FUJITSU SEMICONDUCTOR DATA SHEET DS07-16901-2E 32-bit Microcontrollers CMOS FR60 MB91470/480 Series MB91482/F475/F478/F479/F487/ MB91FV470 ■ DESCRIPTION The MB91470/480 series is Fujitsu's general-purpose 32-bit RISC microcontroller, which is designed for embedded control applications that require high-speed processing performance. This series uses the FR60 CPU, which is compatible with the FR* family of CPUs. * : FR, the abbreviation of FUJITSU RISC controller, is a line of products of FUJITSU Limited. ■ FEATURES • FR60 CPU • 32-bit RISC, load/store architecture, five-stage pipeline • Operating frequency of 80 MHz (PLL clock multiplied) • 16-bit fixed-length instructions (basic instructions) • Instruction execution speed : one instruction per cycle • Memory-to-memory transfer, bit processing, barrel shift instructions, etc. : instructions suitable for embedded applications • Function entry and exit instructions, multi load/store instructions of register contents : instructions compatible with C language. • Register interlock function to facilitate assembly-language coding • Built-in multiplier/instruction-level support • Signed 32-bit multiplication : 5 cycles • Signed 16-bit multiplication : 3 cycles • Interrupts (save PC and PS) : 6 cycles, 16 priority levels • Harvard architecture allowing program access and data access to be executed simultaneously • Instructions compatible with the FR family (Continued) Be sure to refer to the “Check Sheet” for the latest cautions on development. “Check Sheet” is seen at the following support page URL : http://www.fujitsu.com/global/services/microelectronics/product/micom/support/index.html “Check Sheet” lists the minimal requirement items to be checked to prevent problems beforehand in system development. Copyright©2006-2007 FUJITSU LIMITED All rights reserved MB91470/480 Series • Built-in Peripheral functions • Combinations of built-in Flash/ROM and RAM capacities MB91470 series MB91480 series 144 pins Flash memory product MASK ROM product Flash memory product MASK ROM product 256 Kbytes/16 Kbytes MB91F475 ⎯ ⎯ MB91482 384 Kbytes/24 Kbytes MB91F478 ⎯ ⎯ ⎯ 512 Kbytes/32 Kbytes MB91F479 ⎯ MB91F487 ⎯ • • • • • • • • • • • • 2 100 pins I/O ports NMI (Non Maskable Interrupt) External interrupts Bit search module (for REALOS) Function to search for the position of the first bit that has changed from 1 to 0 in a word starting from the MSB 16-bit reload timers Timing generator 8/16-bit PPG timers Multi-function timer • 16-bit free-run Timer • Input capture (Linked to free-run timer) • Output compare (Linked to free-run timer) • A/D start up compare (Linked to free-run timer) • Wave form generator Various wave forms are generated by using output compare output, 16-bit PPG timer and 16-bit dead timer. Base timer Only one timer function can be selected from the 16-bit PWM timer, 16-bit PPG timer, 16/32-bit reload timer, and 16/32-bit PWC timer. 8/16-bit up/down counter Multi-function serial interface • Full-duplex double buffer • With 16-byte FIFO • Asynchronous (start-stop synchronization) communication, clock synchronous communication, I2C* standard mode (Max 100 kbps), I2C high-speed mode (selectable various modes at maximum of 400 kbps) • Selectable parity On/Off • Each channel has built-in baud rate generator • Error detection function for parity, frame and overrun errors • External clock can be used as transfer clock • With I2C function 8/10-bit A/D Converter (Successive comparison type) • Resolution : 8-bit or 10-bit resolution selectable • Conversion Time : 1.2 µs (minimum conversion time for 33 MHz system clock) 1.2 µs (minimum conversion time for 40 MHz system clock) (Continued) MB91470/480 Series (Continued) • 12-bit A/D Converter (successive approximation type) • Resolution : 12 bits • Conversion Time : 2.0 µs (minimum conversion time for 33 MHz system clock) 2.2 µs (minimum conversion time for 40 MHz system clock) • Differential input mode is available. • Clock monitor • Peripheral clock (CLKP) divided by 2/4/8/16/32/64/128/256 can be output. • Multiplication and Addition Calculator • RAM : Instruction RAM (I-RAM) 256 × 16-bit Factor RAM (X-RAM) 64 × 32-bit Variable RAM (Y-RAM) 64 × 32-bit • High-speed multiplication and addition (seven-stage pipeline processing) • Product addition (32-bit × 32-bit + 72-bit) • Operation result is extracted rounded from 72 bits to 32 bits or 72-bit result data reading. • DMAC (DMA Controller) • Transfers can be started by software or by interrupts from the built-in peripherals. • Wild register • Instructions or data located at a target address can be replaced (in the built-in Flash/ROM area only) . • External bus interface • Maximum operating frequency of 40 MHz • 16-bit address full output (64 Kbytes space) capability • 8/16-bit data output • Use of unused data/address pins as general-purpose I/O ports • Totally independent 3-area chip select outputs that can be set at minimum of 64 Kbytes. • Support of interface for various memory (SRAM, ROM/Flash) • Basic bus cycle : 2 cycles • Automatic wait cycle generator that can be programmed for each area and can insert waits • External wait cycle using RDY input • Other Features • Watchdog timer • Low-power consumption modes • Sleep/stop function • CMOS technologies : 0.18 µm • Power supply : Single power supply (VCC = 4.0 V to 5.5 V) * : Purchase of Fujitsu I2C components conveys a license under the Philips I2C Patent Rights to use, these components in an I2C system provided that the system conforms to the I2C Standard Specification as defined by Philips. 3 MB91470/480 Series ■ PRODUCT LINEUP Characteristics MB91470/480 series common EVA MB91FV470 Pin number MB91F475 MB91F478 224 pins MB91F479 144 pins MB91480 series MB91F487 MB91482 100 pins Built-in Flash/ROM capacity 512 Kbytes (Flash) 256 Kbytes 384 Kbytes (Flash) (Flash) 512 Kbytes (Flash) 512 Kbytes (Flash) 256 Kbytes (ROM) Built-in RAM capacity 40 Kbytes 16 Kbytes 32 Kbytes 32 Kbytes 16 Kbytes External bus Yes Yes ⎯ I/O ports 160 113 77 External interrupts NMI 16 channels NMI 10 channels NMI 10 channels Reload timer 2 channels 2 channels 2 channels 2 units 1 unit 2 units 8-bit × 16 channels 16-bit × 8 channels 8-bit × 8 channels 16-bit × 4 channels 8-bit × 16 channels 16-bit × 8 channels 2 units 1 unit 2 units Free-run timer 6 channels 3 channels 6 channels OCU 12 channels 6 channels 12 channels ICU 8 channels 4 channels 8 channels A/D activation compare 6 channels 3 channels 6 channels Wave form generator 12 channels 6 channels 12 channels Base timer 6 channels 4 channels 4 channels Up/down counter 2 channels 1 channel ⎯ 6 units 6 units 3 units 8/10-bit A/D converter 4 channels × 2 units 16 channels × 1 unit 12 channels × 1 unit 4 channels × 2 units 10 channels × 1 unit 12-bit A/D converter 4 channels × 2 units 4 channels × 2 units ⎯ Clock monitor 1 unit ⎯ 1 unit Multiplication and addition calculator 1 unit 1 unit 1 unit DMAC 5 channels 5 channels 5 channels Wild register 16 channels 16 channels 16 channels DSU4 ⎯ ⎯ Timing generator PPG Multi-function timer Multi-function serial interface Debug function 4 MB91470 series 24 Kbytes MB91470/480 Series ■ PACKAGE AND CORRESPONDING PRODUCTS Series name MB91470 series MB91F475 MB91F478 MB91F479 MB91480 series MB91F487 MB91482 FPT-144P-M12 (LQFP-0.40 mm) ⎯ ⎯ BGA-144P-M06 (PFBGA-0.80 mm) ⎯ ⎯ Package FPT-100P-M20 (LQFP-0.50 mm) ⎯ : Supported Note : For details of each package, refer to “■ PACKAGE DIMENSIONS”. 5 MB91470/480 Series ■ PIN ASSIGNMENT • LQFP-144 (MB91470 series) 144 143 142 141 140 139 138 137 136 135 134 133 132 131 130 129 128 127 126 125 124 123 122 121 120 119 118 117 116 115 114 113 112 111 110 109 VSS P50/CS0X P37/A15 P36/A14 P35/A13 P34/A12 P33/A11 P32/A10 P31/A09 P30/A08 P27/A07 P26/A06 P25/A05 P24/A04 P23/A03 P22/A02 P21/A01 P20/A00 VCC VSS P17/D31 P16/D30 P15/D29 P14/D28 P13/D27 P12/D26 P11/D25 P10/D24 P07/D23 P06/D22 P05/D21 P04/D20 P03/D19 P02/D18 P01/D17 P00/D16 (TOP VIEW) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 108 107 106 105 104 103 102 101 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 VCC PQ0/RTO0 PQ1/RTO1 PQ2/RTO2 PQ3/RTO3 PQ4/RTO4 PQ5/RTO5 VCC VSS PP0/IC0 PP1/IC1 PP2/IC2 PP3/IC3 MD2 MD1 MD0 X0 X1 VSS PP4/CKI0 PP5/DTTI0 C VSS VCC PM0/PPG0 PM1/PPG1 PM2/PPG2 PM3/PPG3 PA2/ADTG2 PA3/ADTG3 PA4/ADTG4 PE0/AN3-0/AN3-0P PE1/AN3-1/AN3-0N PE2/AN3-2/AN3-1P PE3/AN3-3/AN3-1N AVSS12 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 VCC P51/CS1X P52/CS2X P53/ASX P54/RDX P55/WR0X P56/WR1X P60/SYSCLK P61/RDY PJ0/TIN0 PJ1/TOUT0 PJ2/TIN1 PJ3/TOUT1 PJ4/TIN2 PJ5/TOUT2 PJ6/TIN3 PJ7/TOUT3 VCC VSS P80/INT0 P81/INT1 P82/INT2 P83/INT3 P84/INT4/PPG4 P85/INT5/PPG5 P86/INT6/PPG6 P87/INT7/PPG7 P90/INT8 P91/INT9 NMIX PL0/AIN0 PL1/BIN0 PL2/ZIN0 INITX VCC VSS (FPT-144P-M12) 6 PH5/SOT3 PH4/SIN3 PH3/SCK3 PH2/SOT2 PH1/SIN2 PH0/SCK2 PG5/SOT1 PG4/SIN1 PG3/SCK1 PG2/SOT0 PG1/SIN0 PG0/SCK0 AVSS10 AVRH2 AVCC10 PD3/AN2-11 PD2/AN2-10 PD1/AN2-9 PD0/AN2-8 PC7/AN2-7 PC6/AN2-6 PC5/AN2-5/SOT5 PC4/AN2-4/SIN5 PC3/AN2-3/SCK5 PC2/AN2-2/SOT4 PC1/AN2-1/SIN4 PC0/AN2-0/SCK4 VCC VSS PE7/AN4-3/AN4-1N PE6/AN4-2/AN4-1P PE5/AN4-1/AN4-0N PE4/AN4-0/AN4-0P AVRH4 AVCC12 AVRH3 MB91470/480 Series • PFBGA-144 (MB91470 series) (TOP VIEW) ▼ Index 1 2 3 4 5 6 7 8 9 10 11 12 13 A 1 48 47 46 45 44 43 42 41 40 39 38 37 B 2 49 88 87 86 85 84 83 82 81 80 79 36 C 3 50 89 120 119 118 117 116 115 114 113 78 35 D 4 51 90 121 144 143 142 141 140 139 112 77 34 E 5 52 91 122 138 111 76 33 F 6 53 92 123 137 110 75 32 G 7 54 93 124 136 109 74 31 H 8 55 94 125 135 108 73 30 J 9 56 95 126 134 107 72 29 K 10 57 96 127 128 129 130 131 132 133 106 71 28 L 11 58 97 98 99 100 101 102 103 104 105 70 27 M 12 59 60 61 62 63 64 65 66 67 68 69 26 N 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 (BGA-144P-M06) 7 MB91470/480 Series • LQFP-100 (MB91480 series) 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 VSS P85/INT5/PPG5 P84INT4/PPG4 P83/INT3 P82/INT2 P81/INT1 P80/INT0 PJ7/TOUT3 PJ6/TIN3 PJ5/TOUT2 PJ4/TIN2 PJ3/TOUT1 PJ2/TIN1 PJ1/TOUT0 PJ0/TIN0 PH2/SOT2 PH1/SIN2 PH0/SCK2 PG5/SOT1 PG4/SIN1 PG3/SCK1 PG2/SOT0 PG1/SIN0 PG0/SCK0 VCC (TOP VIEW) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 PS0/RTO6 PS1/RTO7 PS2/RTO8 PS3/RTO9 PS4/RTO10 PS5/RTO11 VCC VCC VSS C PR0/IC4 PR1/IC5 PR2/IC6 PR3/IC7 PR4/CKI1 PR5/DTTI1 MD2 MD1 MD0 X0 X1 VSS INITX PA2/ADTG2 VSS 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 VCC P86/INT6/PPG6 P87/INT7/PPG7 P90/INT8/PPG8 P91/INT9/PPG9 NMIX PM0/PPG0 PM1/PPG1 PM2/PPG2 PM3/PPG3 PF0/CLKPOUT PP0/IC0 PP1/IC1 PP2/IC2 PP3/IC3 PP4/CKI0 PP5/DTTI0 VSS VCC PQ0/RTO0 PQ1/RTO1 PQ2/RTO2 PQ3/RTO3 PQ4/RTO4 PQ5/RTO5 (FPT-100P-M20) 8 VSS PA1/ADTG1 PA0/ADTG0 PB7/AN1-3 PB6/AN1-2 PB5/AN1-1 PB4/AN1-0 PB3/AN0-3 PB2/AN0-2 PB1/AN0-1 PB0/AN0-0 AVSS10 AVRH2 AVCC10 PD1/AN2-9 PD0/AN2-8 PC7/AN2-7 PC6/AN2-6 PC5/AN2-5 PC4/AN2-4 PC3/AN2-3 PC2/AN2-2 PC1/AN2-1 PC0/AN2-0 VCC MB91470/480 Series ■ PIN DESCRIPTIONS Pin no. MB91470 series LQFP144 50 51 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 M6 N6 42 43 MD2 MD1 Function H, K Mode pin 2 This pin sets the basic operating mode. Connect this pin to either VCC pin or VSS pin. Use circuit type K on the Flash memory model. H, K Mode pin 1 This pin sets the basic operating mode. Connect this pin to either VCC pin or VSS pin. Use circuit type K on the Flash memory model. Mode pin 0 This pin sets the basic operating mode. Connect this pin to either VCC pin or VSS pin. Use circuit type K on the Flash memory model. 52 K5 44 MD0 H, K 53 L6 45 X0 A Clock (oscillation) input 54 K6 46 X1 A Clock (oscillation) output 34 L1 48 INITX I External reset input 30 J4 6 NMIX H NMI (Non Maskable Interrupt) input 109 A12 ⎯ 110 B12 ⎯ 111 A11 ⎯ 112 B11 ⎯ 113 C12 ⎯ 114 B10 ⎯ 115 A10 ⎯ 116 C11 ⎯ 117 C10 ⎯ D16 P00 D17 P01 D18 P02 D19 P03 D20 P04 D21 P05 D22 P06 D23 P07 D24 P10 C C C C C C C C C Bit 16 of external data bus I/O pin General-purpose I/O port Bit 17 of external data bus I/O pin General-purpose I/O port Bit 18 of external data bus I/O pin General-purpose I/O port Bit 19 of external data bus I/O pin General-purpose I/O port Bit 20 of external data bus I/O pin General-purpose I/O port Bit 21 of external data bus I/O pin General-purpose I/O port Bit 22 of external data bus I/O pin General-purpose I/O port Bit 23 of external data bus I/O pin General-purpose I/O port Bit 24 of external data bus I/O pin General-purpose I/O port (Continued) 9 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 118 B9 ⎯ 119 A9 ⎯ 120 D10 ⎯ 121 C9 ⎯ 122 B8 ⎯ 123 A8 ⎯ 124 D9 ⎯ 127 A7 ⎯ 128 B7 ⎯ 129 C7 ⎯ 130 D7 ⎯ 131 A6 ⎯ 132 B6 ⎯ 133 C6 ⎯ 134 D6 ⎯ 135 A5 ⎯ D25 P11 D26 P12 D27 P13 D28 P14 D29 P15 D30 P16 D31 P17 A00 P20 A01 P21 A02 P22 A03 P23 A04 P24 A05 P25 A06 P26 A07 P27 A08 P30 C C C C C C C C C C C C C C C C Function Bit 25 of external data bus I/O pin General-purpose I/O port Bit 26 of external data bus I/O pin General-purpose I/O port Bit 27 of external data bus I/O pin General-purpose I/O port Bit 28 of external data bus I/O pin General-purpose I/O port Bit 29 of external data bus I/O pin General-purpose I/O port Bit 30 of external data bus I/O pin General-purpose I/O port Bit 31 of external data bus I/O pin General-purpose I/O port Bit 0 of external address bus output pin General-purpose I/O port Bit 1 of external address bus output pin General-purpose I/O port Bit 2 of external address bus output pin General-purpose I/O port Bit 3 of external address bus output pin General-purpose I/O port Bit 4 of external address bus output pin General-purpose I/O port Bit 5 of external address bus output pin General-purpose I/O port Bit 6 of external address bus output pin General-purpose I/O port Bit 7 of external address bus output pin General-purpose I/O port Bit 8 of external address bus output pin General-purpose I/O port (Continued) 10 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 136 B5 ⎯ 137 C5 ⎯ 138 D5 ⎯ 139 A4 ⎯ 140 B4 ⎯ 141 