R8C/13 Group SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER REJ03B0069-0120 Rev.1.20 Jan 27, 2006 1. Overview This MCU is built using the high-performance silicon gate CMOS process using a R8C/Tiny Series CPU core and is packaged in a 32-pin plastic molded LQFP. This MCU operates using sophisticated instructions featuring a high level of instruction efficiency. With 1M bytes of address space, it is capable of executing instructions at high speed. The data flash ROM (2 KB X 2 blocks) is embedded. 1.1 Applications Electric household appliance, office equipment, housing equipment (sensor, security), general industrial equipment, audio, etc. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 1 of 27 R8C/13 Group 1. Overview 1.2 Performance Overview Table 1.1. lists the performance outline of this MCU. Table 1.1 Performance outline Item Performance CPU Number of basic instructions 89 instructions Minimum instruction execution time 50 ns (f(XIN) = 20 MHZ, VCC = 3.0 to 5.5 V) 100 ns (f(XIN) = 10 MHZ, VCC = 2.7 to 5.5 V) Operating mode Single-chip Address space 1M bytes Memory capacity See Table 1.2. Peripheral Port Input/Output: 22 (including LED drive port), Input: 2 function LED drive port I/O port: 8 Timer Timer X: 8 bits x 1 channel, Timer Y: 8 bits x 1 channel, Timer Z: 8 bits x 1 channel (Each timer equipped with 8-bit prescaler) Timer C: 16 bits x 1 channel (Circuits of input capture and output compare) Serial interface •1 channel Clock synchronous, UART •1 channel UART A/D converter 10-bit A/D converter: 1 circuit, 12 channels Watchdog timer 15 bits x 1 (with prescaler) Reset start function selectable Interrupt Internal: 11 factors, External: 5 factors, Software: 4 factors, Priority level: 7 levels Clock generation circuit 2 circuits •Main clock generation circuit (Equipped with a built-in feedback resistor) •On-chip oscillator (high-speed, low-speed) On high-speed on-chip oscillator the frequency adjustment function is usable. Oscillation stop detection function Main clock oscillation stop detection function Voltage detection circuit Included Power on reset circuit Included Electrical Supply voltage VCC = 3.0 to 5.5V (f(XIN) = 20MHZ) characteristics VCC = 2.7 to 5.5V (f(XIN) = 10MHZ) Power consumption Typ.9 mA (VCC = 5.0V, (f(XIN) = 20MHZ) Typ.5 mA (VCC = 3.0V, (f(XIN) = 10MHZ) Typ.35 µA (VCC = 3.0V, Wait mode, Peripheral clock stops) Typ.0.7 µA (VCC = 3.0V, Stop mode) Flash memory Program/erase supply voltage VCC = 2.7 to 5.5 V Program/erase endurance 10,000 times (Data flash) 1,000 times (Program ROM) Operating ambient temperature -20 to 85°C -40 to 85°C (D-version) Package 32-pin plastic mold LQFP Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 2 of 27 R8C/13 Group 1. Overview 1.3 Block Diagram Figure 1.1 shows this MCU block diagram. 8 8 I/O port Port P0 1 5 Port P3 Port P1 2 Port P4 Peripheral functions Timer Timer X (8 bits) Timer Y (8 bits) Timer Z (8 bits) Timer C (16 bits) A/D converter (10 bits ✕ 12 channels) System clock generator UART or Clock synchronous serial I/O (8 bits ✕ 1 channel) XIN-XOUT High-speed on-chip oscillator Low-speed on-chip oscillator UART (8 bits ✕ 1 channel) Memory R8C/Tiny Series CPU core Watchdog timer (15 bits) R0H R1H R0L R1L R2 R3 SB ISP INTB A0 A1 FB (1) ROM USP RAM (2) PC FLG Multiplier NOTES: 1. ROM size depends on MCU type. 2. RAM size depends on MCU type. Figure 1.1 Block Diagram Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 3 of 27 R8C/13 Group 1. Overview 1.4 Product Information Table 1.2 lists the product information. Table 1.2 Product Information As of January 2006 ROM capacity Type No. Remarks