (returns “0” when read) (Do not write “1” to this bit.) b7 b0 Timer 34 mode register (T34M: address 002916) Timer 3 count stop bit 0 : Count operation 1 : Count stop Timer 4 count stop bit 0 : Count operation 1 : Count stop Timer 3 count source selection bits 00 : f(XIN)/8 or f(XCIN)/16 01 : Underflow of Timer 2 10 : f(XIN)/16 or f(XCIN)/32 11 : f(XIN)/64 or f(XCIN)/128 Timer 4 count source selection bits 00 : f(XIN)/8 or f(XCIN)/16 01 : Underflow of Timer 3 10 : External count input CNTR1 (Note) 11 : Not available Timer 3 output selection bit (P46) 0 : I/O port 1 : Timer 3 output Not used (returns “0” when read) (Do not write “1” to this bit.) ●Timer 3, Timer 4 The count sources of timer 3 and timer 4 can be selected by setting the timer 34 mode register. A rectangular waveform of timer 3 underflow signal divided by 2 can be output from the P4 6/T3OUT pin. The active edge of the external clock CNTR 1 (Note) can be switched with the bit 7 of the interrupt edge selection register. Note: In the mask option type P, CNTR 1 function cannot be used. ●Timer 5, Timer 6 The count sources of timer 5 and timer 6 can be selected by setting the timer 56 mode register. A rectangular waveform of timer 6 underflow signal divided by 2 can be output from the P4 4/PWM1 pin. (1) Timer 6 PWM 1 mode Timer 6 can output a PWM rectangular waveform with “H” duty cycle n/(n+m) from the P44/PWM1 pin by setting the timer 56 mode register (refer to Figure 19). The n is the value set in timer 6 latch (address 0025 16) and m is the value in the timer 6 PWM register (address 0027 16). If n is “0”, the PWM output is “L”, if m is “0”, the PWM output is “H” (n = 0 is prior than m = 0). In the PWM mode, interrupts occur at the rising edge of the PWM output. b7 b0 Timer 56 mode register (T56M: address 002A16) Timer 5 count stop bit 0 : Count operation 1 : Count stop Timer 6 count stop bit 0 : Count operation 1 : Count stop Timer 5 count source selection bit 0 : f(XIN)/8 or f(XCIN)/16 1 : Underflow of Timer 4 Timer 6 operation mode selection bit 0 : Timer mode 1 : PWM mode Timer 6 count source selection bits 00 : f(XIN)/8 or f(XCIN)/16 01 : Underflow of Timer 5 10 : Underflow of Timer 4 11 : Not available Timer 6 (PWM) output selection bit (P44) 0 : I/O port 1 : Timer 6 output Not used (returns “0” when read) (Do not write “1” to this bit.) Note: In the mask option type P, CNTR1 function cannot be used. Fig. 17 Structure of timer related register 23 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Data bus XCIN Timer 1 latch (8) 1/2 Timer 1 count source “1” Internal system clock selection bit 1/8 XIN “0” “01” selection bits Timer 1 (8) “00” 1/16 FF16 “10” RESET STP instruction Timer 1 interrupt request Timer 1 count stop bit 1/64 P45/T1OUT “11” P45 latch 1/2 Timer 1 output selection bit Timer 2 latch (8) “00” Timer 2 count source selection bits 0 116 Timer 2 (8) P45 direction register “10” P61/CNTR0/CNTR2 Timer 2 interrupt request “01” Timer 2 count stop bit Rising/Falling active edge switch Timer 3 latch (8) “01” “00” P46/T3OUT Timer 3 count source selection bits Timer 3 (8) Timer 3 interrupt request Timer 3 count stop bit “10” P46 latch “11” 1/2 Timer 3 output selection bit Timer 4 latch (8) “01” P46 direction register Timer 4 count source selection bits Timer 4 (8) “00” P60/CNTR1 (Note) Timer 4 interrupt request Timer 4 count stop bit “10” Rising/Falling active edge switch Timer 5 latch (8) “1” Timer 5 count source selection bit Timer 5 (8) “0” Timer 5 interrupt request Timer 5 count stop bit Timer 6 latch (8) “01” Timer 6 count source selection bits Timer 6 (8) “00” Timer 6 interrupt request Timer 6 count stop bit “10” Timer 6 PWM register (8) P44/PWM1 P44 latch “1” “0” PWM 1/2 Timer 6 output selection bit Timer 6 operation mode selection bit P44 direction register Fig. 18 Block diagram of timer 24 Note: In the mask option type P, CNTR1 function cannot be used. MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ts Timer 6 count source Timer 6 PWM mode n ✕ ts m ✕ ts (n+m) ✕ ts Timer 6 interrupt request Timer 6 interrupt request Note: PWM waveform (duty : n/(n + m) and period: (n + m) ✕ ts) is output. n : setting value of Timer 6 m: setting value of Timer 6 PWM register ts: period of Timer 6 count source Fig. 19 Timing chart of timer 6 PWM1 mode 25 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER 16-Bit Timer ■ Note Timer X is a 16-bit timer that can be selected in one of four modes by the Timer X mode registers 1, 2 and can be controlled the timer X write and the real time port by setting the timer X mode registers. Read and write operation on 16-bit timer must be performed for both high- and low-order bytes. When reading a 16-bit timer, read from the high-order byte first. When writing to 16-bit timer, write to the loworder byte first. The 16-bit timer cannot perform the correct operation when reading during write operation, or when writing during read operation. •Timer X Write Control If the timer X write control bit is “0”, when the value is written in the address of timer X, the value is loaded in the timer X and the latch at the same time. If the timer X write control bit is “1”, when the value is written in the address of timer X, the value is loaded only in the latch. The value in the latch is loaded in timer X after timer X underflows. When the value is written in latch only, unexpected value may be set in the high-order counter if the writing in high-order latch and the underflow of timer X are performed at the same timing. ●Timer X Timer X is a down-counter. When the timer reaches “000016”, an underflow occurs with the next count pulse. Then the contents of the timer latch is reloaded into the timer and the timer continues downcounting. When a timer underflows, the interrupt request bit corresponding to that timer is set to “1”. (1) Timer mode A count source can be selected by setting the Timer X count source selection bits (bits 1 and 2) of the Timer X mode register 1. (2) Pulse output mode Each time the timer underflows, a signal output from the CNTR2 pin is inverted. Except for this, the operation in pulse output mode is the same as in timer mode. When using a timer in this mode, set the port shared with the CNTR2 pin to output. (3) Event counter mode The timer counts signals input through the CNTR2 pin. Except for this, the operation in event counter mode is the same as in timer mode. When using a timer in this mode, set the port shared with the CNTR2 pin to input. (4) Pulse width measurement mode A count source can be selected by setting the Timer X count source selection bits (bits 1 and 2) of the Timer X mode register 1. When CNTR2 active edge switch bit is “0”, the timer counts while the input signal of the CNTR2 pin is at “H”. When it is “1”, the timer counts while the input signal of the CNTR2 pin is at “L”. When using a timer in this mode, set the port shared with the CNTR2 pin to input. 26 •Real Time Port Control While the real time port function is valid, data for the real time port are output from ports P85 and P86 each time the timer X underflows. (However, if the real time port control bit is changed from “0” to “1”, data are output without the timer X.) When the data for the real time port is changed while the real time port function is valid, the changed data are output at the next underflow of timer X. Before using this function, set the corresponding port direction registers to output mode. MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Real time port control bit “1” Data bus Q D P85 P85 data for real time port “0 ” Latch P85 direction register P85 latch Real time port control bit “1” Q D Real time port control bit (P85) “0” “0 ” Latch P86 direction register P86 latch Real time port control bit (P86) “0” “1 ” Timer X mode register write signal P86 data for real time port P86 XCIN 1/2 “1 ” Timer X mode register write signal Internal system clock selection bit 1/2 XIN Count source selection bit 1/8 “0 ” 1/64 Timer X stop Timer X write control bit control bit Timer X operating mode bits CNTR2 active h o r der) (8) T i m e r X l a t c h ( h i g Timer X latch (low-order) (8) edge switch bit “00”,“01”,“11” “0 ” P61/CNTR0/CNTR2 Timer X (low-order) (8) Timer X (high-order) (8) “10” “1 ” Pulse width measurement mode Pulse output mode CNTR2 active edge switch bit “0” S Q T “1 ” Q P61 direction register P61 latch Divider “1 ” Timer X interrupt request Pulse output mode CNTR0 Fig. 20 Block diagram of timer X b7 b7 b0 b0 Timer X mode register 1 (TXM1 : address 002E16) Timer X mode register 2 (TXM2 : address 002F16) Timer X write control bit 0 : Write data to both timer latch and timer 1 : Write data to timer latch only Timer X count source selection bits b2 b1 0 0 : f(XIN)/2 or f(XCIN)/4 0 1 : f(XIN)/8 or f(XCIN)/16 1 0 : f(XIN)/64 or f(XCIN)/128 1 1 : Not available Not used (returns “0” when read) Timer X operating mode bits b5 b4 0 0 : Timer mode 0 1 : Pulse output mode 1 0 : Event counter mode 1 1 : Pulse width measurement mode CNTR2 active edge switch bit 0 : • Event counter mode ; counts rising edges • Pulse output mode ; output starts with “H” level • Pulse width measurement mode ; measures “H” periods 1 : • Event counter mode ; counts falling edges • Pulse output mode ; output starts with “L” level • Pulse width measurement mode ; measures “L” periods Timer X stop control bit 0 : Count operating 1 : Count stop Real time port control bit (P85) 0 : Real time port function is invalid 1 : Real time port function is valid Real time port control bit (P86) 0 : Real time port function is invalid 1 : Real time port function is valid P85 data for real time port P86 data for real time port Not used (returns “0” when read) Fig. 21 Structure of timer X related registers 27 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER SERIAL I/O Serial I/O1 FLD automatic display RAM). The P62/SRDY1 /AN8, P64/INT4/S BUSY1/AN10, and P65/S STB1/AN11 pins each have a handshake I/O signal function and can select either “H” active or “L” active for active logic. Serial I/O1 is used as the clock synchronous serial I/O and has an ordinary mode and an automatic transfer mode. In the automatic transfer mode, serial transfer is performed through the serial I/O automatic transfer RAM which has up to 256 bytes (addresses 0F0016 to 0FFF16 : addresses 0F6016 to 0FFF16 are also used as Main address bus Local address bus Serial I/O automatic transfer RAM (0F0016—0FFF16) Main Local data bus data bus Serial I/O1 automatic transfer data pointer Address decoder Serial I/O1 automatic transfer controller XCIN 1/2 Serial I/O1 control register 3 Internal system clock selection bit “1 ” “0 ” P65 latch “0 ” P65/SSTB1 Divider XIN (P65/SSTB1 pin control bit) “1 ” P62/SRDY1•P64/SBUSY1 pin control bit P64 latch “0 ” Serial I/O1 synchronous clock selection bit “0” P64/SBUSY1 “1 ” P62/SRDY1•P64/SBUSY1 P62 latch pin control bit 1/4 1/8 1/16 1/32 1/64 1/128 1/256 Internal synchronous clock selection bits Synchronous circuit “1” SCLK1 “0 ” P62/SRDY1 “1 ” Serial I/O1 clock pin selection bit “0 ” “1 ” Serial transfer status flag P52 latch “0 ” P52/SCLK11 “0 ” “1 ” “1 ” Serial I/O1 counter “1 ” P53/SCLK12 Serial I/O1 clock pin selection bits “0 ” P53 latch “0 ” P51/SOUT1 P51 latch “1” Serial transfer selection bits P50/SIN1 Fig. 22 Block diagram of serial I/O1 28 Serial I/O1 register (8) Serial I/O1 interrupt request MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 Serial I/O1 control register 1 (SIO1CON1 (SC11):address 001916) Serial transfer selection bits 00: Serial I/O disabled (pins P62,P64,P65,and P50—P53 are I/O ports) 01: 8-bit serial I/O 10: Not available 11: Automatic transfer serial I/O (8-bits) Serial I/O1 synchronous clock selection bits (P65/SSTB1 pin control bits) 00: Internal synchronous clock (P65 pin is an I/O port.) 01: External synchronous clock (P65 pin is an I/O port.) 10: Internal synchronous clock (P65 pin is an SSTB1 output.) 11: Internal synchronous clock (P65 pin is an SSTB1 output.) Serial I/O initialization bit 0: Serial I/O initialization 1: Serial I/O enabled Transfer mode selection bit 0: Full duplex (transmit and receive) mode (P50 pin is an SIN1 input.) 1: Transmit-only mode (P50 pin is an I/O port.) Transfer direction selection bit 0: LSB first 1: MSB first Serial I/O1 clock pin selection bit 0:SCLK11 (P53/SCLK12 pin is an I/O port.) 1:SCLK12 (P52/SCLK11 pin is an I/O port.) b7 b0 Serial I/O1 control register 2 (SIO1CON2 (SC12): address 001A16) P62/SRDY1 • P64/SBUSY1 pin control bits 0000: Pins P62 and P64 are I/O ports 0001: Not used 0010: P62 pin is an SRDY1 output, P64 pin is an I/O port. 0011: P62 pin is an SRDY1 output, P64 pin is an I/O port. 0100: P62 pin is an I/O port, P64 pin is an SBUSY1 input. 0101: P62 pin is an I/O port, P64 pin is an SBUSY1 input. 0110: P62 pin is an I/O port, P64 pin is an SBUSY1 output. 0111: P62 pin is an I/O port, P64 pin is an SBUSY1 output. 1000: P62 pin is an SRDY1 input, P64 pin is an SBUSY1 output. 1001: P62 pin is an SRDY1 input, P64 pin is an SBUSY1 output. 1010: P62 pin is an SRDY1 input, P64 pin is an SBUSY1 output. 1011: P62 pin is an SRDY1 input, P64 pin is an SBUSY1 output. 1100: P62 pin is an SRDY1 output, P64 pin is an SBUSY1 input. 1101: P62 pin is an SRDY1 output, P64 pin is an SBUSY1 input. 1110: P62 pin is an SRDY1 output, P64 pin is an SBUSY1 input. 1111: P62 pin is an SRDY1 output, P64 pin is an SBUSY1 input. SBUSY1 output • SSTB1 output function selection bit (Valid in automatic transfer mode) 0: Functions as each 1-byte signal 1: Functions as signal for all transfer data Serial transfer status flag 0: Serial transfer completion 1: Serial transferring SOUT1 pin control bit (at no-transfer serial data) 0: Output active 1: Output high-impedance P51/SOUT1 P-channel output disable bit 0: CMOS 3-state (P-channel output is valid.) 