C4 ⎯ 142 A3 ⎯ 143 A2 ⎯ 2 B2 ⎯ 3 C1 ⎯ 4 C2 ⎯ 5 B3 ⎯ 6 D2 ⎯ A09 P31 A10 P32 A11 P33 A12 P34 A13 P35 A14 P36 A15 P37 CS0X P50 CS1X P51 CS2X P52 ASX P53 RDX P54 WR0X C C C C C C C C C C C C C P55 7 D1 ⎯ WR1X C3 ⎯ SYSCLK P60 Bit 9 of external address bus output pin General-purpose I/O port Bit 10 of external address bus output pin General-purpose I/O port Bit 11 of external address bus output pin General-purpose I/O port Bit 12 of external address bus output pin General-purpose I/O port Bit 13 of external address bus output pin General-purpose I/O port Bit 14 of external address bus output pin General-purpose I/O port Bit 15 of external address bus output pin General-purpose I/O port External chip select 0 output General-purpose I/O port External chip select 1 output General-purpose I/O port External chip select 2 output General-purpose I/O port External address strobe output General-purpose I/O port External read strobe output General-purpose I/O port External write strobe output Corresponding to bit 31 to bit 24 of external data bus I/O General-purpose I/O port C P56 8 Function External write strobe output Corresponding to bit 23 to bit 16 of external data bus I/O General-purpose I/O port C External clock output General-purpose I/O port (Continued) 11 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 9 D3 ⎯ 20 G2 94 21 G3 95 22 G4 96 23 H1 97 RDY P61 INT0 P80 INT1 P81 INT2 P82 INT3 P83 C D D D D INT4 24 25 26 27 28 29 ⎯ H2 H3 H4 J1 J2 J3 ⎯ 98 99 2 3 4 5 ⎯ PPG4 Function External ready input General-purpose I/O port External interrupt 0 input General-purpose I/O port External interrupt 1 input General-purpose I/O port External interrupt 2 input General-purpose I/O port External interrupt 3 input General-purpose I/O port External interrupt 4 input D Output of PPG timer 4 P84 General-purpose I/O port INT5 External interrupt 5 input PPG5 D Output of PPG timer 5 P85 General-purpose I/O port INT6 External interrupt 6 input PPG6 D Output of PPG timer 6 P86 General-purpose I/O port INT7 External interrupt 7 input PPG7 D Output of PPG timer 7 P87 General-purpose I/O port INT8 External interrupt 8 input PPG8 D Output of PPG timer 8 (MB91480 series only) P90 General-purpose I/O port INT9 External interrupt 9 input PPG9 D Output of PPG timer 9 (MB91480 series only) P91 General-purpose I/O port INT10 External interrupt 10 input PPG10 P92 D Output of PPG timer 10 General-purpose I/O port (Continued) 12 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 INT11 ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ PPG11 External interrupt 11 input D ⎯ 73 ⎯ ⎯ 74 65 L9 49 66 K9 ⎯ 67 N10 ⎯ ⎯ ⎯ 65 ⎯ ⎯ 66 ⎯ ⎯ 67 Output of PPG timer 11 P93 General-purpose I/O port INT12 External interrupt 12 input PPG12 D Output of PPG timer 12 P94 General-purpose I/O port INT13 External interrupt 13 input PPG13 D Output of PPG timer 13 P95 General-purpose I/O port INT14 External interrupt 14 input PPG14 D Output of PPG timer 14 P96 General-purpose I/O port INT15 External interrupt 15 input PPG15 D P97 ⎯ Function ADTG0 PA0 ADTG1 PA1 ADTG2 PA2 ADTG3 PA3 ADTG4 PA4 AN0-0 PB0 AN0-1 PB1 AN0-2 PB2 Output of PPG timer 15 General-purpose I/O port D D D D D G G G External trigger input of 8/10-bit A/D converter 0 General-purpose I/O port External trigger input of 8/10-bit A/D converter 1 General-purpose I/O port External trigger input of 8/10-bit A/D converter 2 General-purpose I/O port External trigger input of 12-bit A/D converter 3 General-purpose I/O port External trigger input of 12-bit A/D converter 4 General-purpose I/O port Analog 0 input of 8/10-bit A/D converter 0 General-purpose I/O port Analog 1 input of 8/10-bit A/D converter 0 General-purpose I/O port Analog 2 input of 8/10-bit A/D converter 0 General-purpose I/O port (Continued) 13 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 ⎯ ⎯ 68 ⎯ ⎯ 69 ⎯ ⎯ 70 ⎯ ⎯ 71 ⎯ ⎯ 72 AN0-3 PB3 AN1-0 PB4 AN1-1 PB5 AN1-2 PB6 AN1-3 PB7 G G G G G AN2-0 82 J12 52 SCK4 G 53 SIN4 G 54 SOT4 G 55 SCK5 G 56 SIN5 G 57 SOT5 J10 58 AN2-6 PC6 Clock I/O of multi-function serial interface 4 (not used in I2C mode) (MB91470 series only) Data input of multi-function serial interface 4 (not used in I2C mode) (MB91470 series only) Data output of multi-function serial interface 4 (MB91470 series only) Clock I/O of multi-function serial interface 5 (MB91470 series only) Data input of multi-function serial interface 5 (not used in I2C mode) (MB91470 series only) Analog 5 input of 8/10-bit A/D converter 2 G PC5 88 General-purpose I/O port General-purpose I/O port AN2-5 H13 Analog 3 input of 8/10-bit A/D converter 1 Analog 4 input of 8/10-bit A/D converter 2 PC4 87 General-purpose I/O port General-purpose I/O port AN2-4 H12 Analog 2 input of 8/10-bit A/D converter 1 Analog 3 input of 8/10-bit A/D converter 2 PC3 86 General-purpose I/O port General-purpose I/O port AN2-3 J11 Analog 1 input of 8/10-bit A/D converter 1 Analog 2 input of 8/10-bit A/D converter 2 PC2 85 General-purpose I/O port General-purpose I/O port AN2-2 K10 Analog 0 input of 8/10-bit A/D converter 1 Analog 1 input of 8/10-bit A/D converter 2 PC1 84 General-purpose I/O port General-purpose I/O port AN2-1 J13 Analog 3 input of 8/10-bit A/D converter 0 Analog 0 input of 8/10-bit A/D converter 2 PC0 83 Function Data output of multi-function serial interface 5 (MB91470 series only) General-purpose I/O port G Analog 6 input of 8/10-bit A/D converter 2 General-purpose I/O port (Continued) 14 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 89 H11 59 90 H10 60 91 G13 61 92 G12 ⎯ 93 G11 ⎯ 68 M10 ⎯ AN2-7 PC7 AN2-8 PD0 AN2-9 PD1 AN2-10 PD2 AN2-11 PD3 AN3-0/ AN3-0P G G G G G G PE0 69 L10 ⎯ AN3-1/ AN3-0N 70 N11 ⎯ G 71 N12 ⎯ G 76 L12 ⎯ G 77 M11 ⎯ PE5 General-purpose I/O port Analog 9 input of 8/10-bit A/D converter 2 General-purpose I/O port Analog 10 input of 8/10-bit A/D converter 2 General-purpose I/O port Analog 11 input of 8/10-bit A/D converter 2 General-purpose I/O port 12-bit A/D converter 3 analog 0 input (in single input mode) 12-bit A/D converter 3 analog 0 ( + ) side input (in differential input mode) 12-bit A/D converter 3 analog 1 input (in single input mode) 12-bit A/D converter 3 analog 0 ( − ) side input (in differential input mode) 12-bit A/D converter 3 analog 2 input (in single input mode) 12-bit A/D converter 3 analog 1 ( + ) side input (in differential input mode) 12-bit A/D converter 3 analog 3 input (in single input mode) 12-bit A/D converter 3 analog 1 ( − ) side input (in differential input mode) General-purpose I/O port G PE4 AN4-1/ AN4-0N Analog 8 input of 8/10-bit A/D converter 2 General-purpose I/O port PE3 AN4-0/ AN4-0P General-purpose I/O port General-purpose I/O port PE2 AN3-3/ AN3-1N Analog 7 input of 8/10-bit A/D converter 2 General-purpose I/O port PE1 AN3-2/ AN3-1P Function 12-bit A/D converter 4 analog 0 input (in single input mode) 12-bit A/D converter 4 analog 0 ( + ) side input (in differential input mode) General-purpose I/O port G 12-bit A/D converter 4 analog 1 input (in single input mode) 12-bit A/D converter 4 analog 0 ( − ) side input (in differential input mode) General-purpose I/O port (Continued) 15 MB91470/480 Series Pin no. MB91470 series LQFP144 78 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 K12 ⎯ AN4-2/ AN4-1P G PE6 79 K13 ⎯ AN4-3/ AN4-1N ⎯ ⎯ 11 12-bit A/D converter 4 analog 2 input (in single input mode) 12-bit A/D converter 4 analog 1 ( + ) side input (in differential input mode) General-purpose I/O port G PE7 CLKPOUT Function 12-bit A/D converter 4 analog 3 input (in single input mode) 12-bit A/D converter 4 analog 1 ( − ) side input (in differential input mode) General-purpose I/O port D PF0 Clock monitor output General-purpose I/O port ⎯ ⎯ ⎯ PF1 D General-purpose I/O port ⎯ ⎯ ⎯ PF2 D General-purpose I/O port ⎯ ⎯ ⎯ PF3 D General-purpose I/O port ⎯ ⎯ ⎯ PF4 D General-purpose I/O port ⎯ ⎯ ⎯ PF5 D General-purpose I/O port ⎯ ⎯ ⎯ PF6 D General-purpose I/O port ⎯ ⎯ ⎯ PF7 D General-purpose I/O port 97 F11 77 98 F10 78 SCK0 PG0 SIN0 D D PG1 99 E13 79 100 E12 80 101 E11 81 SOT0 PG2 SCK1 PG3 SIN1 E10 82 103 D13 83 SOT1 PG5 SCK2 PH0 General-purpose I/O port Data input of multi-function serial interface 0 (not used in I2C mode) General-purpose I/O port D D D PG4 102 Clock I/O of multi-function serial interface 0 Data output of multi-function serial interface 0 General-purpose I/O port Clock I/O of multi-function serial interface 1 General-purpose I/O port Data input of multi-function serial interface 1 (not used in I2C mode) General-purpose I/O port D D Data output of multi-function serial interface 1 General-purpose I/O port Clock I/O of multi-function serial interface 2 General-purpose I/O port (Continued) 16 MB91470/480 Series Pin no. MB91470 series LQFP144 104 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 D12 84 SIN2 D PH1 105 D11 85 106 C13 ⎯ 107 B13 ⎯ SOT2 PH2 SCK3 PH3 SIN3 A13 ⎯ 10 E2 86 11 E1 87 12 D4 88 13 E3 89 14 F2 90 15 F1 91 16 E4 92 17 F3 93 31 K1 ⎯ 32 K2 ⎯ SOT3 PH5 TIN0 PJ0 TOUT0 PJ1 TIN1 PJ2 TOUT1 PJ3 TIN2 PJ4 TOUT2 PJ5 TIN3 PJ6 TOUT3 PJ7 AIN0 PL0 BIN0 PL1 Data input of multi-function serial interface 2 (not used in I2C mode) General-purpose I/O port D D D PH4 108 Function Data output of multi-function serial interface 2 General-purpose I/O port Clock I/O of multi-function serial interface 3 General-purpose I/O port Data input of multi-function serial interface 3 (not used in I2C mode) General-purpose I/O port D D D D D D D D D D D Data output of multi-function serial interface 3 General-purpose I/O port Base timer 0 input General-purpose I/O port Base timer 0 output General-purpose I/O port Base timer 1 input General-purpose I/O port Base timer 1 output General-purpose I/O port Base timer 2 input General-purpose I/O port Base timer 2 output General-purpose I/O port Base timer 3 input General-purpose I/O port Base timer 3 output General-purpose I/O port 8/16-bit up count input pin for up/down counter 0 General-purpose I/O port 8/16-bit down count input pin for up/down counter 0 General-purpose I/O port (Continued) 17 MB91470/480 Series Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 33 K3 ⎯ 61 L8 7 62 K8 8 63 N9 9 64 M9 10 46 M5 12 47 N5 13 48 K4 14 49 L5 15 56 M7 16 57 L7 17 ZIN0 PL2 PPG0 PM0 PPG1 PM1 PPG2 PM2 PPG3 PM3 IC0 PP0 IC1 PP1 IC2 PP2 IC3 PP3 CKI0 PP4 DTTI0 D D D D D D D D D D D PP5 38 M2 20 39 N3 21 40 M3 22 41 L2 23 RTO0 PQ0 RTO1 PQ1 RTO2 PQ2 RTO3 PQ3 Function 8/16-bit reset input pin for up/down counter 0 General-purpose I/O port Output of PPG timer 0 General-purpose I/O port Output of PPG timer 1 General-purpose I/O port Output of PPG timer 2 General-purpose I/O port Output of PPG timer 3 General-purpose I/O port Trigger input of input capture 0 General-purpose I/O port Trigger input of input capture 1 General-purpose I/O port Trigger input of input capture 2 General-purpose I/O port Trigger input of input capture 3 General-purpose I/O port External clock input pin of free-run timer ch.0 to ch.2 General-purpose I/O port Input signal controlling wave form generator outputs RTO0 to RTO5 of multi-function timer 0 General-purpose I/O port J J J J Wave form generator output of multi-function timer 0 General-purpose I/O port Wave form generator output of multi-function timer 0 General-purpose I/O port Wave form generator output of multi-function timer 0 General-purpose I/O port Wave form generator output of multi-function timer 0 General-purpose I/O port (Continued) 18 MB91470/480 Series (Continued) Pin no. MB91470 series LQFP144 MB91480 I/O series Pin name circuit type* PFBGA- LQFP144 100 42 M4 24 43 N4 25 ⎯ ⎯ 36 ⎯ ⎯ 37 ⎯ ⎯ 38 ⎯ ⎯ 39 ⎯ ⎯ 40 ⎯ ⎯ 41 RTO4 PQ4 RTO5 PQ5 IC4 PR0 IC5 PR1 IC6 PR2 IC7 PR3 CKI1 PR4 DTTI1 J J D D D D D D PR5 ⎯ ⎯ 26 ⎯ ⎯ 27 ⎯ ⎯ 28 ⎯ ⎯ 29 ⎯ ⎯ 30 ⎯ ⎯ 31 RTO6 PS0 RTO7 PS1 RTO8 PS2 RTO9 PS3 RTO10 PS4 RTO11 PS5 Function Wave form generator output of multi-function timer 0 General-purpose I/O port Wave form generator output of multi-function timer 0 General-purpose I/O port Trigger input of input capture 4 General-purpose I/O port Trigger input of input capture 5 General-purpose I/O port Trigger input of input capture 6 General-purpose I/O port Trigger input of input capture 7 General-purpose I/O port External clock input pin of free-run timer ch.3 to ch.5 General-purpose I/O port Input signal controlling wave form generator outputs RTO6 to RTO11 of multi-function timer 1 General-purpose I/O port J J J J J J Wave form generator output of multi-function timer 1 General-purpose I/O port Wave form generator output of multi-function timer 1 General-purpose I/O port Wave form generator output of multi-function timer 1 General-purpose I/O port Wave form generator output of multi-function timer 1 General-purpose I/O port Wave form generator output of multi-function timer 1 General-purpose I/O port Wave form generator output of multi-function timer 1 General-purpose I/O port * : Refer to “■ I/O CIRCUIT TYPE” for I/O circuit type. 19 MB91470/480 Series Power supply pins and GND pins Pin number MB91470 series 20 MB91480 series Pin name Function LQFP144 PFBGA144 LQFP100 1 18 35 37 44 60 81 126 B1 F4 M1 N2 L3 M8 K11 D8 ⎯ 1 19 32 33 51 76 ⎯ VCC Power supply pins Connect all pins to the same potential. 19 36 45 55 59 80 125 144 A1 G1 N1 L4 N7 N8 L11 C8 ⎯ 18 34 47 50 75 100 ⎯ VSS GND pins Connect all pins to the same potential. 58 K7 35 C 94 G10 62 AVCC10 Analog power supply pin for 8/10-bit A/D converter 0/1/2 96 F12 64 AVSS10 Analog GND pin for 8/10-bit A/D converter 74 M12 ⎯ AVCC12 Analog power supply pin for 12-bit A/D converter 3/4 72 N13 ⎯ AVSS12 Analog GND pin for 12-bit A/D converter 3/4 ⎯ ⎯ ⎯ AVRH0 Analog reference power supply pin for 8/10-bit A/D converter 0 ⎯ ⎯ ⎯ AVRH1 Analog reference power supply pin for 8/10-bit A/D converter 1 95 F13 63 AVRH2 Analog reference power supply pin for 8/10-bit A/D converter 2 73 M13 ⎯ AVRH3 Analog reference power supply pin for 12-bit A/D converter 3 75 L13 ⎯ AVRH4 Analog reference power supply pin for 12-bit A/D converter 4 Capacitor coupling pin for internal regulator MB91470/480 Series ■ I/O CIRCUIT TYPE Type Circuit Remarks X1 Clock input A Oscillation feedback resistance for high speed (main clock oscillation) approx. 