Program ROM Data flash RAM capacity R5F21132FP 8K bytes 2K bytes x 2 512 bytes PLQP0032GB-A Flash memory version R5F21133FP 12K bytes 2K bytes x 2 768 bytes PLQP0032GB-A R5F21134FP 16K bytes 2K bytes x 2 1K bytes PLQP0032GB-A R5F21132DFP 8K bytes 2K bytes x 2 512 bytes PLQP0032GB-A D version R5F21133DFP 12K bytes 2K bytes x 2 768 bytes PLQP0032GB-A R5F21134DFP 16K bytes 2K bytes x 2 1K bytes PLQP0032GB-A Type No. R 5 F Package type 21 13 4 D FP Package type: FP : PLQP0032GB-A Classification: D: Operating ambient temperature –40 °C to 85 °C No symbol: Operating ambient temperature –20 °C to 85 °C ROM capacity: 2 : 8 KBytes. 3 : 12 KBytes. 4 : 16 KBytes. R8C/13 group R8C/Tiny series Memory type: F: Flash memory version Renesas MCU Renesas semiconductors Figure 1.2 Type No., Memory Size, and Package Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 4 of 27 R8C/13 Group 1. Overview 1.5 Pin Assignments Figure 1.3 shows the pin configuration (top view). P30/CNTR0/CMP10 AVSS P31/TZOUT/CMP11 AVCC/VREF P32/INT2/CNTR1/CMP12 P33/INT3/ TCIN P07/AN0 IVCC(3) PIN Assignments (top view) 24 23 22 21 20 19 18 17 P06/AN1 P05/AN2 P04/AN3 MODE P03/AN4 P02/AN5 P01/AN6 P00/AN7/TxD11 25 26 27 28 29 30 31 32 16 15 14 13 12 11 10 9 R8C/13 Group P45/INT0 P10/KI0/AN8/CMP00 P11/KI1/AN9/CMP01 P12/KI2/AN10/CMP02 P13/KI3/AN11 P14/TxD0 P15/RxD0 P16/CLK0 RESET XOUT/P47 (1) VSS XIN/P46 VC C P17/INT1/CNTR0 P37/TxD10/RxD1 CNVSS 1 2 3 4 5 6 7 8 NOTES: 1. P47 functions only as an input port. 2. When using On-chip debugger, do not use P00/AN7/TxD11 and P37/TxD10/RxD1 pins. 3. Do not connect IVcc to Vcc. Package: PLQP0032GB-A (32P6U-A) Figure 1.3 Pin Assignments (Top View) Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 5 of 27 R8C/13 Group 1. Overview 1.6 Pin Description Table 1.3 shows the pin description Table 1.3 Pin description Signal name Power supply input IVcc Pin name Vcc, Vss IVcc I/O type O Analog power supply input AVcc, AVss I Power supply input pins for A/D converter. Connect the AVcc pin to Vcc. Connect the AVss pin to Vss. Connect a capacitor between pins AVcc and AVss. Reset input CNVss MODE Main clock input RESET CNVss MODE XIN I I I I I ___________ Function Apply 2.7 V to 5.5 V to the Vcc pin. Apply 0 V to the Vss pin. This pin is to stabilize internal power supply. Connect this pin to Vss via a capacitor (0.1 µF). Do not connect to Vcc. INT interrupt input INT 0 to_____ INT3 _____ Key input interrupt KI0 to KI3 input Timer X CNTR 0 __________ CNTR0 Timer Y CNTR1 Timer Z TZOUT Timer C TCIN CMP00 to CMP02, CMP10 to CMP12 Serial interface CLK0 RxD0, RxD1 TxD0, TxD10, TxD11 Reference voltage VREF input A/D converter AN0 to AN11 I/O port P00 to P07, P10 to P17, P30 to P33, P37, P45 I I Input “L” on this pin resets the MCU. Connect this pin to Vss via a resistor. Connect this pin to Vcc via a resistor. These pins are provided for the main clock generating circuit I/O. Connect a ceramic resonator or a crystal oscillator between the XIN and XOUT pins. To use an externally derived clock, input it to the XIN pin and leave the XOUT pin open. ______ INT interrupt input pins. Key input interrupt pins. I/O O I/O O I O Timer X I/O pin Timer X output pin Timer Y I/O pin Timer Z output pin Timer C input pin The timer C output pins I/O I O Transfer clock I/O pin. Serial data input pins. Serial data output pins. I Reference voltage input pin for A/D converter. Connect the VREF pin to Vcc. Analog input pins for A/D converter These are 8-bit CMOS I/O ports. Each port has an I/O select direction register, allowing each pin in that port to be directed for input or output individually. Any port set to