1: N-channel open-drain (P-channel output is invalid.) Fig. 23 Structure of serial I/O1 control registers 1, 2 29 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Serial I/O1 operation Either the internal synchronous clock or external synchronous clock can be selected by the serial I/O1 synchronous clock selection bits (b2 and b3 of address 001916 ) of serial I/O1 control register 1 as synchronous clock for serial transfer. The internal synchronous clock has a built-in dedicated divider where 7 different clocks are selected by the internal synchronous clock selection bits (b5, b6 and b7 of address 001C16) of serial I/O1 control register 3. The P62/SRDY1 /AN8, P64/INT4/SBUSY1/AN 10, and P65/S STB1/AN11 pins each select either I/O port or handshake I/O signal by the serial I/O1 synchronous clock selection bits (b2 and b3 of address 001916) of serial I/O1 control register 1 as well as the P62/SRDY1 • P64/SBUSY1 pin control bits (b0 to b3 of address 001A16 ) of serial I/O1 control register 2. For the SOUT1 being used as an output pin, either CMOS output or N-channel open-drain output is selected by the P5 1/S OUT1 P-channel output disable bit (b7 of address 001A16) of serial I/O1 control register 2. Either output active or high-impedance can be selected as a SOUT1 pin state at serial non-transfer by the SOUT1 pin control bit (b6 of address 001A16 ) of serial I/O1 control register 2. However, when the external synchronous clock is selected, perform the following setup to put the SOUT1 pin into a high-impedance state. b7 When the SCLK1 input is “H” after completion of transfer, set the SOUT1 pin control bit to “1”. When the SCLK1 input goes to “L” after the start of the next serial transfer, the SOUT1 pin control bit is automatically reset to “0” and put into an output active state. Regardless of whether the internal synchronous clock or external synchronous clock is selected, the full duplex mode and the transmit-only mode are available for serial transfer, one of which is selected by the transfer mode selection bit (b5 of address 001916 ) of serial I/O1 control register 1. Either LSB first or MSB first is selected for the I/O sequence of the serial transfer bit strings by the transfer direction selection bit (b6 of address 001916) of serial I/O1 control register 1. When using serial I/O1, first select either 8-bit serial I/O or automatic transfer serial I/O by the serial transfer selection bits (b0 and b1 of address 001916) of serial I/O1 control register 1, after completion of the above bit setup. Next, set the serial I/O initialization bit (b4 of address 001916) of serial I/O1 control register 1 to “1” (Serial I/O enable) . When stopping serial transfer while data is being transferred, regardless of whether the internal or external synchronous clock is selected, reset the serial I/O initialization bit (b4) to “0”. b0 Serial I/O1 control register 3 (SIO1CON3 (SC13): address 001C16) Automatic transfer interval set bits 00000: 2 cycles of transfer clocks 00001: 3 cycles of transfer clocks : 11110: 32 cycles of transfer clocks 11111: 33 cycles of transfer clocks Data is written to a latch and read from a decrement counter. Internal synchronous clock selection bits 000: f(XIN)/4 or f(XCIN)/8 001: f(XIN)/8 or f(XCIN)/16 010: f(XIN)/16 or f(XCIN)/32 011: f(XIN)/32 or f(XCIN)/64 100: f(XIN)/64 or f(XCIN)/128 101: f(XIN)/128 or f(XCIN)/256 110: f(XIN)/256 or f(XCIN)/512 Fig. 24 Structure of serial I/O1 control register 3 30 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) 8-bit serial I/O mode Address 001B16 is assigned to the serial I/O1 register. When the internal synchronous clock is selected, a serial transfer of the 8-bit serial I/O is started by a write signal to the serial I/O1 register (address 001B16). The serial transfer status flag (b5 of address 001A16) of serial I/O1 control register 2 indicates the shift register status of serial I/O1, and is set to “1” by writing into the serial I/O1 register, which becomes a transfer start trigger and reset to “0” after completion of 8bit transfer. At the same time, a serial I/O1 interrupt request occurs. When the external synchronous clock is selected, the contents of the serial I/O1 register are continuously shifted while transfer clocks are input to SCLK1. Therefore, the clock needs to be controlled externally. (2) Automatic transfer serial I/O mode The serial I/O1 automatic transfer controller controls the write and read operations of the serial I/O1 register, so the function of address 001B16 is used as a transfer counter (1-byte units). When performing serial transfer through the serial I/O automatic transfer RAM (addresses 0F0016 to 0FFF16 ), it is necessary to set the serial I/O1 automatic transfer data pointer (address 001816) beforehand. Input the low-order 8 bits of the first data store address to be serially transferred to the automatic transfer data pointer set bits. When the internal synchronous clock is selected, the transfer interval for each 1-byte data can be set by the automatic transfer interval set bits (b0 to b4 of address 001C16) of serial I/O1 control register 3 in the following cases: 1. When using no handshake signal 2. When using the SRDY1 output, SBUSY1 output, and SSTB1 output of the handshake signal independently 3. When using a combination of SRDY1 output and SSTB1 output or a combination of SBUSY1 output and SSTB1 output of the handshake signal It is possible to select one of 32 different values, namely 2 to 33 cycles of the transfer clock, as a setting value. When using the SBUSY1 output and selecting the SBUSY1 output • SSTB1 output function selection bit (b4 of address 001A16) of serial I/O1 control register 2 as the signal for all transfer data, provided b7 that the automatic transfer interval setting is valid, a transfer interval is placed before the start of transmission/reception of the first data and after the end of transmission/reception of the last data. For SSTB1 output, regardless of the contents of the SBUSY1 output • SSTB1 output function selection bit (b4), the transfer interval for each 1-byte data is longer than the set value by 2 cycles. Furthermore, when using a combination of SBUSY1 output and SSTB1 output as a signal for all transfer data, the transfer interval after the end of transmission/reception of the last data is longer than the set value by 2 cycles. When the external synchronous clock is selected, automatic transfer interval setting is disabled. After completion of the above bit setup, if the internal synchronous clock is selected, automatic serial transfer is started by writing the value of “number of transfer bytes - 1” into the transfer counter (address 001B16 ). When the external synchronous clock is selected, write the value of “number of transfer bytes - 1” into the transfer counter and input an internal system clock interval of 5 cycles or more. After that, input transfer clock to SCLK1. As a transfer interval for each 1-byte data transfer, input an internal system clock interval of 5 cycles or more from the clock rise time of the last bit. Regardless of whether the internal or external synchronous clock is selected, the automatic transfer data pointer and the transfer counter are decremented after each 1-byte data is received and then written into the automatic transfer RAM. The serial transfer status flag (b5 of address 001A16 ) is set to “1” by writing data into the transfer counter. Writing data becomes a transfer start trigger, and the serial transfer status flag is reset to “0” after the last data is written into the automatic transfer RAM. At the same time, a serial I/O1 interrupt request occurs. The values written in the automatic transfer data pointer set bits (b0 to b7 of address 001816 ) and the automatic transfer interval set bits (b0 to b4 of address 001C 16) are held in the latch. When data is written into the transfer counter, the values latched in the automatic transfer data pointer set bits (b0 to b7) and the automatic transfer interval set bits (b0 to b4) are transferred to the decrement counter. b0 Serial I/O1 automatic transfer data pointer (SIO1DP: address 001816) Automatic transfer data pointer set bits Specify the low-order 8 bits of the first data store address on the serial I/O automatic transfer RAM. Data is written into the latch and read from the decrement counter. Fig. 25 Structure of serial I/O1 automatic transfer data pointer 31 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Automatic transfer RAM FFF16 Automatic transfer data pointer 5216 F5216 F5116 F5016 F4F16 F4E16 Transfer counter 0416 F0016 SIN1 SOUT1 Serial I/O1 register Fig. 26 Automatic transfer serial I/O operation 32 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Handshake signal 1. SSTB1 output signal The SSTB1 output is a signal to inform an end of transmission/reception to the serial transfer destination. The SSTB1 output signal can be used only when the internal synchronous clock is selected. In the initial status, namely, in the status in which the serial I/O initialization bit (b4) is reset to “0”, the SSTB1 output goes to “L”, or the SSTB1 output goes to “H”. At the end of transmit/receive operation, when the data of the serial I/O1 register is all output from SOUT1 , pulses are output in the period of 1 cycle of the transfer clock so as to cause the SSTB1 output to go “H” or the SSTB1 output to go “L.” After that, each pulse is returned to the initial status in which SSTB1 output goes to “L” or the SSTB1 output goes to “H”. Furthermore, after 1 cycle, the serial transfer status flag (b5) is reset to “0”. In the automatic transfer serial I/O mode, whether the SSTB1 output is to be active at an end of each 1-byte data or after completion of transfer of all data can be selected by the SBUSY1 output • SSTB1 output function selection bit (b4 of address 001A16) of serial I/O1 control register 2. SSTB1 Serial transfer status flag SCLK1 SBUSY1 SCLK1 SOUT1 Fig. 28 SBUSY1 input operation (internal synchronous clock) When the external synchronous clock is selected, input an “H” level signal into the SBUSY1 input and an “L” level signal into the SBUSY1 input in the initial status in which transfer is stopped. At this time, the transfer clocks to be input in SCLK1 become invalid. During serial transfer, the transfer clocks to be input in SCLK1 become valid, enabling a transmit/receive operation, while an “L” level signal is input into the S BUSY1 input and an “H” level signal is input into the SBUSY1 input. When changing the input values in the SBUSY1 input and the SBUSY1 input at these operations, change them when the SCLK1 input is in a high state. When the high impedance of the SOUT1 output is selected by the SOUT1 pin control bit (b6), the SOUT1 output becomes active, enabling serial transfer by inputting a transfer clock to SCLK1, while an “L” level signal is input into the S BUSY1 input and an “H” level signal is input into the SBUSY1 input. SOUT1 SBUSY1 Fig. 27 S STB1 output operation 2. SBUSY1 input signal The SBUSY1 input is a signal which receives a request for a stop of transmission/reception from the serial transfer destination. When the internal synchronous clock is selected, input an “H” level signal into the SBUSY1 input and an “L” level signal into the SBUSY1 input in the initial status in which transfer is stopped. When starting a transmit/receive operation, input an “L” level signal into the SBUSY1 input and an “H” level signal into the SBUSY1 input in the period of 1.5 cycles or more of the transfer clock. Then, transfer clocks are output from the SCLK1 output. When an “H” level signal is input into the SBUSY1 input and an “L” level signal into the SBUSY1 input after a transmit/receive operation is started, this transmit/receive operation are not stopped immediately and the transfer clocks from the SCLK1 output is not stopped until the specified number of bits are transmitted and received. The handshake unit of the 8-bit serial I/O is 8 bits and that of the automatic transfer serial I/O is 8 bits. SCLK1 Invalid SOUT1 (Output high-impedance) Fig. 29 SBUSY1 input operation (external synchronous clock) 3. S BUSY1 output signal The S BUSY1 output is a signal which requests a stop of transmission/reception to the serial transfer destination. In the automatic transfer serial I/O mode, regardless of the internal or external synchronous clock, whether the SBUSY1 output is to be active at transfer of each 1-byte data or during transfer of all data can be selected by the SBUSY1 output • S STB1 output function selection bit (b4). In the initial status, the status in which the serial I/O initialization bit (b4) is reset to “0”, the SBUSY1 output goes to “H” and the S BUSY1 output goes to “L”. 33 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER When the internal synchronous clock is selected, in the 8-bit serial I/O mode and the automatic transfer serial I/O mode (SBUSY1 output function outputs in 1-byte units), the S BUSY1 output goes to “L” and the SBUSY1 output goes to “H” before 0.5 cycle (transfer clock) of the timing at which the transfer clock from the SCLK1 output goes to “L” at a start of transmit/receive operation. In the automatic transfer serial I/O mode (the SBUSY1 output function outputs all transfer data), the SBUSY1 output goes to “L” and the SBUSY1 output goes to “H” when the first transmit data is written into the serial I/O1 register (address 001B16). When the external synchronous clock is selected, the SBUSY1 output goes to “L” and the SBUSY1 output goes to “H” when transmit data is written into the serial I/O1 register to start a transmit operation, regardless of the serial I/O transfer mode. At termination of transmit/receive operation, the SBUSY1 output returns to “H” and the SBUSY1 output returns to “L”, the initial status, when the serial transfer status flag is set to “0”, regardless of whether the internal or external synchronous clock is selected. Furthermore, in the automatic transfer serial I/O mode (SBUSY1 output function outputs in 1-byte units), the SBUSY1 output goes to “H” and the SBUSY1 output goes to “L” each time 1-byte of receive data is written into the automatic transfer RAM. SBUSY1 SBUSY1 Serial transfer status flag Serial transfer status flag SCLK1 SCLK1 SOUT1 Write to Serial I/O1 register Fig. 30 SBUSY1 output operation (internal synchronous clock, 8-bits serial I/O) Fig. 31 SBUSY1 output operation (external synchronous clock, 8-bits serial I/O) Automatic transfer interval SCL K1 Serial I/O1 register →Automatic transfer RAM Automatic transfer RAM →Serial I/O1 register SBUSY1 Serial transfer status flag SOUT1 Fig. 32 SBUSY1 output operation in automatic transfer serial I/O mode (internal synchronous clock, SBUSY1 output function outputs each 1-byte) 34 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER 4. SRDY1 output signal The SRDY1 output is a transmit/receive enable signal which informs the serial transfer destination that transmit/receive is ready. In the initial status, when the serial I/O initialization bit (b4) is reset to “0”, the SRDY1 output goes to “L” and the SRDY1 output goes to “H”. After transmitted data is stored in the serial I/O1 register (address 001B16) and a transmit/receive operation becomes ready, the SRDY1 output goes to “H” and the SRDY1 output goes to “L”. When a transmit/ receive operation is started and the transfer clock goes to “L”, the SRDY1 output goes to “L” and the SRDY1 output goes to “H”. 