MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER DESCRIPTION • LED direct drive port ................................................................... 4 • Clock generating circuit The 38K0 group is the 8-bit microcomputer based on the 740 family core technology. The 38K0 group has the USB function, an 8-bit bus interface, a Serial I/O, three 8-bit timers, and an 8-channel 10-bit A-D converter, which are available for the PC peripheral I/O device. The various microcomputers in the 38K0 group include variations of internal memory size and packaging. For details, refer to the section on part numbering. (connect to external ceramic resonator or quartz-crystal oscillator) Power source voltage System clock/Internal clock division mode At 12 MHz/Through mode (φ = 12 MHz) ...................................... ......................................................... 4.50 to 5.25 V (under planning) At 12 MHz/2-divide mode(φ = 6 MHz) .......................................... ............................................. 4.00 to 5.25 V (under development) At 8 MHz/Through mode (φ = 8 MHz) ................... 4.00 to 5.25 V At 6 MHz/Through mode (φ = 6 MHz) ................... 4.00 to 5.25 V At 6 MHz/Through mode (φ = 6 MHz) .......................................... ............................................. 3.00 to 4.00 V (under development) Remarks: The mode under development will be available from Aug./2002. Power dissipation At 5 V power source voltage .................................. 125 mW (typ.) (at 8 MHz system clock, in through mode) At 3.3 V power source voltage ................................ 45 mW (typ.) (at 6 MHz system clock, in through mode) Operating temperature range .................................... –20 to 85°C Packages FP ........................................ 64P6U-A (64-pin 14 ✕ 14 mm LQFP) HP ........................................ 64P6Q-A (64-pin 10 ✕ 10 mm LQFP) • FEATURES • Basic machine-language instructions ....................................... 71 • The minimum instruction execution time .......................... 0.25 µs (at 8 MHz system clock✻) Reference frequency to internal circuit except USB function • • Memory size • • ■Notes 33 34 35 36 37 38 39 41 40 42 43 44 45 49 32 50 31 51 30 52 29 53 28 27 54 55 56 57 58 M38K07M4-XXXFP/HP M38K09F8FP/HP 26 25 24 23 15 16 P60(LED0) 14 13 12 11 10 P12/DQ2/AN2 P13/DQ3/AN3 P14/DQ4/AN4 P15/DQ5/AN5 P16/DQ6/AN6 P17/DQ7/AN7 CNVSS RESET VCCE VREF VSS XIN XOUT VCC CNVSS2 17 9 18 64 8 19 63 7 20 62 6 21 61 5 22 60 3 59 1 P 06 P 07 P40/EXDREQ/RXD P41/EXDACK/TXD P42/EXTC/SCLK P43/EXA1/SRDY P 30 P 31 P 32 P33/EXINT P34/EXCS P35/EXWR P36/EXRD P37/EXA0 P10/DQ0/AN0 P11/DQ1/AN1 46 48 PIN CONFIGURATION (TOP VIEW) 47 P05 P04 P03 P02 P01 P00 P57 P56 P55 P54 P53 P52/INT1 P51/CNTR P50/INT0 P27 P26 1. The specifications of this product are subject to change because it is under development. Inquire the use of Mitsubishi Electric Corporation. 2. The flash memory version cannot be used for application embedded in the MCU card. 2 • • • • • • • • • ROM ................................................................ 16 K to 32 K bytes RAM ............................................................... 1024 to 2048 bytes Programmable input/output ports ............................................. 48 Software pull-up resistors Interrupts .................................................. 15 sources, 15 vectors USB function (USB version 1.1 specification) ........... 4 endpoints External bus interface ....................................... 8-bit ✕ 1 channel Timers ............................................................................. 8-bit ✕ 3 Watchdog timer ............................................................. 16-bit ✕ 1 Serial I/O ...................... 8-bit ✕ 1 (UART or Clock-synchronized) A-D converter ................................................ 10-bit ✕ 8 channels (8-bit reading available) 4 System clock✻: P25 P24 P23 P22 P21 P20 D0D0+ TrON USBVREF DVCC PVCC PVSS P63(LED3) P62(LED2) P61(LED1) Package type : 64P6U-A/64P6Q-A Fig. 1 Pin configuration of 38K0 group 1 12 13 P6 (4) 35 36 37 38 39 40 41 42 INT1 INT0 RAM P5 (8) Watchdog timer Clock generating circuit 21 16 17 18 19 20 PVSS PVCC XIN XOUT 51 52 53 54 P4 (4) SI/O RAM I/F 9 VCCE 14 VCC P3 (8) 55 56 57 58 59 60 61 62 EXTBUS (8) ROM Data bus 11 VSS 23 24 USB CPU 25 26 DVCC TrON D0USBVREF D0+ 22 FUNCTIONAL BLOCK DIAGRAM (Package : 64P6U-A/64P6Q-A) 27 28 29 30 31 32 33 34 P2 (8) 8 RESET VREF 10 P1 (8) 63 64 1 2 3 4 5 6 10-bit A-D converter (8) CNTR0 Timer X (8) Timer 2 (8) P0(8) 43 44 45 46 47 48 49 50 15 7 Timer 1 (8) CNVSS2 CNVSS MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Fig. 2 Functional block diagram 2 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PIN DESCRIPTION Table 1. Pin description Pin VCC, VSS VCCE CNVSS CNVSS2 VREF Name Power source Analog power source CNVSS DVCC PVCC, PVSS RESET XIN CNVSS2 Analog reference voltage input Analog power source Reset input Clock input XOUT Clock output USBVREF USB reference power source TrON USB reference voltage output USB upstream I/O D0+, D0- P00–P07 I/O port P0 P10/DQ0/AN0– I/O port P1 P17/DQ7/AN7 P20–P27 I/O port P2 P30–P32 I/O port P3 P33/ExINT P34/ExCS P35/ExWR P36/ExRD P37/ExA0 P40/ExDREQ/RxD I/O port P4 P41/ExDACK/TxD P42/ExTC/SCLK P43/ExA1/SRDY P50/INT0 P51/CNTR0 P52/INT1 P53–P57 P60–P63 I/O port P5 I/O port P6 Function Function except a port function • Apply voltage of 3.0 V – 5.25 V to VCC, and 0 V to VSS. • Power source pin for ports P1, P3, P4 and analog circuit. Connect this pin to VCC. • This pin controls the operation mode of the chip. Connect this pin to VSS. In the flash memory mode, this pin becoems VPP power source input pin. • This pin controls the operation mode of the chip. Connect this pin to VSS. • Reference voltage input pin for A-D converter. • Power source pin for analog circuit. • Connect the DVCC and PVCC pins to VCC, and the PVSS pin to VSS. • Reset input pin for active “L” • Input and output pins for the main clock generating circuit. • Connect a ceramic resonator or a quartz-crystal oscillator between the XIN and XOUT pins to set the oscillation frequency. •If an external clock is used, connect the clock source to the XIN pin and leave the XOUT pin open. • Power source pin for USB port circuit. In Vcc = 4.00 to 5.25 V use the built-in USB reference voltage circuit. In Vcc = 3.00 to 4.00 V apply 3.3 V power supply from the external because use of the built-in USB reference voltage circuit is prohibited in this voltage range. In Vcc = 3.00 to 3.60 V connect this pin to VCC. • Output pin to pull-up D0+ by 1.5 kΩ external resistor. • USB upstream I/O port • USB input level • USB output level output structure • 8-bit I/O port • Key input pins (key-on wake up interrupt) • I/O direction register allows each pin to be individually programmed as either input or output. • CMOS compatible input level • CMOS 3-state output structure • Pull-up control is enabled. • 8-bit I/O port • A-D converter input pins • I/O direction register allows each pin to be individually • External bus interface function pins programmed as either input or output. • CMOS compatible input level • CMOS 3-state output structure • 8-bit I/O port • I/O direction register allows each pin to be individually programmed as either input or output. • CMOS compatible input level • CMOS 3-state output structure • 8-bit I/O port • I/O direction register allows each pin to be individually • External bus interface function pins programmed as either input or output. • CMOS compatible input level • CMOS 3-state output structure • 4-bit I/O port • Serial I/O function pins • I/O direction register allows each pin to be individually • External bus interface function pins programmed as either input or output. • CMOS compatible input level • CMOS 3-state output structure • 8-bit I/O port • Interrupt input pin • I/O direction register allows each pin to be individually • Timer X funciton pin programmed as either input or output. • Interrupt input pin • CMOS compatible input level • CMOS 3-state output structure • 4-bit I/O port • I/O direction register allows each pin to be individually programmed as either input or output. • CMOS compatible input level • CMOS 3-state output structure • Output large current for LED drive is enabled. 3 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PART NUMBERING Product M38K0 7 M 4 - XXX FP Package type FP : 64P6U-A package HP : 64P6Q-A package ROM number Omitted in the flash memory version. – : Standard Omitted in the flash memory version. ROM/PROM 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 as a user’s ROM area. However, they can be programmed or erased in the flash memory version, so that users can use them. Memory type M : Mask ROM version F : Flash memory 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 4 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER GROUP EXPANSION Packages Mitsubishi plans to expand the 38K0 group as follows. 64P6U-A .................................. 0.8 mm-pitch plastic molded LQFP 64P6Q-A .................................. 0.5 mm-pitch plastic molded LQFP 100D0M ........................... 0.65 mm-pitch metal seal PIGGY BACK Memory Type Support for mask ROM and flash memory versions. Memory Size Flash memory size .......................................................... 32 Kbytes Mask ROM size ............................................................... 16 Kbytes RAM size .......................................................... 1024 to 2048 bytes Memory Expansion Plan : Under development ROM size (bytes) 60K M38K09F8 32K M38K07M4 16K 8K 256 512 1,024 2,048 RAM size (bytes) Products under development or planning: the development schedule and specification may be revised without notice. The development of planning products may be stopped. Fig. 4 Memory expansion plan Currently products are listed below. As of February 2002 Table 2. List of products Product M38K07M4-XXXFP M38K07M4-XXXHP M38K09F8FP M38K09F8HP M38K09RFS ROM size (bytes) ROM size for User in ( ) RAM size (bytes) 16384 (16254) 1024 32768 (32638) 2048 — 2048 Package 64P6U-A 64P6Q-A 64P6U-A 64P6Q-A 100D0M Remarks Mask ROM version Flash memory version Emulator MCU (for program evaluation) 5 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FUNCTIONAL DESCRIPTION CENTRAL PROCESSING UNIT (CPU) [Stack Pointer (S)] [Accumulator (A)] 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”. Figure 6 shows the store and the return movement into the stack. If there are registers other than those described in Figure 5, the users need to store them with the program. The accumulator is an 8-bit register. Data operations such as data transfer, etc., are executed mainly through the accumulator. [Program Counter (PC)] The 38K0 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 instruction cannot be used. The STP, WIT, MUL, and DIV instruction can be used. The CPU has the 6 registers. The register structure is shown in Figure 5. The program counter is a 16-bit counter consisting of two 8-bit registers PCH and PCL. It is used to indicate the address of the next instruction to be executed. [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. [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 PCH Stack pointer b0 Program counter PCL b7 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 6 MITSUBISHI MICROCOMPUTERS 38K0 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 3 Push and pop instructions of accumulator or processor status register Push instruction to stack Pop instruction from stack Accumulator PHA PLA Processor status register PHP PLP 7 MITSUBISHI MICROCOMPUTERS 38K0 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 •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 4 Set and clear instructions of each bit of processor status register C flag Z flag I flag D flag B flag T flag V flag N flag Set instruction SEC – SEI SED – SET – – Clear instruction CLC – CLI CLD – CLT CLV – 8 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [CPU Mode Register (CPUM)] 003B16 The CPU mode register contains the stack page selection bit and the internal system clock selection bit. The CPU mode register is allocated at address 003B16. b7 b0 0 1 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 : 0 page 1 : 1 page Not used (returns “1” when read) (Do not write “0” to this bit) Not used (returns “0” when read) (Do not write “1” to this bit) System clock selection bit 0 : Main clock (XIN) 1 : fSYN System clock division ratio selection bits b7 b6 0 0 : φ = f(system clock)/8 (8-divide mode) 0 1 : φ = f(system clock)/4 (4-divide mode) 1 0 : φ = f(system clock)/2 (2-divide mode) 1 1 : φ = f(system clock) (Through mode) Fig. 7 Structure of CPU mode register 9 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER MEMORY Special Function Register (SFR) Area The Special Function Register 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. ROM The first 128 bytes and the last 2 bytes of ROM are reserved for device testing and the rest is user area for storing programs. In the flash memory version, program and erase can be performed in the reserved area. Interrupt Vector Area The interrupt vector area contains reset and interrupt vectors. Zero Page The 256 bytes from addresses 000016 to 00FF 16 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 The 256 bytes from addresses FF0016 to FFFF16 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. RAM area RAM size (bytes) 000016 Address XXXX16 192 00FF16 256 013F16 384 01BF16 512 023F16 640 02BF16 768 033F16 896 03BF16 1024 043F16 1536 063F16 2048 083F16 SFR area Zero page 004016 010016 RAM XXXX16 Not used 0FE016 0FFF16 SFR area ROM area ROM size (bytes) Address YYYY16 Address ZZZZ16 4096 F00016 F08016 YYYY16 Reserved ROM area (128 bytes) 8192 E00016 E08016 12288 D00016 D08016 16384 C00016 C08016 20480 B00016 B08016 24576 A00016 A08016 28672 900016 908016 32768 800016 808016 36864 700016 708016 40960 600016 608016 45056 500016 508016 49152 400016 408016 53248 300016 308016 FFFE16 57344 200016 208016 FFFF16 61440 100016 108016 ZZZZ16 ROM FF0016 FFDC16 Interrupt vector area Special page Reserved ROM area Fig. 8 Memory map diagram 10 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER 000016 Port P0 (P0) 000116 Port P0 direction register (P0D) 000216 Port P1 (P1) 002016 Prescaler 12 (PRE12) 002116 Timer 1 (T1) 002216 Timer 2 (T2) 000316 Port P1 direction register (P1D) 000416 Port P2 (P2) 000516 Port P2 direction register (P2D) 000616 Port P3 (P3) 000716 Port P3 direction register (P3D) 002316 Timer X mode register (TM) 002416 Prescaler X (PREX) 002516 Timer X (TX) 002616 Transmit/Receive buffer register (TB/RB) 002716 Serial I/O status register (SIOSTS) 000816 Port P4 (P4) 000916 Port P4 direction register (P4D) 000A16 Port P5 (P5) 002816 Reserved 002916 Reserved 002A16 Reserved 002B16 Reserved 000B16 Port P5 direction register (P5D) 000C16 Port P6 (P6) 000D16 Port P6 direction register (P6D) 000E16 Reserved (Note) 000F16 Reserved (Note) 001016 USB control register (USBCON) 001116 USB address enable register (USBAE) 001216 USB address 0 register (USBA0) (Note) (Note) (Note) (Note) 002C16 Reserved (Note) 002D16 Reserved (Note) 002E16 Reserved (Note) 002F16 Reserved (Note) 003016 EXB interrupt source enable register (EXBICON) 001316 USB address 1 register (USBA1) 001416 Frame number register Low (FNUML) 001516 Frame number register High (FNUMH) 003116 EXB interrupt source register (EXBIREQ) 003216 Reserved (Note) 003316 EXB index register (EXBINDEX) 003416 EXB field register 1 (EXBREG1) 003516 EXB field register 2 (EXBREG2) 001616 USB interrupt source enable register (USBICON) 001716 USB interrupt source register (USBIREQ) 001816 Endpoint index register (USBINDEX) 001916 Endpoint field register 1 (EPXXREG1) 003616 A-D control register (ADCON) 003716 A-D conversion register Low (ADL) 003816 A-D conversion register High (ADH) 003916 Watchdog timer control register (WDTCON) 001A16 Endpoint field register 2 (EPXXREG2) 001B16 Endpoint field register 3 (EPXXREG3) 001C16 Endpoint field register 4 (EPXXREG4) 001D16 Endpoint field register 5 (EPXXREG5) 003A16 Reserved (Note) 003B16 CPU mode register (CPUM) 003C16 Interrupt request register 1(IREQ1) 001E16 Endpoint field register 6 (EPXXREG6) 001F16 Endpoint field register 7 (EPXXREG7) 0F E016 Serial I/O control register (SIOCON) 0F E116 UART control register (UARTCON) 0F E216 Baud rate generator (BRG) 0FE316 Reserved (Note) 0FE416 Reserved (Note) 0F E516 Reserved (Note) 0FE616 Reserved (Note) 0F E716 Reserved (Note) 0FE816 Reserved (Note) 0FE916 Reserved (Note) 0FEA16 Reserved (Note) 0FEB16 Reserved (Note) 0FEC16 Endpoint field register 8 (EPXXREG8) 0FED16 Endpoint field register 9 (EPXXREG9) 0FEE16 Reserved (Note) 0FEF16 Reserved (Note) 003D16 Interrupt request register 2(IREQ2) 003E16 Interrupt control register 1(ICON1) 003F16 Interrupt control register 2(ICON2) 0FF016 Port P0 pull-up control register (PULL0) 0FF116 Reserved (Note) 0FF216 Port P5 pull-up control register (PULL5) 0FF316 Interrupt edge selection register (INTEDGE) 0FF416 Reserved (Note) 0FF516 Reserved (Note) 0FF616 Reserved (Note) 0FF716 Reserved (Note) 0FF816 PLL control register (PLLCON) 0FF916 Reserved (Note) 0FFA16 Reserved (Note) 0FFB16 MISRG 0FF C16 Reserved (Note) 0FF D16 Reserved (Note) 0FFE16 Flash memory control register (FMCR) 0F FF16 Reserved (Note) Note: Do not write any data to these addresses, because these areas are reserved. Fig. 9 Memory map of special function register (SFR) 11 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER I/O PORTS 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 bit, 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 are floating. If a pin set to input is written to, only the port output latch is written to and the pin remains floating. Table 5 I/O ports functions Pin P00–P07 Name Port P0 P10–P17 Port P1 P20–P27 Port P2 P30–P32 P33/ExINT Port P3 P34/ExCS P35/ExWR P36/ExRD P37/ExA0 P40/RxD/ ExDREQ Input/Output Input/output, individual bits I/O Format CMOS compatible input level CMOS 3-state output CMOS compatible input level CMOS 3-state output (Power source is VCCE) CMOS compatible input level CMOS 3-state output CMOS/TTL compatible input level CMOS 3-state output (Power source is VccE) Port P4 P41/TxD/ ExDACK P42/SCLK/ ExTC P43/SRDY/ ExA1 P50/INT0 P52/INT1 P51/CNTR0 P53–P57 P60–P63 Port P5 CMOS compatible input level CMOS 3-state output Non-Port Function Key-on wake up A-D conversion input External bus interface funciton I/O Diagram No. (1) A-D control register EXB control register (2) (3) External bus interface funciton output External bus interface funciton input EXB control register (4) (5) EXB control register (6) Serial I/O input External bus interface funciton output Serial I/O output External bus interface funciton input Serial I/O I/O External bus interface funciton input Serial I/O output External bus interface funciton input External interrupt input Serial I/O control register EXB control register Serial I/O control register EXB control register Serial I/O control register EXB control register Serial I/O control register EXB control register Port P5 pull-up control register Interrupt edge selection register Timer X mode register (7) Timer X function I/O Port P6 Related SFRs Port P0 pull-up control register (8) (9) (10) (11) (12) (13) (14) Note: 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. 12 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) Port P0 (4) Ports P30–P32 Pull-up control bit Direction register Direction register Data bus Port latch Data bus VCCE Port latch Key-on wake-up input (5) Port P33 (2) Port P1 EXOE VCCE VCCE External bus interface enable bit External bus interface enable bit Direction register Direction register Data bus Data bus Port latch Port latch EXINT output EXB data output Output buffer EXB data input Input buffer (6) Ports P34, P35, P36, P37 VCCE External bus interface enable bit A-D conversion input Direction register Analog input pin selection bit Data bus Port latch (3) Port P2 Direction register Data bus Port latch EXCS(P34) EXWR(P35) EXRD(P36) EXA0(P37) External bus interface enable bit Fig. 10 Port block diagram (1) 13 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (11) Ports P50, P52 (7) Port P40 Pull-up control bit Serial I/O enable bit Receive enable bit VCCE Direction register External bus interface enable bit Direction register Data bus Data bus Port latch Port latch INT0 (P50), INT1 (P52) interrupt input EXDreq output Serial I/O input (8) Port P41 (12) Port P51 Serial I/O enable bit Receive enable bit VCCE Direction register External bus interface enable bit Direction register Port latch Data bus Data bus Port latch Pulse output mode Timer output CNTR0 interrupt input Serial I/O output EXDack External bus interface enable bit (13) Ports P53–P57 (9) Port P42 Serial I/O enable bit Serial I/O mode selection bit Serial I/O synchronous clock selection bit Serial I/O enable bit External bus interface enable bit Direction register Data bus Direction register VCCE Port latch Data bus Port latch Serial I/O clock output (14) Port P6 Serial I/O external clock input Serial I/O synchronous clock selection bit External bus interface enable bit EXTC (10) Port P43 Data bus Serial I/O mode selection bit Serial I/O enable bit SRDY output enable bit Direction register Port latch VCCE External bus interface enable bit Direction register Data bus Port latch Serial I/O output EXA1 External bus interface enable bit Fig. 11 Port block diagram (2) 14 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 Port P0 pull-up control register (P0PULL : address 0FF016) P00 pull-up control bit 0 : No pull-up 1 : Pull-up P01 pull-up control bit 0 : No pull-up 1 : Pull-up P02 pull-up control bit 0 : No pull-up 1 : Pull-up P03 pull-up control bit 0 : No pull-up 1 : Pull-up P04 pull-up control bit 0 : No pull-up 1 : Pull-up P05 pull-up control bit 0 : No pull-up 1 : Pull-up P06 pull-up control bit 0 : No pull-up 1 : Pull-up P07 pull-up control bit 0 : No pull-up 1 : Pull-up b7 b0 Port P5 pull-up control register (P5PULL : address 0FF216) P50 pull-up control bit 0 : No pull-up 1 : Pull-up Nothing is arranged for this bit. This is a write disabled bit. When this bit is read out, the contents are “0”. P52 pull-up control bit 0 : No pull-up 1 : Pull-up Nothing is arranged for these bits. These are write disabled bits. When these bits are read out, the contents are “0”. Fig. 12 Structure of port I/O-related registers 15 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER INTERRUPTS ■Notes on interrupts When setting the followings, the interrupt request bit may be set to “1”. •When setting external interrupt active edge Related register: Interrupt edge selection register (address 0FF3 16 ), Timer X mode register (address 002316) When not requiring for the interrupt occurrence synchronized with these setting, take the following sequence. ➀Set the corresponding interrupt enable bit to “0” (disabled). ➁Set the interrupt edge select bit (active edge switch bit). ➂Set the corresponding interrupt request bit to “0” after 1 or more instructions have been executed. ➃Set the corresponding interrupt enable bit to “1” (enabled). Interrupts occur by fifteen sources: four external, ten internal, and one software. Interrupt Control Each interrupt is controlled by an interrupt request bit, an interrupt enable bit, and the interrupt disable flag except for the software interrupt set by the BRK instruction. 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 cannot be disabled with any flag or bit. The I flag disables all interrupts except the BRK instruction interrupt. When several interrupts occur at the same time, the interrupts are received according to priority. Interrupt Operation By acceptance of an interrupt, the following operations are automatically performed: 1. The contents of the program counter and the 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. Table 6 Interrupt vector addresses and priority Interrupt Source Priority Reset (Note 2) USB bus reset USB SOF USB device 1 2 3 4 External bus INT0 Timer X Timer 1 Timer 2 INT1 (Note 3) Serial I/O reception Serial I/O transmission CNTR0 Key-on wake up A-D conversion BRK instruction Vector Addresses (Note 1) High Low FFFD16 FFFC16 Interrupt Request Generating Conditions FFF716 FFFA16 FFF816 FFF616 5 FFF516 FFF416 6 7 8 9 10 — 11 FFF316 FFF116 FFED16 FFE716 FFF216 FFF016 FFEE16 FFEC16 FFEA16 FFE816 FFE616 At reset At detection of USB bus reset signal (2.5 µs interval SE0) At detection of USB SOF signal At detection of resume signal (K state or SE0) or suspend signal (3 ms interval bus idle), or at completion of transaction At completion of reception or transmission or at completion of DMA transmission At detection of either rising or falling edge of INT0 input At timer X underflow At timer 1 underflow At timer 2 underflow At detection of either rising or falling edge of INT1 input (Note 4) At completion of serial I/O data reception 12 FFE516 FFE416 At completion of serial I/O data transmission 13 14 15 16 FFE316 FFE216 FFE016 FFDE16 FFDC16 At detection of either rising or falling edge of CNTR0 input At falling of conjunction of input level for port P2 (at input mode) At completion of A-D conversion At BRK instruction execution FFFB16 FFF916 FFEF16 FFEB16 FFE916 FFE116 FFDF16 FFDD16 Notes 1: Vector addresses contain interrupt jump destination addresses. 2: Reset function in the same way as an interrupt with the highest priority. 3: Nothing is arranged in these vector addresses. 4: Fix bit 1 of interrupt control register 2 (address 003F16) to “0”. 