1 MΩ X0 Standby control P-ch Pull-up control • CMOS level output • CMOS level input Digital output • With standby control • With pull-up control P-ch C Digital output N-ch R Digital input Standby control P-ch Pull-up control • CMOS level output • CMOS level hysteresis input Digital output • With standby control • With pull-up control P-ch D Digital output R N-ch Digital input Standby control (Continued) 21 MB91470/480 Series Type Circuit Remarks Pull-up control Digital output P-ch P-ch G Digital output N-ch R • Analog/CMOS level hysteresis I/O pin • CMOS level output • CMOS level hysteresis input (with standby control) • Analog input (Operates as an analog input when the corresponding AICR register bit is “1”.) • With pull-up control Digital input Standby control Analog input • CMOS level hysteresis input • Without standby control P-ch H N-ch R Digital input • CMOS level hysteresis input P-ch • Without standby control • With pull-up resistance P-ch I R N-ch Digital input (Continued) 22 MB91470/480 Series (Continued) Type Circuit P-ch Remarks Pull-up control • CMOS level output • CMOS level hysteresis input Digital output • With standby control • With pull-up control P-ch Digital output J N-ch R Digital input Standby control Flash memory product only • CMOS level input • High voltage control for testing Flash memory N-ch N-ch N-ch K Control signal N-ch N-ch R Mode input 23 MB91470/480 Series ■ HANDLING DEVICES • Preventing latch-up Latch-up phenomenon may occur with CMOS IC, when a voltage higher than VCC or lower than VSS is applied to either the input or output terminals, or when a voltage is applied between VCC pin and VSS pin that exceeds the rated voltage. When latch-up occurs, a significant power-supply current surge results, which may damage some elements due to the excess heat, so great care must be taken to ensure that the maximum rating is never exceeded during use. • Treatment of unused input pins Do not leave an unused input pin open, since it may cause a malfunction. Handle by, for example, using a pull-up or pull-down resistor. • Power pins In products with multiple VCC and VSS pins, the pins of the same potential are internally connected in the device to avoid abnormal operations including latch-up. However, you must connect the pins to the same potential power supply and a ground line externally to lower the electro-magnetic emission level, to prevent abnormal operation of strobe signals caused by the rise in the ground level, and to conform to the total output current rating. Moreover, connect the current supply source with the VCC and VSS pins of this device at the low impedance. It is also advisable to connect a ceramic capacitor of approximately 0.1 µF as a bypass capacitor between VCC and VSS near this device. • Crystal oscillator circuit Noise near the X0 and X1 pins may cause the device to malfunction. Design the printed circuit board so that X0, X1, the crystal oscillator (or ceramic oscillator), and the bypass capacitor to ground are located as close to the device as possible. It is strongly recommended to design the PC board artwork with the X0 and X1pins surrounded by ground plane because stable operation can be expected with such a layout. Please ask the crystal maker to evaluate the oscillational characteristics of the crystal and this device. • About mode pins (MD0 to MD2) These pins should be connected directly to VCC pin or VSS pin. To prevent the device erroneously switching to test mode due to noise, the pattern length between each mode pins and VCC or VSS on the printed circuit board should be as short as possible, and they should be connected at low impedance. • Operation at start-up Be sure to execute setting initialized reset (INIT) with INITX pin immediately after start-up. Immediately after that, also, hold the "L"-level input to the INITX pin for the stabilization wait time required for the oscillator circuit to take the oscillation stabilization wait time for the oscillator circuit and the stabilization wait time for the regulator (For INIT via the INITX pin, the oscillation stabilization wait time setting is initialized to the minimum value). 24 MB91470/480 Series • Notes upon power-on sequence It requires more than 600 µs (between 0.0 V to 5.0 V) to rise voltage upon power on in order to prevent the device malfunction caused by the overshooting in the built-in voltage step-down circuit. After the supply voltage is stable (voltage is risen) , it takes 600 µs until internal supply is stable. Hold the input to the INITX pin during that period. If it takes less than 600 µs (between 0.0 V to 5.0 V) for power up, it requires 2 ms* until internal supply is stable after voltage supply is stable (voltage is risen) . Hold the input to the INITX pin during that period. CASE : voltage rising time is more than 600 µs (0.0 V to 5.0 V) VCC (V) 5.0 0 600 (µs) t Hold for more than 600 µs INITX Internal power supply waits until stable Power-on Start operating CASE : voltage rising time is less than 600 µs (0.0 V to 5.0 V) VCC (V) 5.0 0 600 (µs) t Hold for more than 2 ms* INITX Power-on Internal power supply waits until stable Start operating * : In case of which it takes less than 600 µs (between 0.0 V to 5.0 V) to rise voltage, the time to make internal power supply stable is proportional to the capacitance value of the bypass capacitor for the pin C. It takes 2 ms if the pin C = 4.7 µF ; 4 ms if the pin C = 9.4 µF. 25 MB91470/480 Series • Order of power turning ON/OFF Use the following procedure for turning the power on or off. If not using the A/D converter, connect AVCC =VCC and AVSS = VSS. Turn on the power supply in the sequence VCC → AVCC → AVRH, and turn off the power in the reverse sequence. • Source oscillation input when turning on the power When turning the power on, maintain the clock input until the device is released from the oscillation stabilization wait state. • Cautions for operation during PLL clock mode Even if the oscillator comes off or the clock input stops with the PLL clock selected for MB91470/480 series, MB91470/480 series may continue to operate at the free-run frequency of the PLL’s internal self-oscillating oscillator circuit. Performance of this operation, however, cannot be guaranteed. • Using an external clock When using an external clock, you must always input clock signals with opposite phase from X0 pin to X1 pin simultaneously. However, as the X1 pin halts with an output at the "H" level during stop mode, insert a resistor of approximately 1 kΩ externally to prevent a conflict between the two outputs if using stop mode (oscillation stop mode). The figure below shows an example of how to use an external clock. • Example of Using an External Clock X0 MB91470/480 series X1 • C pin As MB91470/480 series includes an internal regulator, always connect a bypass capacitor of approximately 4.7 µF to the C pin for use by the regulator. MB91470/480 series C 4.7 µF VSS GND • Software reset on the synchronous mode Be sure to meet the following two conditions before setting 0 to the SRST bit of STCR (standby control register) when the software reset is used on the synchronous mode. • Set the interrupt enable flag (I-Flag) to interrupts disabled (I-Flag=0). • Not used NMI 26 MB91470/480 Series ■ BLOCK DIAGRAM •MB91470 series (144 pins) VCC VSS C FR60 CPU core Downconversion circuit Watchdog timer 32 Bit search Flash/ROM (Max 512 Kbytes) 32 MAC D-bus RAM (Max 28 Kbytes) F-bus RAM (Max 4 Kbytes) DMAC 5 channels Bus converter 32 32 SYSCLK MD2 to MD0 INITX X0 X1 32 ↔ 16 adapter 3 channels external bus I/F Clock control 16 NMIX INT0 to INT9 SCK0 to SCK5 SIN0 to SIN5 SOT0 to SOT5 1+10 channels external interrupt 6 channels multi-function serial interface AVRH2 ADTG2 AN2-0 to AN2-11 12 channels input 8/10-bit A/D converter 2 4 channels input 12-bit A/D converter 3 AVRH4 ADTG4 AN4-0 to AN4-3 4 channels input 12-bit A/D converter 4 TOUT0 to TOUT3 CS0X to CS2X RDX WR0X, WR1X RDY Interrupt controller Port I/F 1 channel up/down counter 8 channels PPG GPIO AIN0 BIN0 ZIN0 2 channels reload timer PPG0 to PPG7 Multi-function timer AVCC12 AVSS12 AVRH3 ADTG3 AN3-0 to AN3-3 TIN0 to TIN3 ASX 16 1 unit timing generator AVCC10 AVSS10 A15 to A00 D31 to D16 4 channels base timer -PWC -Reload timer -PWM -PPG 3 channels A/D activating compare 4 channels input capture IC0 to IC3 3 channels free-run timer CKI0 6 channels output compare 6 channels wave form generator RTO0 to RTO5 DTTI0 27 MB91470/480 Series • MB91480 series (100 pins) VCC VSS C Watchdog timer FR60 CPU core Downconversion circuit 32 Bit search Flash/ROM (Max 512 Kbytes) F-bus RAM (Max 4 Kbytes) 32 MAC D-bus RAM (Max 28 Kbytes) Bus converter DMAC 5 channels 32 32 MD2 to MD0 INITX X0 X1 32 ↔ 16 adapter Clock control 16 NMIX INT0 to INT9 SCK0 to SCK2 SIN0 to SIN2 SOT0 to SOT2 1+10 channels external interrupt 3 channels multi-function serial interface 16 Clock monitor Interrupt controller Port I/F 2 units timing generator AVCC10 AVSS10 16 channels PPG 2 channels reload timer AVRH2 ADTG2 AN2-0 to AN2-9 10 channels input 8/10-bit A/D converter 2 ADTG0 AN0-0 to AN0-3 4 channels input 8/10-bit A/D converter 0 6 channels A/D activating compare 4 channels input 8/10-bit A/D converter 1 8 channels input capture IC0 to IC7 6 channels free-run timer CKI0,CKI1 PPG0 to PPG15 Multi-function timer ADTG1 AN1-0 to AN1-3 TIN0 to TIN3 TOUT0 to TOUT3 4 channels base timer -PWC -Reload timer -PWM -PPG 12 channels output compare 12 channels wave form generator 28 RTO0 to RTO11 DTTI0,DTTI1 CLKPOUT GPIO MB91470/480 Series ■ MEMORY SPACE 1. Memory Space The FR family has 4 Gbytes of logical address space (232 addresses) available to the CPU by linear access. • Direct Addressing Areas The following address space areas are used as I/O areas. These areas are called direct addressing areas, in which the address of an operand can be specified directly by the instruction. The size of directly addressable areas depends on the length of the data being accessed as shown below. → byte data access : 000H to 0FFH → half word data access : 000H to 1FFH → word data access : 000H to 3FFH 2. Memory Map •MB91470 series Single chip mode Internal ROM external bus mode External ROM external bus mode I/O I/O I/O Direct addressing area I/O I/O I/O Refer to “■I/O MAP” Access prohibited Access prohibited Access prohibited F-bus RAM 4 Kbytes F-bus RAM 4 Kbytes F-bus RAM 4 Kbytes D-bus RAM 28 Kbytes D-bus RAM 28 Kbytes D-bus RAM 28 Kbytes Access prohibited Access prohibited 0000 0000H 0000 0400H 0001 0000H 0003 F000H 0004 0000H 0004 7000H 0005 0000H Access prohibited 0008 0000H 512 Kbytes Flash/ROM 512 Kbytes Flash/ROM 0010 0000H Access prohibited 0020 0000H External area Maximum value • 12 Kbytes : 00040000H to 00042FFFH • 20 Kbytes : 00040000H to 00044FFFH • 28 Kbytes : 00040000H to 00046FFFH Maximum value • 256 Kbytes : 000C0000H to 000FFFFFH • 384 Kbytes : 000A0000H to 000FFFFFH • 512 Kbytes : 00080000H to 000FFFFFH Access prohibited External area FFFF FFFFH 144 pins 144 pins 144 pins 29 MB91470/480 Series •MB91480 series Single chip mode 0000 0000H I/O Direct addressing area I/O Refer to “■I/O MAP” 0000 0400H 0001 0000H Access prohibited 0003 F000H F-bus RAM 4 Kbytes 0004 0000H D-bus RAM 28 Kbytes 0004 7000H 0005 0000H Maximum value • 12 Kbytes : 00040000H to 00042FFFH • 28 Kbytes : 00040000H to 00046FFFH Access prohibited 0008 0000H 512 Kbytes Flash/ROM 0010 0000H 0020 0000H Access prohibited FFFF FFFFH 100 pins 30 Maximum value • 256 Kbytes : 000C0000H to 000FFFFFH • 512 Kbytes : 00080000H to 000FFFFFH MB91470/480 Series ■ MODE SETTINGS The FR family uses mode pins (MD2 to MD0) and mode data to set the operation mode. 1. Mode Pins The MD2 to MD0 pins specify how the mode vector fetch and reset vector fetch is performed. Settings other than those shown in the following table are prohibited. Mode Pins Reset vector access area Mode name MD2 MD1 MD0 0 0 0 Internal ROM mode vector Internal 0 0 1 External ROM mode vector External Remarks The bus width is set by mode register. 2. Mode data The data that is written to the internal mode register (MODR) by the mode vector fetch is called mode data. After the mode register is set, the device runs in the operating mode specified by this register. The mode data is set by all of the reset sources. User programs cannot set the mode register. <Details of mode data description> bit23 bit22 bit21 bit20 bit19 bit18 bit17 bit16 0 0 0 0 0 ROMA WTH1 WTH0 Operation mode setting bits [bit 23 to bit 19] Reserved bits Be sure to set these bits to “00000B”. Operation is not guaranteed if these bits are set to a value other than “00000B”. [bit 18] ROMA (Internal Flash/ROM enable bit) This bit configures whether the internal Flash/ROM area (8 0000H to F FFFFH) is enabled. ROMA Function Remarks 0 External ROM mode Internal Flash/ROM area (8 0000H to F FFFFH) is used as an external area. 1 Internal ROM mode Internal Flash/ROM area (8 0000H to F FFFFH) is enabled. 