input can select whether to use a pullup resistor or not by program. P10 to P17 also function as LED drive ports. Input port I Main clock output XOUT _____ Rev.1.20 Jan 27, 2006 REJ03B0069-0120 _______ O _______ P46, P47 page 6 of 27 I I/O Port for input-only R8C/13 Group 2. Central Processing Unit (CPU) 2. Central Processing Unit (CPU) Figure 2.1 shows the CPU Register. The CPU contains 13 registers. Of these, R0, R1, R2, R3, A0, A1 and FB comprise a register bank. Two sets of register banks are provided. b31 b15 b8 b7 b0 R2 R0H(High-order of R0) R0L(Low-order of R0) R3 R1H(High-order of R1) R1L(Low-order of R1) R2 Data registers(1) R3 A0 b19 A1 Address registers(1) FB Frame base registers(1) b15 b0 INTBH INTBL Interrupt table register The 4-high order bits of INTB are INTBH and the 16-low bits of INTB are INTBL. b19 b0 PC Program counter b15 b0 USP User stack pointer ISP Interrupt stack pointer SB Static base register b15 b0 FLG b15 b8 IPL b7 U I Flag register b0 O B S Z D C Carry flag Debug flag Zero flag Sign flag Register bank select flag Overflow flag Interrupt enable flag Stack pointer select flag Reserved bit Processor interrupt priority level Reserved bit NOTES: 1. A register bank comprises these registers. Two sets of register banks are provided Figure 2.1 CPU Register 2.1 Data Registers (R0, R1, R2 and R3) R0 is a 16-bit register for transfer, arithmetic and logic operations. The same applies to R1 to R3. The R0 can be split into high-order bit (R0H) and low-order bit (R0L) to be used separately as 8-bit data registers. The same applies to R1H and R1L as R0H and R0L. R2 can be combined with R0 to be used as a 32-bit data register (R2R0). The same applies to R3R1 as R2R0. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 7 of 27 R8C/13 Group 2. Central Processing Unit (CPU) 2.2 Address Registers (A0 and A1) A0 is a 16-bit register for address register indirect addressing and address register relative addressing. They also are used for transfer, arithmetic and logic operations. The same applies to A1 as A0. A0 can be combined with A0 to be used as a 32-bit address register (A1A0). 2.3 Frame Base Register (FB) FB is a 16-bit register for FB relative addressing. 2.4 Interrupt Table Register (INTB) INTB is a 20-bit register indicates the start address of an interrupt vector table. 2.5 Program Counter (PC) PC, 20 bits wide, indicates the address of an instruction to be executed. 2.6 User Stack Pointer (USP) and Interrupt Stack Pointer (ISP) The stack pointer (SP), USP and ISP, are 16 bits wide each. The U flag of FLG is used to switch between USP and ISP. 2.7 Static Base Register (SB) SB is a 16-bit register for SB relative addressing. 2.8 Flag Register (FLG) FLG is a 11-bit register indicating the CPU state. 2.8.1 Carry Flag (C) The C flag retains a carry, borrow, or shift-out bit that has occurred in the arithmetic logic unit. 2.8.2 Debug Flag (D) The D flag is for debug only. Set to “0”. 2.8.3 Zero Flag (Z) The Z flag is set to “1” when an arithmetic operation resulted in 0; otherwise, “0”. 2.8.4 Sign Flag (S) The S flag is set to “1” when an arithmetic operation resulted in a negative value; otherwise, “0”. 2.8.5 Register Bank Select Flag (B) The register bank 0 is selected when the B flag is “0”. The register bank 1 is selected when this flag is set to “1”. 2.8.6 Overflow Flag (O) The O flag is set to “1” when the operation resulted in an overflow; otherwise, “0”. 2.8.7 Interrupt Enable Flag (I) The I flag enables a maskable interrupt. An interrupt is disabled when the I flag is set to “0”, and are enabled when the I flag is set to “1”. The I flag is set to “0” when an interrupt request is acknowledged. 