16 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Interrupt request bit Interrupt enable bit Interrupt disable flag (I) BRK instruction Reset Interrupt request Fig. 13 Interrupt control b7 b0 Interrupt edge selection register (INTEDGE : address 0FF316) INT0 interrupt edge selection bit Not used (return “0” when read) INT1 interrupt edge selection bit Not used (return “0” when read) 0 : Falling edge active 1 : Rising edge active b7 b0 Interrupt request register 1 (IREQ1 : address 003C16) b7 b0 USB bus reset interrupt request bit USB SOF interrupt request bit USB device interrupt request bit EXB interrupt request bit INT0 interrupt request bit Timer X interrupt request bit Timer 1 interrupt request bit Timer 2 interrupt request bit Interrupt request register 2 (IREQ2 : address 003D16) INT1 interrupt request bit Nothing is arranged for this bit. This is a write disabled bit. When this bit is read out, the contents are “0”. Serial I/O receive interrupt request bit Serial I/O transmit interrupt request bit CNTR0 interrupt request bit Key-on wake-up interrupt request bit A-D conversion interrupt request bit Nothing is arranged for this bit. This is a write disabled bit. When this bit is read out, the contents are “0”. ✽ “0” can be set by software, but “1” cannot be set. 0 : No interrupt request issued 1 : Interrupt request issued b7 b0 Interrupt control register 1 (ICON1 : address 003E16) USB bus reset interrupt enable bit USB SOF interrupt enable bit USB device interrupt enable bit EXB interrupt enable bit INT0 interrupt enable bit Timer X interrupt enable bit Timer 1 interrupt enable bit Timer 2 interrupt enable bit ✽ “0” can be set by software, but “1” cannot be set. b7 b0 Interrupt control register 2 (ICON2 : address 003F16) INT1 interrupt enable bit Fix this bit to “0”. Serial I/O receive interrupt enable bit Serial I/O transmit interrupt enable bit CNTR0 interrupt enable bit Key-on wake-up interrupt enable bit A-D conversion interrupt enable bit Fix this bit to “0”. 0 : Interrupts disabled 1 : Interrupts enabled Fig. 14 Structure of interrupt-related registers 17 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Key Input Interrupt (Key-on Wake Up) A Key-on wake up interrupt request is generated by applying a falling edge to any pin of port P0 that have been set to input mode. In other words, it is generated when AND of input level goes from “1” to “0”. An example of using a key input interrupt is shown in Figure 15, where an interrupt request is generated by pressing one of the keys consisted as an active-low key matrix which inputs to ports P00–P03. Port PXx “L” level output PULL 0 register Bit 7 = “0” ✽ ✽✽ Port P07 direction register = “1” Key input interrupt request Port P07 latch P07 output PULL 0 register Bit 6 = “0” ✽ ✽✽ Port P06 direction register = “1” Port P06 latch P06 output PULL 0 register Bit 5 = “0” ✽ ✽✽ Port P05 direction register = “1” Port P05 latch P05 output PULL 0 register Bit 4 = “0” ✽ ✽✽ Port P04 direction register = “1” Port P04 latch P04 output PULL 0 register Bit 3 = “1” ✽ ✽✽ Port P03 direction register = “0” PULL 0 register Bit 2 = “1” ✽ ✽✽ Port P02 direction register = “0” Port P02 latch P02 input PULL 0 register Bit 1 = “1” ✽ ✽✽ P01 input Port P01 direction register = “0” Port P01 latch PULL 0 register Bit 0 = “1” ✽ P00 input ✽✽ Port P0 Input reading circuit Port P03 latch P03 input Port P00 direction register = “0” Port P00 latch ✽ P-channel transistor for pull-up ✽ ✽ CMOS output buffer Fig. 15 Connection example when using key input interrupt and port P0 block diagram 18 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER TIMERS Timer 1 and Timer 2 The 38K0 group has three timers: timer X, timer 1, and timer 2. The division ratio of each timer or prescaler is given by 1/(n + 1), where n is the value in the corresponding timer or prescaler latch. All timers are down count timers. When the timer reaches “00 16”, an underflow occurs at the next count pulse and the corresponding timer latch is reloaded into the timer and the count is continued. When a timer underflows, the interrupt request bit corresponding to that timer is set to “1”. The count source of prescaler 12 is the system clock divided by 16. The output of prescaler 12 is counted by timer 1 and timer 2, and a timer underflow periodically sets the interrupt request bit. Timer X Timer X can each select in one of four operating modes by setting the timer X mode register. (1) Timer Mode b7 The timer counts the count source selected by timer count source selection bit. b0 Timer X mode register (TM : address 002316) Timer X operating mode bits b1 b0 0 0 : Timer mode 0 1 : Pulse output mode 1 0 : Event counter mode 1 1 : Pulse width measurement mode CNT R0 active edge switch bit 0 : Falling edge active for CNTR0 interrupt Count at rising edge in event counter mode 1 : Rising edge active for CNTR0 interrupt Count at falling edge in event counter mode Timer X count stop bit 0 : Count start 1 : Count stop Not used (return “0” when read) Fig. 16 Structure of timer X mode register (2) Pulse Output Mode The timer counts the system clock divided by 16. Whenever the contents of the timer reach “00 16 ”, the signal output from the CNTR0 pin is inverted. If the CNTR0 active edge selection bit is “0”, output begins at “ H”. If it is “1”, output starts at “L”. When using a timer in this mode, set the corresponding port P51 direction register to output mode. (3) Event Counter Mode Operation in event counter mode is the same as in timer mode, except that the timer counts signals input through the CNTR0 pin. When the CNTR0 active edge selection bit is “0”, the rising edge of the CNTR0 pin is counted. When the CNTR0 active edge selection bit is “1”, the falling edge of the CNTR0 pin is counted. (4) Pulse Width Measurement Mode If the CNTR0 active edge selection bit is “0”, the timer counts the system clock divided by 16 while the CNTR0 pin is at “H”. If the CNTR0 active edge selection bit is “1”, the timer counts it while the CNTR0 pin is at “L”. The count can be stopped by setting “1” to the timer X count stop bit in any mode. The corresponding interrupt request bit is set each time a timer underflows. 19 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Data bus Divider System clock 1/16 Pulse width m easurem ent mode Prescaler X latch (8) Timer mode Pulse output mode Prescaler X (8) P51/CNTR0 CNTR0 active edge selection bit “0” Event counter mode Timer X latch (8) Timer X (8) Timer X count stop bit CNTR0 interrupt request bit “1” CNTR0 active edge selection bit Port P51 direction register Timer X interrupt request bit “1” “0” Port P51 latch Q Q Toggle flip-flop R T Timer X latch write Pulse output mode Pulse output mode Data bus Prescaler 12 latch (8) Timer 1 latch (8) Timer 2 latch (8) Timer 1 (8) Timer 2 (8) Divider System clock 1/16 Prescaler 12 (8) Timer 2 interrupt request bit Timer 1 interrupt request bit Fig. 17 Timer block diagram 20 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER SERIAL I/O (1) Clock Synchronous Serial I/O Mode Serial I/O 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. Clock synchronous serial I/O mode can be selected by setting the mode selection bit of the serial I/O control register (bit 6 of address 0FE016) to “1”. For clock synchronous serial I/O, the transmitter and the receiver must use the same clock. If an internal clock is used, transfer is started by a write signal to the Trancemit/Receive buffer register. Data bus Serial I/O control register Address 002616 Receive buffer register Receive buffer full flag (RBF) Receive interrupt request (RI) Receive shift register P40/EXDREQ/RxD Address 0FE016 Shift clock Clock control circuit P42/EXTC/SCLK Serial I/O synchronous clock selection bit Frequency division ratio 1/(n+1) BRG count source selection bit System clock Baud rate generator 1/4 P43/EXA1/SRDY F/F 1/4 Address 0FE216 Clock control circuit Falling-edge detector Shift clock P41/EXDACK/TxD Transmit shift register Transmit shift register shift completion flag (TSC) Transmit interrupt source selection bit Transmit interrupt request (TI) Transmit buffer empty flag (TBE) Address 002716 Transmit buffer register Serial I/O status register Address 002616 Data bus Fig. 18 Block diagram of clock synchronous serial I/O Transfer shift clock (1/2 to 1/2048 of the internal clock, or an external clock) Serial output TXD D0 D1 D2 D3 D4 D5 D6 D7 Serial input RXD D0 D1 D2 D3 D4 D5 D6 D7 Receive enable signal SRDY Write signal to receive/transmit buffer register (address 002616) TBE = 0 TBE = 1 TSC = 0 RBF = 1 TSC = 1 Overrun error (OE) detection Notes 1 : T he transmit interrupt (TI) can be generated either when the transmit buffer register has emptied (TBE = 1) or after the transmit shift operation has ended (TSC=1), by setting the transmit interrupt source selection bit (TIC) of the serial I/O1 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 : T he receive interrupt (RI) is set when the receive buffer full flag (RBF) becomes “1” . Fig. 19 Operation of clock synchronous serial I/O function 21 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ter, but 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 register can hold a character while the next character is being received. (2) Asynchronous Serial I/O (UART) Mode Clock asynchronous serial I/O mode (UART) can be selected by setting the serial I/O mode selection bit of the serial I/O control register to “0”. Eight serial data transfer formats can be selected, and the transfer formats used by a transmitter and receiver must be identical. The transmit and receive shift registers each have a buffer regis- Data bus Address 002616 P40/EXDREQ/RxD Serial I/O1 control register Address 0FE016 OE Receive buffer register Character length selection bit STdetector 7 bits Receive shift register Receive buffer full flag (RBF) Receive interrupt request (RI) 1/16 8 bits UART control register Address 0FE116 SP detector PE FE Clock control circuit Serial I/O synchronous clock selection bit P42/EXTC/SCLK BRG count source selection bit Frequency division ratio 1/(n+1) System clock Baud rate generator Address 0FE216 1/4 ST/SP/PA generator Transmit shift register shift completion flag (TSC) 1/16 Transmit shift register P41/EXDACK/TxD Character length selection bit Transmit buffer register Address 002616 Transmit interrupt source selection bit Transmit interrupt request (TI) Transmit buffer empty flag (TBE) Serial I/O status register Address 002716 Data bus Fig. 20 Block diagram of UART serial I/O Transmit or receive clock Transmit buffer write signal TBE=0 TBE=0 TSC=0 TBE=1 Serial output TXD TSC=1✽ TBE=1 ST D0 D1 SP ST D0 1 start bit 7 or 8 data bits 1 or 0 parity bit 1 or 2 stop bit (s) Receive buffer read signal ✽ Generated RBF=0 RBF=1 Serial input RXD ST D0 D1 D1 SP ST D0 D1 SP at 2nd bit in 2-stop-bit mode RBF=1 SP Notes 1 : Error flag detection occurs at the same time that the RBF flag becomes “1” (at 1st stop bit, during reception). 2 : T he transmit interrupt (TI) can be generated to occur when either the TBE or TSC flag becomes “1”, depending on the setting of the transmit interrupt source selection bit (TIC) of the serial I/O1 control register. 3 : T he receive interrupt (RI) is set when the RBF flag becomes “1”. 4 : After data is written to the transmit buffer register when TSC=1, 0.5 to 1.5 cycles of the data shift cycle is necessary until changing to TSC=0. Fig. 21 Operation of UART serial I/O function 22 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [Serial I/O Control Register (SIOCON)] 0FE016 The serial I/O control register contains eight control bits for the serial I/O function. [UART Control Register (UARTCON)] 0FE116 The UART control register consists of four control bits (bits 0 to 3) which are valid when asynchronous serial I/O is selected and set the data format of an data transfer. [Serial I/O Status Register (SIOSTS)] 002716 The read-only serial I/O status register consists of seven flags (bits 0 to 6) which indicate the operating status of the serial I/O function and various errors. Three of the flags (bits 4 to 6) are valid only in UART mode. The receive buffer full flag (bit 1) is cleared to “0” when the receive buffer is read. If there is an error, it is detected at the same time that data is transferred from the receive shift register to the receive buffer register, and the receive buffer full flag is set. A write to the serial I/O status register clears all the error flags OE, PE, FE, and SE (bit 3 to bit 6, respectively). Writing “0” to the serial I/O enable bit SIOE (bit 7 of the serial I/O control register) also clears all the status flags, including the error flags. All bits of the serial I/O status register are initialized to “0” at reset, but if the transmit enable bit (bit 4) of the serial I/O control register has been set to “1”, the transmit shift register shift completion flag (bit 2) and the transmit buffer empty flag (bit 0) become “1”. [Transmit Buffer/Receive Buffer Register (TB/ RB)] 002616 The transmit buffer register and the receive buffer register are located at the same address. The transmit buffer register is writeonly and the receive buffer register is read-only. If a character bit length is 7 bits, the MSB of data stored in the receive buffer register is “0”. [Baud Rate Generator (BRG)] 0FE216 The baud rate generator determines the baud rate for serial transfer. 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. ■Notes on serial I/O When setting the transmit enable bit to “1”, the serial I/O transmit interrupt request bit is automatically set to “1”. When not requiring the interrupt occurrence synchronized with the transmission enalbed, take the following sequence. ➀Set the serial I/O transmit interrupt enable bit to “0” (disabled). ➁Set the transmit enable bit to “1”. ➂Set the serial I/O transmit interrupt request bit to “0” after 1 or more instructions have been executed. ➃Set the serial I/O transmit interrupt enable bit to “1” (enabled). 23 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 Serial I/O status register (SIOSTS : address 002716) Transmit buffer empty flag (TBE) 0: Buffer full 1: Buffer empty b0 Serial I/O control register (SIOCON : address 0FE016) BRG count source selection bit (CSS) 0: System clock 1: System clock/4 Transmit shift register shift completion flag (TSC) 0: Transmit shift in progress 1: Transmit shift completed Serial I/O synchronous clock selection bit (SCS) 0: BRG output divided by 4 when clock synchronous serial I/O is selected. BRG output divided by 16 when UART is selected. 1: External clock input when clock synchronous serial I/O is selected. External clock input divided by 16 when UART is selected. Overrun error flag (OE) 0: No error 1: Overrun error SRDY output enable bit (SRDY) 0: P43 pin operates as ordinary I/O pin 1: P43 pin operates as SRDY output pin Parity error flag (PE) 0: No error 1: Parity error Transmit interrupt source selection bit (TIC) 0: Interrupt when transmit buffer has emptied 1: Interrupt when transmit shift operation is completed Framing error flag (FE) 0: No error 1: Framing error Transmit enable bit (TE) 0: Transmit disabled 1: Transmit enabled Summing error flag (SE) 0: (OE) U (PE) U (FE) =0 1: (OE) U (PE) U (FE) =1 Receive enable bit (RE) 0: Receive disabled 1: Receive enabled Not used (returns “1” when read) Serial I/O mode selection bit (SIOM) 0: Asynchronous serial I/O (UART) 1: Clock synchronous serial I/O Receive buffer full flag (RBF) 0: Buffer empty 1: Buffer full b7 b7 b0 UART control regi ster (UART CON : address 0FE116) Character length selection bit (CHAS) 0: 8 bits 1: 7 bits Serial I/O enable bit (SIOE) 0: Serial I/O disabled (pins P40–P43 operate as ordinary I/O pins) 1: Serial I/O enabled (pins P40–P43 can operate as serial I/O pins) 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 (ST PS) 0: 1 stop bit 1: 2 stop bits Not used (return “0” when read) (This is a write disabled bit.) Not used (return “1” when read) Fig. 22 Structure of serial I/O control registers 24 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER USB FUNCTION 38K0 Group is equipped with a USB function control circuit (USBFCC) that enables effective interfacing with the host-PC. This circuit is in compliance with USB Specification Version 2.0 Full-Speed Transfer Mode (12 Mbps, equivalent to Version 1.1). This circuit also supports all four transfer-types specified in the standard USB specification. The USBFCC has four endpoints that can select its transfer type. Although Endpoint 0 is fixed to Control Transfer, the Endpoints 1 to 3 can be set to Interrupt Transfer, Bulk Transfer, or Isochronous Transfer. A dedicated circuit automatically performs stage management for Control Transfer and packet management for transactions, which are necessary for matching of data transmit/receive timing, error detection, and retry after error. This dedicated control circuit enables the user to develop a program or timing design very easily. Each endpoint can be programmed for data transfer conditions so that the endpoints are adaptive for all USB device class transfer systems. The data buffer of each endpoint can be assigned to any area in the multi-channel RAM. This feature offers highly efficient memory usage by avoiding re-buffering and enabling simple data modification. The transmit/receive data is directly transferred to the data buffer via the control circuit (direct RAM access type) without disturbing the CPU operation. This mechanism enables the CPU to transfer data smoothly with no drop in performance. In addition to this buffer function, a double-buffer setting will keep a re-buffering stall at a minimum and increase the overall data throughput (max. 64 bytes X 2 channels). As other special signals control, the endpoints have detection functions for the USB bus reset signal, resume signal, suspend signal, and SOF signal, and also have a remote wake-up signal transmit function. When completing data transfer or receiving a special signal, the endpoint generates the corresponding interrupt to the CPU (3 vectors/18 factors). With all this essential yet comprehensive built-in hardware, your system using the 38K2 group will be ready for any USB application that comes its way. 38K0 Group MCU Built-in Peripheral Functions Program ROM CPU External MCU Interrupt request External Bus Interface (EXB) Multi-channel RAM USB USB Bus (USB-Host) Data transmit/Receive path [Direct RAM Access Type] Fig. 23 USB function overview USB Data Transfer The USB specification promises 12 Mbps data transfer in the fullspeed mode, that is equivalent to 1.5 M bytes per second of data transactions. However, in USB data transfer, bit-stuffing may be executed depending on the bit patterns of the transfer data, possibly resulting in 1-byte data (normally 8 bits) handled as up to 10 bits. Because USB uses asynchronous transfers, the clock cycle of the USB internal reference clock may change to adjust to the clock phase. Therefore, the access timing of the USBFCC for the multichannel RAM will change owing to the frequency of internal clock φ: When the USBFCC is operating at φ =8 MHZ, access for a normal transfer is performed every 5 to 6 cycles and access for a bit-stuffing transfer is performed in up to 7 cycles. If the EXB function is enabled in the above conditions, this function generates a maximum wait of 1 clock cycle, so that the access is performed every 4 to 8 cycles. When operating at φ = 6MHZ, a normal access is performed every 4 cycles. If the clock-phase correction of the reference clock occurs, access is performed every 3 to 5 cycles. If bit stuffing occurs at this clock rate, the access cycle will be extended to up to 6 cycles. When the EXB function that generates a maximum 1-wait cycle is used in this condition, the access cycle will be 2 (min.) to 7 (max.) cycles. 25 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER USB Function Control Circuit (USBFCC) Block Diagram The following diagram shows the USBFCC block diagram. The circuit comprises: (1) Serial Interface Engine (SIE) (2) Device Control Unit (DCU) (3) Internal Memory Interface (MIF) (4) CPU Interface (CIF) USB Function Control Circuit DCU control MIF control USB Transceiver SIE DCU SIE status MIF CIF CPU DCU status SIE control D0+ D0- Transmit/Receive data Multi-Channel RAM Fig. 24 USB Function Control Circuit (USBFCC) block diagram (1) Serial Interface Engine (SIE) The SIE performs the following USB lower-layer protocols (packets, transactions): •Sampling of receive data and clock, generation of transmit clock •Serial-to-parallel conversion of transmit/receive data •NRZI (Non Return Zero Invert) encode/decode •Bit stuffing/unstuffing •SYNC (Synchronization Pattern) detection, EOP (End of Packet) detection •USB address detection, endpoint detection •CRC (Cyclic Redundancy Check) generation and checking (3) Memory Interface (MIF) The MIF controls the flow of data transfer between the SIE and the multi-channel RAM under the management of the DCU. (4) CPU Interface (CIF) The CIF performs the following functions: •Mode setting via registers, DCU control signal generation, DCU status signal reading •Interrupt signal generation •Internal bus interface control. (2) Device Control Unit (DCU) The DCU manages the following USB upper-layer protocols (address/endpoint and control-transfer sequence): •Status control for each endpoint •Control-transfer sequence control •Memory interface status control 26 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER USB Port External Circuit Configuration The operation mode of the USB port driver circuit can be configured by USB control register (address 001016). Figure 25 shows the USB port external circuit block diagram. VREFCON VREFE DVCC 0 1 0 Hiz Hiz 1 3.3V output Normal mode 3.3V output Low-power mode USBVREF status VREFE USBVREF USB Reference Voltage Circuit VREFCON 2.2 µF 0.1 µF TRON TRONCON TRONE XOUT PLL 1.5 kΩ D0+ Full Speed fVCO “1” 27 Ω fUSB “0 ” USB Module USBE + - UCLKCON USBDIFE USBE Full Speed D0- 27 Ω USBE Fig. 25 USB port external circuit (D0+, D0-, USBVREF, TrON) block diagram 27 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Endpoint Buffer Area Setting The buffer area used in data transfer can be assigned to any area of the multi-channel RAM for each endpoint. Memory 002016 ●Buffer area beginning address The buffer area configuration register (address 0FED16) defines the beginning address of the buffer area (every 32 bytes) for each Endpoint. However, the only RAM area is configurable. •00h [Address 000016], 01h [Address 002016]: Not configurable •02h [Address 004016] to 1Fh [Address 03E016]: Configurable ●Interrupt-source dependant buffer area offset address An offset value is added to the beginning address of each source, which is specified by the interrupt source register (address 001D16), for each endpoint. This section describes in detail the beginning address specified by the buffer area set register as offset address 00h, according to each endpoint. (1) Endpoint 00 Endpoint 00 has two kinds of interrupt sources for accessing the buffer. The respective address offsets are: •BSRDY00 (SETUP Buffer Ready Interrupt): Offset address = 00h •BRDY00 (OUT or IN Buffer Ready Interrupt): Offset address = 08h (2) Endpoint 01 The buffer area offset address for each interrupt source for of Endpoint 01 varies according to the contents of the EP01 set register (address 001916). •In single buffer mode (DBLB01 = “0”): Endpoint 01 has only one interrupt source for accessing the buffer. B0RDY01 (Buffer 0 Ready Interrupt): Offset address = 00h (a) When selecting Endpoint 00 Offset Memory 00h 02A016 Disabled to be used 01 004016 02 006016 03 02A016 15 03E016 1F Fig. 26 Example setting of buffer area beginning address •In double buffer mode (DBLB01 = “1”): Endpoint 01 has two kinds of interrupt sources for accessing the buffer. B0RDY01 (Buffer 0 Ready Interrupt): Offset address = 00h B1RDY01 (Buffer 1 Ready Interrupt): The offset address varies according to the double buffer beginning address set bit (BSIZ01). -Offset address = 08h when BSIZ01 = 00 -Offset address = 10h when BSIZ01 = 01 -Offset address = 40h when BSIZ01 = 10 -Offset address = 80h when BSIZ01 = 11 (3) Endpoints 02 and 03 Same as Endpoint 01. Notes The selected RAM area must be within addresses 0040 16 to 03FF16. Make sure the buffer area beginning address is set in agreement with the offset address and the number of transmit/receive data bytes. This is particularly important when in the double buffer mode or when handling 64-byte data. 00h (c) When selecting Double Buffer Mode (when BSIZ01 = 11) Offset Memory 00h 02A016 BSRDY00 02A816 SFR RAM Offset 02A016 00 0000 0010 1010 0000 (b) When selecting Single Buffer Mode Memory 0FED16 000016 0FED16 = 15h B0RDY01 08h B0RDY01 BRDY00 80h 032016 B1RDY01 Fig. 27 Examples of interrupt source dependant buffer area offset address 28 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER USB Interrupt Function USB Interrupt Control Circuit (USBINTCON) has 3 requests and 16 USB-device interrupt request sources. Each interrupt source register enables the user to easily determine which interrupt has occurred. Table 7 shows the list of USB interrupt sources. Table 7 USB interrupt sources Interrupt request bit (IREQ1: Address 003C16) USB bus reset USB interrupt bit (USBIREQ: Address 001716) — USB SOF — USB device EP00 EP01 EP02 EP03 SUS RSM Interrupt source At USB bus reset signal detection: After enabling the USB module (USBE = “1”), an interrupt request occurs when 2.5 µs SE0 state is detected in D0+/D0- port. (Equivalent to 120-clock length when fUSB = 48 MHz) At SOF packet receive: After enabling the USB module (USBE = “1”), an interrupt request occurs when SOF packet is detected in D0+/D0- port. Its occurrence does not depend on frame-time or CRC value after SOF packet is transferred. (Normally, SOF packet detection occurs only when fUSB = 48 MHz) At Endpoint 00 data transfer