31 MB91470/480 Series [bit 17, bit 16] WTH1, WTH0 (Bus width specification bit) These bits configure the bus width in external bus mode. In external bus mode, this value is set to the DBW1 and DBW0 bits of AWR0 (CS0 area). WTH1 WTH0 Function Remarks 0 0 8-bit bus width External bus mode 0 1 16-bit bus width External bus mode 1 0 1 1 ⎯ (Setting prohibited) Single chip mode Single chip mode 3. Note The mode data set in the mode vector must be stored as byte data at 0x000FFFF8H. The data should be located in the highest byte from bit 31 to bit 24 because the FR family uses big endian byte ordering. bit 31 Incorrect 0x000FFFF8H Correct 0x000FFFF8H 0x000FFFFCH 32 24 23 16 15 87 0 XXXXXXXX XXXXXXXX XXXXXXXX Mode data Mode data XXXXXXXX XXXXXXXX XXXXXXXX Reset vector MB91470/480 Series ■ I/O MAP [How to read the table] Address 000000H Register +0 +1 +2 +3 PDR0 [R/W] B PDR1 [R/W] B PDR2 [R/W] B PDR3 [R/W] B XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX Block T-unit Port data register Read/write attribute, Access unit (B : byte, H : half word, W : word) Initial value of register after reset Register name (column 1 of the register is at address 4n, column 2 is at address 4 n + 1...) Leftmost register address (For word-length access, column 1 of the register is the MSB of the data.) Note : Initial values of register bits are represented as follows : “ 1 ” : Initial Value “ 1 ” “ 0 ” : Initial Value “ 0 ” “ X ” : Initial Value “ undefined ” “ - ” : No physical register at this location Access to addresses where the data access properties have not been documented is prohibited. 33 MB91470/480 Series Address Register +0 +1 +2 +3 000000H PDR0 [R/W] B, H, W XXXXXXXX PDR1 [R/W] B, H, W XXXXXXXX PDR2 [R/W] B, H, W XXXXXXXX PDR3 [R/W] B, H, W XXXXXXXX 000004H PDR5 [R/W] B, H, W -XXXXXXX PDR6 [R/W] B, H, W ------XX PDR8 [R/W] B, H, W XXXXXXXX PDR9 [R/W] B, H, W XXXXXXXX 000008H PDRA [R/W] B, H, W ---XXXXX PDRB [R/W] B, H, W XXXXXXXX PDRC [R/W] B, H, W XXXXXXXX PDRD [R/W] B, H, W ----XXXX 00000CH PDRE [R/W] B, H, W XXXXXXXX PDRF [R/W] B, H, W XXXXXXXX PDRG [R/W] B, H, W --XXXXXX PDRH [R/W] B, H, W --XXXXXX 000010H PDRJ [R/W] B, H, W XXXXXXXX ⎯ PDRL [R/W] B, H, W -----XXX PDRM [R/W] B, H, W ----XXXX 000014H PDRP [R/W] B, H, W --XXXXXX PDRQ [R/W] B, H, W --XXXXXX PDRR [R/W] B, H, W --XXXXXX PDRS [R/W] B, H, W --XXXXXX 000018H to 00003CH ⎯ Block Port data register (Reserved) 000040H EIRR0 [R/W] B, H, W 00000000 ENIR0 [R/W] B, H, W 00000000 ELVR0 [R/W] B, H, W 00000000 00000000 External interrupt (INT0 to INT7) 000044H DICR [R/W] B, H, W -------0 HCRL [R/W, R] B, H, W 0--11111 ⎯ Delay interrupt/ hold request TMRLR0 [W] H, W XXXXXXXX XXXXXXXX TMR0 [R] H, W XXXXXXXX XXXXXXXX 00004CH ⎯ TMCSR0 [R/W, R] B, H, W ----00-- ---00000 000050H TMRLR1 [W] H, W XXXXXXXX XXXXXXXX TMR1 [R] H, W XXXXXXXX XXXXXXXX 000054H ⎯ TMCSR1 [R/W, R] B, H, W ----00-- ---00000 000048H 000058H to 00005CH ⎯ Reload timer 0 Reload timer 1 (Reserved) (Continued) 34 MB91470/480 Series Address Register +0 +1 +2 +3 000060H SSR0 [R/W, R] B, H, W 00000011 ESCR0 [R/W]/ IBSR0 [R/W, R] B, H, W 00000000 SCR0 [R/W] / IBCR0 [R/W, R] B, H, W 00000000 SMR0 [R/W] B, H, W 000-0000 000064H BGR01[R/W] B, H, W 00000000 BGR00 [R/W] B, H, W 00000000 RDR0 [R]/ TDR0 [W]H, W -------0 00000000 RDR0 [R]/ TDR0 [W]H, W -------0 00000000 ISMK0 [R/W] B, H, W 01111111 ISBA0 [R/W] B, H, W 00000000 ⎯ 000068H 00006CH FBYTE02 [R/W] B, H, W 00000000 FBYTE01 [R/W] B, H, W 00000000 FCR01 [R/W] B, H, W ---00100 FCR00 [R/W, R] B, H, W -0000000 000070H SSR1 [R/W, R] B, H, W 00000011 ESCR1 [R/W]/ IBSR1 [R/W, R] B, H, W 00000000 SCR1 [R/W] / IBCR1 [R/W, R] B, H, W 00000000 SMR1 [R/W] B, H, W 000-0000 000074H BGR11 [R/W] B, H, W 00000000 BGR10 [R/W] B, H, W 00000000 RDR1 [R]/ TDR1 [W]H, W -------0 00000000 RDR1 [R]/ TDR1 [W]H, W -------0 00000000 ISMK1 [R/W] B, H, W 01111111 ISBA1 [R/W] B, H, W 00000000 ⎯ 000078H 00007CH FBYTE21 [R/W] B, H, W 00000000 FBYTE11 [R/W] B, H, W 00000000 FCR11 [R/W] B, H, W ---00100 FCR10 [R/W, R] B, H, W -0000000 000080H SSR2 [R/W, R] B, H, W 00000011 ESCR2 [R/W]/ IBSR2 [R/W, R] B, H, W 00000000 SCR2 [R/W] / IBCR2 [R/W, R] B, H, W 00000000 SMR2 [R/W] B, H, W 000-0000 000084H BGR21 [R/W] B, H, W 00000000 BGR20 [R/W] B, H, W 00000000 RDR2 [R]/ TDR2 [W]H, W -------0 00000000 RDR2 [R]/ TDR2 [W]H, W -------0 00000000 ISMK2 [R/W] B, H, W 01111111 ISBA2 [R/W] B, H, W 00000000 FCR21 [R/W] B, H, W ---00100 FCR20 [R/W, R] B, H, W -0000000 ⎯ 000088H 00008CH FBYTE22 [R/W] B, H, W 00000000 FBYTE21 [R/W] B, H, W 00000000 Block Multifunction serial interface 0 Multifunction serial interface 1 Multifunction serial interface 2 (Continued) 35 MB91470/480 Series Address Register +0 +1 +2 +3 000090H SSR3 [R/W, R] B, H, W 00000011 ESCR3 [R/W]/ IBSR3 [R/W, R] B, H, W 00000000 SCR3 [R/W] / IBCR3 [R/W, R] B, H, W 00000000 SMR3 [R/W] B, H, W 000-0000 000094H BGR31 [R/W] B, H, W 00000000 BGR30 [R/W] B, H, W 00000000 RDR3 [R]/ TDR3 [W]H, W -------0 00000000 RDR3 [R]/ TDR3 [W]H, W -------0 00000000 ISMK3 [R/W] B, H, W 01111111 ISBA3 [R/W] B, H, W 00000000 FCR31 [R/W] B, H, W ---00100 FCR30 [R/W, R] B, H, W -0000000 ⎯ 000098H 00009CH FBYTE32 [R/W] B, H, W 00000000 FBYTE31 [R/W] B, H, W 00000000 0000A0H OCCPBH0, OCCPBL0 [W]/ OCCPH0, OCCPL0 [R] H, W 00000000 00000000 OCCPBH1, OCCPBL1 [W]/ OCCPH1, OCCPL1 [R] H, W 00000000 00000000 0000A4H OCCPBH2, OCCPBL2 [W]/ OCCPH2, OCCPL2 [R] H, W 00000000 00000000 OCCPBH3, OCCPBL3 [W]/ OCCPH3, OCCPL3 [R] H, W 00000000 00000000 0000A8H OCCPBH4, OCCPBL4 [W]/ OCCPH4, OCCPL4 [R] H, W 00000000 00000000 OCCPBH5, OCCPBL5 [W]/ OCCPH5, OCCPL5 [R] H, W 00000000 00000000 0000ACH OCSH1 [R/W] B, H, W -1100000 OCSL0 [R/W] B, H, W 00001100 OCSH3 [R/W] B, H, W -1100000 OCSL2 [R/W] B, H, W 00001100 0000B0H OCSH5 [R/W] B, H, W -1100000 OCSL4 [R/W] B, H, W 00001100 OCMOD0 [R/W] B, H, W --000000 ⎯ 0000B4H 0000B8H 0000BCH 0000C0H CPCLRBH0, CPCLRBL0 [W]/ CPCLRH0, CPCLRL0 [R] H, W 11111111 11111111 TCCSH0 [R/W] B, H, W 00000000 TCCSL0 [R/W] B, H, W 01000000 CPCLRBH1, CPCLRBL1 [W] / CPCLRH1, CPCLRL1 [R] H, W 11111111 11111111 TCCSH1 [R/W] B, H, W 00000000 TCCSL1 [R/W] B, H, W 01000000 TCDTH0, TCDTL0 [R/W] H, W 00000000 00000000 TCCSM0 [R/W] B, H, W ----0000 ADTRGC0 [R/W] B, H, W -000-000 TCDTH1, TCDTL1 [R/W] H, W 00000000 00000000 TCCSM1 [R/W] B, H, W ----0000 ADTRGC1 [R/W] B, H, W -000-000 Block Multifunction serial interface 3 OCU0 Free-run timer 0 Free-run timer 1 (Continued) 36 MB91470/480 Series Address 0000C4H Register +0 +1 CPCLRBH2, CPCLRBL2 [W] / CPCLRH2, CPCLRL2 [R] H, W 11111111 11111111 0000C8H TCCSH2 [R/W] B, H, W 00000000 0000CCH ⎯ TCCSL2 [R/W] B, H, W 01000000 +2 +3 TCDTH2, TCDTL2 [R/W] H, W 00000000 00000000 TCCSM2 [R/W] B, H, W ----0000 ADTRGC2 [R/W] B, H, W -000-000 FRS2 [R/W] B, H, W FRS1 [R/W] B, H, W FRS0 [R/W] B, H, W -000-000 -000-000 -000-000 0000D0H ⎯ FRS4 [R/W] B, H, W FRS3 [R/W] B, H, W -000-000 -000-000 0000D4H IPCPH0, IPCPL0 [R] H, W XXXXXXXX XXXXXXXX IPCPH1, IPCPL1 [R] H, W XXXXXXXX XXXXXXXX 0000D8H IPCPH2, IPCPL2 [R] H, W XXXXXXXX XXXXXXXX IPCPH3, IPCPL3 [R] H, W XXXXXXXX XXXXXXXX 0000DCH PICSH01 [W, R] B, H, W 00000000 PICSL01 [R/W] B, H, W 00000000 ICSH23 [R] B, H, W ------00 TMRRH0, TMRRL0 [R/W] H, W XXXXXXXX XXXXXXXX TMRRH1, TMRRL1 [R/W] H, W XXXXXXXX XXXXXXXX 0000E4H TMRRH2, TMRRL2 [R/W] H, W XXXXXXXX XXXXXXXX ⎯ 0000E8H DTCR0 [R/W] B, H, W 00000000 DTCR1 [R/W] B, H, W 00000000 DTCR2 [R/W] B, H, W 00000000 ⎯ 0000ECH ⎯ SIGCR10 [R/W] B, H, W 00000000 ⎯ SIGCR20 [R/W] B, H, W 000000-1 0000F0H ADCOMP0 [W]/ ADCOMPB0 [R] H, W 00000000 00000000 ADCOMPD0 [W]/ ADCOMPDB0 [R] H, W 00000000 00000000 0000F4H ADCOMP1 [W]/ ADCOMPB1 [R] H, W 00000000 00000000 ADCOMPD1 [W]/ ADCOMPDB1 [R] H, W 00000000 00000000 0000F8H ADCOMP2 [W]/ ADCOMPB2 [R] H, W 00000000 00000000 ADCOMPD2 [W]/ ADCOMPDB2 [R] H, W 00000000 00000000 ⎯ ADTGBUF0 [R/W] B, H, W -000-111 ADTGSEL0 [R/W] B, H, W --000000 Free-run timer 2 Free-run timer selector 0 ICU0 ICSL23[R/W] B, H, W 00000000 0000E0H 0000FCH Block Wave form generator 0 A/D activating compare 0 ADTGCE0 [R/W] B, H, W --000000 (Continued) 37 MB91470/480 Series Address Register +0 +1 +2 +3 000100H PRLH0 [R/W] B, H, W XXXXXXXX PRLL0 [R/W] B, H, W XXXXXXXX PRLH1 [R/W] B, H, W XXXXXXXX PRLL1 [R/W] B, H, W XXXXXXXX 000104H PRLH2 [R/W] B, H, W XXXXXXXX PRLL2 [R/W] B, H, W XXXXXXXX PRLH3 [R/W] B, H, W XXXXXXXX PRLL3 [R/W] B, H, W XXXXXXXX 000108H PPGC0 [R/W] B, H, W 00000000 PPGC1 [R/W] B, H, W 00000000 PPGC2 [R/W] B, H, W 00000000 PPGC3 [R/W] B, H, W 00000000 00010CH PRLH4 [R/W] B, H, W XXXXXXXX PRLL4 [R/W] B, H, W XXXXXXXX PRLH5 [R/W] B, H, W XXXXXXXX PRLL5 [R/W] B, H, W XXXXXXXX 000110H PRLH6 [R/W] B, H, W XXXXXXXX PRLL6 [R/W] B, H, W XXXXXXXX PRLH7 [R/W] B, H, W XXXXXXXX PRLL7 [R/W] B, H, W XXXXXXXX 000114H PPGC4 [R/W] B, H, W 00000000 PPGC5 [R/W] B, H, W 00000000 PPGC6 [R/W] B, H, W 00000000 PPGC7 [R/W] B, H, W 00000000 000118H PRLH8 [R/W] B, H, W XXXXXXXX PRLL8 [R/W] B, H, W XXXXXXXX PRLH9 [R/W] B, H, W XXXXXXXX PRLL9 [R/W] B, H, W XXXXXXXX 00011CH PRLH10 [R/W] B, H, W XXXXXXXX PRLL10 [R/W] B, H, W XXXXXXXX PRLH11 [R/W] B, H, W XXXXXXXX PRLL11 [R/W] B, H, W XXXXXXXX 000120H PPGC8 [R/W] B, H, W 00000000 PPGC9 [R/W] B, H, W 00000000 PPGC10 [R/W] B, H, W 00000000 PPGC11 [R/W] B, H, W 00000000 000124H PRLH12 [R/W] B, H, W XXXXXXXX PRLL12 [R/W] B, H, W XXXXXXXX PRLH13 [R/W] B, H, W XXXXXXXX PRLL13 [R/W] B, H, W XXXXXXXX 000128H PRLH14 [R/W] B, H, W XXXXXXXX PRLL14 [R/W] B, H, W XXXXXXXX PRLH15 [R/W] B, H, W XXXXXXXX PRLL15 [R/W] B, H, W XXXXXXXX 00012CH PPGC12 [R/W] B, H, W 00000000 PPGC13 [R/W] B, H, W 00000000 PPGC14 [R/W] B, H, W 00000000 PPGC15 [R/W] B, H, W 00000000 000130H TRG [R/W] B, H 00000000 00000000 ⎯ GATEC0 [R/W] B --00--00 000134H REVC [R/W] B, H 00000000 00000000 ⎯ GATEC4 [R/W] B ------00 000138H ⎯ Block PPG GATEC8 [R/W] B --00--00 (Continued) 38 MB91470/480 Series Address Register +0 +1 000144H TTCR0 [R/W, W, R] B, H, W 11110000 000148H COMP0 [R/W] B, H, W 00000000 00014CH TTCR1 [R/W, W, R] B, H, W 11110000 COMP2 [R/W] B, H, W 00000000 COMP3 [R/W] B, H, W 00000000 000154H EIRR1 [R/W] B, H, W 00000000 ENIR1 [R/W] B, H, W 00000000 000174H COMP4 [R/W] B, H, W 00000000 COMP6 [R/W] B, H, W 00000000 COMP5 [R/W] B, H, W 00000000 COMP7 [R/W] B, H, W 00000000 ELVR1 [R/W] B, H, W 00000000 00000000 CMCLKR [R/W] B ----0000 BT0TMR [R] B, H, W 00000000 00000000 BT0STC [R/W] B 00000000 ⎯ External interrupt (INT8 to INT15) Clock monitor Base timer 0 BT0PDUT/BT0PRLH/BT0DTBF [R/W] H, W XXXXXXXX XXXXXXXX ⎯ (Reserved) AICR2 [R/W] B, H, W ----1111 11111111 ⎯ Timing generator 1 BT0TMCR [R/W] B, H, W 00000000 00000000 BT0PCSR/BT0PRLL [R/W] H, W XXXXXXXX XXXXXXXX ADCS2 [R/W, W] B, H, W 0000000- Timing generator 0 (Reserved) ⎯ 00016CH 000170H (Reserved) ⎯ 000158H ⎯ PPG ⎯ COMP1 [R/W] B, H, W 00000000 00015CH Block ⎯ 000150H 000168H GATEC12 [R/W] B ------00 ⎯ 000140H 000164H +3 ⎯ 00013CH 000160H +2 ⎯ ADCH2 [R/W] B, H, W 00000000 ADMD2 [R/W] B, H, W 00001111 000178H ADCD002 [R] B, H, W 10----XX XXXXXXXX ADCD012 [R] B, H, W 10----XX XXXXXXXX 00017CH ADCD022 [R] B, H, W 10----XX XXXXXXXX ADCD032 [R] B, H, W 10----XX XXXXXXXX 8/10-bit A/D converter 2 (12 channels) (Continued) 39 MB91470/480 Series Address Register +0 +1 +2 +3 000180H ADCD042 [R] B, H, W 10----XX XXXXXXXX ADCD052 [R] B, H, W 10----XX XXXXXXXX 000184H ADCD062 [R] B, H, W 10----XX XXXXXXXX ADCD072 [R] B, H, W 10----XX XXXXXXXX 000188H ADCD082 [R] B, H, W 10----XX XXXXXXXX ADCD092 [R] B, H, W 10----XX XXXXXXXX 00018CH ADCD102 [R] B, H, W 10----XX XXXXXXXX ADCD112 [R] B, H, W 10----XX XXXXXXXX Block 8/10-bit A/D converter 2 (12 channels) 000190H ⎯ (Reserved) 000194H ⎯ (Reserved) 000198H ⎯ (Reserved) 00019CH ⎯ (Reserved) 0001A0H OCCPBH6, OCCPBL6 [W]/ OCCPH6, OCCPL6 [R] H, W 00000000 00000000 OCCPBH7, OCCPBL7 [W]/ OCCPH7, OCCPL7 [R] H, W 00000000 00000000 0001A4H OCCPBH8, OCCPBL8 [W]/ OCCPH8, OCCPL8 [R] H, W 00000000 00000000 OCCPBH9, OCCPBL9 [W]/ OCCPH9, OCCPL9 [R] H, W 00000000 00000000 0001A8H OCCPBH10, OCCPBL10 [W]/ OCCPH10, OCCPL10 [R] H, W 00000000 00000000 OCCPBH11, OCCPBL11 [W]/ OCCPH11, OCCPL11 [R] H, W 00000000 00000000 0001ACH OCSH7 [R/W] B, H, W -1100000 OCSL6 [R/W] B, H, W 00001100 OCSH9 [R/W] B, H, W -1100000 OCSL8 [R/W] B, H, W 00001100 0001B0H OCSH11 [R/W] B, H, W -1100000 OCSL10 [R/W] B, H, W 00001100 OCMOD1 [R/W] B, H, W --000000 ⎯ 0001B4H 0001B8H 0001BCH 0001C0H CPCLRBH3, CPCLRBL3 [W]/ CPCLRH3, CPCLRL3 [R] H, W 11111111 11111111 TCCSH3 [R/W] B, H, W 00000000 TCCSL3 [R/W] B, H, W 01000000 CPCLRBH4, CPCLRBL4 [W] / CPCLRH4, CPCLRL4 [R] H, W 11111111 11111111 TCCSH4 [R/W] B, H, W 00000000 TCCSL4 [R/W] B, H, W 01000000 TCDTH3, TCDTL3 [R/W] H, W 00000000 00000000 TCCSM3 [R/W] B, H, W ----0000 ADTRGC3 [R/W] B, H, W -000-000 TCDTH4, TCDTL4 [R/W] H, W 00000000 00000000 TCCSM4 [R/W] B, H, W ----0000 ADTRGC4 [R/W] B, H, W -000-000 OCU1 Free-run timer 3 Free-run timer 4 (Continued) 40 MB91470/480 Series Address 0001C4H Register +0 +1 CPCLRBH5, CPCLRBL5 [W] / CPCLRH5, CPCLRL 5 [R] H, W 11111111 11111111 0001C8H TCCSH5 [R/W] B, H, W 00000000 0001CCH ⎯ TCCSL5 [R/W] B, H, W 01000000 +2 +3 TCDTH5, TCDTL5 [R/W] H, W 00000000 00000000 TCCSM5 [R/W] B, H, W ----0000 ADTRGC5 [R/W] B, H, W -000-000 FRS7 [R/W] B, H, W FRS6 [R/W] B, H, W FRS5 [R/W] B, H, W -011-011 -011-011 -011-011 0001D0H ⎯ FRS9 [R/W] B, H, W FRS8 [R/W] B, H, W -011-011 -011-011 0001D4H IPCPH4, IPCPL4 [R] H, W XXXXXXXX XXXXXXXX IPCPH5, IPCPL5 [R] H, W XXXXXXXX XXXXXXXX 0001D8H IPCPH6, IPCPL6 [R] H, W XXXXXXXX XXXXXXXX IPCPH7, IPCPL7 [R] H, W XXXXXXXX XXXXXXXX 0001DCH PICSH45 [W, R] B, H, W 00000000 PICSL45 [R/W] B, H, W 00000000 ICSH67 [R] B, H, W ------00 TMRRH3, TMRRL3 [R/W] H, W XXXXXXXX XXXXXXXX TMRRH4, TMRRL4 [R/W] H, W XXXXXXXX XXXXXXXX 0001E4H TMRRH5, TMRRL5 [R/W] H, W XXXXXXXX XXXXXXXX ⎯ 0001E8H DTCR3 [R/W] B, H, W 00000000 DTCR4 [R/W] B, H, W 00000000 DTCR5 [R/W] B, H, W 00000000 ⎯ 0001ECH ⎯ SIGCR11 [R/W] B, H, W 00000000 ⎯ SIGCR21 [R/W] B, H, W 000000-1 0001F0H ADCOMP3 [W]/ ADCOMPB3 [R] H, W 00000000 00000000 ADCOMPD3 [W]/ ADCOMPDB3 [R] H, W 00000000 00000000 0001F4H ADCOMP4 [W]/ ADCOMPB4 [R] H, W 00000000 00000000 ADCOMPD4 [W]/ ADCOMPDB4 [R] H, W 00000000 00000000 0001F8H ADCOMP5 [W]/ ADCOMPB5 [R] H, W 00000000 00000000 ADCOMPD5 [W]/ ADCOMPDB5 [R] H, W 00000000 00000000 ⎯ ADTGBUF1 [R/W] B, H, W -000-111 ADTGSEL1 [R/W] B, H, W --000000 Free-run timer 5 Free-run timer selector 1 ICU1 ICSL67 [R/W] B, H, W 00000000 0001E0H 0001FCH Block Wave form generator 1 A/D activating compare 1 ADTGCE1[R/W] B, H, W --000000 (Continued) 41 MB91470/480 Series Address Register +0 +1 +2 +3 Block 000200H DMACA0 [R/W] B, H, W *1 00000000 ----XXXX XXXXXXXX XXXXXXXX 000204H DMACB0 [R/W] B, H, W 00000000 00000000 XXXXXXXX XXXXXXXX 000208H DMACA1 [R/W] B, H, W *1 00000000 ----XXXX XXXXXXXX XXXXXXXX 00020CH DMACB1 [R/W] B, H, W 00000000 00000000 XXXXXXXX XXXXXXXX 000210H DMACA2 [R/W] B, H, W *1 00000000 ----XXXX XXXXXXXX XXXXXXXX 000214H DMACB2 [R/W] B, H, W 00000000 00000000 XXXXXXXX XXXXXXXX 000218H DMACA3 [R/W] B, H, W *1 000000000 ----XXXX XXXXXXXX XXXXXXXX 00021CH DMACB3 [R/W] B, H, W 00000000 00000000 XXXXXXXX XXXXXXXX 000220H DMACA4 [R/W] B, H, W *1 00000000 ----XXXX XXXXXXXX XXXXXXXX 000224H DMACB4 [R/W] B, H, W 00000000 00000000 XXXXXXXX XXXXXXXX 000228H to 00023CH ⎯ (Reserved) 000240H DMACR [R/W] B, H, W 0--00000 -------- -------- -------- DMAC 000244H to 00039CH ⎯ (Reserved) 0003A0H DSP-PC [R/W] B, H, W 000000-0 DSP-CSR [R/W, R, W] B, H, W 00000000 DMAC ⎯ 0003A4H DSP-LY [R/W], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003A8H DSP-OT0 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003ACH DSP-OT1 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003B0H DSP-OT2 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003B4H DSP-OT3 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX MAC (Continued) 42 MB91470/480 Series Address Register +0 +1 +2 0003B8H DSP-OT4 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003BCH DSP-OT5 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003C0H DSP-OT6 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003C4H DSP-OT7 [R], W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003C8H DSP-AC0 [R], W -------- -------- -------- 00000000 0003CCH DSP-AC1 [R], W 00000000 00000000 00000000 00000000 0003D0H DSP-AC2 [R], W 00000000 00000000 00000000 00000000 0003D4H to 0003ECH ⎯ 0003F0H BSD0 [W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003F4H BSD1 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003F8H BSDC [W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0003FCH BSRR [R] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX +3 Block MAC (Reserved) Bit search module 000400H DDR0 [R/W] B, H, W 00000000 DDR1 [R/W] B, H, W 00000000 DDR2 [R/W] B, H, W 00000000 DDR3 [R/W] B, H, W 00000000 000404H DDR5 [R/W] B, H, W -0000000 DDR6 [R/W] B, H, W ------00 DDR8 [R/W] B, H, W 00000000 DDR9 [R/W] B, H, W 00000000 000408H DDRA [R/W] B, H, W ---00000 DDRB [R/W] B, H, W 00000000 DDRC [R/W] B, H, W 00000000 DDRD [R/W] B, H, W ----0000 00040CH DDRE [R/W] B, H, W 00000000 DDRF [R/W] B, H, W 00000000 DDRG [R/W] B, H, W --000000 DDRH [R/W] B, H, W --000000 000410H DDRJ [R/W] B, H, W 00000000 ⎯ DDRL [R/W] B, H, W -----000 DDRM [R/W] B, H, W ----0000 Port direction register (Continued) 43 MB91470/480 Series Address 000414H Register +0 +1 +2 +3 DDRP [R/W] B, H, W --000000 DDRQ [R/W] B, H, W --000000 DDRR [R/W] B, H, W --000000 DDRS [R/W] B, H, W --000000 000418H ⎯ 00041CH ⎯ 000420H PFR0 [R/W] B, H, W PFR1 [R/W] B, H, W PFR2 [R/W] B, H, W PFR3 [R/W] B, H, W 11111111 11111111 11111111 11111111 000424H PFR5 [R/W] B, H, W PFR6 [R/W] B, H, W PFR8 [R/W] B, H, W PFR9 [R/W] B, H, W -1111111 ------11 0000---00000000 ⎯ PFRC [R/W] B, H, W --0-00-0 ⎯ 00042CH ⎯ PFRF [R/W] B, H, W -------0 PFRG [R/W] B, H, W --0-00-0 PFRH [R/W] B, H, W --0-00-0 000430H PFRJ [R/W] B, H, W 0-0-0-0- 000434H ⎯ ⎯ 000438H ⎯ 00043CH ⎯ Port function register PFRM [R/W] B, H, W ----0000 ⎯ PFRQ [R/W] B, H, W --000000 Port direction register (Reserved) ⎯ 000428H Block PFRS [R/W] B, H, W --000000 (Reserved) 000440H ICR00 [R/W, R] B, H, W ---11111 ICR01 [R/W, R] B, H, W ---11111 ICR02 [R/W, R] B, H, W ---11111 ICR03 [R/W, R] B, H, W ---11111 000444H ICR04 [R/W, R] B, H, W ---11111 ICR05 [R/W, R] B, H, W ---11111 ICR06 [R/W, R] B, H, W ---11111 ICR07 [R/W, R] B, H, W ---11111 000448H ICR08 [R/W, R] B, H, W ---11111 ICR09 [R/W, R] B, H, W ---11111 ICR10 [R/W, R] B, H, W ---11111 ICR11 [R/W, R] B, H, W ---11111 00044CH ICR12 [R/W, R] B, H, W ---11111 ICR13 [R/W, R] B, H, W ---11111 ICR14 [R/W, R] B, H, W ---11111 ICR15 [R/W, R] B, H, W ---11111 000450H ICR16 [R/W, R] B, H, W ---11111 ICR17 [R/W, R] B, H, W ---11111 ICR18 [R/W, R] B, H, W ---11111 ICR19 [R/W, R] B, H, W ---11111 000454H ICR20 [R/W, R] B, H, W ---11111 ICR21 [R/W, R] B, H, W ---11111 ICR22 [R/W, R] B, H, W ---11111 ICR23 [R/W, R] B, H, W ---11111 Interrupt controller (Continued) 44 MB91470/480 Series Address Register +0 +1 +2 +3 000458H ICR24 [R/W, R] B, H, W ---11111 ICR25 [R/W, R] B, H, W ---11111 ICR26 [R/W, R] B, H, W ---11111 ICR27 [R/W, R] B, H, W ---11111 00045CH ICR28 [R/W, R] B, H, W ---11111 ICR29 [R/W, R] B, H, W ---11111 ICR30 [R/W, R] B, H, W ---11111 ICR31 [R/W, R] B, H, W ---11111 000460H ICR32 [R/W, R] B, H, W ---11111 ICR33 [R/W, R] B, H, W ---11111 ICR34 [R/W, R] B, H, W ---11111 ICR35 [R/W, R] B, H, W ---11111 000464H ICR36 [R/W, R] B, H, W ---11111 ICR37 [R/W, R] B, H, W ---11111 ICR38 [R/W, R] B, H, W ---11111 ICR39 [R/W, R] B, H, W ---11111 000468H ICR40 [R/W, R] B, H, W ---11111 ICR41 [R/W, R] B, H, W ---11111 ICR42 [R/W, R] B, H, W ---11111 ICR43 [R/W, R] B, H, W ---11111 00046CH ICR44 [R/W, R] B, H, W ---11111 ICR45 [R/W, R] B, H, W ---11111 ICR46 [R/W, R] B, H, W ---11111 ICR47 [R/W, R] B, H, W ---11111 000470H to 00047CH ⎯ RSRR [R/W] B, H, W 1-0-0-00 STCR [R/W] B, H, W 001100-1 TBCR [R/W] B, H, W 00XXX-00 CTBR [W] B, H, W XXXXXXXX 000484H CLKR [R/W] B, H, W -000-000 ⎯ DIVR0 [R/W] B, H, W 00000011 DIVR1 [R/W] B, H, W 00000000 ⎯ 000500H ⎯ AICR0 [R/W] B, H, W ----1111 000504H ADCS0 [R/W, W] B, H, W 0000000- ⎯ Interrupt controller (Reserved) 000480H 000488H to 0004FCH Block Clock control block (Reserved) ⎯ ADCH0 [R/W] B, H, W --00--00 ADMD0 [R/W] B, H, W 00001111 000508H ADCD000 [R] B, H, W 10----XX XXXXXXXX ADCD010 [R] B, H, W 10----XX XXXXXXXX 00050CH ADCD020 [R] B, H, W 10----XX XXXXXXXX ADCD030 [R] B, H, W 10----XX XXXXXXXX 8/10-bit A/D converter 0 (4 channels) (Continued) 45 MB91470/480 Series Address Register +0 +1 000510H ⎯ AICR1 [R/W] B, H, W ----1111 000514H ADCS1 [R/W, W] B, H, W 0000000- ⎯ +2 +3 ⎯ ADCH1 [R/W] B, H, W --00--00 ADMD1 [R/W] B, H, W 00001111 000518H ADCD001 [R] B, H, W 10----XX XXXXXXXX ADCD011 [R] B, H, W 10----XX XXXXXXXX 00051CH ADCD021 [R] B, H, W 10----XX XXXXXXXX ADCD031 [R] B, H, W 10----XX XXXXXXXX 000520H ⎯ AICR3 [R/W] B, H, W ----1111 000524H ADCS3 [R/W, W] B, H, W 0000000- ⎯ ADCH3 [R/W] B, H, W --00--00 ADMD3 [R/W] B, H, W 00001111 ADCD003 [R] B, H, W 10--XXXX XXXXXXXX ADCD013 [R] B, H, W 10--XXXX XXXXXXXX 00052CH ADCD023 [R] B, H, W 10--XXXX XXXXXXXX ADCD033 [R] B, H, W 10--XXXX XXXXXXXX 000530H ⎯ AICR4 [R/W] B, H, W ----1111 000534H ADCS4 [R/W, W] B, H, W 0000000- ⎯ ADCH4 [R/W] B, H, W --00--00 ADMD4 [R/W] B, H, W 00001111 ADCD004 [R] B, H, W 10--XXXX XXXXXXXX ADCD014 [R] B, H, W 10--XXXX XXXXXXXX 00053CH ADCD024 [R] B, H, W 10--XXXX XXXXXXXX ADCD034 [R] B, H, W 10--XXXX XXXXXXXX 000540H RCR10 [W] B, H, W RCR00 [W] B, H, W XXXXXXXX XXXXXXXX 000548H to 00055CH 12-bit A/D converter 3 (4 channels) ⎯ 000538H CCRH0 [R/W] B, H, W 00000000 8/10-bit A/D converter 1 (4 channels) ⎯ 000528H 000544H Block CCRL0 [R/W, R] B, H, W -0001000 ⎯ UDCR10 [R] B, H, W 00000000 UDCR00 [R] B, H, W 00000000 ⎯ CSR0 [R/W, R] B, H, W 00000000 12-bit A/D converter 4 (4 channels) Up/down counter 0 (Reserved) (Continued) 46 MB91470/480 Series Address Register +0 +1 +2 +3 000560H SSR4 [R/W, R] B, H, W 00000011 ESCR4 [R/W]/ IBSR4 [R/W, R] B, H, W 00000000 SCR4 [R/W] / IBCR4 [R/W, R] B, H, W 00000000 SMR4 [R/W] B, H, W 000-0000 000564H BGR41 [R/W] B, H, W 00000000 BGR40 [R/W] B, H, W 00000000 RDR4 [R]/TDR4 [W]H, W -------0 00000000 ⎯ 000568H ISMK4 [R/W] B, H, W 01111111 ISBA4 [R/W] B, H, W 00000000 00056CH FBYTE42 [R/W] B, H, W 00000000 FBYTE41 [R/W] B, H, W 00000000 FCR41 [R/W] B, H, W ---00100 FCR40 [R/W, R] B, H, W -0000000 000570H SSR5 [R/W, R] B, H, W 00000011 ESCR5 [R/W]/ IBSR5 [R/W, R] B, H, W 00000000 SCR5 [R/W] / IBCR5 [R/W, R] B, H, W 00000000 SMR5 [R/W] B, H, W 000-0000 000574H BGR51 [R/W] B, H, W 00000000 BGR50 [R/W] B, H, W 00000000 ⎯ 000578H 00057CH 000580H 000584H 000588H FBYTE52 [R/W] B, H, W 00000000 FBYTE51 [R/W] B, H, W 00000000 BT1TMR [R] B, H, W 00000000 00000000 ⎯ 000594H 000598H 00059CH ISMK5 [R/W] B, H, W 01111111 ISBA5 [R/W] B, H, W 00000000 FCR51 [R/W] B, H, W ---00100 FCR50 [R/W, R] B, H, W -0000000 ⎯ BT1PCSR/BT1PRLL [R/W] H, W XXXXXXXX XXXXXXXX Multifunction serial interface 5 Base timer 1 BT1PDUT/BT1PRLH/BT1DTBF [R/W] H, W XXXXXXXX XXXXXXXX ⎯ BT2TMR [R] B, H, W 00000000 00000000 ⎯ Multifunction serial interface 4 BT1TMCR [R/W] B, H, W 00000000 00000000 BT1STC [R/W] B 00000000 00058CH 000590H RDR5 [R]/TDR5 [W]H, W -------0 00000000 Block (Reserved) BT2TMCR [R/W] B, H, W 00000000 00000000 BT2STC [R/W] B 00000000 ⎯ BT2PCSR/BT2PRLL [R/W] H, W XXXXXXXX XXXXXXXX Base timer 2 BT2PDUT/BT2PRLH/BT2DTBF [R/W] H, W XXXXXXXX XXXXXXXX ⎯ (Reserved) (Continued) 47 MB91470/480 Series Address 0005A0H 0005A4H 0005A8H Register +0 +1 +2 BT3TMR [R] B, H, W 00000000 00000000 ⎯ +3 Block BT3TMCR [R/W] B, H, W 00000000 00000000 BT3STC [R/W] B 00000000 ⎯ BT3PCSR/BT3PRLL [R/W] H, W XXXXXXXX XXXXXXXX Base timer 3 BT3PDUT/BT3PRLH/BT3DTBF [R/W] H, W XXXXXXXX XXXXXXXX 0005ACH ⎯ (Reserved) 0005B0H to 0005FCH ⎯ (Reserved) 000600H PCR0 [R/W] B, H, W 00000000 PCR1 [R/W] B, H, W 00000000 PCR2 [R/W] B, H, W 00000000 PCR3 [R/W] B, H, W 00000000 000604H PCR5 [R/W] B, H, W -0000000 PCR6 [R/W] B, H, W ------00 PCR8 [R/W] B, H, W 00000000 PCR9 [R/W] B, H, W 00000000 000608H PCRA [R/W] B, H, W ---00000 PCRB [R/W] B, H, W 00000000 PCRC [R/W] B, H, W 00000000 PCRD [R/W] B, H, W ----0000 00060CH PCRE [R/W] B, H, W 00000000 PCRF [R/W] B, H, W 00000000 PCRG [R/W] B, H, W --000000 PCRH [R/W] B, H, W --000000 000610H PCRJ [R/W] B, H, W 00000000 ⎯ PCRL [R/W] B, H, W -----000 PCRM [R/W] B, H, W ----0000 000614H PCRP [R/W] B, H, W --000000 PCRQ [R/W] B, H, W --000000 PCRR [R/W] B, H, W --000000 PCRS [R/W] B, H, W --000000 000618H to 00063CH ⎯ (Reserved) 000640H ASR0 [R/W] H, W 00000000 00000000 *2 ACR0 [R/W] H, W 1111XX-- --000000 *2 000644H ASR1 [R/W] H, W XXXXXXXX XXXXXXXX *2 ACR1 [R/W] H, W XXXXXX-- --XXXXXX *2 000648H ASR2 [R/W] H, W XXXXXXXX XXXXXXXX *2 ACR2 [R/W] H, W XXXXXX-- --XXXXXX *2 00064CH Pull-up resistor control register External bus interface ⎯ (Continued) 48 MB91470/480 Series Address Register +0 +1 +2 000650H ⎯ 000654H ⎯ 000658H ⎯ 00065CH ⎯ +3 000660H AWR0 [R/W] H, W 0111---- 1111-111 *2 AWR1 [R/W] H, W XXXX---- XXXX-XXX *2 000664H AWR2 [R/W] H, W XXXX---- XXXX-XXX *2 ⎯ 000668H ⎯ 00066CH ⎯ 000670H ⎯ 000674H ⎯ 000678H ⎯ 00067CH ⎯ 000680H CSER [R/W] B, H -----001 External bus interface ⎯ 000684H to 0007F8H 0007FCH ⎯ ⎯ Block MODR [W] XXXXXXXX (Reserved) ⎯ 000800H to 000FFCH ⎯ 001000H DMASA0 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001004H DMADA0 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001008H DMASA1 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 00100CH DMADA1 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001010H DMASA2 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001014H DMADA2 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001018H DMASA3 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX Mode register (Reserved) DMAC (Continued) 49 MB91470/480 Series Address Register +0 +1 +2 +3 00101CH DMADA3 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001020H DMASA4 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001024H DMADA4 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 001028H to 006FFCH ⎯ FLCR [R/W, R] B ----X-0- ⎯ 007004H FLWC [R/W] B --11-011 ⎯ ⎯ 00700CH ⎯ 007010H ⎯ 007014H to 00701CH ⎯ 007020H DMAC (Reserved) 007000H 007008H Block WREN [R/W] H 00000000 00000000 Flash memory (Reserved) ⎯ 007024H ⎯ 007028H ⎯ 00702CH ⎯ 007030H WA00 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007034H WD00 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007038H WA01 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00703CH WD01 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007040H WA02 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007044H WD02 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007048H WA03 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00704CH WD03 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX Wild register control block (Continued) 50 MB91470/480 Series Address Register +0 +1 +2 007050H WA04 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007054H WD04 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007058H WA05 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00705CH WD05 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007060H WA06 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007064H WD06 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007068H WA07 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00706CH WD07 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007070H WA08 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007074H WD08 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007078H WA09 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00707CH WD09 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007080H WA10 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007084H WD10 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007088H WA11 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00708CH WD11 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007090H WA12 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 007094H WD12 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 007098H WA13 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 00709CH WD13 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX +3 Block Wild register control block (Continued) 51 MB91470/480 Series (Continued) Address Register +0 +1 +2 +3 Block 0070A0H WA14 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 0070A4H WD14 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0070A8H WA15 [R/W] W -------- ----XXXX XXXXXXXX XXXXXX-- 0070ACH WD15 [R/W] W XXXXXXXX XXXXXXXX XXXXXXXX XXXXXXXX 0070B0H to 00BFFCH ⎯ 00C000H to 00C0FCH X-RAM (coefficient RAM) [R/W] 64 × 32-bit 00C100H to 00C1FCH Y-RAM (variable RAM) [R/W] 64 × 32-bit 00C200H to 00C3FCH I-RAM (instruction RAM) [R/W] 128 × 32-bit 00C400H to 00FFFCH ⎯ (Reserved) 010000H to 0FFFFCH ⎯ (Reserved) Wild register control block (Reserved) MAC *1 : The lower 16 bits (DTC15 to DTC0) of DMACA0 to DMACA4 cannot be accessed as bytes. *2 : Register whose initial value depends on the reset level. The initial values shown are for INITX = “L”. Notes : • Data is undefined in reserved or (⎯) area. • Do not execute read modify write (RMW) instruction on registers having a write-only bit. • The initial values are varied depending on the product series. Please refer to the hardware manual of MB91470/480 for more details. 