5. SRDY1 input signal The SRDY1 input signal becomes valid only when the SRDY1 input and the SBUSY1 output are used. The SRDY1 input is a signal for receiving a transmit/receive ready completion signal from the serial transfer destination. When the internal synchronous clock is selected, input a low level signal into the SRDY1 input and a high level signal into the SRDY1 input in the initial status in which the transfer is stopped. When an “H” level signal is input into the SRDY1 input and an “L” level signal is input into the SRDY1 input for a period of 1.5 cycles or more of transfer clock, transfer clocks are output from the SCLK1 output and a transmit/receive operation is started. After the transmit/receive operation is started and an “L” level signal is input into the SRDY1 input and an “H” level signal into the SRDY1 input, this operation cannot be immediately stopped. After the specified number of bits are transmitted and received, the transfer clocks from the SCLK1 output is stopped. The handshake unit of the 8-bit serial I/O and that of the automatic transfer serial I/O are of 8 bits. When the external synchronous clock is selected, the SRDY1 input becomes one of the triggers to output the SBUSY1 signal. To start a transmit/receive operation (SBUSY1 output: “L”, S BUSY1 output: “H”), input an “H” level signal into the SRDY1 input and an “L” level signal into the SRDY1 input, and also write transmit data into the serial I/O1 register. SRDY1 SCLK1 Write to serial I/O1 register Fig. 33 SRDY1 output operation SRDY1 SCLK1 SOUT1 Fig. 34 SRDY1 input operation (internal synchronous clock) 35 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER A: SCLK1 SCLK1 SRDY1 SRDY1 SBUSY1 Write to serial I/O1 register SRDY1 SBUSY1 SBUSY1 A: Internal synchronous clock selection SCLK1 B: External synchronous clock selection B: Write to serial I/O1 register Fig. 35 Handshake operation at serial I/O1 mutual connecting (1) A: SCLK1 SCLK1 SRDY1 SRDY1 SBUSY1 Write to serial I/O1 register SRDY1 SBUSY1 SBUSY1 A: Internal synchronous clock selection External synchronous clock selection Fig. 36 Handshake operation at serial I/O1 mutual connecting (2) 36 SCLK1 B: B: Write to serial I/O1 register MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Serial I/O2 ister (address 001D16) to “1”. For clock synchronous serial I/O, the transmitter and the receiver must use the same clock for serial I/O2 operation. If an internal clock is used, transmit/receive is started by a write signal to the serial I/O2 transmit/receive buffer register (TB/ RB) (address 001F 16). When P5 7 (SCLK22) is selected as a clock I/O pin, SRDY2 output function is invalid, and P5 6 (S CLK21) is used as an I/O port. Serial I/O2 can be used as either clock synchronous or asynchronous (UART) serial I/O. A dedicated timer (baud rate generator) is also provided for baud rate generation during serial I/O2 operation. (1) Clock synchronous serial I/O mode The clock synchronous serial I/O mode can be selected by setting the serial I/O2 mode selection bit (b6) of the serial I/O2 control reg- Data bus Serial I/O2 control register Address 001F16 Receive buffer register Shift clock “0 ” P56/SCLK21 P57/SRDY2/SCLK22 XIN Serial I/O2 clock I/O pin selection bit P57/SRDY2/SCLK22 P55/TXD Clock control circuit “1 ” “0 ” Internal system clock selection bit Serial I/O2 synchronous clock selection bit “0 ” “1 ” XCIN Receive interrupt request (RI) Receive shift register P54/RXD Address 001D16 Receive buffer full flag (RBF) “1 ” 1/2 F/F BRG count source selection bit Division ratio 1/(n+1) Baud rate generator BRG clock Address 001616 1/4 switch bit Falling edge detector Serial I/O2 clock I/O pin selection bit 1/4 Clock control circuit Shift clock Transmit shift register Transmit buffer register Address 001F16 Transmit shift register shift completion flag (TSC) Transmit interrupt source selection bit Transmit interrupt request (TI) Transmit buffer empty flag (TBE) Serial I/O2 status register Address 001E16 Data bus Fig. 37 Block diagram of clock synchronous serial I/O2 Transmit/Receive shift clock (1/2—1/2048 of internal clock or external clock) Serial I/O2 output TxD D0 D1 D2 D3 D4 D5 D6 D7 Serial I/O2 input RxD D0 D1 D2 D3 D4 D5 D6 D7 Receive enable signal SRDY2 Write-in signal to serial I/O2 transmit/receive buffer register (address 001F16) TBE = 0 TBE = 1 TSC = 0 RBF = 1 TSC = 1 Overrun error (OE) detection Notes 1 : The transmit interrupt (TI) can be selected to occur either when the transmit buffer has emptied (TBE=1) or after the transmit shift operation has ended (TSC=1), by setting transmit interrupt source selection bit (TIC) of the serial I/O2 control register. 2 : If data is written to the transmit buffer register when TSC=0, the transmit clock is generated continuously and serial data is output continuously from the TxD pin. 3 : The receive interrupt (RI) is set when the receive buffer full flag (RBF) becomes “1”. Fig. 38 Operation of clock synchronous serial I/O2 function 37 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (2) Asynchronous serial I/O (UART) mode The asynchronous serial I/O (UART) mode can be selected by clearing the serial I/O2 mode selection bit (b6) of the serial I/O2 control register (address 001D16 ) to “0”. Eight serial data transfer formats can be selected and the transfer formats used by the transmitter and receiver must be identical. The transmit and receive shift registers each have a buffer (the two buffers have the same address in memory). Since the shift register cannot be written to or read from directly, transmit data is written to the transmit buffer, and receive data is read from the receive buffer. The transmit buffer can also hold the next data to be transmitted, and the receive buffer can receive 2-byte data continuously. Data bus Serial I/O2 control register Address 001D16 Address 001F16 P54/RXD Receive buffer full flag (RBF) Receive interrupt request (RI) Receive buffer register OE Character length selection bit 7 bit ST detector Receive shift register 1/16 8 bit PE FE P56/SCLK21 P57/SRDY2/SCLK22 XIN “0 ” Clock control circuit Serial I/O2 synchronous clock selection bit Serial I/O2 clock I/O pin selection bit UART control register Address 001716 “1 ” Internal system clock selection bit “0 ” “1 ” XCIN SP detector 1/2 BRG count source selection bit Division ratio 1/(n+1) Baud rate generator Address 001616 “1 ” BRG clock switch bit 1/4 ST/SP/PA generator Transmit shift register shift completion flag (TSC) 1/16 Transmit shift register P55/TXD Transmit interrupt source selection bit Transmit interrupt request (TI) Character length selection bit Transmit buffer empty flag (TBE) Address 001E16 Serial I/O2 status register Transmit buffer register Address 001F16 Data bus Fig. 39 Block diagram of UART serial I/O2 Transmit or receive clock Write-in signal to transmit buffer register TBE=0 TSC=0 TBE=1 Serial I/O2 output TXD TBE=0 TBE=1 ST D0 D1 SP TSC=1* ST D0 D1 Read-out signal from receive buffer register SP * Generated at 2nd bit in 2-stop bit mode 1 start bit 7 or 8 data bit 1 or 0 parity bit 1 or 2 stop bit RBF=0 RBF=1 Serial I/O2 input RXD ST Fig. 40 Operation of UART serial I/O2 function 38 D0 D1 SP RBF=1 ST D0 D1 SP MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [Serial I/O2 Control Register] SIO2CON (001D16) The serial I/O2 control register contains eight control bits for serial I/O2 functions. [UART Control Register] UARTCON (001716) This is a 7 bit register containing four control bits, which are valid when UART is selected, two control bits, which are valid when using serial I/O2, and one control bit, which is always valid. Data format of serial data receive/transfer and the output structure of the P5 5/TxD pin, etc. are set by this register. [Serial I/O2 Status Register] SIO2STS (001E16) The read-only serial I/O2 status register consists of seven flags (b0 to b6) which indicate the operating status of the serial I/O2 function and various errors. Three of the flags (b4 to b6) are only valid in the UART mode. The receive buffer full flag (b1) is cleared to “0” when the receive buffer is read. The error detection is performed at the same time data is transferred from the receive shift register to the receive buffer register, and the receive buffer full flag is set. A writing to the serial I/O2 status regis- b7 b0 Serial I/O2 status register (SIO2STS : address 001E16) ter clears error flags OE, PE, FE, and SE (b3 to b6, respectively). Writing “0” to the serial I/O2 enable bit (SIOE : b7 of the serial I/O2 control register) also clears all the status flags, including the error flags. All bits of the serial I/O2 status register are initialized to “0” at reset, but if the transmit enable bit (b4) of the serial I/O2 control register has been set to “1”, the transmit shift register shift completion flag (b2) and the transmit buffer empty flag (b0) become “1”. [Serial I/O2 Transmit Buffer Register/Receive Buffer Register] TB/RB (001F16) The transmit buffer and the receive buffer are located in the same address. The transmit buffer is write-only and the receive buffer is read-only. If a character bit length is 7 bits, the MSB of data stored in the receive buffer is “0”. [Baud Rate Generator] BRG (001616) The baud rate generator determines the baud rate for serial transfer. With the 8-bit counter having a reload register, the baud rate generator divides the frequency of the count source by 1/(n+1), where n is the value written to the baud rate generator. b7 Transmit buffer empty flag (TBE) 0: Buffer full 1: Buffer empty Receive buffer full flag (RBF) 0: Buffer empty 1: Buffer full Transmit shift register shift completion flag (TSC) 0: Transmit shift in progress 1: Transmit shift completed Overrun error flag (OE) 0: No error 1: Overrun error Parity error flag (PE) 0: No error 1: Parity error Framing error flag (FE) 0: No error 1: Framing error Summing error flag (SE) 0: (OE) U (PE) U (FE)=0 1: (OE) U (PE) U (FE)=1 Not used (returns “1” when read) b7 b0 UART control register (UARTCON : address 001716) b0 Serial I/O2 control register (SIO2CON : address 001D16) BRG count source selection bit (CSS) 0: f(XIN) or f(XCIN)/2 or f(XCIN) 1: f(XIN)/4 or f(XCIN)/8 or f(XCIN)/4 Serial I/O2 synchronous clock selection bit (SCS) 0: BRG/ 4 (when clock synchronous serial I/O is selected) BRG/16 (UART is selected) 1: External clock input (when clock synchronous serial I/O is selected) External clock input/16 (UART is selected) SRDY2 output enable bit (SRDY) 0: P57 pin operates as ordinary I/O pin 1: P57 pin operates as SRDY2 output pin Transmit interrupt source selection bit (TIC) 0: Interrupt when transmit buffer has emptied 1: Interrupt when transmit shift operation is completed Transmit enable bit (TE) 0: Transmit disabled 1: Transmit enabled Receive enable bit (RE) 0: Receive disabled 1: Receive enabled Serial I/O2 mode selection bit (SIOM) 0: Asynchronous serial I/O (UART) 1: Clock synchronous serial I/O Serial I/O2 enable bit (SIOE) 0: Serial I/O2 disabled (pins P54 to P57 operate as ordinary I/O pins) 1: Serial I/O2 enabled (pins P54 to P57 operate as serial I/O pins) Character length selection bit (CHAS) 0: 8 bits 1: 7 bits Parity enable bit (PARE) 0: Parity checking disabled 1: Parity checking enabled Parity selection bit (PARS) 0: Even parity 1: Odd parity Stop bit length selection bit (STPS) 0: 1 stop bit 1: 2 stop bits P55/TXD P-channel output disable bit (POFF) 0: CMOS output (in output mode) 1: N-channel open-drain output (in output mode) BRG clock switch bit 0: XIN or XCIN/2 (depends on internal system clock) 1: XCIN Serial I/O2 clock I/O pin selection bit 0: SCLK21 (P57/SCLK22 pin is used as I/O port or SRDY2 output pin.) 1: SCLK22 (P56/SCLK21 pin is used as I/O port.) Not used (return “1” when read) Fig. 41 Structure of serial I/O2 related register 39 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FLD CONTROLLER The 38B4 group has fluorescent display (FLD) drive and control circuits. The FLD controller consists of the following components: •40 pins for FLD control pins •FLDC mode register •FLD data pointer •FLD data pointer reload register •Tdisp time set register •Toff1 time set register •Toff2 time set register •Port P0FLD/port switch register •Port P2FLD/port switch register •Port P8FLD/port switch register •Port P8 FLD output control register •FLD automatic display RAM (max. 160 bytes) A gradation display mode can be used for bright/dark display as a display function. Main data bus Main address bus FLD automatic display RAM 0F6016 Local address bus 0FFF16 Local data bus FLD/P P20/FLD0 FLD/P P21/FLD1 FLD/P P22/FLD2 8 FLD/P P23/FLD3 FLD/P P24/FLD4 FLD/P P25/FLD5 FLD/P P26/FLD6 FLD/P P27/FLD7 000416 0EFA16 FLD/P FLD/P FLD/P FLD/P FLD/P FLD/P FLD/P FLD/P 0EF916 P00/FLD8 P01/FLD9 P02/FLD10 8 P03/FLD11 P04/FLD12 P05/FLD13 P06/FLD14 P07/FLD15 000016 P10/FLD16 P11/FLD17 P12/FLD18 8 P13/FLD19 P14/FLD20 P15/FLD21 P16/FLD22 P17/FLD23 000216 FLDC mode register (0EF416) FLD data pointer reload register (0EF816) Address decoder FLD data pointer (0EF816) Timing generator Fig. 42 Block diagram for FLD control circuit 40 P30/FLD24 P31/FLD25 P32/FLD26 8 P33/FLD27 P34/FLD28 P35/FLD29 P36/FLD30 P37/FLD31 000616 FLD/P P80/FLD32 FLD/P P81/FLD33 FLD/P P82/FLD34 FLD/P P83/FLD35 8 FLD/P P84/FLD36 FLD/P P85/FLD37 FLD/P P86/FLD38 FLD/P P87/FLD39 001016 0EFB16 FLD blanking interrupt FLD digit interrupt MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [FLDC Mode Register] FLDM The FLDC mode register is a 8-bit register respectively which is used to control the FLD automatic display and to set the blanking time Tscan for key-scan. b7 b0 FLDC mode register (FLDM: address 0EF416) Automatic display control bit (P0, P1, P2, P3, P8) 0 : General-purpose mode 1 : Automatic display mode Display start bit 0 : Stop display 1 : Display (start to display by switching “0” to “1”) Tscan control bits 00 : FLD digit interrupt (at rising edge of each digit) 01 : 1 ✕ Tdisp FLD blanking interrupt 10 : 2 ✕ Tdisp (at falling edge of the last digit) 11 : 3 ✕ Tdisp Timing number control bit 0 : 16 timing mode 1 : 32 timing mode Gradation display mode selection control bit 0 : Not selecting 1 : Selecting (Note 1) Tdisp counter count source selection bit 0 : f(XIN)/16 or f(XCIN)/32 1 : f(XIN)/64 or f(XCIN)/128 High-breakdown voltage port drivability selection bit 0 : Drivability strong 1 : Drivability weak Notes 1: When a gradation display mode is selected, a number of timing is max. 16 timing. (Set the timing number control bit to “0”.) 