complete: •Buffer ready (read/write enabled state) •Control transfer completed •Status stage transition •SETUP buffer ready (read enabled state) •Control transfer error At Endpoint 01 data transfer complete: •Buffer 0 ready (read/write enabled state) •Buffer 1 ready (read/write enabled state) •Transfer error At Endpoint 02 data transfer complete: •Buffer 0 ready (read/write enabled state) •Buffer 1 ready (read/write enabled state) •Transfer error At Endpoint 03 data transfer complete: •Buffer 0 ready (read/write enabled state) •Buffer 1 ready (read/write enabled state) •Transfer error At suspend signal detection: After enabling the USB module (USBE = “1”), an interrupt request occurs when 3 ms J state is detected in D0+/D0- port. (Equivalent to 144,000 clock-length when fUSB = 48MHz) At resume signal detection: After enabling the USB module (USBE = “1”) and resume interrupt (RSME = “1”), an interrupt request occurs when a bus state change (J state to SE0 or K state) is detected in D0- port. 29 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER [EPXXREG5] [USBIREQ] [USBICON] [EP00REQ] BRDY00 EP00E CTEND00 CTSTS00 BSYDY00 USB device interrupt request EP00 ERR00 [EP01REQ] EP01E B0RDY01 B1RDY01 EP01 ERR01 [EP02REQ] EP02E B0RDY02 B1RDY02 EP02 ERR02 [EP03REQ] EP03E B0RDY03 B1RDY03 EP03 ERR03 SUSE SUS RSME RSM Fig. 28 USB device interrupt control 30 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER USB Register List The USB register list is shown below. SYMBOL USB SFR Address Register Name 001016 001116 001216 001316 001416 001516 001616 001716 001816 001916 001A16 001B16 001C16 001D16 001E16 001F16 0FEC16 0FED16 USB control register USB Function enable register USB function address register USBCON USBAE USBA0 Frame number register Low Frame number register High USB interrupt source enable register USB interrupt source register Endpoint index register Endpoint field register 1 Endpoint field register 2 Endpoint field register 3 Endpoint field register 4 Endpoint field register 5 Endpoint field register 6 Endpoint field register 7 Endpoint field register 8 Endpoint field register 9 FNUML FNUMH USBICON USBIREQ USBINDEX EPXXREG1 EPXXREG2 EPXXREG3 EPXXREG4 EPXXREG5 EPXXREG6 EPXXREG7 EPXXREG8 EPXXREG9 EP00 stage register EP00 control register 1 EP00 control register 2 EP00 control register 3 EP00 interrupt source register EP00 transmit/receive byte number register EP00STG EP00CON1 EP00CON2 EP00CON3 EP00REQ EP00BYT EP00 buffer area set register EP00BUF EP01 set register EP01 control register 1 EP01 control register 2 EP01 control register 3 EP01 interrupt source register EP01 byte number register 0 EP01 byte number register 1 EP01 MAX. packet size register EP01 buffer area set register EP01CFG EP01CON1 EP01CON2 EP01CON3 EP01REQ EP01BYT0 EP01BYT1 EP01MAX EP01BUF TYP01[1:0] EP02 set register EP02 control register 1 EP02 control register 2 EP02 control register 3 EP02 interrupt source register EP02 byte number register 0 EP02 byte number register 1 EP02 MAX. packet size register EP02 buffer area set register EP02CFG EP02CON1 EP02CON2 EP02CON3 EP02REQ EP02BYT0 EP02BYT1 EP02MAX EP02BUF TYP02[1:0] EP03 set register EP03 control register 1 EP03 control register 2 EP03 control register 3 EP03 interrupt source register EP03 byte number register 0 EP03 byte number register 1 EP03 MAX. packet size register EP03 buffer area set register EP03CFG EP03CON1 EP03CON2 EP03CON3 EP03REQ EP03BYT0 EP03BYT1 EP03MAX EP03BUF TYP03[1:0] bit 7 bit 6 USBE UCLKCON bit 5 USBDIFE bit 4 bit 3 bit 2 bit 1 bit 0 VREFE VREFCON TRONE TRONCON WKUP AD0E USBADD0[6:0] FNUM[7:0] RSME RSM SUSE SUS EP03E EP03 EP02E EP02 FNUM[10:8] EP01E EP00E EP01 EP00 EPIDX[1:0] (1) Endpoint 00 001916 001A16 001B16 001C16 001D16 001E16 001F16 0FEC16 0FED16 ERR00 BSRDY00 SETUP00 PID00[1:0] BVAL00 CTENDE00 CTSTS00 CTEND00 BRDY00 BBYT00[3:0] BADD00[4:0] (2) Endpoint 01 001916 001A16 001B16 001C16 001D16 001E16 001F16 0FEC16 0FED16 DIR01 ITMD01 SQCL01 DBLB01 ERR01 BSIZ01[1:0] PID01[1:0] B0VAL01 B1VAL01 B1RDY01 B0RDY01 B0BYT01[6:0] B1BYT01[6:0] MXPS01[6:0] BADD01[4:0] (3) Endpoint 02 001916 001A16 001B16 001C16 001D16 001E16 001F16 0FEC16 0FED16 DIR02 ITMD02 SQCL02 DBLB02 ERR02 BSIZ02[1:0] PID02[1:0] B0VAL02 B1VAL02 B1RDY02 B0RDY02 B0BYT02[6:0] B1BYT02[6:0] MXPS02[6:0] BADD02[4:0] (4) Endpoint 03 001916 001A16 001B16 001C16 001D16 001E16 001F16 0FEC16 0FED16 DIR03 ITMD03 SQCL03 DBLB03 ERR03 BSIZ03[1:0] PID03[1:0] B0VAL03 B1VAL03 B1RDY03 B0RDY03 B0BYT03[6:0] B1BYT03[6:0] MXPS03[6:0] BADD03[4:0] : Not used Fig. 29 USB related registers 31 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER USB Related Registers The USB related registers are shown below. b0 b7 USB control register (USBCON) [address 001016] Bit symbol WKUP TRONCON TRONE VREFCON VREFE USBDIFE UCLKCON USBE At reset R W H/W S/W 0 : Returning to BUS idle state by writing “1” first and 0 Remote wakeup bit – O O then “0”. (Remote wakeup signal) 1 : K-state output 0 : “L” output mode (valid in TRONE = “1”) TrON output control bit 0 – O O 1 : “H” output mode (valid in TRONE = “1”) 0 : TrON port output disabled (Hi-Z state) TrON output enable bit 0 – O O 1 : TrON port output enabled USB reference voltage control bit 0 : Normal mode (valid in VREFE = “1”) 0 – O O 1 : Low current mode (valid in VREFE = “1”) USB reference voltage enable bit 0 : USB reference voltage circuit operation disabled 0 – O O 1 : USB reference voltage circuit operation enabled USB difference input enable bit 0 : Upstream-port difference input circuit operation disabled 0 – O O 1 : Upstream--port difference input circuit operation enabled 0 : External oscillating clock f(XIN) USB clock select bit 0 – O O 1 : PLL circuit output clock fVCO USB module operation enable bit 0 : USB module reset 0 – O O 1 : USB module operation enabled Bit name Function –: State remaining Fig. 30 Structure of USB control register b0 b7 0 0 0 0 0 0 0 USB function enable register (USBAE) [address 001116] Bit symbol Bit name AD0E USB function enable bit b7:b1 Not used Function 0: USB function address register invalidated 1: USB function address register validated Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 31 Structure of USB function enable register 32 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 USB function address register (USBA0) [address 001216] 0 Bit symbol Function Bit name USBADD0 [6:0] USB function address bit b7 Not used In AD0E = “0”, this value changes after writing. In AD0E = “1”, this value changes after completion of SET_ADDRESS control transferring. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 0 O O – – O O –: State remaining Fig. 32 Structure of USB function address register b0 b7 Frame number register Low (FNUML) [address 001416] Bit symbol FNUM [7:0] Function Bit name Frame number low bit The frame number is updated at SOF reception. At reset R W H/W S/W InIn- O ✕ definite definite Fig. 33 Structure of Frame number register Low b0 b7 0 0 0 0 0 Frame number register High (FNUMH) [address 001516] Bit symbol FNUM [10:8] b7:b3 Bit name Function Frame number high bit The frame number is updated at SOF reception. Not used Write “0” when writing. “0” is read when reading. At reset R W H/W S/W InIn- O ✕ definite definite – – O O –: State remaining Fig. 34 Structure of Frame number register High 33 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 USB interrupt source enable register (USBICON) [address 001616] Bit symbol Bit name b5:b4 USB function/Endpoint 0 interrupt enable bit USB function/Endpoint 1 interrupt enable bit USB function/Endpoint 2 interrupt enable bit USB function/Endpoint 3 interrupt enable bit Not used SUSE Suspend interrupt enable bit RSME Resume interrupt enable bit EP00E EP01E EP02E EP03E Function 0 : Interrupt disabled 1 : Interrupt enabled 0 : Interrupt disabled 1 : Interrupt enabled 0 : Interrupt disabled 1 : Interrupt enabled 0 : Interrupt disabled 1 : Interrupt enabled Write “0” when writing. “0” is read when reading. 0 : Interrupt disabled 1 : Interrupt enabled 0 : Interrupt disabled 1 : Interrupt enabled At reset R W H/W S/W 0 0 O O 0 0 O O 0 0 O O 0 0 O O – – O O 0 0 O O 0 0 O O –: State remaining Fig. 35 Structure of USB interrupt source enable register 34 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 USB interrupt source register (USBIREQ) [address 001716] 0 Bit symbol Bit name EP00 USB function/Endpoint 0 interrupt bit EP01 USB function/Endpoint 1 interrupt bit EP02 USB function/Endpoint 2 interrupt bit EP03 USB function/Endpoint 3 interrupt bit b5:b4 Not used SUS Suspend interrupt bit RSM Resume interrupt bit At reset R W H/W S/W This bit is set to “1” when any one of EP00 interrupt 0 0 O ✕ source register’s bits at least is set to “1”. This bit is cleared to “0” by clearing EP00 interrupt source register to “0016”. Writing to this bit causes no state change. This bit is set to “1” when any one of EP01 interrupt 0 0 O ✕ source register’s bits at least is set to “1”. This bit is cleared to “0” by clearing EP01 interrupt source register to “0016”. Writing to this bit causes no state change. This bit is set to “1” when any one of EP02 interrupt 0 0 O ✕ source register’s bits at least is set to “1”. This bit is cleared to “0” by clearing EP02 interrupt source register to “0016”. Writing to this bit causes no state change. This bit is set to “1” when any one of EP03 interrupt 0 0 O ✕ source register’s bits at least is set to “1”. This bit is cleared to “0” by clearing EP03 interrupt source register to “0016”. Writing to this bit causes no state change. Write “0” when writing. – – O O “0” is read when reading. 0 : No interrupt request issued 0 0 O O 1 : Interrupt request issued This bit is set to “1” when detecting 3 ms or more of Jstate, using USB clock (fUSB) at 48 MHz. “0” can be set by software, but “1” cannot be set. This bit is set to “1” when the USB bus state changes 0 0 O ✕ from J-state to K-state or SE0 in the resume interrupt enable bit = “1”. It is also “1” in the condition of internal clock stopped. This bit is cleared to “0” by clearing the resume interrupt enable bit. Writing to this bit causes no state change. Function –: State remaining Fig.36 Structure of USB interrupt source register b0 b7 0 0 0 0 0 0 Endpoint index register (USBINDEX) [address 001816] Bit symbol Bit name EPIDX [1:0] Endpoint index bit b7:b3 Not used Function b1 b0 0 0 : Endpoint 0 0 1 : Endpoint 1 1 0 : Endpoint 2 1 1 : Endpoint 3 Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 37 Structure of Endpoint index register 35 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) Endpoint 00 b0 b7 0 0 0 0 0 EP00 stage register (EP00STG) [address 001916] 0 0 Bit symbol Function Bit name SETUP00 SETUP packet detection bit b7:b1 Not used This bit is set to “1” at reception of SETUP packet. Writing “0” to this bit clears this bit if the next SETUP token does not occur. Writing “1” to this bit causes no state change of the status flags. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 1 1 O O – – O O –: State remaining Fig. 38 Structure of EP00 stage register b0 b7 0 0 0 0 0 EP00 control register 1 (EP00CON1) [address 001A16] 0 Bit symbol Function Bit name PID00 [1:0] Response PID bit b7:b2 Not used b1 b0 0 0 : NAK 0 1 : Automatic response (ACK, NAK, DATA0, DATA1) 1 X : STALL At occurrence of control transfer error: B1 is set to “1” by the hardware. At reception of SETUP token: B1 and b0 are cleared to “0” by the hardware. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 39 Structure of EP00 control register 1 b0 b7 0 0 0 0 0 0 0 EP00 control register 2 (EP00CON2) [address 001B16] Bit symbol Bit name BVAL00 Buffer enable bit b7:b1 Not used Function 0 : NAK transmission (SIE is disabled to read a buffer.) 1 : Transmitting/receiving data set state (SIE is possible to read from/write to a buffer.) At reception of SETUP token: This bit is cleared to “0” by the hardware. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 40 Structure of EP00 control register 2 36 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 0 0 0 EP00 control register 3 (EP00CON3) [address 001C16] 0 Bit symbol CTENDE00 Control transfer completion enable bit b7:b1 Function Bit name Not used 0 : NAK transmission in the status stage 1 : Control transfer completion enabled (SIE transmits NULL/ACK.) (valid in PID00 = “012”) At reception of SETUP token: This bit is cleared to “0” by the hardware. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 41 Structure of EP00 control register 3 b7 0 0 0 b0 EP00 interrupt source register (EP00REQ) [address 001D16] Bit symbol BRDY00 CTEND00 CTSTS00 BSRDY00 ERR00 b7:b5 Bit name Function 0: No interrupt request issued 1: Interrupt request issued This bit is set to “1” when the buffer is ready state (enabled to be read/written) on USB function/Endpoint 0. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 0 control 0: No interrupt request issued transfer completion interrupt bit 1: Interrupt request issued This bit is set to “1” when control transfer is completed (NULL/ACK transmission in the status stage) on USB function/Endpoint 0. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 0 status 0: No interrupt request issued 1: Interrupt request issued stage transition interrupt bit This bit is set to “1” when transition to status stage occurs in CTENDE00 = “0” (control transfer completion disabled) on USB function/Endpoint 0. “0” can be set by software, but “1” cannot be set. <Transition to status stage occurrence factor> At transfer of control write: When receiving IN-token in data stage (OUT) At transfer of control read: When receiving OUT-token in data stage (IN) At no data transfer: Nothing occurs. USB function/Endpoint 0 SETUP 0: No interrupt request issued 1: Interrupt request issued buffer ready interrupt bit This bit is set to “1” when the exclusive buffer for SETUP is ready state (enabled to be read) on USB function/Endpoint 0. “0” can be set by software, but “1” cannot be set. 0: No interrupt request issued USB function/Endpoint 0 error 1: Interrupt request issued interrupt bit This bit is set to “1” when control transfer error occurs on USB function/Endpoint 0. This bit is cleared to “0” by the hardware when receiving SETUP token. “0” can be set by software, but “1” cannot be set. Write “0” when writing. Not used “0” is read when reading. USB function/Endpoint 0 buffer ready interrupt bit At reset R W H/W S/W 0 0 O O 0 0 O O 0 0 O O 0 0 O O 0 0 O O – – O O –: State remaining Fig. 42 Structure of EP00 interrupt source register 37 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 EP00 transmit/receive byte number register (EP00BYT) [address 001E16] 0 Bit symbol BBYT00 [3:0] b7:b4 Function Bit name Transmit/receive byte number bit OUT : The received byte number is automatically set. IN : Set the transmitting byte number. Write “0” when writing. Not used “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 43 Structure of EP00 transmit/receive byte number register b0 b7 0 0 0 EP00 buffer area set register (EP00BUF) [address 0FED16] Bit symbol Bit name BADD00 [4:0] EP00 beginning address set bit b7:b5 Not used Function Set the beginning address of EP00’s buffer area. (32-byte unit) b4b3b2b1b0 0 0 0 1 0 : 004016 0 0 0 1 1 : 006016 .............. 1 1 1 1 0 : 03C016 1 1 1 1 1 : 03E016 Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 44 Structure of EP00 buffer area set register 38 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (2) Endpoint 01 b0 b7 EP01 set register (EP01CFG) [address 001916] Bit symbol BSIZ01 [1:0] DBLB01 SQCL01 ITMD01 DIR01 TYP01 [1:0] At reset R W H/W S/W Double buffer beginning address set In double buffer mode set the beginning address of 0 – O O buffer 1 area, using a relative value for the beginning bit address of buffer 0. b1b0 0 0 = 8 bytes 0 1 = 16 bytes 1 0 = 64 bytes 1 1 = 128 bytes 0 : Single buffer mode Buffer mode select bit 0 – O O 1 : Double buffer mode 0 : Toggle bit clear disabled Sequence toggle bit clear bit 0 – O O 1 : Writing “1” clears the toggle bit and DATA0 is used as the next data PID. “0” is always read when reading. Interrupt toggle mode select bit 0 : Normal mode 0 – O O 1 : Continuous toggle mode (valid at Interrupt IN transfer) 0 : OUT (Data is received from the host.) Transfer direction bit 0 – O O 1 : IN (Data is transmitted to the host.) b7b6 Transfer type bite 0 – O O 0 0 : Transfer disabled 0 1 : Bulk transfer 1 0 : Interrupt transfer 1 1 : Isochronous transfer Function Bit name –: State remaining Fig. 45 Structure of EP01 set register b0 b7 0 0 0 0 0 0 EP01 control register 1 (EP01CON1) [address 001A16] Bit symbol Bit name PID01 [1:0] Response PID bit b7:b2 Not used Function b1 b0 0 0 : NAK 0 1 : Automatic response (ACK, NAK, DATA0, DATA1) 1 X : STALL At occurrence of over-max. packet size : B1 is set to “1” by the hardware. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 46 Structure of EP01 control register 1 39 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 0 0 0 0 EP01 control register 2 (EP01CON2) [address 001B16] Bit symbol Bit name B0VAL01 Buffer 0 enable bit b7:b1 Not used At reset R W H/W S/W O O 0 – When the selected endpoint is IN, writing “1” to this bit makes the transmitting data a set state (SIE is possible to read). When the selected endpoint is OUT, writing “1” to this bit makes data reception possible (SIE is possible to write). – – O O Write “0” when writing. “0” is read when reading. Function –: State remaining Fig. 47 Structure of EP01 control register 2 b0 b7 0 0 0 0 EP01 control register 3 (EP01CON3) [address 001C16] 0 0 0 Bit symbol Bit name B1VAL01 Buffer 1 enable bit b7:b1 Not used At reset R W H/W S/W O O 0 – When the selected endpoint is IN, writing “1” to this bit makes the transmitting data a set state (SIE is possible to read). When the selected endpoint is OUT, writing “1” to this bit makes data reception possible (SIE is possible to write). In double buffer mode this bit is valid. – – O O Write “0” when writing. Function “0” is read when reading. –: State remaining Fig. 48 Structure of EP01 control register 3 b0 b7 0 0 0 0 0 EP01 interrupt source register (EP01REQ) [address 001D16] Bit symbol B0RDY01 B1RDY01 ERR01 b7:b3 Bit name Function USB function/Endpoint 1 buffer 0 0: No interrupt request issued ready interrupt bit 1: Interrupt request issued This bit is set to “1” when the buffer 0 is ready state (enabled to be read/written) on USB function/Endpoint 1. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 1 buffer 1 0: No interrupt request issued ready interrupt bit 1: Interrupt request issued In single buffer mode this bit is invalid. This bit is set to “1” when the buffer 1 is ready state (enabled to be read/written) on USB function/Endpoint 1 in double buffer mode. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 1 error 0: No interrupt request issued interrupt bit 1: Interrupt request issued This bit is set to “1” when STALL response occurs on USB function/Endpoint 1. “0” can be set by software, but “1” cannot be set. Not used Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 0 O O 0 0 O O 0 0 O O – – O O Fig. 49 Structure of EP01 interrupt source register 40 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 EP01 byte number register 0 (EP01BYT0) [address 001E16] 0 Bit symbol B0BYT01 [6:0] IN : Transmit byte number bit OUT : Receive byte number bit b7 Function Bit name Not used Single buffer mode: Set the transmitting byte number. Double buffer mode : Set the transmitting byte number of buffer 0. Single buffer mode : The received byte number is automatically set. Double buffer mode : The received byte number of buffer 0 is automatically set. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O ✕ – – O O –: State remaining Fig. 50 Structure of EP01 byte number register 0 b7 b0 EP01 byte number register 1 (EP01BYT1) [address 001F16] 0 Bit symbol B1BYT01 [6:0] IN : Transmit byte number bit OUT : Receive byte number bit b7 Function Bit name Not used Single buffer mode: These bits are invalid. Double buffer mode : Set the transmitting byte number of buffer 1. Single buffer mode: These bits are invalid. Double buffer mode : The received byte number of buffer 1 is automatically set. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O ✕ – – O O –: State remaining Fig. 51 Structure of EP01 byte number register 1 b7 0 b0 EP01 MAX. packet size register (EP01MAX) [address 0FEC16] Bit symbol MXPS01 [6:0] b7 Bit name Max. packet size bit Not used Function IN : These bits are invalid. OUT : Set the maximum packet size. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 52 Structure of EP01 MAX. packet size register 41 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 EP01 buffer area set register (EP01BUF) [address 0FED16] Bit symbol Bit name BADD01 [4:0] EP01 beginning address set bit b7:b5 Not used Function Set the beginning address of EP01’s buffer area. (32-byte unit) b4b3b2b1b0 0 0 0 1 0 : 004016 0 0 0 1 1 : 006016 .............. 1 1 1 1 0 : 03C016 1 1 1 1 1 : 03E016 Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 53 Structure of EP01 buffer area set register 42 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (3) Endpoint 02 b0 b7 EP02 set register (EP02CFG) [address 001916] Bit symbol BSIZ02 [1:0] DBLB02 SQCL02 ITMD02 DIR02 TYP02 [1:0] At reset R W H/W S/W Double buffer beginning address set In double buffer mode set the beginning address of buffer 1 0 – O O area, using a relative value for the beginning address of bit buffer 0. b1b0 0 0 = 8 bytes 0 1 = 16 bytes 1 0 = 64 bytes 1 1 = 128 bytes 0 : Single buffer mode Buffer mode select bit 0 – O O 1 : Double buffer mode 0 : Toggle bit clear disabled Sequence toggle bit clear bit 0 – O O 1 : Writing “1” clears the toggle bit and DATA0 is used as the next data PID. “0” is always read when reading. Interrupt toggle mode select bit 0 : Normal mode 0 – O O 1 : Continuous toggle mode (valid at Interrupt IN transfer) 0 : OUT (Data is received from the host.) Transfer direction bit 0 – O O 1 : IN (Data is transmitted to the host.) b7b6 Transfer type bite 0 – O O 0 0 : Transfer disabled 0 1 : Bulk transfer 1 0 : Interrupt transfer 1 1 : Isochronous transfer Function Bit name –: State remaining Fig. 54 Structure of EP02 set register b0 b7 0 0 0 0 0 0 EP02 control register 1 (EP02CON1) [address 001A16] Bit symbol Bit name PID02 [1: 0] Response PID bit b7:b2 Not used Function b1 b0 0 0 : NAK 0 1 : Automatic response (ACK, NAK, DATA0, DATA1) 1 X : STALL At occurrence of over-max. packet size : B1 is set to “1” by the hardware. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 55 Structure of EP02 control register 1 43 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 0 0 0 EP02 control register 2 (EP02CON2) [address 001B16] 0 Bit symbol Bit name B0VAL02 Buffer 0 enable bit b7:b1 Not used At reset R W H/W S/W O O 0 – When the selected endpoint is IN, writing “1” to this bit makes the transmitting data a set state (SIE is possible to read). When the selected endpoint is OUT, writing “1” to this bit makes data reception possible (SIE is possible to write). – – O O Write “0” when writing. “0” is read when reading. Function –: State remaining Fig. 56 Structure of EP02 control register 2 b0 b7 0 0 0 0 0 0 0 EP02 control register 3 (EP02CON3) [address 001C16] Bit symbol Bit name B1VAL02 Buffer 1 enable bit b7:b1 Not used At reset R W H/W S/W O O 0 – When the selected endpoint is IN, writing “1” to this bit makes the transmitting data a set state (SIE is possible to read). When the selected endpoint is OUT, writing “1” to this bit makes data reception possible (SIE is possible to write). In double buffer mode this bit is valid. – – O O Write “0” when writing. Function “0” is read when reading. –: State remaining Fig. 57 Structure of EP02 control register 3 b0 b7 0 0 0 0 0 EP02 interrupt source register (EP02REQ) [address 001D16] Bit symbol B0RDY02 B1RDY02 ERR02 b7 to b3 Bit name Function USB function/Endpoint 2 buffer 0 0 : No interrupt request issued ready interrupt bit 1 : Interrupt request issued This bit is set to “1” when the buffer 0 is ready state (enabled to be read/written) on USB function/Endpoint 2. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 2 buffer 1 0 : No interrupt request issued ready interrupt bit 1 : Interrupt request issued In single buffer mode this bit is invalid. This bit is set to “1” when the buffer 1 is ready state (enabled to be read/written) on USB function/Endpoint 2 in double buffer mode. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 2 error 0 : No interrupt request issued interrupt bit 1 : Interrupt request issued This bit is set to “1” when STALL response occurs on USB function/Endpoint 2. “0” can be set by software, but “1” cannot be set. Not used Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 0 O O 0 0 O O 0 0 O O – – O O Fig. 58 Structure of EP02 interrupt source register 44 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 EP02 byte number register 0 (EP02BYT0) [address 001E16] 0 Bit symbol B0BYT02 [6:0] IN : Transmit byte number bit OUT : Receive byte number bit b7 Function Bit name Not used Single buffer mode: Set the transmitting byte number. Double buffer mode : Set the transmitting byte number of buffer 0. Single buffer mode: The received byte number is automatically set. Double buffer mode : The received byte number of buffer 0 is automatically set. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O ✕ – – O O –: State remaining Fig. 59 Structure of EP02 byte number register 0 b7 b0 EP02 byte number register 1 (EP02BYT1) [address 001F16] 0 Bit symbol B1BYT02 [6:0] IN : Transmit byte number bit OUT : Receive byte number bit b7 Function Bit name Not used Single buffer mode: These bits are invalid. Double buffer mode : Set the transmitting byte number of buffer 1. Single buffer mode: These bits are invalid. Double buffer mode : The received byte number of buffer 1 is automatically set. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O ✕ – – O O –: State remaining Fig. 60 Structure of EP02 byte number register 1 b7 0 b0 EP02 MAX. packet size register (EP02MAX) [address 0FEC16] Bit symbol MXPS02 [6:0] b7 Bit name Max. packet size bit Not used Function IN : These bits are invalid. OUT : Set the maximum packet size. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 61 Structure of EP02 MAX. packet size register 45 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 EP02 buffer area set register (EP02BUF) [address 0FED16] Bit symbol Bit name BADD02 [4:0] EP02 beginning address set bit b7:b5 Not used Function Set the beginning address of EP02’s buffer area. (32-byte unit) b4b3b2b1b0 0 0 0 1 0 : 004016 0 0 0 1 1 : 006016 .............. 1 1 1 1 0 : 03C016 1 1 1 1 1 : 03E016 Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 62 Structure of EP02 buffer area set register 46 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (4) Endpoint 03 b0 b7 EP03 set register (EP03CFG) [address 001916] Bit symbol BSIZ03 [1:0] DBLB03 SQCL03 ITMD03 DIR03 TYP03 [1:0] At reset R W H/W S/W Double buffer beginning address set In double buffer mode set the beginning address of buffer 1 0 – O O area, using a relative value for the beginning address of bit buffer 0. b1b0 0 0 = 8 bytes 0 1 = 16 bytes 1 0 = 64 bytes 1 1 = 128 bytes 0 : Single buffer mode Buffer mode select bit 0 – O O 1 : Double buffer mode 0 : Toggle bit clear disabled Sequence toggle bit clear bit 0 – O O 1 : Writing “1” clears the toggle bit and DATA0 is used as the next data PID. “0” is always read when reading. Interrupt toggle mode select bit 0 : Normal mode 0 – O O 1 : Continuous toggle mode (valid at Interrupt IN transfer) 0 : OUT (Data is received from the host.) Transfer direction bit 0 – O O 1 : IN (Data is transmitted to the host.) b7b6 Transfer type bit 0 – O O 0 0 : Transfer disabled 0 1 : Bulk transfer 1 0 : Interrupt transfer 1 1 : Isochronous transfer Function Bit name –: State remaining Fig. 63 Structure of EP03 set register b0 b7 0 0 0 0 0 0 EP03 control register 1 (EP03CON1) [address 001A16] Bit symbol Bit name PID03 [1:0] Response PID bit b7:b2 Not used Function b1 b0 0 0 : NAK 0 1 : Automatic response (ACK, NAK, DATA0, DATA1) 1 X : STALL At occurrence of over-max. packet size : B1 is set to “1” by the hardware. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 64 Structure of EP03 control register 1 47 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 0 0 0 0 EP03 control register 2 (EP03CON2) [address 001B16] Bit symbol Bit name B0VAL03 Buffer 0 enable bit b7:b1 Not used At reset R W H/W S/W O O 0 – When the selected endpoint is IN, writing “1” to this bit makes the transmitting data a set state (SIE is possible to read). When the selected endpoint is OUT, writing “1” to this bit makes data reception possible (SIE is possible to write). – – O O Write “0” when writing. “0” is read when reading. Function –: State remaining Fig. 65 Structure of EP03 control register 2 b0 b7 0 0 0 0 EP03 control register 3 (EP03CON3) [address 001C16] 0 0 0 Bit symbol Bit name B1VAL03 Buffer 1 enable bit b7:b1 Not used At reset R W H/W S/W O O 0 – When the selected endpoint is IN, writing “1” to this bit makes the transmitting data a set state (SIE is possible to read). When the selected endpoint is OUT, writing “1” to this bit makes data reception possible (SIE is possible to write). In double buffer mode this bit is valid. – – O O Write “0” when writing. Function “0” is read when reading. –: State remaining Fig. 66 Structure of EP03 control register 3 b0 b7 0 0 0 0 0 EP03 interrupt source register (EP03REQ) [address 001D16] Bit symbol B0RDY03 B1RDY03 ERR03 b7:b3 Bit name Function USB function/Endpoint 3 buffer 0 0 : No interrupt request issued ready interrupt bit 1 : Interrupt request issued This bit is set to “1” when the buffer 0 is ready state (enabled to be read/written) on USB function/Endpoint 3. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 3 buffer 1 0 : No interrupt request issued ready interrupt bit 1 : Interrupt request issued In single buffer mode this bit is invalid. This bit is set to “1” when the buffer 1 is ready state (enabled to be read/written) on USB function/Endpoint 3 in double buffer mode. “0” can be set by software, but “1” cannot be set. USB function/Endpoint 3 error 0 : No interrupt request issued interrupt bit 1 : Interrupt request issued This bit is set to “1” when STALL response occurs on USB function/Endpoint 3. “0” can be set by software, but “1” cannot be set. Not used Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 0 O O 0 0 O O 0 0 O O – – O O Fig. 67 Structure of EP03 interrupt source register 48 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 EP03 byte number register 0 (EP03BYT0) [address 001E16] 0 Bit symbol B0BYT03 [6:0] IN : Transmit byte number bit OUT : Receive byte number bit b7 Function Bit name Not used Single buffer mode: Set the transmitting byte number. Double buffer mode : Set the transmitting byte number of buffer 0. Single buffer mode: The received byte number is automatically set. Double buffer mode : The received byte number of buffer 0 is automatically set. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O ✕ – – O O –: State remaining Fig. 68 Structure of EP03 byte number register 0 b7 b0 EP03 byte number register 1 (EP03BYT1) [address 001F16] 0 Bit symbol B1BYT03 [6:0] IN : Transmit byte number bit OUT : Receive byte number bit b7 Function Bit name Not used Single buffer mode: These bits are invalid. Double buffer mode : Set the transmitting byte number of buffer 1. Single buffer mode: These bits are invalid. Double buffer mode : The received byte number of buffer 1 is automatically set. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O ✕ – – O O –: State remaining Fig. 69 Structure of EP03 byte number register 1 b7 0 b0 EP03 MAX. packet size register (EP03MAX) [address 0FEC16] Bit symbol MXPS03 [6:0] b7 Bit name Max. packet size bit Not used Function IN : These bits are invalid. OUT : Set the maximum packet size. Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 70 Structure of EP03 MAX. packet size register 49 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 EP03 buffer area set register (EP03BUF) [address 0FED16] Bit symbol Bit name BADD03 [4:0] EP03 beginning address set bit b7:b5 Not used Function Set the beginning address of EP03’s buffer area. (32-byte unit) b4b3b2b1b0 0 0 0 1 0 : 004016 0 0 0 1 1 : 006016 .............. 1 1 1 1 0 : 03C016 1 1 1 1 1 : 03E016 Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O – – O O –: State remaining Fig. 71 Structure of EP03 buffer area set register 50 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER EXTERNAL BUS INTERFACE (EXB) The external bus interface (EXB) controls the data transfer between the external MCU and the 38K0 group’s CPU or its memory (multichannel RAM). The external bus interface is shown below. 38K0 group CPU Program ROM Peripheral functions External MCU CPU channel [Interrupt type] External bus interface (EXB) Multichannel RAM USB USB bus (USB host) Memory channel [Direct RAM access type] Fig. 72 External bus interface ●CPU channel It is a data transfer course by the interrupt processing between the external MCU and the 38K0 group’s CPU. ●Memory channel It is a data transfer course by direct RAM access of the memory channel controller between the external MCU and the 38K0 group’s memory (multichannel RAM) ●Data transfer of memory channel When the burst mode is selected with the burst bit of the memory channel operation mode register, data transfer can be carried out at the highest speed. After the external bus interface detects a rise of external read signal/write signal and synchronizes it with the internal clock φ, it completes the data transfer between the transmit/ receive buffer and the multichannel RAM in two clocks. However, the waiting time of two clocks at a maximum is generated to access the multichannel RAM in USB being operating because the USB has priority to access. Therefore, it is necessary to set up the access interval which fills the following timing with the external MCU bus side. In φ = 8 MHz, data transfer at about 2 Mbytes/second is possible at a maximum. When there is access simultaneously from the USB, it is about 1.3 Mbytes/second. In φ = 6 MHz, data transfer at about 1.5 Mbytes/second is possible at a maximum. When there is access simultaneously from the USB, it is about 1 Mbytes/second. Address CS, RD, WR, DMA acknowledge Access cycle time from externals: •3 clocks or more of φ + Signal delay time + Data setup time of external MCU in USB inactive •5 clocks or more of φ + Signal delay time + Data setup time of external MCU in USB active Fig. 73 Data transfer timing of memory channel 51 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER EXB Pin Assignment The external bus interface (EXB) pins are shown bellow. The 38K0 group can transmit/receive a data to/from an external MCU, using the following signals: •Control input signal ................ 4 (ExCS, ExA0, ExRD, ExWR) •Data input/output pin .............. 8 (DQ0 to DQ7) •Interrupt output signal ............ 1 (ExINT) Additionally, the DMA interface signal and the buffer status read select signal of 38K0 group can be set up per one by the program. •Control input signal ................ 3 (ExTC, ExDACK, ExRD, ExA1) •Interrupt output signal ............ 1 (ExDREQ) 38K0 group External bus interface (EXB) External pins External chip select External address External read External write External data External interrupt 8 P34/ExCS [“L”] P37/ExA0 [address] P36/ExRD [“L”] P35/ExWR [“L”] P10/DQ0/AN0–P17/DQ7/AN7 [data] P33/ExINT [“L”] DMA request Terminal count DMA acknowledge P40/ExDREQ/RxD [“L”] P42/ExTC/SCLK [“L”] P41/ExDACK/TxD [“L”] Status read select P43/ExA1/SRDY [“H”] CPU Multichannel RAM : Functions as normal ports just after reset. Fig. 74 External bus interface (EXB) pin assignment 52 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER EXB Block Diagram The block diagram of external bus interface (EXB) is shown below. The external bus interface (EXB) consists of: (1) External I/O interface part (2) CPU interface part (3) Internal memory interface part (4) Transmit/Receive data buffer part External I/O interface CPU interface Configuration signal Index register External I/O configuration register EXB interrupt source enable register Cch_WR External MCU bus Cch_RD P34/ExCS TxB_RDY CPU channel controller Decoder data selector RxB_RDY Command decoder P37/ExA0 P36/ExRD P35/ExWR Memory channel control Mch_RD Mch_WR Mch_TC P41/ExDACK/TxD P42/ExTC/SCLK mRX_enb mTX_enb Memory channel status Internal memory interface Memory channel operation mode register P43/ExA1/SRDY Memory address Output selector Memory address counter P40/ExDREQ/RxD End address register Mch_req FIFO_stt Request acknowledge Memory channel controller MRDsel Memory channel transmit buffer control stt_sel Multichannel RAM P33/ExINT Buf_WR ExOE Transmit/Receive data buffer Memory read data P10/DQ0/AN0– P17/DQ7/AN7 Transmit buffer register Memory write data Receive buffer register : Functions as normal ports just after reset. Fig. 75 Block diagram of external bus interface (EXB) 53 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) External I/O Interface Part (2) CPU Interface Part The external I/O interface part consists of a command decoder and an output selector. A command decoder generates the following signals to each unit. The CPU interface part consists of the decoder/data selector of the CPU channel, the CPU write register and CPU channel controller ●CPU interface part •CPU channel read (Cch_RD) •CPU channel write (Cch_WR) ●Decoder/data selector of CPU channel A write operation to the CPU register is performed by generating a write signal for each register with an address decode signal and a write signal. A read operation from the CPU register is performed by generating an output enable signal of the internal data bus with an module select signal and a read signal and generating a select signal for each register with an address decode signal. ●Internal memory interface part •Memory channel read (Mch_RD) •Memory channel write (Mch_WR) •Memory channel terminal count (Mch_TC) ●Transmit/receive data buffer part •Buffer write (Buf_WR) ●External I/O interface part •Status selection (stt_sel) •Output enable (ExOE) Access to the CPU channel can be controlled only by setup of external signals. Access to the memory channel can be controlled by the value of the external I/O configuration register and the state (mRX_enb, mTX_enb signals) of the internal memory interface part. The output selector has the function which selects from the state of CPU channel (TxB_RDY and RxD_RDY) and the state of memory channel (Mch_req) as the signal assigned to P3 3 / ExINT pin and P40/ExDREQ/RxD pin. ●CPU write register There are three CPU write registers as follows: •EXB interrupt source enable register •Index register •External I/O configuration register The EXB interrupt source register is a read-only register. A status signal of the CPU channel controller and a status signal of the memory channel controller in the internal memory interface part are generated. ●CPU channel controller The CPU channel controller generates the following signals, using bits 0 and 1 (RXB_ENB, TXB_ENB) of EXB interrupt source enable register. •Memory channel transmitting buffer control signal (MRD_sel), generated in the internal memory interface part •CPU channel command signal (Cch_RD, Cch_WR), generated in the external I/O interface part •Signals RxB_RDY/RxB_full and TxB_RDY/TxB_empty, generated with read/write signals from the CPU channel 54 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (3) Internal Memory Interface Part (5) External Pin The internal memory interface part consists of the CPU register and the memory channel controller. The external bus interface has the following pins to connect with an external MCU bus. •Chip select ........................... P34/ExCS •Address ................................ P37/ExA0 •Data ...................................... P10/DQ0/AN0 to P17/DQ7/AN7 •Read .................................... P36/ExRD •Write ..................................... P35/ExWR •Interrupt request .................. P33/ExINT ●CPU register The CPU register consists of the follows: •Memory channel operation mode register •Memory address counter •End address register The CPU can set the beginning address into the memory address counter when the memory channel operation enable bit (MC_ENB) of EXB interrupt source enable register is “0”. When this bit is “1”, the write operation from the CPU is invalid and each access from the external bus causes count-up operation. ●Memory channel controller The CPU register consists of the follows: •Main sequencer •Internal memory request signal generating circuit •External memory channel request signal generating circuit •Address end detection circuit •Terminal end input processing circuit (4) Transmit/Receive Data Buffer Part The transmit/receive data buffer part consists of the 8-bit transmit buffer register (TXBUF) and the 8-bit receive buffer register (RXBUF). Both CPU channel and memory channel use the same transmit buffer register/receive buffer register to transfer a data to an external MCU bus. It also has the following pins to connect with an external DMAC. Each pin can be programmed for an ordinary port function or a DMA interface pin function. •DMA request ........................ P40/ExDREQ/RxD •DMA acknowledgment ......... P41/ExDACK/TxD •Terminal count ..................... P42/ExTC/SCLK It also has the status read select pin (P43/ExA1/SRDY pin) to confirm a ready status of the data buffer from an external MCU bus This pin functions as a port just after reset. The status read select function can be set by a program. •Status read select ................ P43/ExA1/SRDY ●CPU channel: Communication with 38K0 group CPU When a read/write operation is performed from an external MCU bus in address signal ExA0 = “H”, the interrupt is generated and the 38K0 group CPU can confirm its access. The 38K0 group CPU judges the interrupt source and it starts a data transmission/reception with an external MCU bus. ●Memory channel: Communication with 38K2 group memory multichannel RAM When a read/write operation is performed from an external MCU bus in address signal ExA0 = “L”, access to the multichannel RAM is performed. Then an address of the multichannel RAM is made by the external bus interface and it is increased at each access completion. Consequently, FIFO access is performed. Even if a read/write operation is performed in DACK = “L” instead of ExCS = “L” and ExA0 = “L”, FIFO access to the multichannel RAM is performed. The beginning address and the end address must be set by the CPU in advance. 55 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●P33/ExINT pin Any one of the following signals for this pin can be selected: •TxB_RDY (transmit buffer ready) output •RxB_RDY (receive buffer ready) output •Mch_req (memory channel request) output Either TxB_RDY or RxB_RDY is normally selected. The memory channel request is for an access request signal to the memory channel. In a small system, a data transfer processing to the internal memory is performed in the interrupt routine. According to that situation, the 38K0 group has the function automatically to switch an interrupt factor attached on the interrupt pin by program. ●P42/ExTC/SCLK pin This pin is a port at the initial state. The terminal count signal can be set by program. If the terminal count signal is set at one bus cycle while a memory channel operation write is being performed, the 38K0 group confirms that its bus cycle is the write cycle of the last data and sets the memory channel status bits to “112”, and the interrupt is generated and the memory channel operation ends even if the memory address counter has not reached the end address. The CPU can obtain the last address where the data is written by reading out the value of memory address counter. (See Figures 87 and 88.) ●P40/ExDREQ/RxD pin This pin is a port at the initial state. Which signal can be set by program. •RxB_RDY (receive buffer ready) output •Mch_req (memory channel request) output Mch_req of DMAC is normally selected. The output method of the memory channel request signal depends on the burst bit (BURST) of memory channel operation mode register. When the burst bit is “0”, this signal is periodically output at each 1-byte transfer. (See Figures 87 and 90.) When the burst bit is “1”, this signal is continuously output while the memory address counter is counting from the beginning address to the end address (See Figures 88 and 91.) ●P41/ExDACK/TxD pin This pin is a port at the initial state. The DMA acknowledge signal can be set by program. The DMA acknowledge signal DACK = “L” is the same state as that of CS = “L” and A0 = “L”. Access to multichannel RAM is started by a rise of read signal or write signal which is set during this term. Note: If the DMA acknowledge signal and the chip select signal are simultaneously active (DACK = “L” and CS = “L”), also set the address signal A0 to “L”. If A0 is “H”, the memory channel and the CPU channel are activated simultaneously and it might cause some error. 56 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER EXB Register List The EXB register list is shown below. Address Register Name EXB SFR SYMBOL 003016 003116 EXB interrupt source enable register EXB interrupt source register EXBICON EXBIREQ 003316 003416 003516 EXB index register Register window 1 (low) Register window 2 (high) EXBINDEX EXBREG1 EXBREG2 bit7 bit6 bit5 bit4 bit2 bit3 MC_ENB MC_STS[1:0] 0 0 0 0 bit1 bit0 TXB_ENB TXB_EMPTY RXB_EMB RXB_FULL INDEX[2:0] 0 LOW_WIN[7:0] HIGH_WIN[7:0] : Not used 0 : “0” fixed Fig. 76 EXB related registers (1) •EXB interrupt source enable register This register enables/disables access from an external bus and an internal interrupt. •EXB index register/Register windows 1, 2 The accessible register is switched by treating addresses 003416 and 003516 as a register window depending on the value of EXB index register at address 003316. •EXB interrupt source register This register indicates the state of CPU channel’s transmit/receive buffer register and the memory channel. The same value can be read out from the external MCU bus by using the buffer status read select signal (A1 pin = “H”). Index 0016 low high low Register Name SYMBOL External I/O configuration register high 0116 low Transmit/Receive buffer register low low low bit4 bit3 EXBCFGL A1_CTR EXBCFGH TC_CTR bit2 bit1 INT_CTR[2:0] DAK_CTR[1:0] bit0 EXB_CTR DRQ_CTR[1:0] At CPU read : RXBUF[7:0] At CPU write : TXBUF[7:0] BURST Memory channel ope- MCHMOD ration mode register MC_DIR[1:0] — Memory address counter high 0416 bit5 — high 0316 bit6 RXBUF/TXBUF high 0216 EXB SFR bit7 MEMADL MEMADH End address register high IM_A[7:0] 0 0 0 0 ENDADL ENDADH 0 IM_A[10:8] 0 END_A[10:8] END_A[7:0] 0 0 0 0 : Not used 0 : “0” fixed Fig. 77 EXB related registers (2) •External I/O configuration register This register selects the function of each pin. •Transmit/Receive buffer register This register consists of the receive buffer register (RXBUF) and the transmit buffer register (TXBUF) •Memory address counter This is a counter to set the beginning address which FIFO accesses. This register is increased by access from the external MCU bus. •End address register This register is to set the end address which FIFO accesses. •Memory channel operation mode register This register sets the operation mode of the memory channel. 57 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER EXB Related Registers The EXB related registers are shown below. b0 b7 0 0 0 0 EXB interrupt source enable register (EXBICON) [address 003016] (Note) 0 Bit symbol RXB_ENB TXB_ENB MC_ENB b7:b3 Bit name Function CPU channel receive enable bit 0 : Operation disabled (Interrupt disabled) 1 : Operation enabled (Receive buffer full interrupt enabled) CPU channel transmit enable bit 0 : Operation disabled (Interrupt disabled) 1 : Operation enabled (Transmit buffer empty interrupt enabled) 0 : Operation disabled (Memory channel operation end Memory channel operation interrupt disabled) enable bit 1 : Operation enabled (Memory channel operation end interrupt disabled) Write “0” when writing. Not used “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O O 0 – O O – – O O –: State remaining Note: Do not set each bit simultaneously. Fig. 78 Structure of EXB interrupt source enable register b0 b7 0 0 0 0 EXB interrupt source register (EXBIREQ) [address 003116] (Note 1) Bit symbol Bit name RXB_FULL Receive buffer full bit TXB_EMPTY Transmit buffer empty bit MC_STS [1:0] (Note 2) Memory channel status bits b7:b4 Not used Function 0 : Receive buffer empty 1 : Receive buffer full 0 : Transmit buffer full 1 : Transmit buffer empty b3b2 0 0 : Memory channel operation stopped 0 1 : Memory channel being operating; No external access 1 0 : Memory channel being operating; External accessing 1 1 : Memory channel operation end; Memory channel operation end interrupt generated Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 0 O – (Note 3) 0 0 O – (Note 4) 0 0 O – – – O O –: State remaining Notes 1: When the the ExA1 pin control bit of external I/O configuration register is “1”, the external MCU bus can read this register contents by setting the ExA1 pin to “H”. 2: The memory channel status bits indicate the status of memory channel. In MC_ENB = “0” these bits are always “002”. When the memory channel operation ends, these bits are set to “112” and the memory channel operation end interrupt is generated. These bits can be read out during operation, so that it will show that whether the external MCU bus is accessing or not. 3: This bit is cleared to “0” when reading the transmit/receive buffer register in the CPU channel receive enable bit = “1” or when the CPU channel receive enable bit is “0”. 