52 MB91470/480 Series ■ INTERRUPT VECTOR Interrupt number Interrupt source Interrupt level Offset TBR default address Decimal Hexadecimal Reset 0 00 ⎯ 3FCH 000FFFFCH Mode vector 1 01 ⎯ 3F8H 000FFFF8H System reserved 2 02 ⎯ 3F4H 000FFFF4H System reserved 3 03 ⎯ 3F0H 000FFFF0H System reserved 4 04 ⎯ 3ECH 000FFFECH System reserved 5 05 ⎯ 3E8H 000FFFE8H System reserved 6 06 ⎯ 3E4H 000FFFE4H Coprocessor absent trap 7 07 ⎯ 3E0H 000FFFE0H Coprocessor error trap 8 08 ⎯ 3DCH 000FFFDCH INTE instruction 9 09 ⎯ 3D8H 000FFFD8H System reserved 10 0A ⎯ 3D4H 000FFFD4H System reserved 11 0B ⎯ 3D0H 000FFFD0H Step trace trap 12 0C ⎯ 3CCH 000FFFCCH NMI request (tool) 13 0D ⎯ 3C8H 000FFFC8H Undefined instruction exception 14 0E ⎯ 3C4H 000FFFC4H NMI request 15 0F ⎯ 3C0H 000FFFC0H External interrupt 0 16 10 ICR00 3BCH 000FFFBCH External interrupt 1 17 11 ICR01 3B8H 000FFFB8H External interrupt 2 18 12 ICR02 3B4H 000FFFB4H External interrupt 3 19 13 ICR03 3B0H 000FFFB0H External interrupt 4 20 14 ICR04 3ACH 000FFFACH External interrupt 5 21 15 ICR05 3A8H 000FFFA8H External interrupt 6 22 16 ICR06 3A4H 000FFFA4H External interrupt 7 23 17 ICR07 3A0H 000FFFA0H Reload timer 0 24 18 ICR08 39CH 000FFF9CH Reload timer 1 25 19 ICR09 398H 000FFF98H Base timer 0 (source 0/source 1) 26 1A ICR10 394H 000FFF94H Multi-function serial interface 0 (UART transmission completed/reception completed/I2C status) 27 1B ICR11 390H 000FFF90H Multi-function serial interface 1 (UART transmission completed/reception completed/I2C status) 28 1C ICR12 38CH 000FFF8CH Base timer 1 (source 0/source 1) 29 1D ICR13 388H 000FFF88H (Continued) 53 MB91470/480 Series Interrupt number Interrupt source Interrupt level Offset TBR default address Decimal Hexadecimal Base timer 2/3 (source 0/source 1) Up/down counter 0 30 1E ICR14 384H 000FFF84H DTTI0/DTTI1 31 1F ICR15 380H 000FFF80H DMAC0 (end/error) 32 20 ICR16 37CH 000FFF7CH DMAC1 (end/error) 33 21 ICR17 378H 000FFF78H DMAC2/3/4 (end/error) 34 22 ICR18 374H 000FFF74H Multi-function serial interface 2 (UART transmission completed/reception completed/I2C status) 35 23 ICR19 370H 000FFF70H Multi-function serial interface 3 (UART transmission completed/reception completed/I2C status) 36 24 ICR20 36CH 000FFF6CH Multi-function serial interface 4 (UART transmission completed/reception completed/I2C status) 37 25 ICR21 368H 000FFF68H Multi-function serial interface 5 (UART transmission completed/reception completed/I2C status) 38 26 ICR22 364H 000FFF64H MAC 39 27 ICR23 360H 000FFF60H PPG0/PPG1 40 28 ICR24 35CH 000FFF5CH PPG2/PPG3/PPG8/PPG9 41 29 ICR25 358H 000FFF58H PPG4/PPG5/PPG10/PPG11 42 2A ICR26 354H 000FFF54H PPG6/PPG7/PPG12/PPG13/PPG14/PPG15 43 2B ICR27 350H 000FFF50H Wave form generator 0/3 (underflow) 44 2C ICR28 34CH 000FFF4CH Wave form generator 1/4 (underflow) 45 2D ICR29 348H 000FFF48H Wave form generator 2/5 (underflow) 46 2E ICR30 344H 000FFF44H Timebase timer overflow 47 2F ICR31 340H 000FFF40H External interrupt 8/9/10/11/12/13/14/15 48 30 ICR32 33CH 000FFF3CH Free-run timer 0/3 (compare clear) 49 31 ICR33 338H 000FFF38H Free-run timer 0/3 (zero detection) 50 32 ICR34 334H 000FFF34H Free-run timer 1/4 (compare clear) 51 33 ICR35 330H 000FFF30H Free-run timer 1/4 (zero detection) 52 34 ICR36 32CH 000FFF2CH Free-run timer 2/5 (compare clear) 53 35 ICR37 328H 000FFF28H Free-run timer 2/5 (zero detection) 54 36 ICR38 324H 000FFF24H 8/10-bit A/D converter 2 55 37 ICR39 320H 000FFF20H 8/10-bit A/D converter 0/ 12-bit A/D converter 3 56 38 ICR40 31CH 000FFF1CH (Continued) 54 MB91470/480 Series (Continued) Interrupt number Interrupt source Interrupt level Offset TBR default address Decimal Hexadecimal 8/10-bit A/D converter 1/ 12-bit A/D converter 4 57 39 ICR41 318H 000FFF18H ICU0/ICU1/ICU4/ICU5 (capture) 58 3A ICR42 314H 000FFF14H ICU2/ICU3/ICU6/ICU7 (capture) 59 3B ICR43 310H 000FFF10H OCU0/OCU1/OCU6/OCU7 (match) 60 3C ICR44 30CH 000FFF0CH OCU2/OCU3/OCU8/OCU9 (match) 61 3D ICR45 308H 000FFF08H OCU4/OCU5/OCU10/OCU11 (match) 62 3E ICR46 304H 000FFF04H Interrupt delay source bit 63 3F ICR47 300H 000FFF00H System reserved (Used by REALOS) 64 40 ⎯ 2FCH 000FFEFCH System reserved (Used by REALOS) 65 41 ⎯ 2F8H 000FFEF8H System reserved 66 42 ⎯ 2F4H 000FFEF4H System reserved 67 43 ⎯ 2F0H 000FFEF0H System reserved 68 44 ⎯ 2ECH 000FFEECH System reserved 69 45 ⎯ 2E8H 000FFEE8H System reserved 70 46 ⎯ 2E4H 000FFEE4H System reserved 71 47 ⎯ 2E0H 000FFEE0H System reserved 72 48 ⎯ 2DCH 000FFEDCH System reserved 73 49 ⎯ 2D8H 000FFED8H System reserved 74 4A ⎯ 2D4H 000FFED4H System reserved 75 4B ⎯ 2D0H 000FFED0H System reserved 76 4C ⎯ 2CCH 000FFECCH System reserved 77 4D ⎯ 2C8H 000FFEC8H System reserved 78 4E ⎯ 2C4H 000FFEC4H System reserved 79 4F ⎯ 2C0H 000FFEC0H Used by INT instruction 80 to 255 50 to FF ⎯ 2BCH to 000H 000FFEBCH to 000FFC00H 55 MB91470/480 Series ■ PIN STATUS IN EACH CPU STATE Terms used as the status of pins mean as follows. • Input enabled Means that the input function can be used. • Input fixed to “0” A state of a pin, in which "0" is transmitted to internal circuitry, with the external input shut off by the input gate adjacent to the pin. • Output Hi-Z Means to place a pin in a high impedance state by disabling the pin driving transistor from driving. • Output storage Means to output the state existing immediately prior to entering this mode. That is, to output according to an internal resource with an output when it is operating or to preserve an output when the output is provided, for example, as a port. • Preserving the previous state Means to be able to output or input the state existing immediately prior to entering this mode. 56 MB91470/480 Series • List of pin status Pin name Function P00 to P07 D16 to D23 P10 to P17 D24 to D31 P20 to P27 A00 to A07 P30 to P37 A08 to A15 P50 to P52 CS0X to CS2X P53 ASX P54 RDX P55, P56 WR0X, WR1X P60 SYSCLK P61 RDY NMIX NMIX P80 to P83 INT0 to INT3 P84 INT4/PPG4 P85 INT5/PPG5 P86 INT6/PPG6 P87 INT7/PPG7 P90 INT8/PPG8 P91 INT9/PPG9 P92 INT10/PPG10 P93 INT11/PPG11 P94 INT12/PPG12 P95 INT13/PPG13 P96 INT14/PPG14 P97 INT15/PPG15 PA0 to PA4 ADTG0 to ADTG4 During initialization INITX = “L”* 1 INITX = “H”* 2 Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Input enabled Input enabled In sleep mode In stop mode HIZ = 0 Retention of the Retention of the immediately immediately prior state prior state Output Hi-Z/ Input “0” fixed Input enabled Input enabled Input enabled Input enabled (only when external interrupt is enabled) Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the immediately immediately prior state prior state Output Hi-Z/ Input “0” fixed Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the immediately immediately prior state prior state Output Hi-Z/ Input “0” fixed Output Hi-Z/ Output Hi-Z/ Input disabled Input enabled Input enabled HIZ = 1 Input enabled PB0 to PB3 AN0-0 to AN0-3 PB4 to PB7 AN1-0 to AN1-3 PC0 AN2-0/SCK4 PC1 AN2-1/SIN4 PC2 AN2-2/SOT4 PC3 AN2-3/SCK5 PC4 AN2-4/SIN5 PC5 AN2-5/SOT5 PC6, PC7 AN2-6, AN2-7 (Continued) 57 MB91470/480 Series (Continued) Pin name Function During initialization 1 INITX = “L”* 2 INITX = “H”* PD0 to PD3 AN2-8 to AN2-11 PE0 to PE3 AN3-0 to AN3-3 PE4 to PE7 AN4-0 to AN4-3 PF0 CLKPOUT PF1 to PF6 GPIO PG0, PG3 SCK0, SCK1 PG1, PG4 SIN0, SIN1 PG2, PG5 SOT0, SOT1 PH0, PH3 SCK2, SCK3 PH1, PH4 SIN2, SIN3 PH2, PH5 SOT2, SOT3 PJ0, PJ2, PJ4, PJ6 TIN0 to TIN3 PJ1, PJ3, PJ5, PJ7 TOUT0 to TOUT3 PL0 AIN0 PL1 BIN0 PL2 ZIN0 PM0 to PM3 PPG0 to PPG3 PP0 to PP3 IC0 to IC3 PP4 CKI0 PP5 DTTI0 PQ0 to PQ5 RTO0 to RTO5 PR0 to PR3 IC4 to IC7 PR4 CKI1 PR5 DTTI1 PS0 to PS5 RTO6 to RTO11 In sleep mode In stop mode HIZ = 0 HIZ = 1 Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state Output Hi-Z/ Output Hi-Z/ Input disabled Input disabled Retention of the Retention of the Output Hi-Z/ immediately immediately Input “0” fixed prior state prior state *1 : INITX = “L” : Indicates the pin status with INITX remaining at the “L” level. *2 : INITX = “H” : Indicates the pin status existing immediately after INITX transition from “L” to “H” level. 58 MB91470/480 Series • List of pin status (external bus mode) Pin name Function P00 to P07 D16 to D23 P10 to P17 D24 to D31 P20 to P27 A00 to A07 P30 to P37 A08 to A15 P50 to P52 CS0X to CS2X P53 ASX P54 RDX P55, P56 WR0X, WR1X P60 SYSCLK P61 RDY During initialization INITX = “L”* Output Hi-Z 1 2 INITX = “H”* Output Hi-Z In sleep mode In Stop mode HIZ = 0 HIZ = 1 Retention of the Retention of the Output Hi-Z immediately immediately prior state prior state Input disabled Input disabled Input “0” fixed *1 : INITX = “L” : Indicates the pin status with INITX remaining at the “L” level. *2 : INITX = “H” : Indicates the pin status existing immediately after INITX transition from “L” to “H” level. 59 MB91470/480 Series ■ ELECTRICAL CHARACTERISTICS 1. Absolute Maximum Ratings Parameter Symbol Rating Unit Remarks Min Max VCC VSS − 0.5 VSS + 6.0 V Analog power supply voltage*1,*2,*6 AVCC10 AVCC12 VSS − 0.5 VSS + 6.0 V Analog reference voltage*7 AVRHn VSS − 0.5 VSS + 6.0 V VI VSS − 0.3 VCC + 0.3 V Analog pin input voltage*1 VIA VSS − 0.3 AVCC + 0.3 V Output voltage*1 VO VSS − 0.3 VCC + 0.3 V “L” level maximum output current*3 IOL ⎯ 10 mA “L” level average output current*4 IOLAV ⎯ 4 mA Except port Q0 to Q5 and S0 to S5 12 mA Port Q0 to Q5 and S0 to S5 “L” level total maximum output current ΣIOL ⎯ 100 mA ΣIOLAV ⎯ 50 mA IOH ⎯ −10 mA “H” level average output current *4 IOHAV ⎯ −4 mA Except port Q0 to Q5 and S0 to S5 −12 mA Port Q0 to Q5 and S0 to S5 “H” level total maximum output current ΣIOH ⎯ −100 mA ΣIOHAV ⎯ −50 mA Power consumption PD ⎯ 800 mW Storage temperature TSTG −55 +125 °C Power supply voltage*1 Input voltage* 1 “L” level total average output current*5 “H” level maximum output current*3 “H” level total average output current*5 *1 : The parameter is based on VSS = AVSS10 = AVSS12 = 0 V. *2 : Be careful not to exceed VCC + 0.3 V, for example, when the power is turned on. Be careful to set AVCC10, AVCC12 equal VCC, for example, when the power is turned on. *3 : The maximum output current is the peak value for a single pin. *4 : The average output is the average current for a single pin over a period of 100 ms. *5 : The total average output current is the average current for all pins over a period of 100 ms. *6 : AVCC10 is the analog supply voltage for the 8/10-bit A/D converter, and AVCC12 is the analog supply voltage for the 12-bit A/D converter. *7 : AVRHn=AVRH0/AVRH1/AVRH2 are the analog reference voltage for the 8/10-bit A/D converter, and AVRH3/ AVRH4 are the analog reference voltage for the 12-bit A/D converter. WARNING: Semiconductor devices can be permanently damaged by application of stress (voltage, current, temperature, etc.) in excess of absolute maximum ratings. Do not exceed these ratings. 60 MB91470/480 Series 2. Recommended Operating Conditions (VSS = AVSS10 = AVSS12 = 0.0 V) Parameter Symbol Value Unit Remarks Min Max VCC 4.0 5.5 V AVCC10 VSS + 4.0 VSS + 5.5 V For all 8/10-bit A/D converter (common use) AVCC12 VSS + 4.0 VSS + 5.5 V For all 12-bit A/D converter (common use) AVRH0 AVSS10 AVCC10 V For 8/10-bit A/D converter 0 AVRH1 AVSS10 AVCC10 V For 8/10-bit A/D converter 1 AVRH2 AVSS10 AVCC10 V For 8/10-bit A/D converter 2 AVRH3 AVSS12 AVCC12 V For 12-bit A/D converter 3 AVRH4 AVSS12 AVCC12 V For 12-bit A/D converter 4 (-) Analog input signal voltage range ANINN AVSS12 AVCC12/2 V (+) Analog input signal voltage range ANINP AVSS12 AVCC12 V ANINN-ANINP voltage difference ANINN− ANINP ⎯ AVCC12/4 V Power supply voltage Analog power supply voltage Analog reference voltage + 70 Operating temperature TA − 40 °C + 85 For all 12-bit A/D converters (common use) (under differential mode) When mounted on single-layer PCB* When mounted on four-layer PCB* * : The remaining rating values assume four-layer PCB. Note : During power-on, it takes approximately 600 µs for the internal power supply to stabilize after the VCC power supply has stabilized. Continue to assert the INITX pin during this period. WARNING: The recommended operating conditions are required in order to ensure the normal operation of the semiconductor device. All of the device’s electrical characteristics are warranted when the device is operated within these ranges. Always use semiconductor devices within their recommended operating condition ranges. Operation outside these ranges may adversely affect reliability and could result in device failure. No warranty is made with respect to uses, operating conditions, or combinations not represented on the data sheet. Users considering application outside the listed conditions are advised to contact their FUJITSU representatives beforehand. 