2: When changing bit 4 (timing number control bit) or bit 5 (gradation display mode selection control bit), set “0” to bit 1 (display start bit) to perform at display stop state. Fig. 43 Structure of FLDC mode register 41 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FLD Automatic Display Pins This setting is performed by writing a value into the FLD/port switch register (addresses 0EF916 to 0EFB16 ) of each port. This setting can be performed in units of bit. When “0” is set, the port is set to the general-purpose port. When “1” is set, the port is set to the FLD pin. There is no restriction on whether the FLD pin is to be used as a segment pin or a digit pin. When the automatic display control bits of the FLDC mode register (address 0EF416 ) are set to “1,” the ports of P0, P1, P2, P3 and P8 are used as FLD automatic display pins. When using the FLD automatic display mode, set each port to the FLD pin or the general-purpose port using the respective switch register in accordance with the number of segments and the number of digits. Table 9 Pins in FLD automatic display mode Port Name P0, P2, P80–P83 P1, P3 P84–P87 Automatic Display Pins FLD0–FLD15 FLD32–FLD35 FLD16–FLD31 FLD36–FLD39 Setting Method The individual bits of the FLD/port switch register (addresses 0EF916–0EFB16 ) can be set each pin either FLD port (“1”) or general-purpose port (“0”). None (FLD only) The individual bits of the FLD/port switch register (address 0EFB16) can be set each pin to either FLD port (“1”) or general-purpose port (“0”). The output can be reversed by the port P8 FLD output control register (address 0EFC16). The port output format is the CMOS output format. When using the port as a display pin, a driver must be installed externally. Setting example 2 Setting example 1 15 8 Number of segments Number of digits Port P2 Port P0 0 0 0 0 0 0 0 0 FLD0(SEG1) FLD1(SEG2) FLD2(SEG3) FLD3(SEG4) FLD4(SEG5) FLD5(SEG6) 1 FLD6(SEG7) 1 FLD7(SEG8) FLD8(SEG1) P01 P02 P03 P04 P05 FLD14(SEG2) 1 FLD15(SEG3) 1 1 1 1 0 0 0 0 1 1 1 1 1 1 1 1 16 10 FLD8(SEG9) FLD9(SEG10) FLD10(SEG11) FLD11(SEG12) FLD12(SEG13) FLD13(SEG14) FLD14(SEG15) FLD15(SEG16) 0 0 1 1 1 1 1 1 P20 P21 FLD2(SEG1) FLD3(SEG2) FLD4(SEG3) FLD5(SEG4) FLD6(SEG5) FLD7(SEG6) 0 0 0 0 0 0 1 1 P20 P21 P22 P23 P24 P25 FLD4(SEG1) FLD5(SEG2) 1 1 1 1 1 1 1 1 FLD8(DIG1) FLD9(DIG2) FLD10(DIG3) FLD11(DIG4) 1 1 1 1 1 1 1 1 FLD6(SEG3) FLD7(SEG4) FLD8(SEG5) FLD9(SEG6) FLD10(SEG7) FLD11(SEG8) FLD12(SEG9) FLD13(SEG10) FLD12(DIG5) FLD13(DIG6) FLD14(DIG7) FLD15(DIG8) 1 1 1 1 1 1 1 1 1 1 1 1 0 0 0 0 FLD16(DIG1) FLD17(DIG2) FLD18(DIG3) FLD19(DIG4) FLD20(DIG5) FLD21(DIG6) FLD22(DIG7) FLD23(DIG8) 1 1 1 1 1 1 1 1 FLD16(DIG9) FLD17(DIG10) FLD18(DIG11) FLD19(DIG12) FLD20(DIG13) FLD21(DIG14) FLD22(DIG15) FLD23(DIG16) 1 1 1 1 1 1 1 1 FLD16(DIG1) FLD17(DIG2) FLD18(DIG3) FLD19(DIG4) FLD20(DIG5) FLD24(SEG8) FLD25(SEG9) FLD26(SEG10) FLD27(SEG11) FLD28(DIG5) FLD29(DIG6) FLD30(DIG7) FLD31(DIG8) 0 0 0 0 1 1 1 1 FLD24(DIG9) FLD25(DIG10) FLD26(DIG11) FLD27(DIG12) FLD28(DIG13) FLD29(DIG14) FLD30(DIG15) FLD31(SEG17) 1 1 1 1 1 1 1 0 FLD24(DIG17) FLD25(DIG18) FLD26(DIG19) FLD27(DIG20) FLD28(SEG7) FLD29(SEG8) FLD30(SEG9) FLD31(SEG10) 1 1 1 FLD24(DIG9) FLD25(DIG10) 1 FLD14(SEG11) 0 FLD32(SEG12) FLD33(SEG13) FLD34(SEG14) FLD35(SEG15) P84 P85 P86 P87 Value of FLD/port switch register Fig. 44 Segment/Digit setting example 42 Setting example 4 18 20 FLD17(DIG2) FLD18(DIG3) FLD19(DIG4) FLD20(SEG4) FLD21(SEG5) FLD22(SEG6) FLD23(SEG7) FLD16(DIG1) Port P3 Port P8 1 1 1 1 1 1 P20 P21 P22 P23 P24 P25 P26 P27 1 0 0 0 0 0 1 Port P1 Setting example 3 25 15 1 1 1 1 1 1 1 1 FLD32(SEG18) FLD33(SEG19) FLD34(SEG20) FLD35(SEG21) FLD36(SEG22) FLD37(SEG23) FLD38(SEG24) FLD39(SEG25) FLD32(SEG11) FLD33(SEG12) FLD34(SEG13) FLD35(SEG14) FLD36(SEG15) FLD37(SEG16) FLD38(SEG17) 1 FLD39(SEG18) 1 1 1 1 1 1 1 FLD21(DIG6) FLD22(DIG7) FLD23(DIG8) 1 1 0 0 FLD15(SEG12) FLD26(SEG13) FLD27(SEG14) FLD28(SEG15) FLD29(SEG16) 0 0 0 0 0 0 0 0 0 0 P80 P81 P82 P83 P84 P85 P86 P87 0 0 0 0 0 Value of FLDRAM write disable register If data is set to “1”, data is protected. This setting does not decide the FLD port function (SEG/DIG). MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FLD Automatic Display RAM [FLD Data Pointer and FLD Data Pointer Reload Register] The FLD automatic display RAM uses the 160 bytes of addresses 0F6016 to 0FFF16 . For FLD, the 3 modes of 16-timing ordinary mode, 16-timing•gradation display mode and 32-timing mode are available depending on the number of timings and the presence/absence of gradation display. The automatic display RAM in each mode is as follows: (1) 16-timing•ordinary mode The 80 bytes of addresses 0FB016 to 0FFF16 are used as a FLD display data store area. Because addresses 0F6016 to 0FAF 16 are not used as the automatic display RAM, they can be the ordinary RAM or serial I/O automatic transfer RAM. (2) 16-timing•gradation display mode The 160 bytes of addresses 0F6016 to 0FFF16 are used. The 80 bytes of addresses 0FB016 to 0FFF 16 are used as an FLD display data store area, while the 80 bytes of addresses 0F6016 to 0FAF16 are used as a gradation display control data store area. (3) 32-timing mode The 160 bytes of addresses 0F6016 to 0FFF16 are used as an FLD display data store area. FLDDP (0EF816) 16-timing•gradation display mode 16-timing•ordinary mode 0F6016 0F6016 0FB016 32-timing mode 0F6016 Gradation display control data stored area Not used 1 to 32 timing display data stored area 0FB016 1 to 16 timing display data stored area 0FFF16 Both the FLD data pointer and FLD data pointer reload register are 8-bit registers assigned at address 0EF816. When writing data to this address, the data is written to the FLD data pointer reload register; when reading data from this address, the value in the FLD data pointer is read. 1 to 16 timing display data stored area 0FFF16 0FFF16 Fig. 45 FLD automatic display RAM assignment 43 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Data Setup (1) 16-timing•ordinary mode The area of addresses 0FB0 16 to 0FFF16 are used as a FLD automatic display RAM. When data is stored in the FLD automatic display RAM, the last data of FLD port P2 is stored at address 0FB0 16 , the last data of FLD port P0 is stored at address 0FC0 16 , the last data of FLD port P1 is stored at address 0FD0 16 , the last data of FLD port P3 is stored at address 0FE0 16 , and the last data of FLD port P8 is stored at address 0FF0 16, to assign in sequence from the last data respectively. The first data of the FLD port P2, P0, P1, P3, and P8 is stored at an address which adds the value of (the timing number – 1) to the corresponding address 0FB0 16, 0FC0 16 , 0FD016 , 0FE016, and 0FF016 . Set the FLD data pointer reload register to the value given by the timing number – 1. “1” is always written to bits 7, 6, and 5. Note that “0” is always read from bits 7, 6, and 5 when reading. “1” is always set to bit 4, but this bit become written value when reading. (2) 16-timing•gradation display mode Display data setting is performed in the same way as that of the 16-timing•ordinary mode. Gradation display control data is arranged at an address resulting from subtracting 0050 16 from the display data store address of each timing and pin. Bright display is performed by setting “0”, and dark display is performed by setting “1”. Set the FLD data pointer reload register to the value given by the timing number – 1. “1” is always written to bits 7, 6, and 5. Note that “0” is always read from bits 7, 6, and 5 when reading. “1” is always set to bit 4, but this bit become written value when reading. (3) 32-timing mode The area of addresses 0F6016 to 0FFF16 are used as a FLD automatic display RAM. When data is stored in the FLD automatic display RAM, the last data of FLD port P2 is stored at address 0F6016 , the last data of FLD port P0 is stored at address 0F8016 , the last data of FLD port P1 is stored at address 0FA0 16 , the last data of FLD port P3 is stored at address 0FC0 16 , and the last data of FLD port P8 is stored at address 0FE0 16, to assign in sequence from the last data respectively. The first data of the FLD port P2, P0, P1, P3, and P8 is stored at an address which adds the value of (the timing number – 1) to the corresponding address 0F6016 , 0F8016, 0FA016 , 0FC016, and 0FE0 16. Set the FLD data pointer reload register to the value given by the timing number –1. “1” is always written to bits 7, 6, and 5. Note that “0” is always read from bits 7, 6, and 5 when reading. Number of FLD segments: 15 Number of timing: 8 (FLD data pointer reload register = 7) B it Address 0FB016 0FB116 0FB216 0FB316 0FB416 0FB516 0FB616 0FB716 0FB816 0FB916 0FBA16 0FBB16 0FBC16 0FBD16 0FBE16 0FBF16 0FC016 0FC116 0FC216 0FC316 0FC416 0FC516 0FC616 0FC716 0FC816 0FC916 0FCA16 0FCB16 0FCC16 0FCD16 0FCE16 0FCF16 0FD016 0FD116 0FD216 0FD316 0FD416 0FD516 0FD616 0FD716 0FD816 0FD916 0FDA16 0FDB16 0FDC16 0FDD16 0FDE16 0FDF16 0FE016 0FE116 0FE216 0FE316 0FE416 0FE516 0FE616 0FE716 0FE816 0FE916 0FEA16 0FEB16 0FEC16 0FED16 0FEE16 0FEF16 0FF016 0FF116 0FF216 0FF316 0FF416 0FF516 0FF616 0FF716 0FF816 0FF916 0FFA16 0FFB16 0FFC16 0FFD16 0FFE16 0FFF16 Note: 7 6 5 4 3 2 1 0 The last timing (The last data of FLDP2) Timing for start (The first data of FLDP2) FLDP2 data area The last timing (The last data of FLDP0) Timing for start (The first data of FLDP0) FLDP0 data area The last timing (The last data of FLDP1) Timing for start (The first data of FLDP1) FLDP1 data area The last timing (The last data of FLDP3) Timing for start (The first data of FLDP3) FLDP3 data area The last timing (The last data of FLDP8) Timing for start (The first data of FLDP8) FLDP8 data area shaded area is used for segment. shaded area is used for digit. Fig. 46 Example of using FLD automatic display RAM in 16-timing•ordinary mode 44 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Number of FLD segments: 25 Number of timing: 15 (FLD data pointer reload register = 14) B it Address 0FB016 0FB116 0FB216 0FB316 0FB416 0FB516 0FB616 0FB716 0FB816 0FB916 0FBA16 0FBB16 0FBC16 0FBD16 0FBE16 0FBF16 0FC016 0FC116 0FC216 0FC316 0FC416 0FC516 0FC616 0FC716 0FC816 0FC916 0FCA16 0FCB16 0FCC16 0FCD16 0FCE16 0FCF16 0FD016 0FD116 0FD216 0FD316 0FD416 0FD516 0FD616 0FD716 0FD816 0FD916 0FDA16 0FDB16 0FDC16 0FDD16 0FDE16 0FDF16 0FE016 0FE116 0FE216 0FE316 0FE416 0FE516 0FE616 0FE716 0FE816 0FE916 0FEA16 0FEB16 0FEC16 0FED16 0FEE16 0FEF16 0FF016 0FF116 0FF216 0FF316 0FF416 0FF516 0FF616 0FF716 0FF816 0FF916 0FFA16 0FFB16 0FFC16 0FFD16 0FFE16 0FFF16 Note: 7 6 5 4 3 2 1 B it 0 Address The last timing (The last data of FLDP2) FLDP2 data area Timing for start (The first data of FLDP2) The last timing (The last data of FLDP0) FLDP0 data area Timing for start (The first data of FLDP0) The last timing (The last data of FLDP1) FLDP1 data area Timing for start (The first data of FLDP1) The last timing (The last data of FLDP3) FLDP3 data area Timing for start (The first data of FLDP3) The last timing (The last data of FLDP8) FLDP8 data area Timing for start (The first data of FLDP8) shaded area is used for segment. shaded area is used for digit. 0F6016 0F6116 0F6216 0F6316 0F6416 0F6516 0F6616 0F6716 0F6816 0F6916 0F6A16 0F6B16 0F6C16 0F6D16 0F6E16 0F6F16 0F7016 0F7116 0F7216 0F7316 0F7416 0F7516 0F7616 0F7716 0F7816 0F7916 0F7A16 0F7B16 0F7C16 0F7D16 0F7E16 0F7F16 0F8016 0F8116 0F8216 0F8316 0F8416 0F8516 0F8616 0F8716 0F8816 0F8916 0F8A16 0F8B16 0F8C16 0F8D16 0F8E16 0F8F16 0F9016 0F9116 0F9216 0F9316 0F9416 0F9516 0F9616 0F9716 0F9816 0F9916 0F9A16 0F9B16 0F9C16 0F9D16 0F9E16 0F9F16 0FA016 0FA116 0FA216 0FA316 0FA416 0FA516 0FA616 0FA716 0FA816 0FA916 0FAA16 0FAB16 0FAC16 0FAD16 0FAE16 0FAF16 Note: 7 6 5 4 3 2 1 0 The last timing (The last data of FLDP2) FLDP2 gradation display data area Timing for start (The first data of FLDP2) The last timing (The last data of FLDP0) FLDP0 gradation display data area Timing for start (The first data of FLDP0) The last timing (The last data of FLDP1) FLDP1 gradation display data area Timing for start (The first data of FLDP1) The last timing (The last data of FLDP3) FLDP3 gradation display data area Timing for start (The first data of FLDP3) The last timing (The last data of FLDP8) FLDP8 gradation display data area Timing for start (The first data of FLDP8) shaded area is used for gradation display data. Fig. 47 Example of using FLD automatic display RAM in 16-timing•gradation display mode 45 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Number of FLD segments: 18 Number of timing: 20 (FLD data pointer reload register = 19) B it Address 0FB016 0FB116 0FB216 0FB316 0FB416 0FB516 0FB616 0FB716 0FB816 0FB916 0FBA16 0FBB16 0FBC16 0FBD16 0FBE16 0FBF16 0FC016 0FC116 0FC216 0FC316 0FC416 0FC516 0FC616 0FC716 0FC816 0FC916 0FCA16 0FCB16 0FCC16 0FCD16 0FCE16 0FCF16 0FD016 0FD116 0FD216 0FD316 0FD416 0FD516 0FD616 0FD716 0FD816 0FD916 0FDA16 0FDB16 0FDC16 0FDD16 0FDE16 0FDF16 0FE016 0FE116 0FE216 0FE316 0FE416 0FE516 0FE616 0FE716 0FE816 0FE916 0FEA16 0FEB16 0FEC16 0FED16 0FEE16 0FEF16 0FF016 0FF116 0FF216 0FF316 0FF416 0FF516 0FF616 0FF716 0FF816 0FF916 0FFA16 0FFB16 0FFC16 0FFD16 0FFE16 0FFF16 Note: 7 6 5 4 3 2 1 B it 0 Address Timing for start (The first data of FLDP1) The last timing (The last data of FLDP3) FLDP3 data area Timing for start (The first data of FLDP3) The last timing (The last data of FLDP8) FLDP8 data area Timing for start (The first data of FLDP8) 0F6016 0F6116 0F6216 0F6316 0F6416 0F6516 0F6616 0F6716 0F6816 0F6916 0F6A16 0F6B16 0F6C16 0F6D16 0F6E16 0F6F16 0F7016 0F7116 0F7216 0F7316 0F7416 0F7516 0F7616 0F7716 0F7816 0F7916 0F7A16 0F7B16 0F7C16 0F7D16 0F7E16 0F7F16 0F8016 0F8116 0F8216 0F8316 0F8416 0F8516 0F8616 0F8716 0F8816 0F8916 0F8A16 0F8B16 0F8C16 0F8D16 0F8E16 0F8F16 0F9016 0F9116 0F9216 0F9316 0F9416 0F9516 0F9616 0F9716 0F9816 0F9916 0F9A16 0F9B16 0F9C16 0F9D16 0F9E16 0F9F16 0FA016 0FA116 0FA216 0FA316 0FA416 0FA516 0FA616 0FA716 0FA816 0FA916 0FAA16 0FAB16 0FAC16 0FAD16 0FAE16 0FAF16 shaded area is used for segment. shaded area is used for digit. Fig. 48 Example of using FLD automatic display RAM in 32-timing mode 46 7 6 5 4 3 2 1 0 The last timing (The last data of FLDP2) FLDP2 data area Timing for start (The first data of FLDP2) The last timing (The last data of FLDP0) FLDP0 data area Timing for start (The first data of FLDP0) The last timing (The last data of FLDP1) FLDP1 data area MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Setting Method When Using Grid Scan Type FLD When using the grid scan type FLD, set “1” in the RAM area corresponding to the digit ports that output “1” at each timing. Set “0” in the RAM area corresponding to the other digit ports. Number of FLD segments: 16 Number of timing: 10 (FLD data pointer reload register = 9) B it Address Number of timing: 10 The first second third.......................9th 10th DIG10 (P31) DIG9 (P30) DIG8 (P17) DIG2 (P11) DIG1 (P10) Segment output Fig. 49 Example of digit timing using grid scan type 0FB016 0FB116 0FB216 0FB316 0FB416 0FB516 0FB616 0FB716 0FB816 0FB916 0FBA16 0FBB16 0FBC16 0FBD16 0FBE16 0FBF16 0FC016 0FC116 0FC216 0FC316 0FC416 0FC516 0FC616 0FC716 0FC816 0FC916 0FCA16 0FCB16 0FCC16 0FCD16 0FCE16 0FCF16 0FD016 0FD116 0FD216 0FD316 0FD416 0FD516 0FD616 0FD716 0FD816 0FD916 0FDA16 0FDB16 0FDC16 0FDD16 0FDE16 0FDF16 0FE016 0FE116 0FE216 0FE316 0FE416 0FE516 0FE616 0FE716 0FE816 0FE916 0FEA16 0FEB16 0FEC16 0FED16 0FEE16 0FEF16 0FF016 0FF116 0FF216 0FF316 0FF416 0FF516 0FF616 0FF716 0FF816 0FF916 0FFA16 0FFB16 0FFC16 0FFD16 0FFE16 0FFF16 Note: 7 6 5 4 3 2 1 0 The last timing (The last data of FLDP2) FLDP2 data area Timing for start (The first data of FLDP2) The last timing (The last data of FLDP0) FLDP0 data area Timing for start (The first data of FLDP0) 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 The last timing (The last data of FLDP1) 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 0 The last timing (The last data of FLDP3) FLDP1 data area Timing for start (The first data of FLDP1) FLDP3 data area Timing for start (The first data of FLDP3) The last timing (The last data of FLDP8) FLDP8 data area Timing for start (The first data of FLDP8) shaded area is used for segment. shaded area is used for digit. Fig. 50 Example of using FLD automatic display RAM using grid scan type 47 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Timing Setting Key-scan Each timing is set by the FLDC mode register, Tdisp time set register, Toff1 time set register, and Toff2 time set register. ●Tdisp time setting Set the Tdisp time by the Tdisp counter count source selection bit of the FLDC mode register and the Tdisp time set register. Supposing that the value of the Tdisp time set register is n, the Tdisp time is represented as Tdisp = (n+1) ✕ t (t: count source synchronization). When the Tdisp counter count source selection bit of the FLDC mode register is “0” and the value of the Tdisp time set register is 200 (C816), the Tdisp time is: Tdisp = (200+1) ✕ 4 (at XIN= 4 MHz) = 804 µs. When reading the Tdisp time set register, the value in the counter is read out. ●Toff1 time setting Set the Toff1 time by the Toff1 time set register. Supposing that the value of the Toff1 time set register is n1, the Toff1 time is represented as Toff1 = n1 ✕ t. When the Tdisp counter count source selection bit of the FLDC mode register is “0” and the value of the Toff1 time set register is 30 (1E16 ), Toff1 = 30 ✕ 4 (at XIN = 4 MHz) = 120 µs. Set a value of 0316 or more to the Toff1 time set register (address 0EF6 16). ●Toff2 time setting Set the Toff2 time by the Toff2 time set register. Supposing that the value of the Toff2 time set register is n2, the Toff2 time is represented as Toff2 = n2 ✕ t. When the Tdisp counter count source selection bit of the FLDC mode register is “0” and the value of the Toff2 time set register is 180 (B416 ), Toff2 = 180 ✕ 4 (at XIN = 4 MHz) = 720 µs. This Toff2 time setting is valid only for FLD ports which are in the gradation display mode and whose gradation display control RAM value is “1”. When setting “1” to bit 7 of the P8FLD output control register (address 0EFC 16), set a value of 03 16 or more to the Toff2 time set register (address 0EF716). When a key-scan is performed with the segment during key-scan blanking period Tscan, take the following sequence: 1. Write “0” to bit 0 of the FLDC mode register (address 0EF416 ). 