4: This bit is cleared to “0” when writing to the transmit/receive buffer register in the CPU channel transmit enable bit = “1” or when the CPU channel transmit enable bit is “0”. Fig. 79 Structure of EXB interrupt source register 58 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 EXB index register (EXBINDEX) [address 003316] 0 0 Bit symbol Bit name INDEX [2:0] Index bits b7:b3 Not used At reset R W H/W S/W – O O The accessible register, using the register window, 0 depends on these index bits contents as follows: b2b1b0 0 0 0 : External I/O configuration register 0 0 1 : Transmit/Receive buffer register 0 1 0 : Memory channel operation mode register 0 1 1 : Memory address counter 1 0 0 : End address register 1 0 1 : Do not set. 1 1 0 : Do not set. 1 1 1 : Do not set. – – O O Write “0” when writing. “0” is read when reading. Function –: State remaining Fig. 80 Structure of EXB index register b7 b0 Register window 1 (EXBREG1) [address 003416] Bit symbol LOW_WIN [7:0] Bit name – At reset R W H/W S/W In- O O The accessible register, using this register window, Independs on the EXB index register contents as definite definite follows: Index value : External I/O configuration register “0016” “0116” : Transmit/Receive buffer register “0216” : Memory channel operation mode register “0316” : Memory address counter “0416” : End address register Function Fig. 81 Structure of Register window 1 b7 b0 Register window 2 (EXBREG2) [address 003516] Bit symbol HIGH_WIN [7:0] Bit name – At reset R W H/W S/W In- O O The accessible register, using this register window, Independs on the EXB index register contents as definite definite follows: Index value : External I/O configuration register “0016” “0116” : Transmit/Receive buffer register : Memory channel operation mode register “0216” : Memory address counter “0316” : End address register “0416” Function Fig. 82 Structure of Register window 2 59 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 Index = 0016 : External I/O configuration register (EXBCFGL) [address 003416] 0 Bit symbol EXB_CTR INT_CTR [2:0] Function Bit name EXB pin control bit (Pins P10 to P17, P30 to P34) P33/ExINT pin control bit A1_CTR P43/ExA1 pin control bit b7:b5 Not used 0 : Port 1 : EXB function pin Selects a signal of P33/ExINT pin. ON/OFF is programmed by each bit. An output logical sum of P33/ExINT pins set for ON are performed and it is output as an “L” active signal. b3b2b1 0 0 1 : RxB_RDY (RxBuf ready) output 0 1 0 : TxB_RDY (TxBuf ready) output 1 0 0 : Mch_req (Memory channel request) output Others : Do not set. 0 : Port 1 : A1 input (used to read status) Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O O 0 – O O – – O O –: State remaining Fig. 83 Index00[low]; Structure of External I/O configuration register b0 b7 0 0 0 Index = 0016 : External I/O configuration register (EXBCFGH) [address 003516] Bit symbol Function Bit name DRQ_CTR [1:0] P40/ExDREQ/RxD pin control bit DAK_CTR [1:0] P41/ExDACK/TxD pin control bit TC_CTR P42/ExTC/SCLK pin control bit b7:b5 Not used b1b0 0 0 : Port 0 1 : Do not set. 1 0 : ExDREQ function; RxB_RDY (RxBuf ready) output 1 1 : ExDREQ function; Mch_req (Memory channel request) output Specifies P41/ExDACK/TxD pin function. Selects which mode; requiring read or write signal, or not requiring it for use of DMA acknowledge function. b3b2 0 0 : Port 0 1 : Do not set. 1 0 : ExDACK function; DMA acknowledge input (Mode for read and write signals used together) 1 1 :ExDACK function; DMA acknowledge input (Mode for read and write signals not required) 0 : Port 1 : ExTC (terminal count) input Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O O 0 – O O – – O O –: State remaining Fig. 84 Index00[high]; Structure of External I/O configuration register 60 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 Index =0116 : Transmit/Receive buffer register (RXBUF/TXBUF) [address 003416] Bit symbol RXBUF/ TXBUF Bit name – At reset R W H/W S/W O O 0 – The data received from an external bus is written here at the rise timing of external write signal. The data transmitted to an external bus is written here at the timing of internal CPU write or memory write. Function The receive buffer register (RXBUF) contents can be read out by reading to this address with the CPU. The data which the CPU has written to this address is stored in the transmit buffer register (TXBUF). However, do not perform write operation with the CPU to this address if the memory channel direction control bits of memory channel operation mode register is “102” (transmit mode) and the memory channel status bits of EXB interrupt source register are “012” or “102” (memory channel being operating). Fig. 85 Index01[low]; Structure of Transmit/Receive buffer register b0 b7 0 0 0 0 Index =0216 : Memory channel operation mode register (MCHMOD) [address 003416] 0 Bit symbol Function Bit name MC_DIR [1:0] Memory channel direction control bit BURST Burst bit b7:b3 Not used b1b0 0 0 : Operation disabled 0 1 : Receive mode 1 0 : Transmit mode 1 1 : Do not set. 0 : Cycle mode (each byte transfer according to assertion or negation) 1 : Burst mode (continuous transfer till the terminal count) Write “0” when writing. “0” is read when reading. At reset R W H/W S/W 0 – O O 0 – O O – – O O –: State remaining Fig. 86 Index02[low]; Structure of Memory channel operation mode register b7 b0 Index = 0316 : Memory address counter (MEMADL) [address 003416] Bit symbol IM_A [7:0] Bit name – At reset R W H/W S/W Register to set the low-order address of memory 0 – O O channel operation beginning. This contents are increased each time one memory access ends. Function Fig. 87 Index03[low]; Structure of Memory address counter 61 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b0 b7 0 0 0 0 Index = 0316 : Memory address counter (MEMADH) [address 003516] 0 Bit symbol Bit name IM_A [10:8] – b7:b3 Not used At reset R W H/W S/W Register to set the high-order address of memory 0 – O O channel operation start. This contents are increased each time one memory access ends. Write “0” when writing. – – O O “0” is read when reading. Function –: State remaining Fig. 88 Index03[high]; Structure of Memory address counter b0 b7 Index = 0416 : End address register (ENDADL) [address 003416] Bit symbol END_A [7:0] Bit name – At reset R W H/W S/W Register to set the low-order address of memory 0 – O O channel operation end. Function –: State remaining Fig. 89 Index04[low]; Structure of End address register b0 b7 0 0 0 0 0 Index = 0416 : End address register (ENDADH) [address 003516] Bit symbol END_A [10:8] b7:b3 Bit name – Not used At reset R W H/W S/W Register to set the high-order address of memory 0 – O O channel operation end. Write “0” when writing. – – O O “0” is read when reading. Function –: State remaining Fig. 90 Index04[high]; Structure of End address register 62 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER EXB Operation Timing Diagram (1) CPU Channel Receiving Operation CPU channel receiving operation is shown bellow. ➀ ➁ ➂ Address ExA0 A0 = “1” A0 = “1” Chip select ExCS CS = “0” CS = “0” Read ExRD ➁ Write ExWR Data DQ0 to DQ7 #0 #1 Internal clock φ Interrupt request ExINT [RxB_RDY] RxB_RDY RxB_RDY Receive buffer full bit RXB_FULL Receive buffer RXBUF #0 #1 Transmit buffer TXBUF CPU channel receive enable bit RXB_ENB ➀ Receive buffer read ➂ <Initial setting> External I/O configuration register INT_CTR[3:1] (P33/ExINT pin control) = 0012 (RxB_RDY interrupt) <Operation start> EXB interrupt source enable register RXB_ENB (CPU channel receive enable) = “1” (Receive buffer full interrupt enabled) ➀ Writing the command for enabling operation makes RXB_RDY assertion and the P33/ExINT pin goes to “L”. If the CPU channel receive enable bit (RXB_ENB) is “0”, both the receive buffer full bit (RXB_FULL) and the receive buffer ready signal (RxB_RDY) to an external are inactive. ➁ When a write operation is performed from an external MCU bus in the condition of ExCS = “L” and WxA0 = “H”, it will result in as follows: • The data is written into the receive buffer (RXBUF) • Negation of the receive buffer ready signal (RxB_RDY) to an external is made • The RXB_FULL interrupt is generated. ➂ When the CPU reads out the receive buffer (RXBUF) with an interrupt processing program, the receive buffer full bit (RXB_FULL) is cleared to “0”. Fig. 91 CPU channel receiving operation 63 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (2) CPU Channel Transmitting Operation CPU channel transmitting operation is shown bellow. ➀ ➁ ➂ ➁’ Address ExA0 A0 = “1” A0 = “1” Chip select ExCS CS = “0” CS = “0” ➂ Read ExRD Write ExWR Data DQ0 to DQ7 #0 #1 Internal clock φ Interrupt request ExINT [TxB_RDY] TxB_RDY TxB_RDY Transmit buffer empty bit TXB_EMPTY Receive buffer RXBUF Transmit buffer TXBUF CPU channel transmit enable bit TXB_ENB #0 #1 ➀ Transmit data write ➁’ ➁ <Initial setting> External I/O configuration register INT_CTR[3:1] (P33/ExINT pin control) = 0102 (TxB_RDY interrupt) <Operation start> EXB interrupt source enable register TXB_ENB (CPU channel transmit enable) = “1” (Transmit buffer empty interrupt enabled) ➀ Writing the command for enabling operation generates TXB_EMPTY interrupt. If the CPU channel transmit enable bit (TXB_ENB) is “0”, both the transmit buffer empty bit (TXB_EMPTY) and the transmit buffer ready signal (TxB_RDY) to an external are inactive. ➁ When the CPU writes the data into the transmit buffer (TXBUF) with an interrupt processing program, the transmit buffer empty bit (TXB_EMPTY) is cleared to “0” and assertion of the transmit buffer ready signal (TxB_RDY) to an external is made. ➂ When a read operation is performed from an external MCU bus in the condition of ExCS = “L” and ExA0 = “H”, it will result in as follows: • The contents of the transmit buffer (TXBUF) is read out • The transmit buffer empty bit (TXB_EMPTY) is set to “1” • Negation of the transmit buffer ready signal (TxB_RDY) to an external is made. Fig. 92 CPU channel tranmitting operation 64 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (3) Memory Channel Receiving Operation (1)Cycle Mode Memory channel receiving operation (1) is shown bellow. ➀ ➁ ➂ ➃ ➁’ Address ExA0 A0 = “0” A0 = “0” Chip select ExCS CS = “0” CS = “0” ➂’ ➄ DMA acknowledge ExDACK Read ExRD Write ExWR Data DQ0 to DQ7 #0 #1 Internal clock φ mWR ➔ detection mWR ➔ DMA request ExDREQ detection Mch_req Mch_req Receive buffer RXBUF #0 #1 ➀ Operation enabled Main sequencer 0 1 2 3 5 Memory channel operation end interrupt Internal memory access req Memory address req 010016 010116 010216 Counter end Acknowledgment of internal memory access ack ack ➃ ➄ <Initial setting> External I/O configuration register Set as necessary. Memory channel operation mode register MC_DIR[1:0] (Memory channel direction control) = 012 (Receive mode) Burst (burst) = “0” (Cycle mode) Memory address counter (Example) 010016 End address register (Example) 010116 <Operation start command> EXB interrupt source enable register MC_ENB (Memory channel operation enable) = “1” (Operation start) ➀ In the memory channel receive mode when the command for enabling operation is written, operation starts (main sequencer starts) and assertion of the memory channel request which synchronized with a rise of φ is made. ➁ When the external MCU bus is in the condition of ExCS = “L” and ExA0 = “L” or a fall of ExWR is detected in the condition of ExDACK = “L”, negation of the memory channel request which synchronized with a rise of φ is made. ➂ When a rise of ExWR is detected, an internal memory access sequence which synchronized with a rise of φ is activated and a data is written in the internal memory within two clocks at a minimum. ➃ The memory address counter is increased simultaneously at write completion and assertion of the next memory channel request is made. ➄ When the write operation to the end address has been completed, the memory address counter is increased, but assertion of the next memory channel request is not made and the memory channel operation end interrupt is generated. Fig. 93 Memory channel receiving operation (1) 65 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (4) Memory Channel Receiving Operation (2)Burst Mode Memory channel receiving operation (2) is shown bellow. ➀ ➁ ➂ ➁’ ➃ ➄ Address ExA0 A0 = “x” A0 = “x” A0 = “x” Chip select ExCS CS = “1” CS = “1” CS = “1” Dack = “0” Dack = “0” Dack = “0” DMA acknowledge ExDACK Read ExRD ➁’ ➁ Write ExWR Data DQ0 to DQ7 #0 #1 #2 Internal clock φ mWR ➔ detection mWR ➔ DMA request ExDREQ detection Mch_req Receive buffer RXBUF #0 #1 #2 Operation enabled ➀ Main sequencer 0 1 2 3 5 Memory channel operation end interrupt Internal memory access req Memory address req 010016 req 010116 010216 010316 Counter end Burst end Acknowledgment of internal memory access ack ack ➂ ack ➃ ➄ <Initial setting> External I/O configuration register Set as necessary. Memory channel operation mode register MC_DIR[1:0] (Memory channel direction control) = 012 (Receive mode) Burst (burst) = “1” (Burst mode) Memory address counter (Example) 010016 End address register (Example) 010216 <Operation start command> EXB interrupt source enable register MC_ENB (Memory channel operation enable) = “1” (Operation start) ➀ In the memory channel receive mode when the command for enabling operation is written, assertion of the memory channel request which synchronized with a rise of φ is made. ➁ When a rise of ExWR is detected, an internal memory access sequence which synchronized with a rise of φ is activated and a data is written in the internal memory within two clocks at a minimum. ➂ The memory address counter is increased simultaneously at the former data write completion. ➃ When the memory address counter reaches the end address, the detection circuit of external write signal (ExWR) operation is enabled and negation of the memory channel request which synchronized with the following φ is made. ➄ When the write operation to the end address has been completed, the memory address counter is increased and the memory channel operation end interrupt is generated. Fig. 94 Memory channel receiving operation (2) 66 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (5) Memory Channel Receiving Operation (3)Burst Mode (Terminal Count) Memory channel receiving operation (3) is shown bellow. ➀’ Address ExA0 A0 = “x” A0 = “x” Chip select ExCS CS = “1” CS = “1” Dack = “0” Dack = “0” DMA acknowledge ExDACK ➁’ ➀ ➀ ➀’ Terminal count ExTC ➁ TC Write ExWR Data DQ0 to DQ7 #0 #1 Internal clock φ mWR ➔ detection mWR ➔ DMA request ExDREQ detection Mch_req mTC ➔ Receive buffer RxBuf #0 #1 detection TC synchronizing ➁’ TC end ➁ ➁’ Operation enabled Main sequencer 0 1 2 3 (5) 5 Memory channel operation end interrupt Memory address ➁’ req Internal memory access 010016 010116 ➁’ ➁ 010216 Counter end Burst end Acknowledgment of internal memory access ack ack <Initial setting> External I/O configuration register Set as necessary. Memory channel operation mode register MC_DIR[1:0] (Memory channel direction control) = 012 (Receive mode) Burst (burst) = “1” (Burst mode) Memory address counter (Example) 010016 End address register (Example) 010716 <Operation start command> EXB interrupt source enable register MC_ENB (Memory channel operation enable) = “1” (Operation start) ➀ When a rise of TC is detected, negation of the memory channel request which synchronized with a rise of φ is made. ➁ When the write operation to the end address has been completed, the memory channel operation end interrupt is generated. Fig. 95 Memory channel receiving operation (3) 67 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (6) Memory Channel Transmitting Operation (1)-Cycle Mode Memory channel transmitting operation (1) is shown bellow. ➀ ➁ ➂ ➃ ➄ ➂’ ➅ Address ExA0 A0 = “x” A0 = “x” Chip select ExCS CS = “1” CS = “1” DMA acknowledge ExDACK Dack = “0” ➂ Dack = “0” ➃ ➂’ ➅ Read ExRD Write ExWR #0 Data DQ0 to DQ7 #1 Internal clock φ mRD ➔ detection mRD ➔ DMA request ExDREQ detection Mch_req Mch_req Transmission completed Transmit buffer TXBUF #0 ➀ #1 Operation enabled Main sequencer 0 1 2 3 4 5 Memory channel operation end interrupt req Internal memory access Memory address req 010116 010016 010216 Counter end Acknowledgment of internal memory access ack ack ➄ ➁ <Initial setting> External I/O configuration register Set as necessary. Memory channel operation mode register MC_DIR[1:0] (Memory channel direction control) = 102 (Transmit mode) Burst (burst) = “0” (Cycle mode) Memory address counter (Example) 010016 End address register (Example) 010116 <Operation start command> EXB interrupt source enable register ➀ MC_ENB (Memory channel operation enable) = “1” (Operation start) In the memory channel transmit mode when the command for enabling operation is written, operation starts (main sequencer starts) and an internal memory access sequence which synchronized with a rise of φ is activated. ➁ A data is read out from the internal memory within two clocks at a minimum and this data is stored in the transmit buffer (TXBUF). The memory address counter is simultaneously increased and assertion of the memory channel request is made. ➂ When the external MCU bus is in the condition of ExCS = “L” and ExA0 = “L” or a fall of ExRD is detected in the condition of ExDACK = “L”, negation of the memory channel request which synchronized with a rise of φ is made. ➃ When a rise of ExRD is detected, an internal memory access sequence which synchronized with a rise of φ is activated. ➄ A data is read out from the internal memory within two clocks at a minimum and this data is stored in the transmit buffer (TXBUF). The memory address counter is simultaneously increased and assertion of the memory channel request is made. When the read operation from the end address has been completed, the transition to the status to wait the memory channel operation end occurs. ➅ When a rise of ExRD is detected, the memory channel operation sequence ends and the memory channel operation end interrupt is generated. Fig. 96 Memory channel tranmitting operation (1) 68 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (7) Memory Channel Transmitting Operation (2)-Burst Mode Memory channel transmitting operation (2) is shown bellow. ➀ ➁ ➂ ➃ ➂’ ➄ ➅ Address ExA0 A0 = “x” A0 = “x” A0 = “x” Chip select ExCS CS = “1” CS = “1” CS = “1” Dack = “0” Dack = “0” DMA acknowledge ExDACK ➂ Dack = “0” ➅ ➂’ Read ExRD Write ExWR Data DQ0 to DQ7 #0 #1 #2 Internal clock φ mRD ➔ detection mRD ➔ DMA request ExDREQ detection Mch_req Transmission completed Transmit buffer TXBUF #0 #1 #2 Operation enabled ➀ Main sequencer 0 1 2 3 4 5 Memory channel operation end interrupt Internal memory access Memory address req req 010016 req 010116 010216 010316 Counter end Burst end Acknowledgment of internal memory access ack ack ➁ ack ➃ ➄ <Initial setting> External I/O configuration register Set as necessary. Memory channel operation mode register MC_DIR[1:0] (Memory channel direction control) = 102 (Transmit mode) Burst (burst) = “1” (Burst mode) Memory address counter (Example) 010016 End address register (Example) 010216 <Operation start command> EXB interrupt source enable register MC_ENB (Memory channel operation enable) = “1” (Operation start) ➀ In the memory channel transmit mode when the command for enabling operation is written, an internal memory access sequence which synchronized with a rise of φ is activated. ➁ A data is read out from the internal memory within two clocks at a minimum and this data is stored in the transmit buffer (TXBUF). The memory address counter is simultaneously increased and assertion of the memory channel request is made. ➂ When a rise of ExRD is detected, an internal memory access sequence which synchronized with a rise of φ is activated. ➃ A data is read out from the internal memory within two clocks at a minimum and this data is stored in the transmit buffer (TXBUF). The memory address counter is simultaneously increased. ➄ When the read operation from the end address has been completed, the detection circuit of external read signal (ExRD) operation is enabled and negation of the memory channel request which synchronized with the following φ is made. ➅ When a rise of ExRD is detected, the memory channel operation sequence ends and the memory channel operation end interrupt is generated. Fig. 97 Memory channel tranmitting operation (2) 69 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER MULTICHANNEL RAM The 38K0 group has the built-in multichannel RAM including the small logic circuit (RAM I/F) instead of ordinary RAM. The multichannel RAM has the USB channel and the EXB channel in addition to the CPU channel. The multichannel RAM controls access from CPU, USB and EXB, synchronizing control with φ. The USB transfer rate is about 1.5 Mbytes/second. Access to the multichannel RAM is performed at every about 5.3 clocks in φ = 8 MHz, or at every about 4 clocks in φ = 6 MHz. The USB’s access has priority to the EXB’s. The one wait function (ONW function) of 38000 series CPU is used internally to control access with the CPU. When receiving an access request from the USB or the EXB, the multichannel RAM outputs ONW signal to wait the CPU for one clock, and access of the USB or the EXB is performed. If the multichannel RAM is outputting ONW signal while the CPU is in the state of reading/writing for the RAM area, the CPU read cycle or write cycle is extended by 1 period of φ. No wait No wait No wait ONW = “H” Except RAM No RD/WR φ CPU AD CPU bus cycle RAM area Except RAM RAM area CPU USB CPU RD/WR USB REQ Multichannel RAM EXB REQ ONW RAM access right RAM bus cycle RAM RD/WR Fig. 98 Multichannel RAM timing diagram (no wait) One wait CPU accessing RAM at the latter part One wait Prohibiting continuous access of USB/EXB Prior CPU Prior CPU One wait USB having priority of USB/EXB simultaneous access Prior USB One wait 2-cycle wait (max.) for EXB Prior CPU φ CPU bus cycle RAM area CPU AD RAM area RAM area RAM area RD/WR USB REQ Multichannel RAM EXB REQ ONW RAM access right EXB CPU USB CPU USB CPU EXB CPU RAM bus cycle RAM RD/WR Fig. 99 Multichannel RAM timing diagram (one wait) 70 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Multichannel RAM Operation Example The multichannel RAM operation example is shown below. This example shows the case that an external MCU uses the 38K0 group as a peripheral LSI (USB controller). The following explains that the external MCU reads out the data which is received via the USB. ➀ The data which is received via the USB is written into the multichannel RAM. ➁ Receive completion is propagated to the CPU. ➂ The external bus interface is activated owing to the CPU. ➃ (1) The external bus interface sets the data which is read from the multichannel RAM into the internal data buffer. (2) The external MCU reads out the data bus buffer of the external bus interface. (3) The above operation is repeated by the number of the received bytes. After that, the data transfer is completed. Program ROM External MCU CPU ➂ Activating Peripheral functions ➁ Notice of receive completion External MCU bus External bus interface ➃ FIFO read of received data by External bus interface Multichannel RAM USB USB bus (USB host) ➀ FIFO write of received data by USB Fig. 100 Multichannel RAM operation example 71 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER A-D CONVERTER Comparator and Control Circuit The functional blocks of the A-D converter are described below. The comparator and control circuit compares an analog input voltage with the comparison voltage, and then stores the result in the A-D conversion registers 1, 2. When an A-D conversion is completed, the control circuit sets the AD conversion completion bit and the AD interrupt request bit to “1”. Note that because the comparator consists of a capacitor coupling, set f(system clock) to 500 kHz or more during an A-D conversion. [A-D Conversion Register 1, 2 (AD1, AD2)] 003716, 003816 The A-D conversion register is a read-only register that stores the result of an A-D conversion. When reading this register during an A-D conversion, the previous conversion result is read. Bit 7 of the A-D conversion register 2 must be set to “0”.Not only 10-bit reading but also only high-order 8-bit reading of conversion result can be performed by selecting the reading procedure of the A-D conversion registers 1, 2 after A-D conversion is completed (in Figure 102). The 8-bit reading inclined to MSB is performed when reading the A-D converter register 1 after A-D conversion is started or reset; and when the A-D converter register 1 is read after reading the AD converter register 2, the 8-bit reading inclined to LSB is performed. b7 b0 A-D control register (ADCON : address 003616) Analog input pin selection bits 0 0 0 : P10/DQ0/AN0 0 0 1 : P11/DQ1/AN1 0 1 0 : P12/DQ2/AN2 0 1 1 : P13/DQ3/AN3 1 0 0 : P14/DQ4/AN4 1 0 1 : P15/DQ5/AN5 1 1 0 : P16/DQ6/AN6 1 1 1 : P17/DQ7/AN7 AD conversion completion bit 0 : Conversion in progress 1 : Conversion completed Not used (indefinite at read) (These bits are write disabled bits.) [A-D Control Register (ADCON)] 003616 The A-D control register controls the A-D conversion process. Bits 0 to 2 select a specific analog input pin. Bit 3 signals the completion of an A-D conversion. The value of this bit remains at “0” during an A-D conversion, and changes to “1” when an A-D conversion ends. Writing “0” to this bit starts the A-D conversion. Comparison Voltage Generator The comparison voltage generator divides the voltage between VREF and AVSS into 1024, and that outputs the comparison voltage. The A-D converter successively compares the comparison voltage Vref in each mode, dividing the VREF voltage (see below), with the input voltage. • 10-bit reading VREF Vref = 1024 ✕ n (n = 0–1023) Fig. 101 Structure of A-D control register 10-bit reading (Read address 003816 before 003716) b7 (address 003816) 0 b0 b9 b8 b7 (address 003716) b0 b7 b6 b5 b4 b3 b2 b1 b0 • 8-bit reading Vref = VREF ✕ n (n = 0–255) 256 Channel Selector The channel selector selects one of the input ports P17/AN7–P10/ AN0. Note : Bits 2 to 7 of address 003816 become “0” at reading. 