61 MB91470/480 Series 3. DC Characteristics (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V) Parameter Symbol Pin Conditions Value Min Typ Max Unit Remarks VIH CMOS input pin ⎯ VCC × 0.7 ⎯ VCC V VIHS CMOS hysteresis input pin ⎯ VCC × 0.8 ⎯ VCC V VIL CMOS input pin ⎯ VSS ⎯ VCC × 0.3 V VILS CMOS hysteresis input pin ⎯ VSS ⎯ VCC × 0.2 V VOH1 Except port VCC = 5.0 V, Q0 to Q5 and IOH = 4 mA port S0 to S5 VCC − 0.5 ⎯ ⎯ V VOH2 Port Q0 to Q5 and port S0 to S5 VCC − 0.5 ⎯ ⎯ V VOL1 Except port VCC = 5.0 V, Q0 to Q5 and IOL = 4 mA port S0 to S5 ⎯ ⎯ VSS + 0.4 V VOL2 Port Q0 to Q5 and port S0 to S5 VCC = 5.0 V, IOL = 12 mA ⎯ ⎯ VSS + 0.4 V Input leak current ILI ⎯ VCC = 5.0 V, VSS < VI < VCC −5 ⎯ ⎯ µA Pull-up resistance RPULL ⎯ 50 ⎯ kΩ ⎯ When the multiply and mA accumulate unit is not used. ⎯ When the multiply and mA accumulate unit is used. “H” level input voltage “L” level input voltage “H” level output voltage “L” level output voltage Power supply current ICC INITX, pull-up pin VCC VCC = 5.0 V, IOH = 12 mA ⎯ Flash memory VCC = 5.0 V, fC = 20 MHz, PLL × 4, CLKB = 80 MHz CLKP = 40 MHz CLKT = 40 MHz ⎯ ⎯ 100 140 (Continued) 62 MB91470/480 Series (Continued) Parameter (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V) Symbol ICC Pin VCC MASK ROM VCC = 5.0 V, fC = 20 MHz, PLL × 4, CLKB = 80 MHz CLKP = 40 MHz CLKT = 40 MHz Value Min ⎯ ⎯ ⎯ Power supply current ICCS ICCH Input capacitance Conditions CIN VCC VCC Other than VCC, VSS, AVSS12, AVSS10, AVCC12, AVCC10, AVRH0, AVRH1, AVRH2, AVRH3, AVRH4 Typ 65 105 50 Max Unit Remarks ⎯ When the multiply and mA accumulate unit is not used. ⎯ When the multiply and mA accumulate unit is used. ⎯ In sleep mode (When multiplication mA and addition calculator circuit is not used.) VCC = 5.0 V, fC = 20 MHz, PLL × 4, CLKB = 80 MHz CLKP = 40 MHz CLKT = 40 MHz ⎯ 80 ⎯ In sleep mode (When multiplication mA and addition calculator circuit is used.) VCC = 5.0 V, TA = + 25 °C ⎯ 350 ⎯ µA In stop mode VCC = 5.0 V, TA = + 85 °C ⎯ 1500 ⎯ µA In stop mode ⎯ 5 15 pF ⎯ 63 MB91470/480 Series 4. Flash Memory Write/Erase Characteristics Parameter 64 Conditions Value Min Typ Max Unit Remarks Sector erase time (8 Kbytes sectors) VCC = 5.0 V, TA = + 25 °C ⎯ 0.5 2.0 s Not including time for internal writing before deletion. Word write time VCC = 5.0 V, TA = + 25 °C ⎯ 6 100 µs Not including system-level overhead time. Chip write time VCC = 5.0 V, TA = + 25 °C ⎯ 1.8 29.5 s Not including system-level overhead time. Erase/write cycle ⎯ 10000 ⎯ ⎯ cycle Flash memory data hold time ⎯ 10 ⎯ ⎯ year MB91470/480 Series 5. AC Characteristics (1) Clock Timing (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V) Parameter Sym- Pin bol Name Clock frequency fC Condition X0 X1 Value Min Typ Unit Max When using the PLL within the MHz self-oscillating range, set the multiplier so that the internal clock does not exceed ns the internal operating clock frequency. 10*2 ⎯ 20 100 ⎯ 50*2 5*1 ⎯ 80 MHz CPU 5*1 ⎯ 40 MHz Peripheral 5*1 ⎯ 40 MHz External bus 12.5 ⎯ 200 ns CPU 25 ⎯ 200 ns Peripheral 25 ⎯ 200 ns External bus ⎯ Clock cycle time tC X0 X1 fCP Internal operating clock frequency fCPP ⎯ fCPT tCP Internal operating clock cycle time tCPP ⎯ When 20 MHz is input as the X0 clock frequency and the oscillator circuit PLL system is set to × 4 multiplication tCPT Remarks *1 : The values assume a gear cycle of 1/16. *2 : When the PLL is used, the PLL multiplication rate varies depending on the frequency of the clock input to the X0 and X1 pins. Set the PLL multiplication rate so that the PLL output clock frequency is in the range between 40 MHz and 80 MHz. PLL Multiplication Rate PLL output clock frequency when X0 = 10 MHz PLL output clock frequency when X0 = 20 MHz 1 2 3 (Setting not allowed) (Setting not allowed) 40 MHz 60 MHz 4 5 6 7 8 40 MHz 50 MHz 60 MHz 70 MHz 80 MHz 80 MHz (Setting not allowed) • Conditions for measuring the clock timing ratings tC Output pin 0.8 VCC C = 50 pF 65 MB91470/480 Series • Operation assurance range Power supply voltage VCC (V) 5.5 4.0 fCP (MHz) 0 0.31 80 but the upper limit of fCPT/fCPP is 40 MHz. Internal clock • Internal clock setting range (MHz) 80 Internal clock CPU (CLKB) : Peripheral (CLKP) External bus (CLKT) : 40 Oscillation input clock fC = 20 MHz (PLL multiplied by 4) 5 16 :16 2:2 1:2 CPU : Divided ratio for peripherals/external bus. Notes : • When the PLL is used, the external clock input should be in the range of 10 MHz to 20 MHz. • Treat the PLL oscillation stabilization time as > 600 µs • Set the internal clock gear setting to within the values shown in the clock timing ratings table. 66 MB91470/480 Series (2) Clock Output Timing (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol Pin Name Cycle time tCYC SYSCLK↑→ SYCSCLK↓ tCHCL SYSCLK↓→ SYCSCLK↑ tCLCH Value Condition ⎯ SYSCLK Unit Remarks Min Max tCPT ⎯ ns *1 tCYC/2 − 5 tCYC/2 + 5 ns *2 tCYC/2 − 5 tCYC/2 + 5 ns *1 : tCYC is the frequency of one clock cycle including the gear cycle. *2 : The following ratings are for the gear ratio set to × 2. For the ratings when the gear ratio is set to 1/4 and 1/8, can be calculated by substituting 1/4 or 1/8 for n respectively in the following equation. (1/2 × 1/n) × tCYC-5 Note : For tCPT (internal clock cycle time) , refer to “(1) Clock Timing”. tCYC tCHCL tCLCH VOH VOH SYSCLK VOL (3) PLL Oscillation stabilization time (LOCK UP TIME) (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter PLL Oscillation stabilization wait time (LOCK UP TIME) Symbol Pin Name Condition tLOCK* ⎯ ⎯ Value Min Max 600 ⎯ Unit µs * : The length of time to wait for the PLL oscillations to stabilize. 67 MB91470/480 Series (4) Reset Input Ratings (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter INITX input time (at power-on and stop mode) Symbol tINTL Pin Name INITX Condition ⎯ INITX input time (other than the above) Value Unit Min Max Oscillation time of oscillator tc × 10 ⎯ ns tc × 10 ⎯ ns Notes : • It takes approximately 600 µs for the internal power to stabilize after the power supply has stabilized. Continue to input “L” level to the INITX pin during this period. • For tCPT (internal clock cycle time) , refer to “(1) Clock Timing”. tINTL INITX 0.2 VCC 68 MB91470/480 Series (5) Normal Bus Access Read/Write Operation (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Value CondiParameter Symbol Pin Name Unit Remarks tion Min Max ASX setup tASLCH ASX hold tCHASH CS0X to CS2X setup tCSLCH CS0X to CS2X hold tCHCSH Address setup Address hold Valid address → Valid data input time RDX delay time SYSCLK ASX ⎯ SYSCLK CS0X to CS2X ⎯ ⎯ ns 3 1/2 × tCYC + 10 ns 3 ⎯ ns 3 1/2 × tCYC + 10 ns 3 ⎯ ns 3 ⎯ ns tASCH SYSCLK A15 to A00 tASRL RDX A15 to A00 tASWL WR0X, WR1X A15 to A00 3 ⎯ ns tCHAX SYSCLK A15 to A00 3 1/2 × tCYC + 10 ns tRHAX RDX A15 to A00 3 ⎯ ns tWHAX WR0X, WR1X A15 to A00 3 ⎯ ns tAVDV A15 to A00 D31 to D16 ⎯ ⎯ 3/2 × tCYC − 7 ns SYSCLK RDX ⎯ ⎯ 10 ns ⎯ ⎯ 10 ns ⎯ tCYC − 5 ns 18 ⎯ ns 0 ⎯ ns tCYC − 5 ⎯ ns ⎯ 10 ns ⎯ 10 ns tCYC ⎯ ns 3 ⎯ ns tCYC − 5 ⎯ ns tCHRL tCHRH ⎯ ⎯ RDX ↓ → Valid data input time tRLDV Data setup → RDX ↑ time tDSRH RDX ↑ → Data hold time tRHDX RDX minimum pulse width tRLRH RDX ⎯ tCHWL SYSCLK RDX ⎯ WR0X, WR1X delay time 3 tCHWH Data setup → WR0X, WR1X ↑ time tDSWH WR0X, WR1X ↑ → Data hold time tWHDX WR0X, WR1X minimum pulse width tWLWH RDX D31 to D16 ⎯ WR0X, WR1X D31 to D16 ⎯ WR0X, WR1X ⎯ *1 *2 *1 (Continued) 69 MB91470/480 Series (Continued) *1 : When the bus timing is delayed by an automatic wait instruction or RDY input, add the time (tCYC × the number of delay cycles added) to this rating. *2 : The following ratings are for the gear ratio set to × 2. For the ratings when the gear ratio is set to between 1/3 and 1/16, substitute the value between 1/3 and 1/16 for n in the following equation. Formula : 3/ (2n) × tCYC−15 Note : Load capacitance C = 50 pF tCYC SYSCLK VOH VOH tCHASH tASLCH ASX VOH VOL tCSLCH CS0X to CS2X tCHCSH VOH VOL tASCH A15 to A00 tCHAX VOH VOL VOH VOL tCHRL tCHRH tRLRH RDX VOH VOL tASRL tRHAX tRLDV tDSRH tRHDX tAVDV VOH VOL D31 to D16 (Read) tCHWL VOH VOL tCHWH tWLWH VOH WR0X, WR1X tASWL tWHAX tDSWH D31 to D16 (Write) 70 VOH VOL tWHDX VOH VOL MB91470/480 Series (6) Multiplex Bus Access Read/Write Operation (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol A15 to A00 address setup time → SYSCLK ↑ tASCH SYSCLK ↑ → A15 to A00 address Hold Time tCHAX A15 to A00 address setup time → ASX ↑ tASASH ASX ↑ → A15 to A00 address hold time tASHAX Pin Name Value Condition Unit Min Max 3 ⎯ ns 3 1/2 × tCYC + 10 ns 12 ⎯ ns tCYC − 5 tCYC + 5 ns SYSCLK, D31 to D16 ⎯ ASX, D31 to D16 Notes : • This rating is not guaranteed when the CSX → RDX/WRX Setup Delay setting by AWR : bit1 is “0”. • Normal bus interface ratings are applicable except this rating. • For tCYC (cycle time), refer to “(2) Clock Output Timing”. tCYC SYSCLK AS VOH VOH VOH VOL tASASH tASCH D31 to D16 (A15 to A00) tASHAX tCHAX VOH VOL 71 MB91470/480 Series (7) Ready Input Timing (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol RDY setup time → SYSCLK ↑ tRDYS SYSCLK ↑ → RDY hold time tRDYH Pin Name Value Condition SYSCLK, RDY Max 18 ⎯ ns 0 ⎯ ns ⎯ tCYC VOH SYSCLK VOH VOL VOL tRDYS tRDYS tRDYH tRDYH RDY (When WAIT is used) VOH VOL VOH VOL RDY (When WAIT is not used) VOH VOH VOL 72 Unit Min VOL MB91470/480 Series (8) UART Timing (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol Pin Serial clock cycle time tSCYC SCK↓→SOT delay time Conditions Value Unit Min Max SCK0 to SCK5 8 × tCYCP ⎯ ns tSLOV SCK0 to SCK5 SOT0 to SOT5 −50 +50 ns Valid SIN→SCK↑ tIVSH SCK0 to SCK5 SIN0 to SIN5 50 ⎯ ns SCK↑→ Valid SIN hold time tSHIX SCK0 to SCK5 SIN0 to SIN5 0 ⎯ ns Serial clock “H” pulse width tSHSL SCK0 to SCK5 4 × tCYCP ⎯ ns Serial clock “L” pulse width tSLSH SCK0 to SCK5 4 × tCYCP ⎯ ns SCK↓→SOT delay time tSLOV SCK0 to SCK5 SOT0 to SOT5 ⎯ 50 ns Valid SIN→SCK↑ tIVSH SCK0 to SCK5 SIN0 to SIN5 50 ⎯ ns SCK↑→ Valid SIN hold time tSHIX SCK0 to SCK5 SIN0 to SIN5 50 ⎯ ns Internal shift clock mode External shift clock mode Notes : • The above ratings are the AC characteristics for CLK synchronous mode. • tCYCP indicates the peripheral clock cycle time. 73 MB91470/480 Series • Internal shift clock mode tSCYC SCK0 to SCK5 VOH VOL VOL tSLOV VOH VOL SOT0 to SOT5 tIVSH tSHIX VOH VOL SIN0 to SIN5 VOH VOL • External shift clock mode tSLSH tSHSL VOH SCK0 to SCK5 VOL VOL VOL tSLOV SOT0 to SOT5 VOH VOL tIVSH SIN0 to SIN5 74 VOH VOL tSHIX VOH VOL MB91470/480 Series (9) Free-run Timer Clock, Up/Down Counter, Base Timer, and External Interrupt Input Timing (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol Free-run timer input clock pulse width Up-down counter input pulse width Base timer input pulse width Pin Name Unit Min Max CKI0, CKI1 4 × tCYCP ⎯ ns AIN0 BIN0 ZIN0 4 × tCYCP ⎯ ns 4 × tCYCP ⎯ ns 4 × tCYCP ⎯ ns 1.0 ⎯ µs tTIWH tTIWL ⎯ TIN0 to TIN3 External interrupt input pulse width Value Condition INT0 to INT15 Note : tCYCP indicates the peripheral clock cycle time. tTIWH VOH CKI0, CKI1 AIN0, BIN0, ZIN0 TIN0 to TIN3 INT0 to INT15 tTIWL VOH VOL VOL 75 MB91470/480 Series (10) Trigger Input Timing (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol Pin Name tICWH tICWL IC0 to IC7 Base timer trigger input tTGINWH tTGINWL TIN0 to TIN3 A/D activation trigger input tADTGWH tADTGWL ADTG0 to ADTG4 Input Capture trigger input Condition ⎯ Note : tCYCP indicates the peripheral clock cycle time. tICWH tTGINWH tADTGWH VOH IC0 to IC7 TIN0 to TIN3 ADTG0 to ADTG4 tICWL tTGINWL tADTGWL VOH VOL 76 VOL Value Unit Min Max 5 × tCYCP ⎯ ns 4 × tCYCP ⎯ ns 5 × tCYCP ⎯ ns MB91470/480 Series (11) I2C Timing a. Master Mode (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Standard Mode Symbol Condition Fast Mode *3 Min Max Min Max Unit SCL clock frequency fSCL 0 100 0 400 kHz “L” width of the SCL clock tLOW 4.7 ⎯ 1.3 ⎯ ms “H” width of the SCL clock tHIGH 4.0 ⎯ 0.6 ⎯ ms Bus free time between STOP and START conditions tBUS 4.7 ⎯ 1.3 ⎯ ms SCL↓→ SDA output delay time tDLDAT ⎯ 5 × tCYCP *1 ⎯ 5 × tCYCP *1 ns Setup time for a repeated START condition SCL↑→SDA↓ tSUSTA 4.7 ⎯ 0.6 ⎯ ms R=1 kΩ, C=50 pF*4 Hold time for a repeated START condition SDA↓→SCL↓ tHDSTA 4.0 ⎯ 0.6 ⎯ ms Setup time for STOP condition SCL↑→SDA↑ tSUSTO 4.0 ⎯ 0.6 ⎯ ms SDA Data input hold time (vs. SCL↓) tHDDAT 2 × tCYCP *1 ⎯ 2 × tCYCP *1 ⎯ ms SDA Data input setup time (vs. SCL↑) tSUDAT 250 ⎯ 100 *2 ⎯ ns Remarks The first clock pulse is generated after this. *1 : tCYCP indicates the peripheral clock cycle time. *2 : A Fast-mode I2C-bus device can be used in a Standard-mode I2C-bus system, but the requirement tSUDAT ≥ 250 ns must then be met. If a device does not extend the “L” period of the SCL signal, it is necessary to output the next piece of data to the SDA line 1250 ns (SDA and SCL rising Max time + tSUDAT) before the SCL line is released. *3 : For use at over 100 kHz, set the resource clock to at least 6 MHz. *4 : R and C are the pull-up resistance and load capacitance of the SCL and SDA lines. 77 MB91470/480 Series b. Slave Mode (VCC = 4.0 V to 5.5 V, VSS = AVSS10 = AVSS12 = 0.0 V, TA = − 40 °C to + 85 °C) Parameter Symbol Condition Standard Mode Fast Mode *3 Min Max Min Max Unit SCL clock frequency fSCL 0 100 0 400 kHz “L” width of the SCL clock tLOW 4.7 ⎯ 1.3 ⎯ µs “H” width of the SCL clock tHIGH 4.0 ⎯ 0.6 ⎯ µs Bus free time between STOP and START conditions tBUS 4.7 ⎯ 1.3 ⎯ µs SCL ↓ → SDA output delay time tDLDAT ⎯ 5 × tCYCP *1 ⎯ 5 × tCYCP *1 ns Setup time for a repeated START condition SCL ↑ → SDA ↓ tSUSTA 4.7 ⎯ 0.6 ⎯ µs R=1 kΩ, C=50 pF*4 Hold time for a repeated START condition SDA ↓ → SCL ↓ tHDSTA 4.0 ⎯ 0.6 ⎯ µs Setup time for STOP condition SCL ↑ → SDA ↑ tSUSTO 4.0 ⎯ 0.6 ⎯ µs SDA Data input hold time (vs. SCL ↓) tHDDAT 2 × tCYCP *1 ⎯ 2 × tCYCP *1 ⎯ µs SDA Data input setup time (vs. SCL ↑) tSUDAT 250 ⎯ 100 *2 ⎯ ns Remarks The first clock pulse is generated after this. *1 : tCYCP indicates the peripheral clock cycle time. *2 : A Fast-mode I2C-bus device can be used in a Standard-mode I2C-bus system, but the requirement tSUDAT ≥ 250 ns must then be met. If a device does not extend the “L” period of the SCL signal, it is necessary to output the next piece of data to the SDA line 1250 ns (SDA and SCL rising Max time + tSUDAT) before the SCL line is released. *3 : For use at over 100 kHz, set the resource clock to at least 6 MHz. *4 : R and C are pull-up resistance and load capacitance of the SCL and SDA lines. 