2.8.8 Stack Pointer Select Flag (U) ISP is selected when the U flag is set to “0”, USP is selected when the U flag is set to “1”. The U flag is set to “0” when a hardware interrupt request is acknowledged or the INT instruction of software interrupt numbers 0 to 31 is executed. 2.8.9 Processor Interrupt Priority Level (IPL) IPL, 3 bits wide, assigns processor interrupt priority levels from level 0 to level 7. If a requested interrupt has greater priority than IPL, the interrupt is enabled. 2.8.10 Reserved Bit When write to this bit, set to “0”. When read, its content is indeterminate. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 8 of 27 R8C/13 Group 3. Memory 3. Memory Figure 3.1 is a memory map of this MCU. This MCU provides 1-Mbyte address space from addresses 0000016 to FFFFF16. The internal ROM (program ROM) is allocated lower addresses beginning with address 0FFFF16. For example, a 16-Kbyte internal ROM is allocated addresses from 0C00016 to 0FFFF16. The fixed interrupt vector table is allocated addresses 0FFDC16 to 0FFFF16. They store the starting address of each interrupt routine. The internal ROM (data flash) is allocated addresses from 0200016 to 02FFF16. The internal RAM is allocated higher addresses beginning with address 0040016. For example, a 1-Kbyte internal RAM is allocated addresses 0040016 to 007FF16. The internal RAM is used not only for storing data, but for calling subroutines and stacks when interrupt request is acknowledged. Special function registers (SFR) are allocated addresses 0000016 to 002FF16. The peripheral function control registers are located them. All addresses, which have nothing allocated within the SFR, are reserved area and cannot be accessed by users. 0000016 SFR (See Chapter 4 for details.) 002FF16 0040016 Internal RAM 0XXXX16 0200016 Internal ROM (data flash)(1) 0FFDC16 Undefined instruction Overflow BRK instruction Address match Single step 02FFF16 Watchdog timer,Oscillation stop detection,Voltage detection 0YYYY16 Internal ROM (program ROM) (Reserved) (Reserved) Reset 0FFFF16 0FFFF16 Expansion area FFFFF16 NOTES: 1. The data flash block A (2K bytes) and block B (2K bytes) are shown. 2. Blank spaces are reserved. No access is allowed. Internal ROM Internal RAM Type name Address 0YYYY16 Address 0XXXX16 Size Size R5F21134FP, R5F21134DFP 16K bytes 0C00016 1K bytes R5F21133FP, R5F21133DFP 12K bytes 0D00016 768 bytes 006FF16 R5F21132FP, R5F21132DFP 8K bytes 0E00016 512 bytes 005FF16 Figure 3.1 Memory Map Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 9 of 27 007FF16 R8C/13 Group 4. Special Function Register (SFR) 4. Special Function Register (SFR) SFR(Special Function Register) is the control register of peripheral functions. Tables 4.1 to 4.4 list the SFR information Table 4.1 SFR Information(1)(1) Register Address Symbol After reset 000016 000116 000216 000316 000416 000516 000616 000716 000816 000916 000A16 000B16 000C16 000D16 000E16 000F16 001016 Processor mode register 0 (1) Processor mode register 1 System clock control register 0 System clock control register 1 High-speed on-chip oscillator control register 0 Address match interrupt enable register Protect register High-speed on-chip oscillator control register 1 Oscillation stop detection register Watchdog timer reset register Watchdog timer start register Watchdog timer control register Address match interrupt register 0 PM0 PM1 CM0 CM1 HR0 AIER PRCR HR1 OCD WDTR WDTS WDC RMAD0 0016 0016 011010002 001000002 0016 XXXXXX002 00XXX0002 4016 000001002 XX16 XX16 000111112 0016 0016 X016 Address match interrupt