8-bit reading (Read only address 003716) b7 (address 003716) b0 b9 b8 b7 b6 b5 b4 b3 b2 Fig. 102 10-bit A-D mode reading 72 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Data bus A-D control register (address 003616) b7 b0 3 A-D interrupt request A-D control circuit Channel selector P10/DQ0/AN0 P11/DQ1/AN1 P12/DQ2/AN2 P13/DQ3/AN3 P14/DQ4/AN4 P15/DQ5/AN5 P16/DQ6/AN6 P17/DQ7/AN7 Comparator A-D conversion register 2 (address 003816) A-D conversion register 1 (address 003716) 10 Resistor ladder VREF VSS Fig. 103 A-D converter block diagram 73 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER WATCHDOG TIMER ●Watchdog timer H count source selection bit operation Bit 7 of the watchdog timer control register (address 003916) permits selecting a watchdog timer H count source. When this bit is set to “0”, the count source becomes the underflow signal of watchdog timer L. The detection time is set to 131.072 ms at system clock 8 MHz frequency. When this bit is set to “1”, the count source becomes the system clock divided by 16. The detection time in this case is set to 512 µs at system clock 8 MHz 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 run-away). The watchdog timer consists of an 8-bit watchdog timer L and an 8-bit watchdog timer H. Standard Operation of Watchdog Timer When any data is not written into the watchdog timer control register (address 003916) 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 003916) 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 0039 16) may be started before an underflow. When the watchdog timer control register (address 003916) is read, the values of the high-order 6 bits of the watchdog timer H, STP instruction disable bit (bit 6), and watchdog timer H count source selection bit (bit 7) are read. ●Operation of STP instruction disable bit Bit 6 of the watchdog timer control register (address 003916) 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 reset occurs. When this bit is set to “1”, it cannot be rewritten to “0” by program. This bit is cleared to “0” after resetting. Initial Value of Watchdog Timer At reset or writing to the watchdog timer control register (address 003916), each watchdog timer H and L is set to “FF16.” Data bus “FF16” is set when watchdog timer control register is written to. Watchdog timer L (8) System clock 1/16 “FF16” is set when watchdog timer control register is written to. “0” “1” Watchdog timer H (8) Watchdog timer H count source selection bit STP instruction disable bit STP instruction Reset circuit RESET Internal reset Fig. 104 Block diagram of Watchdog timer b7 b0 Watchdog timer control register (WDTCON : address 003916) 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: System clock/16 Fig. 105 Structure of Watchdog timer control register 74 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER RESET CIRCUIT To reset the microcomputer, RESET pin should be held at an “L” level for 16 cycles or more of XIN. Then the RESET pin is returned to an “H” level (the power source voltage should be between 3.0 V and 5.25 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 0.6 V for VCC of 3.0 V. Poweron Power source RESET VCC (Note) voltage 0V Reset input voltage 0V 0.2VCC Note : Reset release voltage ; Vcc = 3.0 V RESET VCC Power source voltage detection circuit Fig. 106 Example of reset circuit XIN φ RESET Internal reset ? ? Address ? ? FFFC FFFD ADH,L Reset address from the vector table. ? Data ? ? ? ADL ADH SYNC XIN: 10.5 to 18.5 clock cycles Notes 1: The frequency relation of f(XIN) and f(φ) is f(XIN)=8 • f(φ). 2: The question marks (?) indicate an undefined state that depends on the previous state. Fig. 107 Reset sequence 75 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PLL CIRCUIT (FREQUENCY SYNTHESIZER) The PLL circuit generates f VCO (PLL output clock), which is required for f USB (USB clock) and f SYN (fUSB division clock), from f(XIN) (external input reference clock). Figure 108 shows the PLL circuit block diagram. It is possible to input 6 or 12 MHz clock from the externals as a standard clock input. When using the USB function, set the PLL operation mode selection bit so that fvco may be set to 48 MHz. The PLL circuit operates by setting the PLL operation enable bit to “1”. When supplying fVCO to the USB block, wait for the oscillation stable time (1ms or less) of PLL before selecting f VCO with the USB clock selection bit. According to the setting of the USB clock division ratio selection bit, the division clock of fUSB is supplied to fSYN. When using this clock as system clock, set the USB clock division ratio selection bit so that it may be set to 6 MHz, 8 MHz or 12 MHz. (However, using it only when fUSB is 48MHz is recommended). fUSB f(XIN) PLL fVCO PLLCON (address 0FF816) Division circuit fSYN USBCON (address 001016) Fig. 108 Block diagram of PLL circuit 76 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 b0 PLL control register (PLLCON: address 0FF816) Not used (return “0” when read) USB clock division ratio selection bits b4b3 0 0: Divided by 8 (fSYN = fUSB/8) 0 1: Divided by 6 (fSYN = fUSB/6) 1 0: Divided by 4 (fSYN = fUSB/4) 1 1: Not selected PLL operation mode selection bits b6b5 0 0: Not multiplied (fVCO = fXIN) 0 1: Double (fVCO = fXIN ✕ 2) 1 0: Quadruple (fVCO = fXIN ✕ 4) 1 1: Multiplied by 8 (fVCO = fXIN ✕ 8) PLL Enable Bit 0: Disabled 1: Enabled Fig. 109 Structure of PLL control register 77 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER CLOCK GENERATING CIRCUIT An oscillation circuit can be formed by connecting a resonator between XIN and XOUT. Use the circuit constants in accordance with the resonator manufacturer’s recommended values. No external resistor is needed between XIN and XOUT since a feed-back resistor exists on-chip. Oscillation Control (1) Stop mode (2) f(XIN) clock If the STP instruction is executed, the internal clock φ stops at an “H” level, and the XIN oscillator stops. When the oscillation stabilizing time set after STP instruction released bit is “0,” the prescaler 12 is set to “FF16” and timer 1 is set to “0116.” When the oscillation stabilizing time set after STP instruction released bit is “1,” set the sufficient time for oscillation of used oscillator to stabilize since nothing is set to the prescaler 12 and timer 1. X IN divided by 16 is compulsorily connected to the input of the prescaler 12. Oscillator restarts when an external interrupt (including USB resume interrupt) is received, but the internal clock φ remains at “H” until timer 1 underflows. The internal clock φ is not supplied until timer 1 underflows. Because the sufficient time is required for the oscillation to stabilize when a ceramic resonator etc. is used. When the oscillator is restarted by reset, apply “L” level to the RESET pin until the oscillation is stable since a wait time will not be generated automatically. The frequency applied to the XIN pin is used as an internal system clock frequency. (2) Wait mode Frequency Control Either fSYN or f(XIN) can be selected as an internal system clock. Furthermore, the frequency of internal clock φ can be selected by the system clock division ratio selection bit. (1) fSYN clock f SYN clock is generated by the PLL circuit. f(X IN ) or fVCO can be selected as an input clock. When using as an internal system clock, there is restriction on use. Refer to the clause of “PLL CIRCUIT”. If the WIT instruction is executed, the internal clock φ stops at an “H” level, but the oscillator does not stop. The internal clock φ 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. To ensure that the interrupts will be received to release the STP or WIT state, their interrupt enable bits must be set to “1” before executing of the STP or WIT instruction. When releasing the STP state, the prescaler 12 and timer 1 will start counting the clock XIN divided by 16. Accordingly, set the timer 1 interrupt enable bit to “0” before executing the STP instruction. ■Note When using the oscillation stabilizing time set after STP instruction released bit set to “1”, evaluate time to stabilize oscillation of the used oscillator and set the value to the timer 1 and prescaler 12. 78 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER b7 XIN b0 MISRG (MISRG: address 0FFB16) XOUT CI N Oscillation stabilizing time set after STP instruction released bit 0: Automatically set “0116” to Timer 1, “FF16” to Prescaler 12 1: Automatically set nothing Not used (indefinite at read) COUT Fig. 112 Structure of MISRG Fig. 110 Ceramic resonator or quartz-crystal oscilltor circuit XIN XOUT Open External oscillation circuit VCC VSS Fig. 111 External clock input circuit XIN XOUT PLL fvco USB clock selection bit fUSB 1/4 1/6 1/8 USB clock division ration selection bits fSYN System clock selection bit fsio fAD 1/2 1/2 1/2 1/2 Prescaler 12 Timer 1 Reset or STP 1/1 1/2 1/4 1/8 FF16 System clock division ration selection bits 0116 instruction Timing φ (internal clock) Q S R S Q STP instruction WIT instruction R Q S R STP instruction Reset Interrupt disable flag l Interrupt request Fig. 113 System clock generating circuit block diagram (single-chip mode) 79 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Reset CM6 “0”←→“1” Note: Set PLLCON [4:3] = 10 before switching the system clock from XIN to fSYN. f(SYN) 2-divide mode f(φ) = 6.0 MHz CM 7 = 1 CM 6 = 0 CM 5 = 1 PLLCON [4:3] = 10 CM5 “0”←→“1” CM6 “0”←→“1” Note: Set PLLCON [4:3] = 00 before switching the system clock from XIN to fSYN. CM5 “0”←→“1” CM6 “0”←→“1” Note: Set PLLCON [4:3] = 01 before switching the system clock from XIN to fSYN. CM6 “0”←→“1” CM7 “1”←→“0” XIN 4-divide mode f(φ) = 1.5 MHz CM7 = 0 CM6 = 0 CM5 = 0 PLLCON [4:3] = xx (arbitrary) XIN through mode f(φ) = 1.5 MHz CM7 = 0 CM6 = 0 CM5 = 0 PLLCON [4:3] = xx (arbitrary) CM5 “1”←→“0” C “0 M6 C M ”← “1 7 →“ 1” ”← → “0 ” CM7 “1”←→“0” XIN 2-divide mode f(φ) = 3.0 MHz CM 7 = 1 CM 6 = 0 CM 5 = 0 PLLCON [4:3] = xx (arbitrary) CM5 “1”←→“0” CM6 “0”←→“1” ” 6 →“1 CM ”← 1” “0 M7 →“ C ”← “0 XIN 8-divide mode f(φ) = 0.75 MHz CM 7 = 0 CM 6 = 0 CM 5 = 0 PLLCON [4:3] = 00 f(SYN) through mode f(φ) = 12.0 MHz CM7 = 1 CM6 = 1 CM5 = 1 PLLCON [4:3] = 10 Under planning f(SYN) through mode f(φ) = 6.0 MHz CM7 = 1 CM6 = 1 CM5 = 1 PLLCON [4:3] = 00 f(SYN) through mode f(φ) = 8.0 MHz CM7 = 1 CM6 = 1 CM5 = 1 PLLCON [4:3] = 01 CM5 “0”←→“1” Note: Set PLLCON [4:3] = 00 before switching the system clock from XIN to fSYN. CM5 “0”←→“1” Note: Set PLLCON [4:3] = 01 before switching the system clock from XIN to fSYN. Notes 1 : Switch the mode by the allows shown between the mode blocks. (Do not switch between the modes directly without an allow.) 2 : Set the USB clock (fUSB) to 48 MHz when switching the system clock to fSYN. 3 : Do not change a division ratio of USB clock when using fSYN as the system clock. 4 : See section “PLL CIRCUIT” in details for enabling/disabling PLL operation and usage notes of fSYN. 5 : Set the system clock to XIN when entering STOP mode. 6 : In all modes, switching to WAIT mode is possible. When it is released, the MCU returns to the original mode. In WAIT mode the timers can operate. Remarks : This diagram assumes that the 6 MHz signals are applied to XIN pin. Fig. 114 State transitions of clock 80 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER FLASH MEMORY MODE Summary The 38K0 group’s flash memory version has an internal new DINOR (DIvided bit line NOR) flash memory that can be rewritten with a single power source when VCC is 4.5 to 5.25 V, and 2 power sources when VCC is 3.0 to 4.5 V. For this flash memory, three flash memory modes are available in which to read, program, and erase: the parallel I/O and standard serial I/O modes in which the flash memory can be manipulated using a programmer and the CPU rewrite mode in which the flash memory can be manipulated by the Central Processing Unit (CPU). Table 8 lists the summary of the 38K0 group’s flash memory version. This flash memory version has some blocks on the flash memory as shown in Figure 115 and each block can be erased. The flash memory is divided into User ROM area and Boot ROM area. In addition to the ordinary User ROM area to store the MCU operation control program, the flash memory has a Boot ROM area that is used to store a program to control rewriting in CPU rewrite and standard serial I/O modes. This Boot ROM area has had a standard serial I/O mode control program stored in it when shipped from the factory. However, the user can write a rewrite control program in this area that suits the user’s application system. This Boot ROM area can be rewritten in only parallel I/O mode. Table 8 Summary of 38K0 group’s flash memory version Item Power source voltage (Vcc) Program/Erase VPP voltage (VPP) Flash memory mode Specifications 3.00 – 5.25 V (Program and erase in 4.00 to 5.25 V of Vcc.) 3.00 – 4.00 V (Program and erase in 3.00 to 5.25 V of Vcc.) 4.50 – 5.25 V 3 modes; Flash memory can be manipulated as follows: •CPU rewrite mode: Manipulated by the Central Processing Unit (CPU). •Parallel I/O mode: Manipulated using an external programmer (Note 1) •Standard serial I/O mode: Manipulated using an external programmer (Note 1) Erase block division User ROM area Boot ROM area Program method Erase method Program/Erase control method Number of commands Number of program/Erase times Data retention period ROM code protection 1 block (32 Kbytes) 1 block (4 Kbytes) (Note 2) Byte program Batch erasing Program/Erase control by software command 6 commands 100 times 10 years Available in parallel I/O mode and standard serial I/O mode Notes 1: In the parallel I/O mode or the standard serial I/O mode, use the exclusive external equipment flash programmer which supports the 38K2 Group (flash memory version). 2: The Boot ROM area has had a standard serial I/O mode control program stored in it when shipped from the factory. This Boot ROM area can be rewritten in only parallel I/O mode. 81 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) CPU Rewrite Mode Microcomputer Mode and Boot Mode In CPU rewrite mode, the internal flash memory can be operated on (read, program, or erase) under control of the Central Processing Unit (CPU). In CPU rewrite mode, only the User ROM area shown in Figure 115 can be rewritten; the Boot ROM area cannot be rewritten. Make sure the program and block erase commands are issued for only the User ROM area and each block area. The control program for CPU rewrite mode can be stored in either User ROM or Boot ROM area. In the CPU rewrite mode, because the flash memory cannot be read from the CPU, the rewrite control program must be transferred to internal RAM area to be executed before it can be executed. The control program for CPU rewrite mode must be written into the User ROM or Boot ROM area in parallel I/O mode beforehand. (If the control program is written into the Boot ROM area, the standard serial I/O mode becomes unusable.) See Figure 115 for details about the Boot ROM area. Normal microcomputer mode is entered when the microcomputer is reset with pulling CNVSS pin low. In this case, the CPU starts operating using the control program in the User ROM area. When the microcomputer is reset by pulling the P16 (CE) pin high, the CNVSS pin high, the CPU starts operating using the control program in the Boot ROM area. This mode is called the “Boot” mode. Block Address Block addresses refer to the maximum address of each block. These addresses are used in the block erase command. User ROM area 800016 Block 1 : 32 Kbytes FFFF16 Boot ROM area F00016 FFFF16 4 Kbytes Notes 1: The Boot ROM area can be rewritten in only parallel I/O mode. (Access to any other areas is inhibited.) 2: To specify a block, use the maximum address in the block. Fig. 115 Block diagram of built-in flash memory 82 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Outline Performance (CPU Rewrite Mode) CPU rewrite mode is usable in the single-chip or Boot mode. The only User ROM area can be rewritten in CPU rewrite mode. In CPU rewrite mode, the CPU erases, programs and reads the internal flash memory as instructed by software commands. This rewrite control program must be transferred to a memory such as the internal RAM before it can be executed. The MCU enters CPU rewrite mode by applying 4.50 V to 5.25 V to the CNVSS pin and setting “1” to the CPU Rewrite Mode Select Bit (bit 1 of address 0FFE16). Software commands are accepted once the mode is entered. Use software commands to control program and erase operations. Whether a program or erase operation has terminated normally or in error can be verified by reading the status register. Figure 116 shows the flash memory control register. Bit 0 is the RY/BY status flag used exclusively to read the operating status of the flash memory. During programming and erase operations, it is “0” (busy). Otherwise, it is “1” (ready). This is equivalent to the RY/BY pin function in parallel I/O mode. Bit 1 is the CPU Rewrite Mode Select Bit. When this bit is set to “1”, the MCU enters CPU rewrite mode. Software commands are accepted once the mode is entered. In CPU rewrite mode, the b7 CPU becomes unable to access the internal flash memory directly. Therefore, use the control program in a memory other than internal flash memory for write to bit 1. To set this bit to “1”, it is necessary to write “0” and then write “1” in succession. The bit can be set to “0” by only writing “0”. Bit 2 is the CPU Rewrite Mode Entry Flag. This flag indicates “1” in CPU rewrite mode, so that reading this flag can check whether CPU rewrite mode has been entered or not. Bit 3 is the flash memory reset bit used to reset the control circuit of internal flash memory. This bit is used when exiting CPU rewrite mode and when flash memory access has failed. When the CPU Rewrite Mode Select Bit is “1”, setting “1” for this bit resets the control circuit. To set this bit to “1”, it is necessary to write “0” and then write “1” in succession. To release the reset, it is necessary to set this bit to “0”. Bit 4 is the User Area/Boot Area Select Bit. When this bit is set to “1”, Boot ROM area is accessed, and CPU rewrite mode in Boot ROM area is available. In Boot mode, this bit is set to “1” automatically. Reprogramming of this bit must be in a memory other than internal flash memory. Figure 117 shows a flowchart for setting/releasing CPU rewrite mode. b0 Flash memory control register (address 0FFE16) FMCR (Note 1) RY/BY status flag 0: Busy (being written or erased) 1: Ready CPU rewrite mode select bit (Note 2) 0: Normal mode (Software commands invalid) 1: CPU rewrite mode (Software commands acceptable) CPU rewrite mode entry flag 0: Normal mode (Software commands invalid) 1: CPU rewrite mode Flash memory reset bit (Note 3) 0: Normal operation 1: Reset User area / Boot area select bit (Note 4) 0: User ROM area accessed 1: Boot ROM area accessed Reserved bits (indefinite at read/ “0” at write) Notes 1: The contents of flash memory control register are “XXX00001” just after reset release. 2: For this bit to be set to “1”, the user needs to write “0” and then “1” to it in succession. If it is not this procedure, this bit will not be set to ”1”. Additionally, it is required to ensure that no interrupt will be generated during that interval. Use the control program in the area except the built-in flash memory for write to this bit. 3: This bit is valid when the CPU rewrite mode select bit is “1”. Set this bit 3 to “0” subsequently after setting bit 3 to “1”. 4: Use the control program in the area except the built-in flash memory for write to this bit. Fig. 116 Structure of flash memory control register 83 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Start Single-chip mode or Boot mode (Note 1) Set CPU mode register (Note 2) Transfer CPU rewrite mode control program to memory other than internal flash memory Jump to control program transferred in memory other than internal flash memory (Subsequent operations are executed by control program in this memory) Set CPU rewrite mode select bit to “1” (by writing “0” and then “1” in succession) Check CPU rewrite mode entry flag Using software command execute erase, program, or other operation Execute read array command or reset flash memory by setting flash memory reset bit (by writing “1” and then “0” in succession) (Note 3) Write “0” to CPU rewrite mode select bit End Notes 1: When starting the MCU in the single-chip mode or memory expansion mode, supply 4.5 V to 5.25 V to the CNVss pin until checking the CPU rewrite mode entry flag. 2: Set the system clock division ration selection bits of CPU mode register (bits 6 and 7 at address 003B16). 3: Before exiting the CPU rewrite mode after completing erase or program operation, always be sure to execute the read array command or reset the flash memory. Fig. 117 CPU rewrite mode set/release flowchart 84 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Notes on CPU Rewrite Mode Take the notes described below when rewriting the flash memory in CPU rewrite mode. ●Operation speed During CPU rewrite mode, set the internal clock φ to 1.5 MHz or less using the system clock division ratio selection bits (bits 6 and 7 of address 003B16). ●Instructions inhibited against use The instructions which refer to the internal data of the flash memory cannot be used during CPU rewrite mode . ●Interrupts inhibited against use The interrupts cannot be used during CPU rewrite mode because they refer to the internal data of the flash memory. ●Watchdog timer If the watchdog timer has been already activated, internal reset due to an underflow will not occur because the watchdog timer is surely cleared during program or erase. ●Reset Reset is always valid. The MCU is activated using the boot mode at release of reset in the condition of CNVss = “H”, so that the program will begin at the address which is stored in addresses FFFC16 and FFFD16 of the boot ROM area. 85 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ____ Software Commands Table 9 lists the software commands. After setting the CPU Rewrite Mode Select Bit to “1”, write a software command to specify an erase or program operation. Each software command is explained below. During the program movement, The RY/BY Status Flag of flash memory control register is set to “0”. When the program completes, it becomes “1”. At program end, program results can be checked by reading the status register. ●Read Array Command (FF16) The read array mode is entered by writing the command code “FF16” in the first bus cycle. When an address to be read is input in one of the bus cycles that follow, the contents of the specified address are read out at the data bus (D0 to D7). The read array mode is retained intact until another command is written. Start Write 4016 Write Write address Write data ●Read Status Register Command (7016) When the command code “70 16” is written in the first bus cycle, the contents of the status register are read out at the data bus (D0 to D7) by a read in the second bus cycle. The status register is explained in the next section. Status register read ●Clear Status Register Command (5016) This command is used to clear the bits SR4 and SR5 of the status register after they have been set. These bits indicate that operation has ended in an error. To use this command, write the command code “5016” in the first bus cycle. SR7 = 1 ? or RY/BY = 1 ? ●Program Command (4016) Program operation starts when the command code “4016” is written in the first bus cycle. Then, if the address and data to program are written in the 2nd bus cycle, the control circuit of flash memory (data programming and verification) will start a program. Whether the write operation is completed can be confirmed by _____ reading the status register or the RY/BY Status Flag. When the program starts, the read status register mode is entered automatically and the contents of the status register is read at the data bus (DB0 to DB7). The status register bit 7 (SR7) is set to “0” at the same time the write operation starts and is returned to “1” upon completion of the write operation. In this case, the read status register mode remains active until the read array command (FF16) is written. SR4 = 0 ? NO YES NO Program error YES Program completed Fig. 118 Program flowchart Table 9 List of software commands (CPU rewrite mode) Command Cycle number Mode First bus cycle Data Address (D0 to D7) X Second bus cycle Data Mode Address (D0 to D7) Read array 1 Write Read status register 2 Write X 7016 Clear status register 1 Write X 5016 Program 2 Write X 4016 Write WA (Note 2) WD (Note 2) Erase all blocks 2 Write X 2016 Write X 2016 Block erase 2 Write X 2016 Write (Note 3) D016 (Note 4) FF16 Read X BA SRD (Note 1) Notes 1: SRD = Status Register Data 2: WA = Write Address, WD = Write Data 3: BA = Block Address to be erased (Input the maximum address of each block.) 4: X denotes a given address in the User ROM area . 