2. Set the port corresponding to the segment for key-scan to the output port. 3. Perform the key-scan. 4. After the key-scan is performed, write “1” to bit 0 of FLDC mode register (address 0EF416). FLD Automatic Display Start To perform FLD automatic display, set the following registers. •Port P0FLD/port switch register •Port P2FLD/port switch register •Port P8FLD/port switch register •FLDC mode register •Tdisp time set register •Toff1 time set register •Toff2 time set register •FLD data pointer FLD automatic display mode is selected by writing “1” to the bit 0 of the FLDC mode register (address 0EF416 ), and the automatic display is started by writing “1” to bit 1. During FLD automatic display, bit 1 of the FLDC mode register (address 0EF416) always keeps “1”, and FLD automatic display can be interrupted by writing “0” to bit 1. 48 ■ Note When performing a key-scan according to the above step 1 to 4, take the following points into consideration. 1. Do not set “0” in bit 1 of the FLDC mode register (address 0EF4 16). 2. Do not set “1” in the ports corresponding to digits. MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Repeat synchronous Tdisp Segment Digit output Tn Tscan Tn-1 Tn-2 T4 T3 FLD digit interrupt request occurs at the rising edge of digit (each timing). T2 T1 Segment setting by software FLD blanking interrupt request occurs at the falling edge of the last timing. Segment Digit Toff1 Tdisp Segment Digit When a gradation display mode is selected Toff1 Toff2 Tdisp Pin under the condition that bit 5 of the FLDC mode register is “1”, and the corresponding gradation display control data value is “1”. n: Number of timing Fig. 51 FLDC timing 49 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER P84 to P87 FLD Output Reverse Function P84 to P87 are provided with a function to reverse the polarity of the FLD output. This function is useful in adjusting the polarity when using an externally installed driver. The output polarity can be reversed by setting “1” to bit 0 of the port P8 FLD output control register. P84 to P87 Toff Invalid Function P84 to P87 can output waveform in which Toff is invalid, when P84 to P87 is selected FLD ports (See Figure 52). The function is useful when using a 4 bits →16 bits decoder. The Toff can be invalid by setting “1” to bit 2 of the port P8FLD output control register (address 0EFC16). Segment Digit At Toff2 control bit = “0” in gradation display mode (at gradation display control data= “1”) At Toff2 control bit = “1” in gradation display mode (at gradation display control data= “1”) Toff1 Toff2 Tdisp Dimmer signal P84 to P87 Output Delay Function P84 to P87 can output waveform in which is delayed for 16 µs, when selecting FLD port and selecting Toff invalid function (See Figure 52). When using a 4 bits →16 bits decoder, the function can be useful for prevention of leak radiation caused by phase discrepancy between segment output waveform and digit output waveform. This function can be set by setting “1” to bit 3 of the port P8FLD output control register (address 0EFC16). P84–P87 Toff invalid P84–P87 Toff invalid Delay 16 µs Fig. 52 P84 to P87 FLD output waveform Dimmer Signal Output Function P63 can output the dimmer signal. When using a 4 bits →16 bits decoder, the dimmer signal can be used as a control signal for a 4 bits →16 bits decoder. When using M35501FP, the dimmer signal can be used as the CLK signal. The dimmer signal can be output by setting “1” to bit 4 of the port P8FLD output control register (address 0EFC16). b7 Toff2 Control Bit The value of the Toff2 time set register is valid when gradation display mode is selected. The FLD ports output (set) the data of display RAM at the end of the Toff1 time and output “0” (reset) at the end of the Toff2 time, when bit 7 of the port P8FLD output control register is “0”. The FLD ports output (set) the data of display RAM at the end of the Toff2 time and output “0” (reset) at the end of Tdisp time, when bit 7 of the port P8FLD output control register is “1”. b0 Port P8FLD output control register (P8FLDCON: address 0EFC16) P84–P87 FLD output reverse bit 0: Output normally 1: Reverse output Not used (“0” at reading) P84–P87 Toff invalid bit 0: Operating normally 1: Toff invalid P84–P87 delay control bit (Note) 0: No delay 1: Delay P63/AN9 dimmer output control bit 0: Ordinary port 1: Dimmer output Not used (“0” at reading) Toff2 control bit 0: Gradation display data is reset at Toff2 (set at Toff1) 1: Gradation display data is set at Toff2 (reset at Tdisp) Note: Valid only when selecting FLD port and P84–P87 Toff invalid function Fig. 53 Structure of port P8 FLD output control register 50 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER A-D CONVERTER The 38B4 group has a 10-bit A-D converter. The A-D converter performs successive approximation conversion. conversion interrupt request bit to “1”. Note that the comparator is constructed linked to a capacitor, so set f(XIN) to at least 250 kHz during A-D conversion. Use a CPU system clock dividing the main clock XIN as the internal system clock. [A-D Conversion Register] AD One of these registers is a high-order register, and the other is a loworder register. The high-order 8 bits of a conversion result is stored in the A-D conversion register (high-order) (address 0034 16), and the low-order 2 bits of the same result are stored in bit 7 and bit 6 of the A-D conversion register (low-order) (address 0033 16 ). During A-D conversion, do not read these registers. b7 b0 A-D control register (ADCON: address 003216) Analog input pin selection bits 0000: P70/AN0 0001: P71/AN1 0010: P72/AN2 0011: P73/AN3 0100: P74/AN4 0101: P75/AN5 0110: P76/AN6 0111: P77/AN7 1000: P62/SRDY1/AN8 1001: P63/AN9 1010: P64/INT4/SBUSY1/AN10 1011: P65/SSTB1/AN11 [A-D Control Register] ADCON This register controls A-D converter. Bits 3 to 0 are analog input pin selection bits. Bit 4 is an AD conversion completion bit and “0” during A-D conversion. This bit is set to “1” upon completion of A-D conversion. A-D conversion is started by setting “0” in this bit. AD conversion completion bit 0: Conversion in progress 1: Conversion completed [Comparison Voltage Generator] Not used (returns “0” when read) The comparison voltage generator divides the voltage between AV SS and VREF, and outputs the divided voltages. b7 [Channel Selector] b0 A-D conversion register (high-order) (ADH: address 003416) The channel selector selects one of the input ports P77/AN 7–P70/ AN 0, and P65/SSTB1/AN11–P62/SRDY1/AN8 and inputs it to the comparator. When port P6 4 is selected as an analog input pin, an external interrupt function (INT4) is invalid. AD conversion result stored bits b7 b0 A-D conversion register (low-order) (ADL: address 003316) [Comparator and Control Circuit] The comparator and control circuit compares an analog input voltage with the comparison voltage and stores the result in the A-D conversion register. When an A-D conversion is completed, the control circuit sets the AD conversion completion bit and the AD Not used (returns “0” when read) AD conversion result stored bits Fig. 54 Structure of A-D control register Data bus b7 b0 A-D control register 4 A-D control circuit Channel selector P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6 P77/AN7 P62/SRDY1/AN8 P63/AN9 P64/INT4/SBUSY1/AN10 P65/SSTB1/AN11 Comparator A-D interrupt request A-D conversion register (H) A-D conversion register (L) (Address 003416) (Address 003316) Resistor ladder AVSS VREF Fig. 55 Block diagram of A-D converter 51 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PULSE WIDTH MODULATION (PWM) The 38B4 group has a PWM function with a 14-bit resolution. When the oscillation frequency XIN is 4 MHz, the minimum resolution bit width is 250 ns and the cycle period is 4096 µs. The PWM timing generator supplies a PWM control signal based on a signal that is the frequency of the XIN clock. The explanation in the rest assumes XIN = 4 MHz. Data bus It is set to “1” when write. bit7 PWM register (low-order) (address 001516) bit7 bit5 bit0 bit0 PWM register (high-order) (address 001416) PWM latch (14-bit) MSB LSB 14 P87 latch P87/PWM0 14-bit PWM circuit When an internal XCIN 1/2 system clock selection bit is set (64 µs cycle) Timing “1” to “0” generating XI N unit for PWM (4096 µs cycle) (4MHz) “0” Fig. 56 PWM block diagram 52 PWM P87/PWM output selection bit P87/PWM output selection bit P87 direction register MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Data Setup Transfer From Register To Latch The PWM output pin also function as port P8 7. Set port P87 to be the PWM output pin by setting bit 0 of the PWM control register (address 0026 16) to “1”. The high-order 8 bits of output data are set in the high-order PWM register PWMH (address 0014 16) and the low-order 6 bits are set in the low-order PWM register PWML (address 0015 16). Data written to the PWML register is transferred to the PWM latch once in each PWM period (every 4096 µs), and data written to the PWMH register is transferred to the PWM latch once in each subperiod (every 64 µs). When the PWML register is read, the contents of the latch are read. However, bit 7 of the PWML register indicates whether the transfer to the PWM latch is completed; the transfer is completed when bit 7 is “0”. PWM Operation The timing of the 14-bit PWM function is shown in Figure 57. The 14-bit PWM data is divided into the low-order 6 bits and the high-order 8 bits in the PWM latch. The high-order 8 bits of data determine how long an “H” level signal is output during each sub-period. There are 64 sub-periods in each period, and each sub-period t is 256 ✕ τ (= 64 µs) long. The signal’s “H” has a length equal to N times τ, and its minimum resolution = 250 ns. The last bit of the sub-period becomes the ADD bit which is specified either “H” or “L”, by the contents of PWML. As shown in Table 10, the ADD bit is decided either “H” or “L”. That is, only in the sub-period tm shown in Table 10 in the PWM cycle period T = 64t, the “H” duration is lengthened during the minimum resolution width τ period in comparison with the other period. For example, if the high-order eight bits of the 14-bit data are “0316” and the low-order six bits are “05 16”, the length of the “H” level output in sub-periods t 8, t24 , t32, t 40 and t56 is 4 τ, and its length 3 τ in all other sub-periods. Time at the “H” level of each sub-period almost becomes equal because the time becomes length set in the high-order 8 bits or becomes the value plus τ, and this sub-period t (= 64 µs, approximate 15.6 kHz) becomes cycle period approximately. Table 10 Relationship between low-order 6-bit data and setting period of ADD bit Low-order Sub-periods tm lengthened (m = 0 to 63) 6-bit data LSB 000000 None 000001 000010 000100 001000 010000 100000 m = 32 m = 16, 48 m = 8, 24, 40, 56 m = 4, 12, 20, 28, 36, 44, 52, 60 m = 2, 6, 10, 14, 18, 22, 26, 30, 34, 38, 42, 46, 50, 54, 58, 62 m = 1, 3, 5, 7, .................................................., 57, 59, 61, 63 4096 µs 64 µs 64 µs m=0 15.75 µs m=7 15.75 µs 15.75 µs 64 µs m=8 16.0 µs 64 µs 64 µs m=9 15.75 µs m = 63 15.75 µs 15.75 µs Pulse width modulation register H: 00111111 Pulse width modulation register L: 000101 Sub-periods where “H” pulse width is 16.0 µs: m = 8, 24, 32, 40, 56 Sub-periods where “H” pulse width is 15.75 µs: m = all other values Fig. 57 PWM timing 53 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 PWM control register (PWMCON: address 002616) P87/PWM output selection bit 0: I/O port 1: PWM output Not used (return “0” when read) Fig. 58 Structure of PWM control register Data 7B16 stored at address 001416 Data 6A16 stored at address 001416 PWM register (high-order) 5916 6A16 7B16 Data 2416 stored at address 001516 PWM register (low-order) 1316 Bit 7 cleared after transfer A416 Data 3516 stored at address 001516 2416 3516 Transfer from register to latch PWM latch (14-bit) 165316 1A9316 Transfer from register to latch B516 1AA416 1AA416 1EE416 1EF516 When bit 7 of PWML is “0”, transfer from register to latch is disabled. T = 4096 µs (64 ✕ 64 µs) t = 64 µs 6A (Example 1) 6B 6A 6B 6A 6B 6A 6B 6A 6B 6B 5 2 5 6B 6A 6B 6A 6B 6A 6B 6A 6B 6A 6B 6A 6B 6A 6B 6A PWM output 1 Low-order 6-bits output H = 6A16 L = 2416 5 6A (Example 2) 5 5 5 6B16............36 times (107) 6A 6A 6A 6B 6A 5 5 6A16............28 times (106) 6B 6A 6B 6A 6A 6A 5 106 ✕ 64 6B 6A 6B 6A 6B 5 5 5 5 5 36 6A 6A 6A 6B 6A 6B 6A 6B 6A 6A PWM output Low-order 6 bits output H = 6A16 L = 1816 4 3 4 6B16............24 times 4 3 4 6A16............40 times 4 106 ✕ 64 3 4 24 t = 64 µs (256 ✕ 0.25 µs) Minimum bit width PWM output 6B τ = 0.25 µs 6A 69 68 67 ......... 02 01 6A 69 68 67 ......... 02 01 FF FE FD FC ......... 97 96 2 ADD 8-bit counter 02 01 The ADD portions with additional τ are determined either “H” or “L” by low-order 6-bit data. 00 ADD FF FE FD FC ......... 