register 1 RMAD1 0016 0016 X016 Voltage detection register 1(2) Voltage detection register 2 (2) VCR1 VCR2 000010002 0016 (3) 100000002(4) INT0 input filter select register Voltage detection interrupt register (2) INT0F D4INT XXXXX0002 0016 (3) 010000012(4) 001116 001216 001316 001416 001516 001616 001716 001816 001916 001A16 001B16 001C16 001D16 001E16 001F16 002016 002116 002216 002316 002416 002516 002616 002716 002816 002916 002A16 002B16 002C16 002D16 002E16 002F16 003016 003116 003216 003316 003416 003516 003616 003716 003816 003916 003A16 003B16 003C16 003D16 003E16 003F16 X : Undefined NOTES: 1. Blank spaces are reserved. No access is allowed. 2. Software reset or the watchdog timer reset does not affect this register. 3. Owing to Reset input. 4. In the case of RESET pin = H retaining. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 10 of 27 R8C/13 Group 4. Special Function Register (SFR) Table 4.2 SFR Information(2)(1) Register Symbol After reset Key input interrupt control register AD conversion interrupt control register KUPIC ADIC XXXXX0002 XXXXX0002 Compare 1 interrupt control register UART0 transmit interrupt control register UART0 receive interrupt control register UART1 transmit interrupt control register UART1 receive interrupt control register CMP1IC S0TIC S0RIC S1TIC S1RIC INT2IC TXIC TYIC TZIC INT1IC INT3IC TCIC CMP0IC INT0IC XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XXXXX0002 XX00X0002 Address 004016 004116 004216 004316 004416 004516 004616 004716 004816 004916 004A16 004B16 004C16 004D16 004E16 004F16 005016 005116 005216 005316 005416 005516 005B16 INT2 interrupt control register Timer X interrupt control register Timer Y interrupt control register Timer Z interrupt control register INT1 interrupt control register INT3 interrupt control register Timer C interrupt control register 005C16 Compare 0 interrupt control register 005D16 INT0 interrupt control register 005616 005716 005816 005916 005A16 005E16 005F16 006016 006116 006216 006316 006416 006516 006616 006716 006816 006916 006A16 006B16 006C16 006D16 006E16 006F16 007016 007116 007216 007316 007416 007516 007616 007716 007816 007916 007A16 007B16 007C16 007D16 007E16 007F16 X : Undefined NOTES: 1. Blank spaces are reserved. No access is allowed. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 11 of 27 R8C/13 Group 4. Special Function Register (SFR) Table 4.3 SFR Information(3)(1) Register Timer Y, Z mode register Prescaler Y register Timer Y secondary register Timer Y primary register Timer Y, Z waveform output control register Prescaler Z register Timer Z secondary register Timer Z primary register Symbol TYZMR PREY TYSC TYPR PUM PREZ TZSC TZPR 0016 FF16 FF16 FF16 0016 FF16 FF16 FF16 Timer Y, Z output control register Timer X mode register Prescaler X register Timer X register Count source set register TYZOC TXMR PREX TX TCSS 0016 0016 FF16 FF16 0016 Timer C register TC 0016 0016 External input enable register INTEN 0016 Key input enable register KIEN 0016 Timer C control register 0 Timer C control register 1 Capture, compare 0 register TCC0 TCC1 TM0 009E16 Compare 1 register TM1 009F16 00A016 UART0 transmit/receive mode register U0MR U0BRG U0TB 0016 0016 0016 0016(2) FF16 FF16 0016 XX16 XX16 X X1 6 000010002 000000102 XX16 XX16 0016 XX16 XX16 X X1 6 000010002 000000102 XX16 X X1 6 0016 Address 008016 008116 008216 008316 008416 008516 008616 008716 After reset 008816 008916 008A16 008B16 008C16 008D16 008E16 008F16 009016 009116 009216 009316 009416 009516 009616 009716 009816 009916 009A16 009B16 009C16 009D16 00A116 00A216 UART0 bit rate register UART0 transmit