86 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Erase All Blocks Command (2016/2016) By writing the command code “2016” in the first bus cycle and the confirmation command code “2016” in the second bus cycle that follows, the operation of erase all blocks (erase and erase verify) starts. Whether the erase all blocks command is terminated can be con____ firmed by reading the status register or the RY/BY Status Flag of flash memory control register. When the erase all blocks operation starts, the read status register mode is entered automatically and the contents of the status register can be read out at the data bus (D0 to D7). The status register bit 7 (SR7) is set to “0” at the same time the erase operation starts and is returned to “1” upon completion of the erase operation. In this case, the read status register mode remains active until the read array command (FF16) is written. ____ The RY/BY Status Flag is “0” during erase operation and “1” when the erase operation is completed as is the status register bit 7. After the erase all blocks end, erase results can be checked by reading the status register. For details, refer to the section where the status register is detailed. ●Block Erase Command (2016/D016) By writing the command code “2016” in the first bus cycle and the confirmation command code “D016” and the block address in the second bus cycle that follows, the block erase (erase and erase verify) operation starts for the block address of the flash memory to be specified. Whether the block erase operation is completed can be confirmed ____ by reading the status register or the RY/BY Status Flag of flash memory control register. At the same time the block erase operation starts, the read status register mode is automatically entered, so that the contents of the status register can be read out. The status register bit 7 (SR7) is set to “0” at the same time the block erase operation starts and is returned to “1” upon completion of the block erase operation. In this case, the read status register mode remains active until the read array command (FF16) is written. ____ The RY/BY Status Flag is “0” during block erase operation and “1” when the block erase operation is completed as is the status register bit 7. After the block erase ends, erase results can be checked by reading the status register. For details, refer to the section where the status register is detailed. Start Write 2016 Write 2016/D016 Block address 2016:Erase all blocks D016:Block erase Status register read SR7 = 1 ? or RY/BY = 1 ? NO YES SR5 = 0 ? NO Erase error YES Erase completed Fig. 119 Erase flowchart 87 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Status Register (SRD) The status register shows the operating status of the flash memory and whether erase operations and programs ended successfully or in error. It can be read in the following ways: (1) By reading an arbitrary address from the User ROM area after writing the read status register command (7016) (2) By reading an arbitrary address from the User ROM area in the period from when the program starts or erase operation starts to when the read array command (FF16) is input. Also, the status register can be cleared by writing the clear status register command (5016). After reset, the status register is set to “8016”. Table 10 shows the status register. Each bit in this register is explained below. •Erase status (SR5) The erase status indicates the operating status of erase operation. If an erase error occurs, it is set to “1”. When the erase status is cleared, it is set to “0”. •Program status (SR4) The program status indicates the operating status of write operation. When a write error occurs, it is set to “1”. The program status is set to “0” when it is cleared. If “1” is written for any of the SR5 and SR4 bits, the program, erase all blocks, and block erase commands are not accepted. Before executing these commands, execute the clear status register command (5016) and clear the status register. •Sequencer status (SR7) The sequencer status indicates the operating status of the flash memory. This bit is set to “0” (busy) during write or erase operation and is set to “1” when these operations ends. After power-on, the sequencer status is set to “1” (ready). Table 10 Definition of each bit in status register Each bit of SRD0 bits Status name SR7 (bit7) SR6 (bit6) Sequencer status Reserved SR5 (bit5) SR4 (bit4) Erase status Program status SR3 (bit3) SR2 (bit2) SR1 (bit1) SR0 (bit0) Definition “1” “0” Ready - Busy - Terminated in error Terminated in error Terminated normally Terminated normally Reserved Reserved - - Reserved Reserved - - 88 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Full Status Check By performing full status check, it is possible to know the execution results of erase and program operations. Figure 120 shows a full status check flowchart and the action to be taken when each error occurs. Read status register SR4 = 1 and SR5 = 1 ? YES Command sequence error NO SR5 = 0 ? NO Erase error Execute the clear status register command (5016) to clear the status register. Try performing the operation one more time after confirming that the command is entered correctly. Should an erase error occur, the block in error cannot be used. YES SR4 = 0 ? NO Program error Should a program error occur, the block in error cannot be used. YES End (block erase, program) Note: When one of SR5 and SR4 is set to “1”, none of the program, erase all blocks, and block erase commands is accepted. Execute the clear status register command (5016) before executing these commands. Fig. 120 Full status check flowchart and remedial procedure for errors 89 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Functions To Inhibit Rewriting Flash Memory Version To prevent the contents of internal flash memory from being read out or rewritten easily, this MCU incorporates a ROM code protect function for use in parallel I/O mode and an ID code check function for use in standard serial I/O mode. ●ROM Code Protect Function The ROM code protect function is the function to inhibit reading out or modifying the contents of internal flash memory by using the ROM code protect control register (address FFDB16) in parallel I/O mode. Figure 121 shows the ROM code protect control register (address FFDB16). (This address exists in the User ROM area.) b7 If one or both of the pair of ROM Code Protect Bits is set to “0”, the ROM code protect is turned on, so that the contents of internal flash memory are protected against readout and modification. The ROM code protect is implemented in two levels. If level 2 is selected, the flash memory is protected even against readout by a shipment inspection LSI tester, etc. When an attempt is made to select both level 1 and level 2, level 2 is selected by default. If both of the two ROM Code Protect Reset Bits are set to “00”, the ROM code protect is turned off, so that the contents of internal flash memory can be read out or modified. Once the ROM code protect is turned on, the contents of the ROM Code Protect Reset Bits cannot be modified in parallel I/O mode. Use the serial I/O or CPU rewrite mode to rewrite the contents of the ROM Code Protect Reset Bits. b0 ROM code protect control register (address FFDB16) ROMCP Reserved bits (“1” at read/write) ROM code protect level 2 set bits (ROMCP2) (Notes 1, 2) b3b2 0 0: Protect enabled 0 1: Protect enabled 1 0: Protect enabled 1 1: Protect disabled ROM code protect reset bits (Note 3) b5b4 0 0: Protect removed 0 1: Protect set bits effective 1 0: Protect set bits effective 1 1: Protect set bits effective ROM code protect level 1 set bits (ROMCP1) (Note 1) b7b6 0 0: Protect enabled 0 1: Protect enabled 1 0: Protect enabled 1 1: Protect disabled Notes 1: When ROM code protect is turned on, the internal flash memory is protected against readout or modification in parallel I/O mode. 2: When ROM code protect level 2 is turned on, ROM code readout by a shipment inspection LSI tester, etc. also is inhibited. 3: The ROM code protect reset bits can be used to turn off ROM code protect level 1 and ROM code protect level 2. However, since these bits cannot be modified in parallel I/O mode, they need to be rewritten in serial I/O mode or CPU rewrite mode. Fig. 121 Structure of ROM code protect control register 90 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ID Code Check Function Use this function in standard serial I/O mode. When the contents of the flash memory are not blank, the ID code sent from the programmer is compared with the ID code written in the flash memory to see if they match. If the ID codes do not match, the commands sent from the programmer are not accepted. The ID code consists of 8-bit data, and its areas are FFD4 16 to FFDA16. Write a program which has had the ID code preset at these addresses to the flash memory. Address FFD416 ID1 FFD516 ID2 FFD616 ID3 FFD716 ID4 FFD816 ID5 FFD916 ID6 FFDA16 ID7 FFDB16 ROM cord protect control Interrupt vector area Fig. 122 ID code store addresses 91 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (2) Parallel I/O Mode Parallel I/O mode is the mode which parallel output and input software command, address, and data required for the operations (read, program, erase, etc.) to a built-in flash memory. Use the exclusive external equipment flash programmer which supports the 38K0 Group (flash memory version). Refer to each programmer maker’s handling manual for the details of the usage. User ROM and Boot ROM Areas In parallel I/O mode, the user ROM and boot ROM areas shown in Figure 115 can be rewritten. Both areas of flash memory can be operated on in the same way. The boot ROM area is 4 Kbytes in size. It is located at addresses F00016 through FFFF16. Make sure program and block erase operations are always performed within this address range. (Access to any location outside this address range is prohibited.) In the Boot ROM area, an erase block operation is applied to only one 4 Kbyte block. The boot ROM area has had a standard serial I/O mode control program stored in it when shipped from the Mitsubishi factory. Therefore, using the device in standard serial I/O mode, you must perform program and block erase in the user ROM area. 92 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (3) Standard Serial I/O Mode The standard serial I/O mode inputs and outputs the software commands, addresses and data needed to operate (read, program, erase, etc.) the internal flash memory. This I/O is clock synchronized serial. This mode requires a purpose-specific peripheral unit.The standard serial I/O mode is different from the parallel I/O mode in that the CPU controls flash memory rewrite (uses the CPU rewrite mode), rewrite data input and so forth. The standard serial I/O mode is started by connecting “H” to the P16 (CE) pin and “H” to the P4 2 (SCLK) pin and “H” to the CNVSS (VPP) pin (apply 4.5 V to 5.25 V to Vpp from an external source), and releasing the reset operation. (In the ordinary microcomputer mode, set CNVss pin to “L” level.) This control program is written in the Boot ROM area when the product is shipped from Mitsubishi. Accordingly, make note of the fact that the standard serial I/O mode cannot be used if the Boot ROM area is rewritten in parallel I/O mode. Figure 123 shows the pin connections for the standard serial I/O mode. In standard serial I/O mode, serial data I/O uses the four serial I/O pins SCLK, RxD, TxD and SRDY (BUSY). The SCLK pin is the transfer clock input pin through which an external transfer clock is input. The TxD pin is for CMOS output. The SRDY (BUSY) pin outputs “L” level when ready for reception and “H” level when reception starts. Serial data I/O is transferred serially in 8-bit units. In standard serial I/O mode, only the User ROM area shown in Figure 115 can be rewritten. The Boot ROM area cannot. In standard serial I/O mode, a 7-byte ID code is used. When there is data in the flash memory, commands sent from the peripheral unit (programmer) are not accepted unless the ID code matches. Outline Performance (Standard Serial I/O Mode) In standard serial I/O mode, software commands, addresses and data are input and output between the MCU and peripheral units (serial programer, etc.) using 4-wire clock-synchronized serial I/O. In reception, software commands, addresses and program data are synchronized with the rise of the transfer clock that is input to the SCLK pin, and are then input to the MCU via the RxD pin. In transmission, the read data and status are synchronized with the fall of the transfer clock, and output from the TxD pin. The TxD pin is for CMOS output. Transfer is in 8-bit units with LSB first. When busy, such as during transmission, reception, erasing or program execution, the SRDY (BUSY) pin is “H” level. Accordingly, always start the next transfer after the SRDY (BUSY) pin is “L” level. Also, data and status registers in a memory can be read after inputting software commands. Status, such as the operating state of the flash memory or whether a program or erase operation ended successfully or not, can be checked by reading the status register. Here following explains software commands, status registers, etc. 93 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 11 Description of pin function (Standard Serial I/O Mode) Pin name VCC,VSS VCCE CNVSS CNVSS2 VREF DVCC, PVCC PVSS RESET XIN XOUT USBVREF TrON D0+,D0P00 to P07 P10 to P15 P16 P17 P20 to P27 P30 to P37 P40 P41 P42 P43 P50 to P57 P60 to P63 Signal name Power supply Power supply VPP CNVSS2 Analog reference voltage Analog power supply Analog power supply Reset input Clock input Clock output USB reference voltage input USB reference voltage output USB upstream input Input port P0 Input port P1 Input port P1 I/O I/O I I I Input port P1 Input port P2 Input port P3 RxD input TxD output SCLK input BUSY output Input port P5 Input port P6 I I I I O I O I I I I I I I O I Function Apply 3.00 to 5.25 V to the Vcc pin and 0 V to the Vss pin. Connect this pin to Vcc. Connect this pin to VPP (VPP = 4.50 to 5.25 V). Connect this pin to Vss. Connect this pin to Vcc when not using. Connect this pin to Vcc. Connect this pin to Vss. To reset, input “L” level for 20 cycles or longer clocks of φ. Connect a ceramic or crystal resonator between the XIN and XOUT pins. When entering an externally drived clock, enter it from XIN and leave XOUT open. Connect this pin to Vcc when not using. Leave this pin open when not using. Input “L” level when not using. Input “L” or “H” level, or keep open. Input “L” or “H” level, or keep open. Input “L” or “H” level, or keep open. Input “H” level only at release of reset. Input “L” or “H” level, or keep open. Input “L” or “H” level, or keep open. Input “L” or “H” level, or keep open. This is a serial data input pin. This is a serial data output pin. This is a serial clock input pin.Input “H” level only at release of reset. This is a BUSY output pin. Input “L” or “H” level, or keep open. Input “L” or “H” level, or keep open. 94 MITSUBISHI MICROCOMPUTERS 38K0 Group P05 P04 P03 P02 P01 P00 P57 P56 P55 P54 P53 P52/INT1 P51/CNTR0 P50/INT0 P27 P26 SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Vcc 34 33 37 36 35 44 43 42 41 40 39 38 31 30 29 28 51 52 53 54 55 56 57 58 59 60 M38K09F8FP/HP 27 26 25 24 23 22 21 20 61 62 19 18 17 15 16 8 9 10 11 12 13 14 5 6 7 P25 P24 P23 P22 P21 P20 D0D0+ TrON USBVREF DVCC PVCC PVSS P63(LED3) P62(LED2) P61(LED1) CNVss SCLK RESET CE 4.5 to 5.25 V Vcc (Note 2) Vss → Vcc Vcc (Note 2) CE Connect to oscillator circuit. (Note 1) VPP Mode setup method Signal Value RESET P12/DQ2/AN2 P13/DQ3/AN3 P14/DQ4/AN4 P15/DQ5/AN5 P16/DQ6/AN6 P17/DQ7/AN7 CNVSS RESET VCCE VREF VSS XIN XOUT VCC CNVSS2 P60(LED0) 1 63 64 3 4 SCLK BUSY 32 49 50 2 R XD TXD P06 P07 P40/EXDREQ/RXD P41/EXDACK/TXD P42/EXTC/SCLK P43/EXA1/SRDY P30 P31 P32 P33/EXINT P34/EXCS P35/EXWR P36/EXRD P37/EXA0 P10/DQ0/AN0 P11/DQ1/AN1 47 46 45 48 Vss Notes 1: Connect to Vcc in the case of Vcc = 4.5 V to 5.25 V. Connect to VPP (= 4.5 V to 5.25 V) in the case of Vcc = 4.0 V to 4.5 V. 2: Supply Vcc at releasimg Reset. Package outline: 64P6U-A, 64P6Q-A Fig. 123 Pin connection diagram in standard serial I/O mode (1) 95 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Software Commands Table 12 lists software commands. In standard serial I/O mode, erase, program and read are controlled by transferring software commands via the RxD pin. Software commands are explained here below. Basically, the software commands of the standard serial I/O mode are the same as that of the parallel I/O mode, but the block erase function is excluded, and 4 commands are added: ID check, download, version data output and Boot ROM area output functions. Table 12 Software commands (Standard serial I/O mode) Control command 1st byte transfer 2nd byte 3rd byte 4th byte 5th byte 6th byte ..... When ID is not verified Data output to 259th byte Data input to 259th byte Not acceptable 1 Page read FF16 Address (middle) Address (high) Data output Data output Data output 2 Page program 4116 Address (middle) Address (high) Data input Data input Data input 3 Erase all blocks A716 D016 4 Read status register 7016 SRD output 5 Clear status register 5016 6 ID check function F516 Address (low) Address (middle) 7 Download function FA16 Size (low) 8 Version data output function FB16 9 Boot ROM area output function FC16 Version data output Address (middle) Not acceptable Not acceptable Acceptable SRD1 output Not acceptable ID size ID1 Size (high) Address (high) Checksum Data input Version data output Address (high) Version data output Data output Version data output Data output To required number of times Version data output Data output To ID7 Acceptable Not acceptable Version data output to 9th byte Data output to 259th byte Acceptable Not acceptable Notes1: Shading indicates transfer from the internal flash memory microcomputer to a programmer. All other data is transferred from a programmer to the internal flash memory microcomputer. 2: SRD refers to status register data. SRD1 refers to status register 1 data. 3: All commands can be accepted when the flash memory is totally blank. 4: Address low is A0 to A7; Address middle is A8 to A15; Address high is A16 to A23. Address-high A16 to A23 are always “0016”. 96 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) Transfer the “FF16” command code with the 1st byte. (2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively. (3) From the 4th byte onward, data (D0 to D 7) for the page (256 bytes) specified with addresses A8 to A23 will be output sequentially from the smallest address first synchronized with the fall of the clock. The contents of software commands are explained as follows. ●Page Read Command This command reads the specified page (256 bytes) in the flash memory sequentially one byte at a time. Execute the page read command as explained here following. SCLK RxD FF16 A8 to A15 A16 to A23 TxD data0 data255 SRDY (BUSY) Fig. 124 Timing for page read ●Read Status Register Command This command reads status information. When the “70 16” command code is transferred with the 1st byte, the contents of the status register (SRD) with the 2nd byte and the contents of status register 1 (SRD1) with the 3rd byte are read. SCLK RxD TxD 7016 SRD output SRD1 output SRDY (BUSY) Fig. 125 Timing for reading status register 97 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Clear Status Register Command This command clears the bits (SR3 to SR5) which are set when the status register operation ends in error. When the “5016” command code is sent with the 1st byte, the aforementioned bits are cleared. When the clear status register operation ends, the SRDY (BUSY) signal changes from “H” to “L” level. SCLK RxD 5016 TxD SRDY (BUSY) Fig. 126 Timing for clear status register ●Page Program Command This command writes the specified page (256 bytes) in the flash memory sequentially one byte at a time. Execute the page program command as explained here following. (1) Transfer the “4116” command code with the 1st byte. (2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively. (3) From the 4th byte onward, as write data (D0 to D 7 ) for the page (256 bytes) specified with addresses A8 to A23 is input sequentially from the smallest address first, that page is automatically written. When reception setup for the next 256 bytes ends, the S RDY (BUSY) signal changes from “H” to “L” level. The result of the page program can be known by reading the status register. For more information, see the section on the status register. SCLK RxD 4116 A8 to A15 A16 to data0 A23 data255 TxD SRDY (BUSY) Fig. 127 Timing for page program 98 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Erase All Blocks Command This command erases the contents of all blocks. Execute the erase all blocks command as explained here following. (1) Transfer the “A716” command code with the 1st byte. (2) Transfer the verify command code “D0 16” with the 2nd byte. With the verify command code, the erase operation will start and continue for all blocks in the flash memory. When erase all blocks end, the SRDY (BUSY) signal changes from “H” to “L” level. The result of the erase operation can be known by reading the status register. SCLK RxD A716 D016 TxD SRDY (BUSY) Fig. 128 Timing for erase all blocks 99 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Download Command This command downloads a program to the RAM for execution. Execute the download command as explained here following. (1) Transfer the “FA16” command code with the 1st byte. (2) Transfer the program size with the 2nd and 3rd bytes. (3) Transfer the check sum with the 4th byte. The check sum is added to all data sent with the 5th byte onward. (4) The program to execute is sent with the 5th byte onward. When all data has been transmitted, if the check sum matches, the downloaded program is executed. The size of the program will vary according to the internal RAM. SCLK RxD TxD FA16 Data size Data size (low) (high) Check sum Program data Program data SRDY (BUSY) Fig. 129 Timing for download 100 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Version Information Output Command This command outputs the version information of the control program stored in the Boot ROM area. Execute the version information output command as explained here following. (1) Transfer the “FB16” command code with the 1st byte. (2) The version information will be output from the 2nd byte onward. This data is composed of 8 ASCII code characters. SCLK RxD FB16 TxD ‘V’ ‘E’ ‘R’ ‘X’ SRDY (BUSY) Fig. 130 Timing for version information output ●Boot ROM Area Output Command This command reads the control program stored in the Boot ROM area in page (256 bytes) unit. Execute the Boot ROM area output command as explained here following. (1) Transfer the “FC16” command code with the 1st byte. (2) Transfer addresses A8 to A15 and A16 to A23 with the 2nd and 3rd bytes respectively. (3) From the 4th byte onward, data (D0 to D 7) for the page (256 bytes) specified with addresses A8 to A23 will be output sequentially from the smallest address first synchronized with the fall of the clock. SCLK RxD TxD FC16 A 8 to A 15 A 1 6 to A23 data0 data255 SRDY (BUSY) Fig. 131 Timing for Boot ROM area output 101 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER (1) Transfer the “F516” command code with the 1st byte. (2) Transfer addresses A0 to A7, A8 to A15 and A16 to A23 (“0016”) of the 1st byte of the ID code with the 2nd, 3rd and 4th respectively. (3) Transfer the number of data sets of the ID code with the 5th byte. (4) Transfer the ID code with the 6th byte onward, starting with the 1st byte of the code. ●ID Check This command checks the ID code. Execute the boot ID check command as explained here following. SCLK RxD F516 D416 FF16 0016 ID size ID1 ID7 TxD SRDY (BUSY) Fig. 132 Timing for ID check ●ID Code When the flash memory is not blank, the ID code sent from the serial programmer and the ID code written in the flash memory are compared to see if they match. If the codes do not match, the command sent from the serial programmer is not accepted. An ID code contains 8 bits of data. Area is, from the 1st byte, addresses FFD416 to FFDA16. Write a program into the flash memory, which already has the ID code set for these addresses. Address FFD416 ID1 FFD516 ID2 FFD616 ID3 FFD716 ID4 FFD816 ID5 FFD916 ID6 FFDA16 ID7 FFDB16 ROM code protect control Interrupt vector area Fig. 133 ID code storage addresses 102 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Status Register (SRD) The status register indicates operating status of the flash memory and status such as whether an erase operation or a program ended successfully or in error. It can be read by writing the read status register command (70 16 ). Also, the status register is cleared by writing the clear status register command (5016). Table 13 lists the definition of each status register bit. After releasing the reset, the status register becomes “8016”. •Sequencer status (SR7) The sequencer status indicates the operating status of the the flash memory. After power-on and recover from deep power down mode, the sequencer status is set to “1” (ready). This status bit is set to “0” (busy) during write or erase operation and is set to “1” upon completion of these operations. •Erase status (SR5) The erase status indicates the operating status of erase operation. If an erase error occurs, it is set to “1”. When the erase status is cleared, it is set to “0”. •Program status (SR4) The program status indicates the operating status of write operation. If a write error occurs, it is set to “1”. When the program status is cleared, it is set to “0”. Table 13 Status register (SRD) Definition SRD0 bits Status name “1” “0” Ready Busy Reserved Erase status Terminated in error Terminated normally SR4 (bit4) SR3 (bit3) Program status Reserved Terminated in error - Terminated normally - SR2 (bit2) SR1 (bit1) Reserved Reserved - - SR0 (bit0) Reserved - - SR7 (bit7) Sequencer status SR6 (bit6) SR5 (bit5) 103 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ●Status Register 1 (SRD1) The status register 1 indicates the status of serial communications, results from ID checks and results from check sum comparisons. It can be read after the SRD by writing the read status register command (7016). Also, status register 1 is cleared by writing the clear status register command (5016). Table 14 lists the definition of each status register 1 bit. This register becomes “0016” when power is turned on and the flag status is maintained even after the reset. •Boot update completed bit (SR15) This flag indicates whether the control program was downloaded to the RAM or not, using the download function. •Check sum consistency bit (SR12) This flag indicates whether the check sum matches or not when a program, is downloaded for execution using the download function. •ID check completed bits (SR11 and SR10) These flags indicate the result of ID checks. Some commands cannot be accepted without an ID check. •Data reception time out (SR9) This flag indicates when a time out error is generated during data reception. If this flag is attached during data reception, the received data is discarded and the MCU returns to the command wait state. Table 14 Status register 1 (SRD1) SRD1 bits SR15 (bit7) SR14 (bit6) Boot update completed bit Reserved SR13 (bit5) SR12 (bit4) Reserved Checksum match bit SR11 (bit3) SR10 (bit2) ID check completed bits SR9 (bit1) SR8 (bit0) Definition Status name Data reception time out Reserved “1” “0” Update completed - Not Update - Match 00 01 Not verified Verification mismatch 10 11 Reserved Verified Time out - Mismatch Normal operation - 104 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Full Status Check Results from executed erase and program operations can be known by running a full status check. Figure 124 shows a flowchart of the full status check and explains how to remedy errors which occur. Read status register SR4 = 1 and SR5 = 1 ? YES Command sequence error NO SR5 = 0 ? NO Erase error Execute the clear status register command (5016) to clear the status register. Try performing the operation one more time after confirming that the command is entered correctly. Should an erase error occur, the block in error cannot be used. YES SR4 = 0 ? NO Program error Should a program error occur, the block in error cannot be used. YES End (Erase, program) Note: When one of SR5 to SR4 is set to “1” , none of the program, erase all blocks, and block erase commands is accepted. Execute the clear status register command (5016) before executing these commands. Fig. 134 Full status check flowchart and remedial procedure for errors 105 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Example Circuit Application for Standard Serial I/O Mode Figure 135 shows a circuit application for the standard serial I/O mode. Control pins will vary according to a programmer, therefore see a programmer manual for more information. VCC VCC Clock input SCLK BUSY output SRDY (BUSY) Data input RxD Data output TxD VPP power source input CNVss P16 (CE) M38K09F8 Notes 1: Control pins and external circuitry will vary according to a programmer. For more information, see the programmer manual. 