54 96 95 “H” period length specified by PWMH 256 Fig. 59 14-bit PWM timing 97 τ (64 µs), fixed ......... 02 01 00 95 ......... MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER INTERRUPT INTERVAL DETERMINATION FUNCTION The 38B4 group has an interrupt interval determination circuit. This interrupt interval determination circuit has an 8-bit binary up counter. Using this counter, it determines a duration of time from the rising edge (falling edge) of an input signal pulse on the P47/INT2 pin to the rising edge (falling edge) of the signal pulse that is input next. How to determine the interrupt interval is described below. 1. Enable the INT2 interrupt by setting bit 2 of the interrupt control register 1 (address 003E 16). Select the rising interval or falling interval by setting bit 2 of the interrupt edge selection register (address 003A 16). 2. Set bit 0 of the interrupt interval determination control register (address 0031 16) to “1” (interrupt interval determination operating). 3. Select the sampling clock of 8-bit binary up counter by setting bit 1 of the interrupt interval determination control register. When writing “0”, f(XIN)/128 is selected (the sampling interval: 32 µs at f(X IN) = 4.19 MHz); when “1”, f(XIN)/256 is selected (the sampling interval: 64 µs at f(X IN) = 4.19 MHz). 4. When the signal of polarity which is set on the INT 2 pin (rising or falling edge) is input, the 8-bit binary up counter starts counting up of the selected counter sampling clock. 5. When the signal of polarity above 4 is input again, the value of the 8-bit binary up counter is transferred to the interrupt interval determination register (address 0030 16), and the remote control interrupt request occurs. Immediately after that, the 8-bit binary up counter continues to count up again from “0016 ”. 6. When count value reaches “FF16 ”, the 8-bit binary up counter stops counting up. Then, simultaneously when the next counter sampling clock is input, the counter sets value “FF 16 ” to the interrupt interval determination register to generate the counter overflow interrupt request. Counter sampling clock selection bit f(XIN)/128 f(XIN)/256 Noise filter INT2 interrupt input Noise Filter The P47/INT 2 pin builds in the noise filter. The noise filter operation is described below. 1. Select the sampling clock of the input signal with bits 2 and 3 of the interrupt interval determination control register. When not using the noise filter, set “00”. 2. The P47/INT2 input signal is sampled in synchronization with the selected clock. When sampling the same level signal in a series of three sampling, the signal is recognized as the interrupt signal, and the interrupt request occurs. When setting bit 4 of interrupt interval determination control register to “1”, the interrupt request can occur at both rising and falling edges. When using the noise filter, set the minimum pulse width of the INT2 input signal to 3 cycles or more of the sample clock. Note: In the low-speed mode (CM7 = 1), the interrupt interval determination function cannot operate. 8-bit binary up counter Counter overflow interrupt request or remote control interrupt request Interrupt interval determination register address 003016 One-sided/both-sided detection selection bit Noise filter sampling clock selection bit 1/128 1/32 1/64 Data bus Divider f(XIN) Fig. 60 Interrupt interval determination circuit block diagram 55 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 Interrupt interval determination control register (IIDCON: address 003116) Interrupt interval determination circuit operating selection bit 0 : Stopped 1 : Operating Counter sampling clock selection bit 0 : f(XIN)/128 1 : f(XIN)/256 Noise filter sampling clock selection bits (INT2) 00 : Filter stop 01 : f(XIN)/32 10 : f(XIN)/64 11 : f(XIN)/128 One-sided/both-sided edge detection selection bit 0 : One-sided edge detection 1 : Both-sided edge detection (can be used when using a noise filter) Not used (return “0” when read) Fig. 61 Structure of interrupt interval determination control register (When IIDCON4 = “0”) Noise filter sampling clock INT2 pin Acceptance of interrupt Counter sampling clock N 8-bit binary up counter value 0 1 3 2 5 4 0 1 FF 3 2 FF N FF 6 Counter overflow interrupt request Remote control interrupt request Remote control interrupt request 1 0 6 N Interrupt interval determination register value FE 6 Fig. 62 Interrupt interval determination operation example (at rising edge active) (When IIDCON4 = “1”) Noise filter sampling clock INT2 pin Acceptance of interrupt Counter sampling clock FE N 8-bit binary up counter value 0 1 N Interrupt interval determination register value 2 0 2 N Remote control interrupt request 2 1 0 1 3 2 Remote control interrupt request 3 2 0 2 2 Remote control interrupt request Remote control interrupt request 0 FF 2 3 Fig. 63 Interrupt interval determination operation example (at both-sided edge active) 56 1 FF FF Counter overflow interrupt request 1 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER WATCHDOG TIMER “0”, the underflow signal of watchdog timer L becomes the count source. The detection time is set then to f(XIN ) = 2.1 s at 4 MHz frequency and f(XCIN) = 512 s at 32 kHz frequency. When this bit is set to “1”, the count source becomes the signal divided by 8 for f(XIN) (or divided by 16 for f(X CIN)). The detection time in this case is set to f(XIN) = 8.2 ms at 4 MHz frequency and f(XCIN) = 2 s at 32 KHz frequency. This bit is cleared to “0” after resetting. The watchdog timer gives a mean of returning to the reset status when a program cannot run on a normal loop (for example, because of a software runaway). The watchdog timer consists of an 8-bit watchdog timer L and a 12-bit watchdog timer H. Standard Operation Of Watchdog Timer When any data is not written into the watchdog timer control register (address 002B 16) after resetting, the watchdog timer is in the stop state. The watchdog timer starts to count down by writing an optional value into the watchdog timer control register (address 002B16) and an internal reset occurs at an underflow of the watchdog timer H. Accordingly, programming is usually performed so that writing to the watchdog timer control register (address 002B16) may be started before an underflow. When the watchdog timer control register (address 002B16 ) is read, the values of the high-order 6 bits of the watchdog timer H, STP instruction disable bit, and watchdog timer H count source selection bit are read. ●Operation of STP instruction disable bit Bit 6 of the watchdog timer control register (address 002B16) permits disabling the STP instruction when the watchdog timer is in operation. When this bit is “0”, the STP instruction is enabled. When this bit is “1”, the STP instruction is disabled. Once the STP instruction is executed, an internal resetting occurs. When this bit is set to “1”, it cannot be rewritten to “0” by program. This bit is cleared to “0” after resetting. ■ Note ●Initial value of watchdog timer At reset or writing to the watchdog timer control register (address 002B 16), a watchdog timer H is set to “FFF16” and a watchdog timer L to “FF16 ”. When releasing the stop mode, the watchdog timer performs its count operation even in the stop release waiting time. Be careful not to cause the watchdog timer H to underflow in the stop release waiting time, for example, by writing data in the watchdog timer control register (address 002B16) before executing the STP instruction. ●Watchdog timer H count source selection bit operation Bit 7 of the watchdog timer control register (address 002B16) permits selecting a watchdog timer H count source. When this bit is set to XCIN “FF16” is set when watchdog timer control register is written to. 1/2 “FFF16” is set when watchdog timer control register is written to. “0 ” “1 ” Internal system clock selection bit (Note) Data bus Watchdog timer L (8) 1/8 “1 ” “0 ” Watchdog timer H (12) Watchdog timer H count source selection bit XIN STP instruction disable bit STP instruction Reset circuit RESET Internal reset Note: Either high-speed, middle-speed or low-speed mode is selected by bit 7 of CPU mode register. Fig. 64 Block diagram of watchdog timer b7 b0 Watchdog timer control register (WDTCON : address 002B16) Watchdog timer H (for read-out of high-order 6 bit) STP instruction disable bit 0: STP instruction enabled 1: STP instruction disabled Watchdog timer H count source selection bit 0: Watchdog timer L underflow 1: f(XIN)/8 or f(XCIN)/16 Fig. 65 Structure of watchdog timer control register 57 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER BUZZER OUTPUT CIRCUIT The 38B4 group has a buzzer output circuit. One of 1 kHz, 2 kHz and 4 kHz (at XIN = 4.19 MHz) frequencies can be selected by the buzzer output control register (address 0EFD16). Either P4 3/B UZ01 or P20/ BUZ02/FLD 0 can be selected as a buzzer output port by the output port selection bits (b2 and b3 of address 0EFD16). The buzzer output is controlled by the buzzer output ON/OFF bit (b4). Port latch f(XIN) Divider 1/1024 1/2048 1/4096 Buzzer output Buzzer output ON/OFF bit Output port control signal Port direction register Fig. 66 Block diagram of buzzer output circuit b7 b0 Buzzer output control register (BUZCON: address 0EFD16) Output frequency selection bits (XIN = 4.19 MHz) 00 : 1 kHz (f(XIN)/4096) 01 : 2 kHz (f(XIN)/2048) 10 : 4 kHz (f(XIN)/1024) 11 : Not available Output port selection bits 00 : P20 and P43 function as ordinary ports. 01 : P43/BUZ01 functions as a buzzer output. 10 : P20/BUZ02/FLD0 functions as a buzzer output. 11 : Not available Buzzer output ON/OFF bit 0 : Buzzer output OFF (“0” output) 1 : Buzzer output ON Not used (return “0” when read) Fig. 67 Structure of buzzer output control register 58 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER RESET CIRCUIT ______ To reset the microcomputer, RESET pin should be held at an “L” ______ level for 2 µs or more. Then the RESET pin is returned to an “H” level (the power source voltage should be between 2.7 V and 5.5 V, and the oscillation should be stable), reset is released. After the reset is completed, the program starts from the address contained in address FFFD 16 (high-order byte) and address FFFC16 (low-order byte). Make sure that the reset input voltage is less than 0.5 V for V CC of 2.7 V (switching to the high-speed mode, a power source voltage must be between 4.0 V and 5.5 V). Poweron RESET Power source voltage 0V VCC Reset input voltage 0V (Note) 0.2VCC Note : Reset release voltage ; Vcc=2.7 V RESET VCC Power source voltage detection circuit Fig. 68 Reset circuit example XIN φ RESET Internal reset Address ? ? ? ? FFFC F FFD ADL Data ADH, ADL ADH SYNC XIN: about 4000 cycles Notes 1: The frequency relation of f(XIN) and f(φ) is f(XIN)=4 • f(φ). 2: The question marks (?) indicate an undefined state that depends on the previous state. Fig. 69 Reset sequence 59 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Address Register contents Address Register contents (1) Port P0 000016 (2) Port P0 direction register 000116 (3) Port P1 (33) Timer 34 mode register 002916 0016 0016 (34) Timer 56 mode register 002A16 0016 000216 0016 (35) Watchdog timer control register 002B16 3F16 (4) Port P2 000416 0016 (36) Timer X (low-order) 002C16 FF16 (5) Port P2 direction register 000516 0016 (37) Timer X (high-order) 002D16 FF16 (6) Port P3 000616 0016 (38) Timer X mode register 1 002E16 0016 (7) Port P4 000816 0016 (39) Timer X mode register 2 002F16 0016 (8) Port P4 direction register 000916 0016 003116 0016 (9) Port P5 000A16 0016 (40) Interrupt interval determination control register (41) A-D control register 003216 1016 (10) Port P5 direction register 000B16 0016 (42) Interrupt source switch register 003916 0016 (11) Port P6 000C16 0016 (43) Interrupt edge selection register 003A16 0016 (12) Port P6 direction register 000D16 0016 (44) CPU mode register 003B16 0 1 0 0 1 0 0 0 (13) Port P7 000E16 0016 (45) Interrupt request register 1 003C16 0016 (14) Port P7 direction register 000F16 0016 (46) Interrupt request register 2 003D16 0016 (15) Port P8 001016 0016 (47) Interrupt control register 1 003E16 0016 (16) Port P8 direction register 001116 0016 (48) Interrupt control register 2 003F16 0016 (17) Port P9 001216 0016 (49) Pull-up control register 1 0EF016 0016 (18) Port P9 direction register 001316 0016 (50) Pull-up control register 2 0EF116 0016 (19) UART control register 001716 8016 (51) FLDC mode register 0EF416 0016 (20) Serial I/O1 control register 1 001916 0016 (52) Tdisp time set register 0EF516 0016 (21) Serial I/O1 control register 2 001A16 0016 (53) Toff1 time set register 0EF616 FF16 (22) Serial I/O1 control register 3 001C16 0016 (54) Toff2 time set register 0EF716 FF16 (23) Serial I/O2 control register 001D16 0016 (55) Port P0FLD/port switch register 0EF916 0016 (24) Serial I/O2 status register 001E16 8016 (56) Port P2FLD/port switch register 0EFA16 0016 (25) Timer 1 002016 FF16 (57) Port P8FLD/port switch register 0EFB16 0016 (26) Timer 2 002116 0116 (58) Port P8FLD output control register 0EFC16 0016 (27) Timer 3 002216 FF16 (59) Buzzer output control register 0EFD16 0016 (28) Timer 4 002316 FF16 (60) Processor status register (29) Timer 5 002416 FF16 (61) Program counter (30) Timer 6 002516 FF16 (31) PWM control register 002616 0016 (32) Timer 12 mode register 002816 0016 0016 (PS) ✕ ✕ ✕ ✕ ✕ 1 ✕ ✕ (PCH) FFFD16 contents (PCL) FFFC16 contents ✕: Not fixed Since the initial values for other than above mentioned registers and RAM contents are indefinite at reset, they must be set. Fig. 70 Internal status at reset 60 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER CLOCK GENERATING CIRCUIT Oscillation Control The 38B4 group has two built-in oscillation circuits. An oscillation circuit can be formed by connecting a resonator between XIN and XOUT (XCIN and XCOUT). Use the circuit constants in accordance with the resonator manufacturer’s recommended values. No external resistor is needed between XIN and X OUT since a feedback resistor exists on-chip. However, an external feedback resistor is needed between X CIN and XCOUT. Immediately after power on, only the XIN oscillation circuit starts oscillating, and XCIN and XCOUT pins function as I/O ports. (1) Stop mode If the STP instruction is executed, the internal system clock stops at an “H” level, and XIN and XCIN oscillators stop. Timer 1 is set to “FF16” and timer 2 is set to “0116 ”. Either XIN divided by 8 or XCIN divided by 16 is input to timer 1 as count source, and the output of timer 1 is connected to timer 2. The bits of the timer 12 mode register are cleared to “0”. Set the interrupt enable bits of the timer 1 and timer 2 to disabled (“0”) before executing the STP instruction. Oscillator restarts when an external interrupt is received or reset, but the internal system clock is not supplied to the CPU until timer 1 underflows. This allows time for the clock circuit oscillation to