78 MB91470/480 Series 6. Electrical Characteristics for the A/D Converter (1) 8/10-bit A/D Converter (VCC = 4.0 V to 5.5 V, AVRHn = 4.0 V to 5.5 V, VSS = AVSS10 = 0 V, TA = − 40 °C to + 85 °C) Symbol Pin Name Resolution ⎯ Total error Parameter Value Unit Min Typ Max ⎯ ⎯ ⎯ 10 bit ⎯ ⎯ −4 ⎯ +4 LSB Linearity error ⎯ ⎯ − 3.5 ⎯ + 3.5 LSB Differential linearity error ⎯ ⎯ −3 ⎯ +3 LSB Remarks Zero transition voltage VOT When AVRHn = AN0-0 to AN0-3 5.0 V AN1-0 to AN1-3 AVSS10−3.5 AVSS10+0.5 AVSS10+4.5 LSB AN2-0 to AN2-11 Full-scale transition voltage VFST AN0-0 to AN0-3 AN1-0 to AN1-3 AVRHn−5.5 AN2-0 to AN2-11 Conversion time*1 ⎯ ⎯ 1.2 ⎯ ⎯ µs Analog port input current IAIN AN0-0 to AN0-3 AN1-0 to AN1-3 AN2-0 to AN2-11 ⎯ ⎯ 10 µA Analog input voltage VAIN AN0-0 to AN0-3 AN1-0 to AN1-3 AN2-0 to AN2-11 AVSS10 ⎯ AVRHn V Reference voltage ⎯ AVRHn AVSS10 ⎯ AVCC10 V Power supply current (Analog + digital) IA AVCC10 ⎯ 2 ⎯ mA IAH*2 AVCC10 ⎯ ⎯ 5 µA IR AVRHn ⎯ 1 ⎯ For each 1 unit, mA at AVRHn = 5.0 V AVSS10 = 0 V IRH*2 AVRHn ⎯ ⎯ 5 µA Analog input capacitance ⎯ ⎯ ⎯ ⎯ 12.5 pF Interchannel disparity ⎯ AN0-0 to AN0-3 AN1-0 to AN1-3 AN2-0 to AN2-11 ⎯ ⎯ 4 LSB Reference voltage supply current (between AVRH and AVSS) AVRHn−1.5 AVRHn+2.5 LSB For each 1 unit For each 1 unit, at stop mode *1 : When VCC = AVCC10 = 5.0 V and Machine clock = 33 MHz *2 : The current when the CPU is in stop mode and the A/D converter is not operating (at VCC = AVCC10 = AVRHn = 5.0 V) . Notes : • The above figures do not guarantee the accuracy between each unit. • Output impedance of the external circuit ≤ 2 kΩ. • AVRHn = AVRH0, AVRH1, and AVRH2 79 MB91470/480 Series (2) 12-bit A/D Converter (VCC = 4.0 V to 5.5 V, AVRHn = 4.0 V to 5.5 V, VSS = AVSS12 = 0 V, TA = − 40 °C to + 85 °C) Parameter Symbol Pin Name Resolution ⎯ Linearity error Differential linearity error Value Unit Remarks Min Typ Max ⎯ ⎯ ⎯ 12 bit ⎯ ⎯ −3.6 ⎯ + 3.6 LSB ⎯ ⎯ −3 ⎯ +3 LSB Zero transition voltage VOT AN3-0 to AN3-3 AN4-0 to AN4-3 Typ − 20 mV AVSS12 + 0.5 LSB Typ + 20 mV ⎯ Full-scale transition voltage VFST AN3-0 to AN3-3 AN4-0 to AN4-3 Typ − 20 mV AVRHn − 1.5 LSB Typ + 20 mV ⎯ 2.0 ⎯ ⎯ µs When machine clock = 33 MHz 2.2 ⎯ ⎯ µs When machine clock = 40 MHz Conversion time ⎯ ⎯ Analog port input current IAIN AN3-0 to AN3-3 AN4-0 to AN4-3 ⎯ ⎯ 10 µA Analog input voltage VAIN AN3-0 to AN3-3 AN4-0 to AN4-3 AVSS12 ⎯ AVRHn V Reference voltage ⎯ AVRHn AVSS12 ⎯ AVCC12 V Analog supply current (analog + digital) IA AVCC12 ⎯ 2 ⎯ mA IAH* AVCC12 ⎯ ⎯ 5 µA When AVRHn = 5.0 V For each unit Reference voltage supply current (between AVRH and AVSS) IR AVRHn ⎯ 1 ⎯ For each unit, mA at AVRHn = 5.0 V, AVSS12 = 0 V IRH* AVRHn ⎯ ⎯ 5 µA Analog input capacitance ⎯ ⎯ ⎯ ⎯ 18 pF Interchannel disparity ⎯ AN3-0 to AN3-3 AN4-0 to AN4-3 ⎯ ⎯ 4 LSB For each unit, at stop mode * : The current when the CPU is in stop mode and the A/D converter is not operating (at VCC = AVCC10 = AVRHn = 5.0 V) . Notes : • The above figures do not guarantee the accuracy between each unit. • Output impedance of the external circuit ≤ 2 kΩ • AVRHn = AVRH3, AVRH4 80 MB91470/480 Series • External impedance and sampling time of analog inputs • The A/D converter is fitted with a sample and hold circuit. If the external impedance is so high that there is not sufficient time for sampling, the internal sample and hold capacitor will not fully charge to the analog voltage, and the precision of the A/D conversion will be adversely affected. Therefore, in order to satisfy the A/D conversion precision specifications, either adjust the register values and operating frequency or reduce the external impedance so that the sampling time is greater than the minimum value as given by the relationship between external impedance and minimum sampling time. If you are still unable to hold enough sampling time, connect a capacitor of about 0.1 µF to the analog input pin. • Analog input circuit schematic R Analog input Comparator C During sampling : ON 8/10-bit A/D converter 12-bit A/D converter R 4.6 kΩ 1.0 kΩ C 12.5 pF 18.0 pF Note : The values are reference values. • To satisfy the A/D conversion precision standard, consider the relationship between the external impedance and minimum sampling time and either adjust the resistor value and operating frequency or decrease the external impedance so that the sampling time is longer than the minimum value. • The relationship between the external impedance and minimum sampling time (External impedance = 0 kΩ to 20 kΩ) 8/10-bit A/D converter 100 90 80 70 60 50 40 30 20 10 0 12-bit A/D converter 0 2 4 6 8 10 12 Minimum sampling time [µs] 14 8/10-bit A/D converter 20 External impedance [kΩ] External impedance [kΩ] (External impedance = 0 kΩ to 100 kΩ) 18 16 14 12 10 8 6 4 2 0 12-bit A/D converter 0 0.4 0.8 1.2 1.6 2.0 2.4 2.8 3.2 Minimum sampling time [µs] • About errors • The relative error increases as the value of |AVRH − AVSS| decreases. 81 MB91470/480 Series • Definition of 8/10-bit A/D Converter Terms • Resolution • Linearity error : Analog variation that is recognized by the A/D converter. : Deviation between the line connecting zero transition point (0000000000←→0000000001) and full-scale transition point (1111111110←→1111111111) and actual conversion characteristics. • Differential linear error : Deviation from the ideal value of input voltage necessary to change the output code by ILSB. • Total Error : This error is the difference between actual and ideal values, including the zero transition error/full-scale transition error/linearity error. Linearity error FFFH Differential linear error Actual conversion characteristic Actual conversion characteristic (N + 1)H FFEH Digital output VFST (Measurement value) VNT 004H (Measurement value) 003H Digital output {1 LSB (N − 1) + V OT} FFDH Ideal characteristic NH V(N+1)T (N − 1)H (Measurement value) Actual conversion characteristic Ideal characteristic 002H VNT (Measurement value) (N − 2)H 001H VOT AVSS Actual conversion characteristic (Measurement value) Analog input AVRH AVSS Analog input AVRH VNT − {1 LSB × (N − 1) + VOT} [LSB] 1 LSB V (N+1) T − VNT Differential linear error in digital output N = − 1 [LSB] 1 LSB VFST − VOT 1 LSB = 1022 N : A/D converter digital output value VOT : Voltage at which digital output changes from 000H to 001H. VFST : Voltage at which digital output changes from 3FEH to 3FFH. VNT : Voltage at which digital output changes from (N − 1) H to NH. Linear error in digital output N = (Continued) 82 MB91470/480 Series (Continued) Total error 3FFH 1.5 LSB' Actual conversion characteristic 3FEH Digital output 3FDH {1 LSB' (N − 1) + 0.5 LSB'} 004H VNT 003H (Measurement value) Actual conversion characteristic 002H Ideal characteristic 001H 0.5 LSB' AVSS Analog input AVRH AVRH − AVSS [V] 1024 VNT − {1 LSB’ × (N − 1) + 0.5 LSB’} Total error of digital output N = 1 LSB’ N : A/D converter digital output value VNT : Voltage at which digital output changes from (N + 1) H to NH. VOT’ (ideal value) = AVSS + 0.5 LSB’ [V] VFST’ (ideal value) = AVRH − 1.5 LSB’ [V] 1 LSB’ (ideal value) = 83 MB91470/480 Series • Definition of 12-bit A/D Converter Terms • Resolution • Linearity error : Analog variation that is recognized by the A/D converter. : Deviation between the line connecting zero transition point (000000000000←→000000000001) and full-scale transition point (111111111110←→111111111111) and actual conversion characteristics. • Differential linear error : Deviation from the ideal value of input voltage necessary to the output code by ILSB. Linearity error FFFH Differential linear error Actual conversion characteristic Actual conversion characteristic (N + 1)H FFEH Digital output VFST (Measurement value) VNT 004H (Measurement value) 003H Digital output {1 LSB (N − 1) + V OT} FFDH Ideal characteristic NH V(N+1)T (N − 1)H (Measurement value) Actual conversion characteristic Ideal characteristic 002H VNT (Measurement value) (N − 2)H 001H VOT AVSS Actual conversion characteristic (Measurement value) Analog input AVRH AVSS Analog input VNT − {1 LSB’ × (N − 1) + VOT} [LSB] 1 LSB’ V (N+1) T − VNT Differential linear error in digital output N = − 1 [LSB] 1 LSB’ VFST − VOT 1 LSB = 4094 N : A/D converter digital output value VOT : Voltage at which digital output changes from 000H to 001H. VFST : Voltage at which digital output changes from FFEH to FFFH. VNT : Voltage at which digital output changes from (N − 1)H to NH. Linear error in digital output N = 84 AVRH MB91470/480 Series ■ ORDERING INFORMATION Part No. Package MB91F475PMC1-GE1 FPT-144P-M12 MB91F475BGL-GE1 BGA-144P-M06 MB91F478PMC1-GE1 FPT-144P-M12 MB91F478BGL-GE1 BGA-144P-M06 MB91F479PMC1-GE1 FPT-144P-M12 MB91F479BGL-GE1 BGA-144P-M06 MB91F487PMC-GE1 FPT-100P-M20 MB91482PMC-GE1 FPT-100P-M20 85 MB91470/480 Series ■ PACKAGE DIMENSIONS 100-pin plastic LQFP Lead pitch 0.50 mm Package width × package length 14.0 mm × 14.0 mm Lead shape Gullwing Sealing method Plastic mold Mounting height 1.70 mm Max Weight 0.65 g Code (Reference) P-LFQFP100-14×14-0.50 (FPT-100P-M20) 100-pin plastic LQFP (FPT-100P-M20) Note 1) * : These dimensions do not include resin protrusion. Note 2) Pins width and pins thickness include plating thickness. Note 3) Pins width do not include tie bar cutting remainder. 16.00±0.20(.630±.008)SQ * 14.00±0.10(.551±.004)SQ 75 51 76 50 0.08(.003) Details of "A" part +0.20 26 100 1 C 0.08(.003) (0.50(.020)) 0.25(.010) 0.60±0.15 (.024±.006) 25 0.20±0.05 (.008±.002) 0.10±0.10 (.004±.004) (Stand off) 0˚~8˚ "A" 0.50(.020) +.008 1.50 –0.10 .059 –.004 (Mounting height) INDEX M 0.145±0.055 (.0057±.0022) 2005 FUJITSU LIMITED F100031S-c-2-1 Dimensions in mm (inches). Note: The values in parentheses are reference values Please confirm the latest Package dimension by following URL. http://edevice.fujitsu.com/fj/DATASHEET/ef-ovpklv.html (Continued) 86 MB91470/480 Series 144-pin plastic LQFP Lead pitch 0.40 mm Package width × package length 16.0 × 16.0 mm Lead shape Gullwing Sealing method Plastic mold Mounting height 1.70 mm MAX Weight 0.88 g Code (Reference) P-LFQFP144-16×16-0.40 (FPT-144P-M12) 144-pin plastic LQFP (FPT-144P-M12) Note 1) * : These dimensions include resin protrusion. Resin protrusion is +0.25(.010)Max(each side). Note 2) Pins width and pins thickness include plating thickness. Note 3) Pins width do not include tie bar cutting remainder. 18.00±0.20(.709±.008)SQ +0.40 +.016 *16.00 –0.10 .630 –.004 SQ 73 108 72 109 0.08(.003) Details of "A" part +0.20 1.50 –0.10 +.008 (Mounting height) .059 –.004 INDEX 0~8˚ 37 144 LEAD No. 1 0.60±0.15 (.024±.006) 36 0.40(.016) C "A" 0.18±0.035 .007±.001 +0.05 0.07(.003) M 2003 FUJITSU LIMITED F144024S-c-3-3 0.145 –0.03 .006 0.10±0.05 (.004±.002) (Stand off) 0.25(.010) +.002 –.001 Dimensions in mm (inches). Note: The values in parentheses are reference values. Please confirm the latest Package dimension by following URL. http://edevice.fujitsu.com/fj/DATASHEET/ef-ovpklv.html (Continued) 87 MB91470/480 Series (Continued) 144-ball plastic PFBGA Ball pitch 0.80 mm Package width × package length 12.00 × 12.00 mm Lead shape Soldering ball Sealing method Plastic mold Ball size ∅0.45 mm Mounting height 1.45 mm Max. Weight 0.32 g (BGA-144P-M06) 144-ball plastic PFBGA (BGA-144P-M06) B 12.00±0.10(.472±.004) 0.20(.008) S B 0.80(.031) REF 13 12 11 10 9 8 7 6 5 4 3 2 1 0.80(.031) REF A 12.00±0.10 (.472±.004) (INDEX AREA) 0.20(.008) S A 1.25±0.20 0.35±0.10 (.014±.004) (Stand off) (.049±.008) (Seated height) N M L K J H G F E D C B A INDEX 144-ø0.45±0.10 (144-ø.018±.004) ø0.08(.003) M S A B S 0.10(.004) S C 2003 FUJITSU LIMITED B144006S-c-1-1 Please confirm the latest Package dimension by following URL. http://edevice.fujitsu.com/fj/DATASHEET/ef-ovpklv.html 88 Dimensions in mm (inches). Note: The values in parentheses are reference values. MB91470/480 Series ■ MAIN CHANGES IN THIS EDITION Page 6 Section ■ PIN ASSIGNMENT • LQFP-144 (MB91470 series) 12 ■ PIN DESCRIPTIONS 14 25 27, 28 Changed the pin name as follows : PE0/AN3-0 → PE0/AN3-0/AN3-0P PE1/AN3-1 → PE1/AN3-1/AN3-0N PE2/AN3-2 → PE2/AN3-2/AN3-1P PE3/AN3-3 → PE3/AN3-3/AN3-1N PE7/AN4-3 → PE7/AN4-3/AN4-1N PE6/AN4-2 → PE6/AN4-2/AN4-1P PE5/AN4-1 → PE5/AN4-1/AN4-0N PE4/AN4-0 → PE4/AN4-0/AN4-0P Added the following description in the Function of PPG8, PPG9; (MB91480 series only) Added the following description in the Function of SCK4, SIN4, SOT4, SCK5, SIN5, SOT5; (MB91470 series only) ■ HANDLING DEVICES Added the “• Notes upon power-on sequence” ■ BLOCK DIAGRAM Changed in the figure 65 66 Change Results ■ ELECTRICAL CHARACTERISTICS 5. AC Characteristics (1) Clock Timing In the figure of “Conditions for measuring the clock timing ratings”, deleted tCF, tCR and PWH, PWL and its range lines. Changed as follows in the “Operation assurance range” fCPS → fCP but the upper limit of fCPT/fCPP is 40 MHz. → but the upper limit of fCPT/fCPP is 40 MHz. 71 ■ ELECTRICAL CHARACTERISTICS 5. AC Characteristics (6) Multiplex Bus Access Read/Write Operation Changed in the figure as follows : tCHAH → tCHAX 83 ■ ELECTRICAL CHARACTERISTICS 6. Electrical Characteristics for the A/D converter Changed in the figure of “Total error” 85 ■ ORDERING INFORMATION Changed the part number MB91F487PMC1-GE1 → MB91F487PMC-GE1 The vertical lines marked in the left side of the page show the changes. 89 MB91470/480 Series The information for microcontroller supports is shown in the following homepage. http://www.fujitsu.com/global/services/microelectronics/product/micom/support/index.html FUJITSU LIMITED All Rights Reserved. The contents of this document are subject to change without notice. Customers are advised to consult with FUJITSU sales representatives before ordering. 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