buffer register 00A316 00A516 UART0 transmit/receive control register 0 UART0 transmit/receive control register 1 00A616 UART0 receive buffer register 00A416 U0C0 U0C1 U0RB 00A716 00A816 UART1 transmit/receive mode register 00A916 UART1 bit rate register UART1 transmit buffer register 00AA16 U1MR U1BRG U1TB 00AB16 00AD16 UART1 transmit/receive control register 0 UART1 transmit/receive control register 1 00AE16 UART1 receive buffer register U1C0 U1C1 U1RB UART transmit/receive control register 2 UCON 00AC16 00AF16 00B016 00B116 00B216 00B316 00B416 00B516 00B616 00B716 00B816 00B916 00BA16 00BB16 00BC16 00BD16 00BE16 00BF16 X : Undefined NOTES: 1. Blank spaces are reserved. No access is allowed. 2. When output compare mode (the TCC13 bit in the TCC1 register = 1) is selected, the value after reset is set to “FFFF16”. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 12 of 27 R8C/13 Group 4. Special Function Register (SFR) Table 4.4 SFR Information(4)(1) Register Address AD register Symbol AD AD control register 2 ADCON2 0016 AD control register 0 AD control register 1 ADCON0 ADCON1 00000XXX2 0016 Port P0 register Port P1 register Port P0 direction register Port P1 direction register P0 P1 PD0 PD1 XX16 XX16 0016 0016 Port P3 register P3 XX16 Port P3 direction register Port P4 register PD3 P4 0016 XX16 Port P4 direction register PD4 0016 00FF16 Pull-up control register 0 Pull-up control register 1 Port P1 drive capacity control register Timer C output control register PUR0 PUR1 DRR TCOUT 00XX00002 XXXXXX0X2 0016 0016 01B316 Flash memory control register 4 FMR4 010000002 Flash memory control register 1 FMR1 1000000X2 01B716 Flash memory control register 0 FMR0 000000012 0FFFF16 Option function select register OFS 00C016 00C116 After reset XX16 X X1 6 00C216 00C316 00C416 00C516 00C616 00C716 00C816 00C916 00CA16 00CB16 00CC16 00CD16 00CE16 00CF16 00D016 00D116 00D216 00D316 00D416 00D516 00D616 00D716 00D816 00D916 00DA16 00DB16 00DC16 00DD16 00DE16 00DF16 00E016 00E116 00E216 00E316 00E416 00E516 00E616 00E716 00E816 00E916 00EA16 00EB16 00EC16 00ED16 00EE16 00EF16 00F016 00F116 00F216 00F316 00F416 00F516 00F616 00F716 00F816 00F916 03FA16 00FB16 00FC16 00FD16 00FE16 01B416 01B516 01B616 (2) (Note 2) X : Undefined NOTES: 1. Blank columns, 010016 to 01B216 and 01B816 to 02FF16 are all reserved. No access is allowed. 2. The watchdog timer control bit is assigned. Refer to "Figure11.2 OFS, WDC, WDTR and WDTS registers" of Hardware Manual for details Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 13 of 27 R8C/13 Group 5. Electrical Characteristics 5. Electrical Characteristics Table 5.1 Absolute Maximum Ratings Condition Rated value Unit VCC Symbol Supply voltage Parameter VCC=AVCC -0.3 to 6.5 V AVCC Analog supply voltage VCC=AVCC -0.3 to 6.5 V VI Input voltage -0.3 to VCC+0.3 V VO Output voltage -0.3 to VCC+0.3 V Pd Power dissipation 300 mW Topr Operating ambient temperature -20 to 85 / -40 to 85 (D version) C Tstg Storage temperature Topr=25 C C -65 to 150 Table 5.2 Recommended Operating Conditions Symbol Parameter VCC AVcc Supply voltage Analog supply voltage Vss Supply voltage Conditions Min. Standard Typ. 2.7 Max. 5.5 VCC(3) 0 Unit V V V V AVss Analog supply voltage VIH "H" input voltage 0.8VCC VCC V VIL "L" input voltage 0 0.2VCC V -60.0 mA -10.0 mA - 5 .0 mA 60 mA 10 mA 30 mA 10 mA mA mA mA MHz MHz I OH (peak) Sum of all pins' IOH "H" peak all output currents (peak) "H" peak output current I OH (avg) "H" average output current I OL (sum) Sum of all pins' IOL "L" peak all output currents (peak) "L" peak output Except P10 to P17 current P10 to P17 I OH (sum) I OL (peak) I OL (avg) f (XIN) "L" average output current 0 Drive ability HIGH Drive ability LOW Except P10 to P17 P10 to P17 Drive ability HIGH Drive ability LOW Main clock input oscillation frequency 3.0V ≤ Vcc ≤ 5.5V 2.7V ≤ Vcc < 3.0V 0 0 NOTES: 1. VCC = AVCC = 2.7 to 5.5V at Topr = -20 to 85 °C / -40 to 85 °C, unless otherwise specified. 