stabilize. Frequency Control (1) Middle-speed mode The internal system clock is the frequency of XIN divided by 4. After reset, this mode is selected. (2) High-speed mode The internal system clock is the frequency of XIN. (3) Low-speed mode The internal system clock is the frequency of XCIN divided by 2. ■Note If you switch the mode between middle/high-speed and low-speed, stabilize both XIN and XCIN oscillations. The sufficient time is required for the sub clock to stabilize, especially immediately after power on and at returning from stop mode. When switching the mode between middle/high-speed and low-speed, set the frequency on condition that f(XIN) > 3f(XCIN). (4) Low power consumption mode The low power consumption operation can be realized by stopping the main clock XIN in low-speed mode. To stop the main clock, set bit 5 of the CPU mode register to “1”. When the main clock X IN is restarted (by setting the main clock stop bit to “0”), set enough time for oscillation to stabilize. By clearing furthermore the XCOUT drivability selection bit (b3) of CPU mode register to “0”, low power consumption operation of less than 200 µA (f(XCIN) = 32 kHz) can be realized by reducing the drivability between XCIN and X COUT. At reset or during STP instruction execution this bit is set to “1” and a strong drivability that has an easy oscillation start is set. (2) Wait mode If the WIT instruction is executed, the internal system clock stops at an “H” level. The states of X IN and XCIN are the same as the state before executing the WIT instruction. The internal system clock restarts at reset or when an interrupt is received. Since the oscillator does not stop, normal operation can be started immediately after the clock is restarted. XCIN XCOUT Rf CCIN XIN XOUT Rd CCOUT CI N COUT Fig. 71 Ceramic resonator circuit XCIN XCOUT XIN XOUT open open External oscillation circuit External oscillation circuit or external pulse VCC VCC VSS VSS Fig. 72 External clock input circuit 61 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER XCOUT XCIN “0” “1” Port XC switch bit (Note 3) 1/2 XOUT XI N Timer 2 count source selection bit (Note 2) Timer 1 count source selection bit (Note 2) Internal system clock selection bit (Notes 1, 3) “1” Low-speed mode Timer 1 “1” 1/4 1/2 “0” Timer 2 “0” “0” “1” High-speed or middle-speed mode Main clock division ratio selection bit (Note 3) Middle-speed mode “1” Timing φ (internal clock) “0” Main clock stop bit (Note 3) Q High-speed or low-speed mode S R S Q STP instruction WIT instruction R Q S R Reset Interrupt disable flag l Interrupt request Notes 1: When low-speed mode is selected, set the port Xc switch bit (b4) to “1”. 2: Refer to the structure of the timer 12 mode register. 3: Refer to the structure of the CPU mode register. Fig. 73 Clock generating circuit block diagram 62 STP instruction MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Reset C M4 CM “1” ” “1 4 C ” “1 ” “0 M 6 “1 ” ” “0 Middle-speed mode (φ =1 MHz) “0” CM7=0(4 MHz selected) CM6=0(high-speed) CM5=0(XIN oscillating) CM4=0(32 kHz stopped) “0 C ” M 4 CM “1 6 ” “0 ” High-speed mode (φ =4 MHz) C M6 “1” “0” C M7 “1” “1” C M7 “0” CM7=0(4 MHz selected) CM6=0(high-speed) CM5=0(XIN oscillating) CM4=1(32 kHz oscillating) “0” CM7=0(4 MHz selected) CM6=1(middle-speed) CM5=0(XIN oscillating) CM4=1(32 kHz oscillating) “0” “0” CM7=0(4 MHz selected) CM6=1(middle-speed) CM5=0(XIN oscillating) CM4=0(32 kHz stopped) High-speed mode (φ =4 MHz) C M4 C M6 “1” “1” Middle-speed mode (φ =1 MHz) 5 C M “0 ” ” “0 6 CM ” 1 “ “1 ” ” “0 CM CM 6 “0 ” Low-power dissipation mode (φ =16 kHz) CM7=1(32 kHz selected) CM6=1(middle-speed) CM5=1(XIN stopped) CM4=1(32 kHz oscillating) CM7=1(32 kHz selected) CM6=0(high-speed) CM5=0(XIN oscillating) CM4=1(32 kHz oscillating) 5 “1 ” Low-power dissipation mode (φ =16 kHz) C M6 “1” “0” “0” “1” ” “1 “0” C M5 “1” CM7=1(32 kHz selected) CM6=1(middle-speed) CM5=0(XIN oscillating) CM4=1(32 kHz oscillating) C M5 Low-speed mode (φ =16 kHz) C M6 “1” Low-speed mode (φ =16 kHz) “0” CM7=1(32 kHz selected) CM6=0(high-speed) CM5=1(XIN stopped) CM4=1(32 kHz oscillating) b7 b4 CPU mode register (CPUM : address 003B16) CM4 : Port Xc switch bit 0: I/O port function 1: XCIN-XCOUT oscillating function CM5 : Main clock (XIN- XOUT) stop bit 0: Oscillating 1: Stopped CM6: Main clock division ratio selection bit 0: f(XIN) (High-speed mode) 1: f(XIN)/4 (Middle-speed mode) CM7: Internal system clock selection bit 0: XIN–XOUT selected (Middle-/High-speed mode) 1: XCIN–XCOUT selected (Low-speed mode) Notes 1: Switch the mode by the allows shown between the mode blocks. (Do not switch between the mode directly without an allow.) 2: The all modes can be switched to the stop mode or the wait mode and return to the source mode when the stop mode or the wait mode is ended. 3: Timer operates in the wait mode. 4: When the stop mode is ended, a delay of approximately 1 ms occurs by Timer 1 in middle-/high-speed mode. 5: When the stop mode is ended, a delay of approximately 0.25 s occurs by Timer 1 in low-speed mode. 6: The example assumes that 4 MHz is being applied to the XIN pin and 32 kHz to the XCIN pin. φ indicates the internal system clock. Fig. 74 State transitions of system clock 63 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER NOTES ON PROGRAMMING Processor Status Register The contents of the processor status register (PS) after a reset are undefined, except for the interrupt disable flag (I) which is “1”. After a reset, initialize flags which affect program execution. In particular, it is essential to initialize the index X mode (T) and the decimal mode (D) flags because of their effect on calculations. Interrupts The contents of the interrupt request bits do not change immediately after they have been written. After writing to an interrupt request register, execute at least one instruction before performing a BBC or BBS instruction. Decimal Calculations •To calculate in decimal notation, set the decimal mode flag (D) to “1”, then execute an ADC or SBC instruction. Only the ADC and SBC instructions yield proper decimal results. After executing an ADC or SBC instruction, execute at least one instruction before executing a SEC, CLC, or CLD instruction. •In decimal mode, the values of the negative (N), overflow (V), and zero (Z) flags are invalid. Automatic Transfer Serial I/O When using the automatic transfer serial I/O mode of the serial I/O1, set an automatic transfer interval as the following. Otherwise the serial data might be incorrectly transmitted/received. •Set an automatic transfer interval for each 1-byte data transfer as the following: (1) Not using FLD controller Keep the interval for 5 cycles or more of internal system clock from clock rising of the last bit of 1-byte data. (2) Using FLD controller (a) Not using gradation display Keep the interval for 12 cycles or more of internal system clock from clock rising of the last bit of 1-byte data. (b) Using gradation display Keep the interval for 18 cycles or more of internal system clock from clock rising of the last bit of 1-byte data. A-D Converter If a value n (between 0 and 255) is written to a timer latch, the frequency division ratio is 1/(n+1). The comparator uses internal capacitors whose charge will be lost if the clock frequency is too low. Therefore, make sure that f(XIN) is at least on 250 kHz during an A-D conversion. Do not execute the STP or WIT instruction during an A-D conversion. Multiplication and Division Instructions Instruction Execution Time •The index X mode (T) and the decimal mode (D) flags do not affect the MUL and DIV instruction. •The execution of these instructions does not change the contents of the processor status register. The instruction execution time is obtained by multiplying the frequency of the internal system clock by the number of cycles needed to execute an instruction. The number of cycles required to execute an instruction is shown in the list of machine instructions. The frequency of the internal system clock is the same of the XIN frequency in high-speed mode. Timers Ports The contents of the port direction registers cannot be read. The following cannot be used: •The data transfer instruction (LDA, etc.) •The operation instruction when the index X mode flag (T) is “1” •The addressing mode which uses the value of a direction register as an index •The bit-test instruction (BBC or BBS, etc.) to a direction register •The read-modify-write instructions (ROR, CLB, or SEB, etc.) to a direction register. Use instructions such as LDM and STA, etc., to set the port direction registers. Serial I/O •Using an external clock When using an external clock, input “H” to the external clock input pin and clear the serial I/O interrupt request bit before executing serial I/O transfer and serial I/O automatic transfer. •Using an internal clock When using an internal clock, set the synchronous clock to the internal clock, then clear the serial I/O interrupt request bit before executing a serial I/O transfer and serial I/O automatic transfer. 64 At STP Instruction Release At the STP instruction release, all bits of the timer 12 mode register are cleared. The XCOUT drivability selection bit (the CPU mode register) is set to “1” (high drive) in order to start oscillating. DATA REQUIRED FOR MASK ORDERS The following are necessary when ordering a mask ROM production: (1) Mask ROM Order Confirmation Form (2) Mark Specification Form (3) Data to be written to ROM, in EPROM form (three identical copies) MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER MASK OPTION OF PULL-DOWN RESISTOR (object product: M38B4XMXH-XXXXFP) Power Dissipation Calculating Example 1 Whether built-in pull-down resistors are connected or not to highbreakdown voltage ports P20 to P27 and P80 to P83 can be specified in ordering mask ROM. The option type can be specified from among 8 types; A to G, P as shown Table 11. ●Fixed number depending on microcomputer’s standard • VOH output fall voltage of high-breakdown port 2 V (max.); | Current value | = at 18 mA • Resistor value 43 V / 900 µA = 48 kΩ (min.) • Power dissipation of internal circuit (CPU, ROM, RAM etc.) = 5 V ✕ 15 mA = 75 mW Table 11 Mask option type of pull-down resistor Option type A ($41) B ($42) C ($43) D ($44) E ($45) F ($46) G ($47) P ($50) Connective port of pull-down resistor (connected at “1” writing) Restriction P20 P2 1 P22 P23 P24 P25 P2 6 P2 7 P80 P8 1 P82 P83 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 (Note 4) Notes 1: The electrical characteristics of high-breakdown voltage ports P20 to P27 and P80 to P83 ’s built-in pull-down resistors are the same as that of high-breakdown voltage ports P00 to P0 7. 2: The absolute maximum ratings of power dissipation may be exceed owing to the number of built-in pull-down resistor. After calculating the power dissipation, specify the option type. 3: One time PROM version and EPROM version cannot be specified whether built-in pull-down resistors are connected or not likewise option type A. 4: INT 3 function and CNTR1 function cannot be used in the option type P. Power Dissipation Calculating Method ●Fixed number depending on microcomputer’s standard • VOH output fall voltage of high-breakdown port 2 V (max.); | Current value | = at 18 mA • Resistor value 43 V / 900 µA = 48 kΩ (min.) • Power dissipation of internal circuit (CPU, ROM, RAM etc.) = 5 V ✕ 15 mA = 75 mW ●Fixed number depending on use condition • Apply voltage to VEE pin: Vcc – 45 V • Timing number 17; digit number 16; segment number 20 • Ratio of Toff time corresponding Tdisp time: 1/16 • Turn ON segment number during repeat cycle: 31 • All segment number during repeat cycle: 340 (= 17 ✕ 20) • Total number of built-in resistor: for digit; 16, for segment; 20 • Digit pin current value: 18 (mA) • Segment pin current value: 3 (mA) (1) Digit pin power dissipation {18 ✕ 16 ✕ (1–1/16) ✕ 2} / 17 = 31.77 mW (2) Segment pin power dissipation {3 ✕ 31 ✕ (1–1/16) ✕ 2} / 17 = 10.26 mW (3) Pull-down resistor power dissipation (digit) (45 – 2)2 /48 ✕ (16 ✕ 16/16) ✕ (1 – 1/16) / 17 = 33.99 mW (4) Pull-down resistor power dissipation (segment) (45 – 2)2 /48 ✕ (31 ✕ 20/20) ✕ (1 – 1/16) / 17 = 65.86 mW (5) Internal circuit power dissipation (CPU, ROM, RAM etc.) = 75 mW (1) + (2)+ (3) + (4) + (5) = 217 mW DIG0 DIG1 DIG2 ●Fixed number depending on use condition • Apply voltage to VEE pin: Vcc – 45 V • Timing number a; digit number b; segment number c • Ratio of Toff time corresponding Tdisp time: 1/16 • Turn ON segment number during repeat cycle: d • All segment number during repeat cycle: e (= a ✕ c) • Total number of built-in resistor: for digit; f, for segment; g • Digit pin current value h (mA) • Segment pin current value i (mA) DIG3 DIG14 DIG15 DIG16 Timing number (1) Digit pin power dissipation {h ✕ b ✕ (1–Toff/Tdisp) ✕ voltage} / a (2) Segment pin power dissipation {i ✕ d ✕ (1–Toff/Tdisp) ✕ voltage} / a (3) Pull-down resistor power dissipation (digit) {power dissipation per 1 digit ✕ (b ✕ f / b) ✕ (1–Toff/Tdisp) } / a (4) Pull-down resistor power dissipation (segment) {power dissipation per 1 segment ✕ (d ✕ g / c) ✕ (1–Toff/Tdisp) } / a (5) Internal circuit power dissipation (CPU, ROM, RAM etc.) = 75 mW 1 2 3 14 15 16 17 Repeat cycle Tscan Fig. 75 Digit timing waveform (1) (1) + (2)+ (3) + (4) + (5) = X mW 65 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Power Dissipation Calculating Example 2 (when 2 or more digit is turned ON at same time) ●Fixed number depending on microcomputer’s standard • VOH output fall voltage of high-breakdown port 2 V (max.); | Current value | = at 18 mA • Resistor value 43 V / 900 µA = 48 kΩ (min.) • Power dissipation of internal circuit (CPU, ROM, RAM etc.) = 5 V ✕ 15 mA = 75 mW ●Fixed number depending on use condition • Apply voltage to VEE pin: Vcc – 45 V • Timing number 11; digit number 12; segment number 24 • Ratio of Toff time corresponding Tdisp time: 1/16 • Turn ON segment number during repeat cycle: 114 • All segment number during repeat cycle: 264 (= 11 ✕ 24) • Total number of built-in resistor: for digit; 10, for segment; 22 • Digit pin current value: 18 (mA) • Segment pin current value: 3 (mA) (1) Digit pin power dissipation {18 ✕ 12 ✕ (1–1/16) ✕ 2} / 11 = 36.82 mW (2) Segment pin power dissipation {3 ✕ 114 ✕ (1–1/16) ✕ 2} / 11 = 58.30 mW (3) Pull-down resistor power dissipation (digit) (45 – 2)2 /48 ✕ (12 ✕ 10/12) ✕ (1 – 1/16) / 11 = 32.84 mW (4) Pull-down resistor power dissipation (segment) (45 – 2)2 /48 ✕ (114 ✕ 22/24) ✕ (1 – 1/16) / 11 = 343.08 mW (5) Internal circuit power dissipation (CPU, ROM, RAM etc.) = 75 mW (1) + (2)+ (3) + (4) + (5) = 547 mW DIG0 DIG1 DIG2 DIG3 DIG4 DIG5 DIG6 DIG7 DIG8 DIG9 Timing number 1 2 3 4 5 6 7 8 9 10 11 Repeat cycle Tscan Fig. 76 Digit timing waveform (2) 66 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ABSOLUTE MAXIMUM RATINGS Table 12 Absolute maximum ratings Parameter Symbol VCC VEE Pull-down power source voltage VI Input voltage P47, P50–P5 7, P6 1–P65, P7 0– P77, P84–P8 