2: In this example, the VPP power supply is supplied from an external source (programmer). To use the user’s power source, connect to 4.5 V to 5.25 V. Fig. 135 Example circuit application for standard serial I/O mode 106 MITSUBISHI MICROCOMPUTERS 38K0 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. Instruction Execution Time The instruction execution time is obtained by multiplying the frequency of the internal clock φ by the number of cycles needed to execute an instruction. However, When using the USB function or EXB function, an occurrence of one-wait due to the multichannel RAM will double an internal clock φ cycle. 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. 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. Timers • When n (0 to 255) is written to a timer latch, the frequency division ratio is 1/(n+1). • When a count source of timer X is switched, stop a count of timer X. Multiplication and Division Instructions • 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. 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. A-D Converter The comparator uses capacitive coupling amplifier whose charge will be lost if the clock frequency is too low. Therefore, make sure that f(system clock) in the middle/highspeed mode is at least on 500 kHz during an A-D conversion. Do not execute the STP or WIT instruction during an A-D conversion. 107 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Definition of A-D Conversion Accuracy ➂ Non-linearity error This means a deviation from the line between VOT and VFST of a converted value between VOT and VFST. ➃ Differential non-linearity error This means a deviation from the input potential difference required to change a converted value between VOT and VFST by 1 LSB of the 1 LSB at the relative accuracy. The A-D conversion accuracy is defined below (refer to Figure 136). •Relative accuracy ➀ Zero transition voltage (VOT) This means an analog input voltage when the actual A-D conversion output data changes from “0” to “1.” ➁ Full-scale transition voltage (VFST) This means an analog input voltage when the actual A-D conversion output data changes from “1023” to “1022.” •Absolute accuracy This means a deviation from the ideal characteristics between 0 to VREF of actual A-D conversion characteristics. Output data Full-scale transition voltage (V FST) 1023 1022 Differential non-linearity error= c Non-linearity error= a [LSB] b-a a [LSB] b a n+1 n Actual A-D conversion characteristics c a: 1LSB at relative accuracy b: Vn+1-V n c: Difference between the ideal Vn and actual Vn Ideal line of A-D conversion between V0 to V1022 1 0 V0 Vn V1 Zero transition voltage (V 0T) Vn+1 V1022 Analog voltage VREF Fig. 136 Definition of A-D conversion accuracy Vn: Analog input voltage when the output data changes from “n” to “n + 1” (n = 0 to 1022) VFST – V OT 1022 VREF • 1 LSB at absolute accuracy → 1024 • 1 LSB at relative accuracy → (V) (V) 108 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER NOTES ON USAGE Handling of Power Source Pin In order to avoid a latch-up occurrence, connect a capacitor suitable for high frequencies as bypass capacitor between power source pin (Vcc pin) and GND pin (Vss pin). Besides, connect the capacitor to as close as possible. For bypass capacitor which should not be located too far from the pins to be connected, a ceramic or electrolytic capacitor of 1.0 µF is recommended. Flash Memory Version The CNVss pin is connected to the internal memory circuit block by a low-ohmic resistance, since it has the multiplexed function to be a programmable power source pin (VPP pin) as well. To improve the noise reduction, connect a track between CNVss pin and Vss pin or Vcc pin with 1 to 10 kΩ resistance. The mask ROM version track of CNVss pin has no operational interference even if it is connected to Vss pin or Vcc pin via a resistor. USB Port Pins (D0+, D0-) Treatment •The USB specification requires a driver-impedance 28 to 44 Ω. In order to meet the USB specification impedance requirements, connect a resistor (27 Ω recommended) in series to the USB port pins. In addition, in order to reduce the ringing and control the falling/ rising timing and a crossover point, connect a capacitor between the USB port pins and the Vss pin if necessary. The values and structure of those peripheral elements depend on the impedance characteristics and the layout of the printed circuit board. Accordingly, evaluate your system and observe waveforms before actual use and decide use of elements and the values of resistors and capacitors. •Make sure the USB D+/D- lines do not cross any other wires. Keep a large GND area to protect the USB lines. Also, make sure you use a USB specification compliant connecter for the connection. Electric Characteristic Differences Between Mask ROM and Flash Memory Version MCUs There are differences in electric characteristics, operation margin, noise immunity, and noise radiation between Mask ROM and Flash Memory version MCUs due to the difference in the manufacturing processes. When manufacturing an application system with the Flash Memory version and then switching to use of the Mask ROM version, please perform sufficient evaluations for the commercial samples of the Mask ROM version. 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) or one floppy disk. USBVREF pin Treatment (Noise Elimination) •Connect a capacitor between the USBVREF pin and the Vss pin. The capacitor should have a 2.2 µF capacitor (electrolytic capacitor) and a 0.1 µF capacitor (ceramic type capacitor) connected in parallel. ✽ Mask ROM Confirmation Forms/Mark Specification Forms http://www.infomicom.maec.co.jp/ •In Vcc = 3.0 to 3.6 V operation, connect the USBVREF pin directly to the Vcc pin in order to supply power to the USB port circuit. In addition, you will need to disable the built-in USB reference voltage circuit in this operation (set bit 4 of the USB control register to “0”.) If you are using the bus powered supply in this condition, the DC-DC converter must be placed outside the MCU. •In Vcc = 4.00 to 5.25 V operation, do not connect the external DC-DC converter to the USBVREF pin. Use the built-in USB reference voltage circuit. 109 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER ELECTRICAL CHARACTERISTICS Absolute Maximum Ratings Table 15 Absolute maximum ratings Parameter Symbol VCC Power source voltage AVCC Analog power source voltage VCCE, VREF, PVCC, DVCC, USBVREF Conditions All voltages are based on VSS. Output transistors are cut off. Ratings Unit –0.3 to 6.5 V –0.3 to VCC + 0.3 V –0.3 to VCC + 0.3 V VI Input voltage P00–P07, P10–P17, P20–P27, P30– P37, P40–P43, P50–P57, P60–P63 VI Input voltage RESET, XIN, CNVSS2 –0.3 to VCC + 0.3 V VI Input voltage CNVSS –0.3 to VCC + 0.3 V –0.3 to 6.5 V –0.5 to 3.8 V –0.3 to VCC + 0.3 V –0.5 to 3.8 V Mask ROM version Flash memory version VI Input voltage D0+, D0- VO Output voltage P00–P07, P10–P17, P20–P27, P30– P37, P40–P43, P50–P57, P60–P63, XOUT VO Output voltage D0+, D0-, TrON Pd Power dissipation Topr Operating temperature (Note) Ta = 25°C MCU operating In flash memory mode (For flash memory version) Tstg Storage temperature 500 mW –20 to 85 °C 25±5 °C –40 to 125 °C Note: The maximum rating value depends on not only the MCU’s power dissipation but the heat consumption characteristics of the package. 110 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Recommended Operating Conditions Table 16 Recommended operating conditions (Vcc = 3.00 to 5.25 V, Vss = 0 V, Ta = –20 to 85°C, unless otherwise noted) Symbol VCC Limits Parameter Power source voltage VCC Unit Min. Typ. Max. System clock 12 MHz (2-/4-/8-divide mode) 4.00 5.00 5.25 V System clock 8 MHz 4.00 5.00 5.25 V System clock 6 MHz 3.00 5.00 5.25 V AVCC Analog power source voltage PVCC, DVCC VCC AVCC Analog power source voltage VCCE VCC VREF Analog reference voltage VREF VREF Analog reference voltage USBVREF VSS Power source voltage VSS 0 AVSS Analog power source voltage PVSS 0 VIH “H” input voltage VIH VIH V V 2.0 VCC V Vcc = 3.6 to 4.0 V 3.0 3.6 V Vcc = 3.0 to 3.6 V 3.0 VCC V V V 0.8VCC VCC V V P10–P17, P30–P37, P40–P43 0.8VCCE VCCE V RESET, XIN, CNVSS, CNVSS2 0.8VCC VCC V 2.0 3.6 V 0 0.2VCC V 0 0.2VCCE V 0 0.2VCC V 0 0.8 V P00–P07, P20–P27, P50–P57, P60–P63 “H” input voltage “H” input voltage VIH “H” input voltage D0+, D0- VIL “L” input voltage P00–P07, P20–P27, P50–P57, P60–P63 VIL “L” input voltage P10–P17, P30–P37, P40–P43 VIL “L” input voltage RESET, XIN, CNVSS, CNVSS2 VIL “L” input voltage D0+, D0- 111 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 17 Recommended operating conditions (Vcc = 3.00 to 5.25 V, Vss = 0 V, Ta = –20 to 85°C, unless otherwise noted) Symbol Limits Parameter Min. Typ. Max. Unit ∑IOH(peak) “H” total peak output current (Note 1) P00–P07, P20–P27, P50–P57, P60–P63 –80 mA ∑IOH(peak) “H” total peak output current (Note 1) P10–P17, P30–P37, P40–P43 –80 mA ∑IOL(peak) “L” total peak output current (Note 1) P00–P07, P20–P27, P50–P57 80 mA ∑IOL(peak) “L” total peak output current (Note 1) P60–P63 80 mA ∑IOL(peak) “L” total peak output current (Note 1) P10–P17, P30–P37, P40–P43 80 mA ∑IOH(avg) “H” total average output current (Note 1) P00–P07, P20–P27, P50–P57, P60–P63 –40 mA ∑IOH(avg) “H” total average output current (Note 1) P10–P17, P30–P37, P40–P43 –40 mA ∑IOL(avg) “L” total average output current (Note 1) P00–P07, P20–P27, P50–P57 40 mA ∑IOL(avg) “L” total average output current (Note 1) P60–P63 40 mA ∑IOL(avg) “L” total average output current (Note 1) P10–P17, P30–P37, P40–P43 40 mA mA IOH(peak) “H” peak output current (Note 2) P00–P07, P20–P27, P50–P57, P60–P63 –10 IOH(peak) “H” peak output current (Note 2) P10–P17, P30–P37, P40–P43 –10 mA IOL(peak) “L” peak output current (Note 2) P00–P07, P20–P27, P50–P57 10 mA mA IOL(peak) “L” peak output current (Note 2) P60–P63 20 IOL(peak) “L” peak output current (Note 2) P10–P17, P30–P37, P40–P43 10 mA IOH(avg) “H” average output current (Note 3) P00–P07, P20–P27, P50–P57, P60–P63 –5 mA IOH(avg) “H” average output current (Note 3) P10–P17, P30–P37, P40–P43 –5 mA IOL(avg) “L” average output current (Note 3) P00–P07, P20–P27, P50–P57 5 mA IOL(avg) “L” average output current (Note 3) P60–P63 10 mA IOL(avg) “L” average output current (Note 3) P10–P17, P30–P37, P40–P43 5 mA f(XIN) Main clock input oscillation frequency Vcc = 4.00 to 5.25 V 6 12 MHz (Note 4) Vcc = 3.00 to 4.00 V 6 6 MHz System clock frequency Vcc = 4.00 to 5.25 V 6 12 MHz Vcc = 3.00 to 4.00 V 6 6 MHz Vcc = 4.00 to 5.25 V 8 MHz Vcc = 3.00 to 4.00 V 6 MHz f(XIN) or f(SYN) f(φ) φ frequency Notes 1: The total peak output current is the absolute value of the peak currents flowing through all the applicable ports. The total average output current is the average value of the absolute value of the currents measured over 100 ms flowing through all the applicable ports. 2: The peak output current is the absolute value of the peak current flowing in each port. 3: The average output current is the average value of the absolute value of the currents measured over 100 ms. 4: The duty of oscillation frequency is 50 %. 112 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Electrical Characteristics Table 18 Electrical characteristics (1) (Vcc = 3.00 to 5.25 V, Vss = 0 V, Ta = –20 to 85°C, unless otherwise noted) Symbol Parameter VOH “H” output voltage P00–P07, P20–P27, P50–P57, P60–P63 VOH “H” output voltage P10–P17, P30–P37, P40–P43 VOH “H” output voltage D0+, D0- VOL “L” output voltage P00–P07, P20–P27, P50–P57 VOL “L” output voltage P60–P63 VOL “L” output voltage P10–P17, P30–P37, P40–P43 VOL “L” output voltage D0+, D0- VT+–VT- Hysteresis CNTR0, INT0, INT1 Hysteresis P10/DQ0–P17/DQ7, P30–P32, P33/ExINT, P34/ExCS, P35/ExWR, P36/ExRD, P37/ ExA0, P40/ExDREQ/RxD, P41/ExDACK/ TxD, P42/ExTC/SCLK, P43/ExA1/SRDY Hysteresis D0+, D0Hysteresis RESET “H” input current P00–P07, P20–P27, P50–P57, P60–P63 “H” input current P10–P17, P30–P37, P40–P43 “H” input current RESET, CNVSS “H” input current XIN “L” input current P00–P07, P20–P27, P50–P57, P60–P63 “L” input current P10–P17, P30–P37, P40–P43 “L” input current RESET, CNVSS, CNVSS2 “L” input current XIN “L” input current P00–P07, P50, P52 (Pull-ups “on”) VT+–VT- VT+–VT VT+–VTIIH IIH IIH IIH IIL IIL IIL IIL IIL VRAM RAM hold voltage Test conditions IOH = –10 mA (Vcc = 4.00 to 5.25 V) IOH = –1 mA IOH = –10 mA (VCCE = 4.00 to 5.25 V) IOH = –1 mA D+ and D- pins pulldown with 0 V via a resistor of 15 kΩ ± 5 % IOL = 10 mA (Vcc = 4.00 to 5.25 V) IOL = 1 mA IOL = 20 mA (Vcc = 4.00 to 5.25 V) IOL = 1 mA IOL = 10 mA (VCCE = 4.00 to 5.25 V) IOL = 1 mA (VCCE = 3.00 to 5.25 V) D+ and D- pins pull-up with 3.6 V via a resistor of 1.5 kΩ ± 5 % Min. VCC–2.0 Limits Typ. Max. Unit V VCC–1.0 V V VCCE–2.0 V VCCE–1.0 2.8 0 3.6 V 2.0 V 1.0 2.0 V V 1.0 2.0 V 1.0 V 0.3 V V 0.6 V 0.6 V 0.25 V 0.5 VI = VCC (Pull-ups “off”) 5.0 V µA VI = VCCE 5.0 µA 5.0 µA VI = VCC VI = VCC VI = VSS (Pull-ups “off”) µA 4.0 –5.0 µA VI = VSS –5.0 µA VI = VSS VI = VSS VI = VSS (Vcc = 4.00 to 5.25 V) VI = VSS When clock is stopped –5.0 µA –120.0 µA 5.25 µA V –20.0 –10.0 2.00 –4.0 –60.0 µA 113 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 19 Electrical characteristics (2) (Vcc = 3.00 to 5.25 V, Vss = 0 V, Ta = –20 to 85°C, unless otherwise noted) Symbol ICC Test conditions Parameter Power source current (Output transistor is isolated.) Normal mode (Note 1) Vcc = 4.00 to 5.25 V Vcc = 3.00 to 4.00 V Wait mode (Note 2) Vcc = 3.00 to 3.60 V Vcc = 4.00 to 5.25 V Vcc = 3.00 to 4.00 V Stop mode (Note 3) Vcc = 4.00 to 5.25 V Vcc = 3.00 to 5.25 V <Test conditions> Notes 1: Operating in single-chip mode Clock input from XIN pin (XOUT oscillator stopped) fUSB = 48 MHz All USB difference-input circuits enabled Leaving I/O pins open Operating functions: PLL circuit, CPU, Timers 2: Operating in single-chip mode with Wait mode Clock input from XIN pin (XOUT oscillator stopped) fUSB = 48 MHz All USB difference-input circuits enabled Leaving I/O pins open Operating functions: PLL circuit, Timers, USB receiving Disabled functions: CPU 3: Operating in single-chip mode with Stop mode Oscillation stopped All USB difference-input circuits disabled Leaving I/O pins open 114 f(XIN) = system clock = 12 MHz, φ = 6 MHz, USB reference voltage circuit enabled f(XIN) = 12 MHz, System clock = φ = 8 MHz, USB reference voltage circuit enabled f(XIN) = 6 MHz, System clock = φ = 8 MHz, USB reference voltage circuit enabled f(XIN) = system clock = φ = 6 MHz, USB reference voltage circuit enabled f(XIN) = system clock = φ = 6 MHz, USB reference voltage circuit disabled f(XIN) = system clock = φ = 6 MHz, USB reference voltage circuit disabled f(XIN) = 12 MHz, System clock = φ = 8 MHz, USB reference voltage circuit enabled f(XIN) = system clock = φ = 6 MHz, USB reference voltage circuit disabled USB reference voltage circuit enabled Low current mode USB reference voltage circuit disabled Ta = 25 °C USB reference voltage circuit disabled Ta = 85 °C Min. Limits Typ. 23.5 Max. 60 24.5 60 mA 24.0 60 mA 22.0 60 mA 35 mA 30 mA 13.0 Unit mA 6.0 mA 2.0 mA 125.0 250 µA µA 0.1 10 µA MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 20 A-D Converter characteristics (VCC = 3.00 to 5.25 V, VSS = 0 V, Ta = –20 to 85°C, unless otherwise noted) Symbol Parameter Test conditions Limits Min. — Resolution — Linearity error — Differential nonlinear error Ta = 25 °C Ta = 25 °C VOT Zero transition voltage VCC = VREF = 5.12 V 0 VFST Full scale transition voltage VCC = VREF = 5.12 V 5105 tCONV Conversion time RLADDER Ladder resistor IVREF Reference power source input current A-D port input current Max. 10 50 Unit Bits ±3 ±1.5 LSB LSB 15 35 mV 5125 5150 mV 122 tc(XIN) or tc(fSYN) kΩ 200 µA 5 5.0 µA 35 A-D converter operating; VREF = 5.0 V A-D converter not operating; VREF = 5.0 V II(AD) Typ. 150 115 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Timing Requirements Table 21 Timing requirements (1) (VCC = 4.00 to 5.25 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Limits Typ. Max. Unit tW(RESET) Reset input “L” pulse width Min. 2 tC(XIN) Main clock input cycle time 83 ns tWH(XIN) Main clock input “H” pulse width 35 ns tWL(XIN) Main clock input “L” pulse width 35 ns tC(CNTR) CNTR0 input cycle time 200 ns tWH(CNTR) CNTR0 input “H” pulse width 80 ns tWL(CNTR) CNTR0 input “L” pulse width 80 ns tWH(INT) INT0, INT1 input “H” pulse width 80 ns tWL(INT) INT0, INT1 input “L” pulse width 80 ns tC(SCLK) Serial I/O clock input cycle time (Note) 800 ns tWH(SCLK) Serial I/O clock input “H” pulse width (Note) 370 ns tWL(SCLK) Serial I/O clock input “L” pulse width (Note) 370 ns tsu(RxD–SCLK) Serial I/O input set up time 220 ns th(SCLK–RxD) Serial I/O input hold time 100 ns µs Note: These limits are the rating values in the clock synchronous mode, bit 6 of address 0FE016 = “1”. In the UART mode, bit 6 of address 0FE016 = “0”; the rating values are set to one fourth. Table 22 Timing requirements (2) (VCC = 3.00 to 4.00 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Limits Unit tW(RESET) Reset input “L” pulse width Min. 2 tC(XIN) Main clock input cycle time 166 ns tWH(XIN) Main clock input “H” pulse width 70 ns Typ. Max. µs tWL(XIN) Main clock input “L” pulse width 70 ns tC(CNTR) CNTR0 input cycle time 500 ns tWH(CNTR) CNTR0 input “H” pulse width 230 ns tWL(CNTR) CNTR0 input “L” pulse width 230 ns tWH(INT) INT0, INT1 input “H” pulse width 230 ns tWL(INT) INT0, INT1 input “L” pulse width 230 ns tC(SCLK) Serial I/O clock input cycle time (Note) 2000 ns tWH(SCLK) Serial I/O clock input “H” pulse width (Note) 950 ns tWL(SCLK) Serial I/O clock input “L” pulse width (Note) 950 ns tsu(RxD–SCLK) Serial I/O input set up time 400 ns th(SCLK–RxD) Serial I/O input hold time 200 ns Note: These limits are the rating values in the clock synchronous mode, bit 6 of address 0FE016 = “1”. In the UART mode, bit 6 of address 0FE016 = “0”; the rating values are set to one fourth. 116 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Switching Characteristics Table 23 Switching characteristics (1) (VCC = 4.00 to 5.25 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Limits Min. Typ. Max. Unit tWH(SCLK) Serial I/O clock output “H” pulse width tC(SCLK)/2–30 ns tWL(SCLK) Serial I/O clock output “L” pulse width tC(SCLK)/2–30 ns td(SCLK–TxD) Serial I/O output delay time tv(SCLK–TxD) Serial I/O output valid time tr(SCLK) Serial I/O clock output rising time 30 ns tf(SCLK) Serial I/O clock output falling time 30 ns tr(CMOS) CMOS output rising time (Note) 30 ns tf(CMOS) CMOS output falling time (Note) 30 ns 140 ns ns –30 Notes: Pins XOUT, D0+ and D0- are excluded. Table 24 Switching characteristics (2) (VCC = 3.00 to 4.00 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Parameter Limits Min. Typ. Max. Unit tWH(SCLK) Serial I/O clock output “H” pulse width tC(SCLK)/2–50 ns tWL(SCLK) Serial I/O clock output “L” pulse width tC(SCLK)/2–50 ns td(SCLK–TxD) Serial I/O output delay time tv(SCLK–TxD) Serial I/O output valid time tr(SCLK) Serial I/O clock output rising time 50 ns tf(SCLK) Serial I/O clock output falling time 50 ns tr(CMOS) CMOS output rising time (Note) 50 ns tf(CMOS) CMOS output falling time (Note) 50 ns 350 ns ns –30 Notes: Pins XOUT, D0+ and D0- are excluded. Measured output pin 100 pF CMOS output Fig. 137 Output switching characteristics measurement circuit 117 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER Table 25 Switching characteristics (USB ports) (VCC = 3.00 to 5.25 V, VSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted) Symbol Limits Parameter Typ. Min. Max. Unit tfr(D+/D-) USB full-speed output rising time CL = 50 pF 4 20 ns tff(D+/D-) USB full-speed output rising time CL = 50 pF 4 20 ns tfrfm(D+/D-) USB full-speed ports rising/falling ratio tfr(D+/D-)/tff(D+/D-) 90 111.11 % Vcrs(D+/D-) USB output signal cross-over voltage 1.3 2.0 V TrON RL = 27 Ω RL = 1.5 kΩ RL = 27 Ω Measured output pin Measured output pin RL = 15 kΩ CL RL = 15 kΩ CL USB port output USB port output Fig. 138 USB output switching characteristics measurement circuit (1) for D0- 118 Fig. 139 USB output switching characteristics measurement circuit (2) for D0+ MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER tC(CNTR) tWL(CNTR) tWH(CNTR) CNTR0 0.8VCC 0.2VCC tWL(INT) tWH(INT) 0.8VCC INT0/INT1 0.2VCC tW(RESET) RESET 0.8VCC 0.2VCC tC(XIN) tWL(XIN) tWH(XIN) 0.8VCC XIN 0.2VCC tC(SCLK) tf SCLK tWL(SCLK) tr tWH(SCLK) 0.8VCCE 0.2VCCE tsu(RxD-SCLK) th(SCLK-RxD) 0.8VCCE 0.2VCCE RxD(at receive) td(SCLK-TxD) tv(SCLK-TxD) TxD (at transmit) Fig. 140 Timing chart 119 MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER PACKAGE OUTLINE MMP 64P6U-A EIAJ Package Code LQFP64-P-1414-0.8 Plastic 64pin 14✕14mm body LQFP Weight(g) Lead Material Cu Alloy MD e JEDEC Code — 64 b2 Under Planning D ME HD 49 l2 1 48 Recommended Mount Pad 16 A A1 A2 b c D E e HD HE L L1 Lp HE E Symbol 33 17 A 32 L1 F A3 A2 e A3 x M L c b A1 y x y Lp Detail F 120 b2 I2 MD ME Dimension in Millimeters Min Nom Max 1.7 — — 0.1 0.2 0 1.4 — — 0.32 0.37 0.45 0.105 0.125 0.175 13.9 14.1 14.0 13.9 14.1 14.0 0.8 — — 16.0 15.8 16.2 15.8 16.2 16.0 0.3 0.5 0.7 1.0 — — 0.45 0.6 0.75 — 0.25 — — — 0.2 0.1 — — 0ϒ 8ϒ — 0.225 — — — — 0.95 — 14.4 — 14.4 — — MITSUBISHI MICROCOMPUTERS 38K0 Group SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER 64P6Q-A MMP Plastic 64pin 10✕10mm body LQFP Weight(g) – Lead Material Cu Alloy MD ME JEDEC Code – e EIAJ Package Code LQFP64-P-1010-0.50 b2 HD D 64 49 1 I2 Recommended Mount Pad 48 A A1 A2 b c D E e HD HE L L1 Lp HE E Symbol 33 16 17 32 A F e x L M Detail F Lp c A1 y b A3 A2 L1 A3 x y b2 I2 MD ME Dimension in Millimeters Min Nom Max 1.7 – – 0.1 0.2 0 1.4 – – 0.13 0.18 0.28 0.105 0.125 0.175 9.9 10.0 10.1 9.9 10.0 10.1 0.5 – – 11.8 12.0 12.2 11.8 12.0 12.2 0.3 0.5 0.7 1.0 – – 0.45 0.6 0.75 – 0.25 – – – 0.08 – – 0.1 – 0° 10° – – 0.225 1.0 – – 10.4 – – – – 10.4 HEAD OFFICE: 2-2-3, MARUNOUCHI, CHIYODA-KU, TOKYO 100-8310, JAPAN 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. 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REVISION HISTORY Rev. 38K0 GROUP DATA SHEET Date Description Summary Page 1.0 7/19/01 2.0 3/05/02 First edition issued All pages The symbol “PRELIMINARY” is deleted from the header. P. 1 Some Features are revised: Power source voltage, Power dissipation, Operating temperature range. Fig.1: The design of top view is revised. P. 3 Table 1: The Function of Vcc, VccE and USBVREF is revised. P. 5 100D0M package is added. Table 2: The product M38K09RFS is added. P. 9 Fig. 7: The description of system clock division ratio selection bits is revised. P. 25–30 The explanations from pages 25 to 30 are added. P. 32 Fig. 31: The Function is revised. P. 49 Fig. 69: The Function is revised. P. 57 Fig. 76: Bit name of EXBIREQ. is revised: P. 58 Fig. 78: Note is added. Fig. 79: Bit attributes are revised. P. 60 Fig. 84: Register symbol is revised. P. 72 The explanations of A-D converter are revised. P. 75 The voltages regarding RESET is revised. P. 76 Some explanations of PLL CIRCUIT including the clock frequency is revised. P. 80 Fig. 114 is added. P. 81 The explanations of FLASH MEMORY MODE and Table 8 are revised. P. 82 The explanations of Microcomputer Mode and Boot Mode, and Fig.115 are revised. P. 85 The explanations of Operation speed are revised. P. 92 The explanations of (2) Parallel I/O Mode are revised. P. 93 The explanations of (3) Standard Serial I/O Mode are revised. P. 94 Table 11: The Function of Vcc, VccE, CNVss, P10 to P15, P16 and P17 is revised. P. 95 Fig. 123: The descriptions of CE and SCLK are added. P. 106 Fig. 135: P16 (CE) is added. P. 107 The explanations of Instruction Execution Time are revised. P. 108 The explanations of Definition of A-D Conversion Accuracy is added. P. 109 The explanations are added: USB Port Pins, USBVREF pin Treatment and Electric Characteristic Differences Between Mask ROM and Flash Memory Version MCUs. (1/2) REVISION HISTORY Rev. 38K0 GROUP DATA SHEET Date Description Summary Page 2.0 3/05/02 P. 110 Table 15: Operating temperature is revised. P. 111 Table 16: Measuring conditions, Power source voltage Vcc and Analog power source voltage VccE are revised. Analog power source voltage USBVREF is added. P. 112 Table 17: Measuring conditions, f(XIN) and Notes 1 and 2 are revised. [f(XIN) or f(SYN)] and f(φ) are added. P. 113 Table 18: Measuring conditions and some of VOH, VOL, VT+–VT- and IIL are revised or added. P. 114 Table 19: The information are revised. P. 115 Table 20: Measuring conditions and IVREF are revised. P. 116 to Tables 21 to 25: The information are revised or added. 118 P. 118 Figures 138 and 139 are added. P. 119 Fig. 140 is revised. (2/2)