7, P90 , P91 VI Input voltage P40–P46, P6 0 VI VI Conditions Power source voltage Input voltage Input voltage P00–P07, P2 0–P2 7, P80–P8 3 RESET, XIN All voltages are based on VSS. Output transistors are cut off. Ratings Unit –0.3 to 6.5 V VCC – 45 to V CC +0.3 (Note 1) V VCC – 42 to V CC +0.3 (Note 2) V –0.3 to VCC +0.3 V –0.3 to 13 V VCC – 45 to V CC +0.3 (Note 1) V VCC – 42 to V CC +0.3 (Note 2) V –0.3 to VCC +0.3 V –0.3 to VCC +0.3 V VI Input voltage XCIN VO Output voltage P00–P07, P1 0–P17 , P20–P2 7, VCC – 45 to V CC +0.3 (Note 1) V P30–P37, P8 0–P8 3 VCC – 42 to V CC +0.3 (Note 2) V –0.3 to VCC +0.3 V VO Output voltage P50–P57, P6 1–P65 , P70–P7 7, P84–P87, P9 0, P91 , XOUT, XCOUT VO Output voltage P40–P46, P6 0 Pd Power dissipation –0.3 to 13 V Ta = –20 to 65 °C 800 mW Ta = 65 to 85 °C 800 – 12.5 ✕ (Ta – 65) mW Topr Operating temperature –20 to 85 °C Tstg Storage temperature –40 to 125 °C Notes 1: When Vcc is 4.0 to 5.5 V. 2: When Vcc is 2.7 to 4.0 V. 67 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER RECOMMENDED OPERATING CONDITIONS Table 13 Recommended operating conditions (1) (Vcc = 2.7 to 5.5 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol VCC Parameter Power source voltage In high-speed mode In middle-/low-speed mode, 2 MHz or less in high-speed mode VSS VEE VIH VIH Power source voltage Pull-down power source voltage VCC = 4.0 to 5.5 V VCC = 2.7 to 4.0 V Analog reference voltage (when A-D conver ter is used) Analog power source voltage Analog input voltage AN0–AN11 “H” input voltage P40 –P47, P50–P57 , P60–P65, VCC = 4.0 to 5.5 V P70 –P77, P90, P91 VCC = 2.7 to 4.0 V “H” input voltage P84 –P87 VCC = 4.0 to 5.5 V VCC = 2.7 to 4.0 V “H” input voltage P00 –P07 “H” input voltage P20 –P27, P80–P83 VCC = 4.0 to 5.5 V VIH VIH VIL “H” input voltage “H” input voltage “L” input voltage VIL VIL VIL VIL “L” input voltage “L” input voltage “L” input voltage “L” input voltage VREF AVSS VIA VIH VIH 68 VCC = 2.7 to 4.0 V RESET XIN, X CIN P40 –P47, P50–P57 , P60–P65, VCC = 4.0 to 5.5 V P70 –P77, P90, P91 VCC = 2.7 to 4.0 V P84 –P87 P00 –P07, P20–P27, P8 0–P83 RESET XIN, X CIN Min. 4.0 2.7 Limits Typ. 5.0 5.0 0 VCC–43 VCC–40 2.0 Max. 5.5 5.5 VCC VCC VCC 0 0 0.75V CC 0.8V CC 0.4V CC 0.5Vcc 0.8V CC 0.52V CC 0.75V CC 0.8V CC 0.8V CC 0 0 0 0 0 0 VCC VCC VCC VCC Vcc VCC VCC VCC VCC VCC 0.25V CC 0.2VCC 0.16V CC 0.2VCC 0.2VCC 0.2VCC Unit V V V V V V V V V V V V V V V V V V V V V V V MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 14 Recommended operating conditions (2) (Vcc = 2.7 to 5.5 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol ΣI OH(peak) Parameter f(CNTR 0) f(CNTR 1) f(XIN ) H” total peak output current (Note 1) P00 –P07, P10–P17, P2 0–P27, P30–P37 , P80–P83 “H” total peak output current (Note 1) P50 –P57, P61–P65, P7 0–P77, P90, P9 1 “L” total peak output current (Note 1) P50 –P57, P60–P65, P7 0–P77, P90, P9 1 “L” total peak output current (Note 1) P40 –P46, P84–P87 “H” total average output current (Note 1) P00 –P07, P10–P17, P2 0–P27, P30–P37 , P80–P87 “H” total average output current (Note 1) P50 –P57, P61–P65, P7 0–P77, P90, P9 1 “L” total average output current (Note 1) P50 –P57, P60–P65, P7 0–P77, P90, P9 1 “L” total average output current (Note 1) P40 –P46, P84–P87 “H” peak output current (Note 2) P00 –P07, P10–P17, P2 0–P27, P30–P37 , P80–P83 “H” peak output current (Note 2) P50 –P57, P61–P65, P7 0–P77, P84–P87 , P90, P91 “L” peak output current (Note 2) P50 –P57, P61–P65, P7 0–P77, P84–P87 , P90, P91 “L” peak output current (Note 2) P40 –P46, P60 “H” average output current (Note 3) P00 –P07, P10–P17, P2 0–P27, P30–P37 , P80–P83 “H” average output current (Note 3) P50 –P57, P60–P65, P7 0–P77, P84–P87 , P90, P91 “L” average output current (Note 3) P50 –P57, P61–P65, P7 0–P77, P84–P87 , P90, P91 “L” average output current (Note 3) P40 –P46, P60 Clock input frequency for timers 2, 4, and X (duty cycle 50 %) Main clock input oscillation frequency (Note 4) f(XCIN ) Sub-clock input oscillation frequency (Notes 4, 5) ΣI OH(peak) ΣI OL(peak) ΣI OL(peak) ΣI OH(avg) ΣI OH(avg) ΣI OL(avg) ΣI OL(avg) I OH(peak) I OH(peak) I OL(peak) I OL(peak) I OH(avg) I OH(avg) I OL(avg) I OL(avg) Min. VCC VCC VCC VCC Limits Typ. = 4.0 to 5.5 V = 2.7 to 4.0 V = 4.0 to 5.5 V = 2.7 to 4.0 V 32.768 Max. –240 Unit mA –60 mA 100 mA 60 mA –120 mA –30 mA 50 mA 30 mA –40 mA –10 mA 10 mA 30 mA –18 mA –5 mA 5 mA 15 mA 250 100 4.2 2 50 kHz kHz MHz MHz kHz Notes 1: The total output current is the sum of all the currents flowing through all the applicable ports. The total average current is an average value measured over 100 ms. The total peak current is the peak value of all the currents. 2: The peak output current is the peak current flowing in each port. 3: The average output current IOL (avg), IOH (avg) in an average value measured over 100 ms. 4: When the oscillation frequency has a duty cycle of 50%. 5: When using the microcomputer in low-speed mode, set the sub-clock input oscillation frequency on condition that f(XCIN ) < f(XIN)/3. 69 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ELECTRICAL CHARACTERISTICS Table 15 Electrical characteristics (1) (VCC = 2.7 to 5.5 V, Ta = –20 to 85 °C, unless otherwise noted) Parameter Symbol VOH VOH VOL VOL VT+ –VT– VT+ –VT– VT+ –VT– I IH I IH I IH I IH I IH I IL I IL VCC = 4.0 to 5.5 V VCC = 2.7 to 4.0 V VCC = 4.0 to 5.5 V “H” output voltage VCC = 2.7 to 4.0 V VCC = 4.0 to 5.5 V “L” output voltage VCC = 2.7 to 4.0 V VCC = 4.0 to 5.5 V “L” output voltage VCC = 2.7 to 4.0 V Hysteresis P40 –P42, P45–P47, P5, P6 0, P61,P6 4 (Note 1) Hysteresis RESET, XIN Hysteresis XCIN “H” input current P47, P50 –P57, P61–P65, P7 0–P77, P84–P87 “H” input current P40–P46, P6 0 “H” input current P00–P07 , P20–P27, P80 –P83 (Note 2) “H” input current RESET, X CIN “H” input current XIN “L” input current P40–P47, P6 0 “L” input current P50–P57 , P61–P65, P70 –P77 , P84–P87, P90 , P91 “H” output voltage P00–P07, P1 0–P17, P20– P27, P30 –P37, P80–P83 P50–P57, P6 0–P65, P70– P77, P84 –P87, P90, P91 P50–P57, P6 1–P65, P84– P87, P90, P91 P40–P46, P6 0 Test conditions IOH = –18 mA IOH = –10 mA IOH = –10 mA IOH = –10 mA IOL = 10 mA IOL = 1.6 mA IOL = 15 mA IOL = 5 mA VI = V CC VI = 12 V VI = V CC VI = V CC VI = V CC VI = V SS VI = V SS Pull-up “off” VCC = 5 V, VI = VSS Pull-up “on” VCC = 3 V, VI = VSS Pull-up “on” VI = V SS I IL “L” input current P00–P07 , P20–P27, P80 –P83 (Note 2) VI = V SS I IL “L” input current RESET, X CIN VI = V SS I IL “L” input current XIN VEE = VCC–43 V, RPULLD Pull-down resistor P00–P07 , P10–P17, P30–P37 VOL =VCC (P2 0–P27, P80–P83 at option) Output transistors “off” VEE = VCC–43 V, I LEAK Output leak current P00–P07 , P10–P17, P20–P27 , P30–P37, VOL =VCC–43 V P80–P83 Output transistors “off” VI = 5 V I READH “H” read current P00–P07 , P20–P27, P80–P83 When clock is stopped VRAM RAM hold voltage Notes 1: P42, P45 , P46, and P60 of the mask option type P do not have hysteresis characteristics. 2: Except when reading ports P0, P2, or P8. 70 Limits Min. VCC–2.0 VCC–1.5 VCC–2.0 VCC–1.0 Typ. 0.6 0.3 0.4 0.5 0.5 Max. 2.0 0.4 2.0 1.0 5.0 10.0 5.0 5.0 4.0 –5.0 –5.0 µA –25 µA –4.0 72 47 µA µA µA kΩ –10 µA Vcc µA V 1 2 V V V V V V V V V V µA µA µA µA µA µA µA µA –70 –5.0 –5.0 143 Unit MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 16 Electrical characteristics (2) (V CC =2.7 to 5.5 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Power source current ICC Limits Test conditions Min. High-speed mode f(X IN) = 4.2 MHz f(X CIN) = 32 kHz Output transistors “off” Typ. Max. Unit 7.5 mA High-speed mode f(X IN) = 4.2 MHz (in WIT state) f(X CIN) = 32 kHz Output transistors “off” 1 mA Middle-speed mode f(X IN) = 4.2 MHz f(X CIN) = stopped Output transistors “off” 3 mA Middle-speed mode f(X IN) = 4.2 MHz (in WIT state) f(X CIN) = stopped Output transistors “off” 1 mA Low-speed mode f(X IN) = stopped f(X CIN) = 32 kHz Low-power dissipation mode (CM 3 = 0) Output transistors “off” 60 µA Low-speed mode f(X IN) = stopped f(X CIN) = 32 kHz (in WIT state) Low-power dissipation mode (CM 3 = 0) Output transistors “off” 20 µA Increment when A-D conversion is executed 0.6 mA All oscillation stopped (in STP state) Output transistors “off” 0.1 Ta = 25 °C Ta = 85 °C 1 µA 10 µA A-D converter characteristics Table 17 A-D converter characteristics (1) (V CC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, f(XIN ) = 250 kHz to 4.2 MHz in high-speed mode, unless otherwise noted) Symbol Parameter — Resolution — Absolute accuracy (excluding quantization error) Test conditions Min. VCC = VREF = 5.12 V Limits Typ. Max. 10 Bits ±1 ±2.5 LSB 62 tc(φ) 150 200 µA 5.0 µA TCONV Conversion time 61 IVREF Reference input current IIA Analog port input current 0.5 RLADDER Ladder resistor 35 VREF = 5.0 V 50 Unit kΩ Table 18 A-D converter characteristics (2) (V CC = 2.7 to 4.0 V, VSS = 0 V, Ta = –20 to 85 °C, f(X IN) = 250 kHz to 2 MHz in high-speed mode, unless otherwise noted) Symbol Parameter — Resolution — Absolute accuracy (excluding quantization error) Test conditions Limits Min. VCC = VREF = 3.3 V Typ. 10 Bits ±6 LSB 62 tc(φ) 95 120 µA 5.0 µA Conversion time IVREF Reference input current IIA Analog port input current 0.5 RLADDER Ladder resistor 35 61 30 Unit ±3 TCONV VREF = 3.3 V Max. kΩ 71 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER TIMING REQUIREMENTS Table 19 Timing requirements (1) (VCC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter ____________ Limits Min. Typ. Max. Unit tW (RESET) Reset input “L” pulse width 2.0 µs tC (XIN) Main clock input cycle time (XIN input) 238 ns tWH (XIN) Main clock input “H” pulse width 60 ns tWL (XIN) Main clock input “L” pulse width 60 ns tC (XCIN) Sub-clock input cycle time (XCIN input) 20 µs tWH (XCIN) Sub-clock input “H” pulse width 5.0 µs tWL (XCIN) Sub-clock input “L” pulse width 5.0 µs tC (CNTR) CNTR0, CNTR 1 input cycle time 4.0 µs tWH (CNTR) CNTR0, CNTR 1 input “H” pulse width 1.6 µs tWL (CNTR) CNTR0, CNTR 1 input “L” pulse width 1.6 µs tWH (INT) INT0 to INT4 input “H” pulse width 80 ns tWL (INT) INT0 to INT4 input “L” pulse width 80 ns tC (SCLK) Serial I/O clock input cycle time 0.95 µs tWH (SCLK) Serial I/O clock input “H” pulse width 400 ns tWL (SCLK) Serial I/O clock input “L” pulse width 400 ns tsu (SCLK–SIN) Serial I/O input set up time 200 ns th (SCLK–SIN) Serial I/O input hold time 200 ns Table 20 Timing requirements (2) (VCC = 2.7 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter ____________ Limits Min. Typ. Max. Unit tW (RESET) Reset input “L” pulse width 2.0 µs tC (XIN) Main clock input cycle time (XIN input) 500 ns tWH (XIN) Main clock input “H” pulse width 120 ns tWL (XIN) Main clock input “L” pulse width 120 ns tC (XCIN) Sub-clock input cycle time (X CIN input) 20 µs tWH (XCIN) Sub-clock input “H” pulse width 5.0 µs tWL (XCIN) Sub-clock input “L” pulse width 5.0 µs tC (CNTR) CNTR 0, CNTR1 input cycle time 10 µs tWH (CNTR) CNTR 0, CNTR1 input “H” pulse width 4.0 µs tWL (CNTR) CNTR 0, CNTR1 input “L” pulse width 4.0 µs tWH (INT) INT0 to INT4 input “H” pulse width 230 ns tWL (INT) INT0 to INT4 input “L” pulse width 230 ns tC (SCLK) Serial I/O clock input cycle time 2.0 µs tWH (SCLK) Serial I/O clock input “H” pulse width 950 ns tWL (SCLK) Serial I/O clock input “L” pulse width 950 ns tsu (SCLK–SIN) Serial I/O input set up time 400 ns th (SCLK–SIN) Serial I/O input hold time 300 ns 72 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER SWITCHING CHARACTERISTICS Table 21 Switching characteristics (1) (V CC = 4.0 to 5.5 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Test conditions Limits Min. Typ. Max. Unit tWH(SCLK) Serial I/O clock output “H” pulse width CL = 100 pF tC(SCLK)/2–160 tWL(SCLK) Serial I/O clock output “L” pulse width CL = 100 pF tC(SCLK)/2–160 ns td(SCLK–SOUT) Serial I/O output delay time tv (SCLK–SOUT) Serial I/O output valid time tr(SCLK) Serial I/O clock output rising time CL = 100 pF 40 ns tf(SCLK) Serial I/O clock output falling time CL = 100 pF 40 ns tr(Pch–strg) P-channel high-breakdown voltage output rising time (Note 1) CL = 100 pF VEE = V CC–43 V 55 ns tr(Pch–weak) P-channel high-breakdown voltage output rising time (Note 2) CL = 100 pF VEE = V CC–43 V 1.8 µs ns 0.2 tc 0 ns ns Notes 1: When bit 7 of the FLDC mode register (address 0EF416) is at “0”. 2: When bit 7 of the FLDC mode register (address 0EF416) is at “1”. Table 22 Switching characteristics (2) (V CC = 2.7 to 4.0 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Test conditions Limits Min. tWH(SCLK) Serial I/O clock output “H” pulse width CL = 100 pF tC(SCLK)/2–240 tWL(SCLK) Serial I/O clock output “L” pulse width CL = 100 pF tC(SCLK)/2–240 td(SCLK–SOUT) Serial I/O output delay time tv (SCLK–SOUT) Serial I/O output valid time Typ. Max. Unit ns ns 0.4 tc 0 ns ns tr(SCLK) Serial I/O clock output rising time CL = 100 pF 60 ns tf(SCLK) Serial I/O clock output falling time CL = 100 pF 60 ns tr(Pch–strg) P-channel high-breakdown voltage output rising time (Note 1) CL = 100 pF VEE = V CC–40 V 140 ns tr(Pch–weak) P-channel high-breakdown voltage output rising time (Note 2) CL = 100 pF VEE = V CC–40 V 3.6 µs Notes 1: When bit 7 of the FLDC mode register (address 0EF416) is at “0”. 2: When bit 7 of the FLDC mode register (address 0EF416) is at “1”. 73 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Serial I/O clock output port P52/SCLK11, P53/SCLK12, P56/SCLK21, P57/SCLK22 CL P0,P1,P2, P3,P80–P83 High-breakdown P-channel opendrain output port CL (Note) VEE Note: Ports P2 and P8 need external resistors. Fig. 77 Circuit for measuring output switching characteristics 74 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Timing Diagram tC(CNTR) tWL(CNTR) tWH(CNTR) CNTR0,CNTR1 0.8VCC 0.2VCC tWL(INT) tWH(INT) INT0–INT4 0.8VCC 0.2VCC tW(RESET) RESET 0.8VCC 0.2VCC tC(XIN) tWL(XIN) tWH(XIN) XI N 0.8VCC 0.2VCC tC(XCIN) tWL(XCIN) tWH(XCIN) XCIN 0.8VCC 0.2VCC tC(SCLK) tf(SCLK) SCLK tWL(SCLK) tr tWH(SCLK) 0.8VCC 0.2VCC tsu(SIN-SCLK) th(SCLK-SIN) 0.8VCC 0.2VCC SI N td(SCLK-SOUT) tv(SCLK-SOUT) SOUT Fig. 78 Timing diagram 75 MITSUBISHI MICROCOMPUTERS 38B4 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PACKAGE OUTLINE 80P6N-A Plastic 80pin 14✕20mm body QFP EIAJ Package Code QFP80-P-1420-0.80 Weight(g) 1.58 Lead Material Alloy 42 MD e JEDEC Code – 80 ME HD D b2 65 1 64 I2 24 Symbol HE E Recommended Mount Pad 41 A 40 25 c A2 L1 A A1 A2 b c D E e HD HE L L1 x y y 76 b x M A1 F e L Detail F b2 I2 MD ME 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 19.8 20.0 20.2 0.8 – – 16.5 16.8 17.1 22.5 22.8 23.1 0.4 0.6 0.8 1.4 – – – – 0.2 0.1 – – 0° 10° – – – 0.5 1.3 – – 14.6 – – – – 20.6 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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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 • • • • • • • © 2000 MITSUBISHI ELECTRIC CORP. New publication, effective MAY 2000. Specifications subject to change without notice. REVISION DESCRIPTION LIST Rev. No. 1.0 38B4 GROUP DATA SHEET Revision Description First Edition Rev. date 000510 (1/1)