2. The typical values when average output current is 100ms. 3. Hold Vcc=AVcc. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 14 of 27 5 15 5 20 10 R8C/13 Group 5. Electrical Characteristics Table 5.3 A/D Conversion Characteristics Symbol Parameter – Resolution – Absolute accuracy RLADDER tCONV VREF VIA Ladder resistance Conversion time Measuring condition Standard Unit Min. Typ. Max. Vref =VCC 10 Bit 10 bit mode øAD=10 MHz, Vref=Vcc=5.0V ±3 LSB 8 bit mode øAD=10 MHz, Vref=Vcc=5.0V ±2 LSB 10 bit mode øAD=10 MHz, Vref=Vcc=3.3V(3) ±5 LSB 8 bit mode Vref=Vcc=3.3V(3) ±2 LSB kΩ 10 bit mode 8 bit mode øAD=10 MHz, VREF=VCC 10 øAD=10 MHz, Vref=Vcc=5.0V 3.3 2.8 øAD=10 MHz, Vref=Vcc=5.0V Reference voltage Analog input voltage 40 µs µs V VCC(4) 0 Vref V 0.25 10 MHz 1.0 10 NOTES: 1. VCC=AVCC=2.7 to 5.5V at Topr = -20 to 85 °C / -40 to 85 °C, unless otherwise specified. 2. If fAD exceeds 10 MHz more, divide the fAD and hold A/D operating clock frequency (ØAD) 10 MHz or below. 3. If the AVcc is less than 4.2V, divide the fAD and hold A/D operating clock frequency (ØAD) fAD/2 or below. 4. Hold Vcc=Vref. MHz – A/D operating Without sample & hold clock frequency(2) With sample & hold P0 P1 P2 P3 P4 Figure 5.1 Port P0 to P4 measurement circuit Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 15 of 27 30pF R8C/13 Group 5. Electrical Characteristics Table 5.4 Flash Memory (Program ROM) Electrical Characteristics Symbol Parameter Measuring condition Min. Standard Typ. Max Unit times – – Program/Erase endurance(2) Byte program time 50 µs – Block erase time 0.4 s td(SR-ES) 1000(3) 8 Time delay from Suspend Request until Erase Suspend ms – Erase Suspend Request Interval 10 – Program, Erase Voltage 2.7 5.5 V – – Read Voltage 2.7 5.5 60 V – Data hold time(7) 0 Program, Erase Temperature Ambient temperature = 55 °C 20 ms °C year NOTES: 1. Referenced to VCC=AVcc=2.7 to 5.5V at Topr = 0°C to 60°C unless otherwise specified. 2. Definition of Program/Erase The endurance of Program/Erase shows a time for each block. If the program/erase number is “n” (n = 1000, 10000), “n” times erase can be performed for each block. For example, if performing one-byte write to the distinct addresses on Block A of 2K-byte block 2048 times and then erasing that block, the number of Program/Erase cycles is one time. However, performing multiple writes to the same address before an erase operation is prohibited (overwriting prohibited). 3. Numbers of Program/Erase cycles for which all electrical characteristics is guaranteed. 4. To reduce the number of Program/Erase cycles, a block erase should ideally be performed after writing in series as many distinct addresses (only one time each) as possible. If programming a set of 16 bytes, write up to 128 sets and then erase them one time. This will result in ideally reducing the number of Program/Erase cycles. Additionally, averaging the number of Program/Erase cycles for Block A and B will be more effective. It is important to track the total number of block erases and restrict the number. 5. If error occurs during block erase, attempt to execute the clear status register command, then the block erase command at least three times until the erase error disappears. 6. Customers desiring Program/Erase failure rate information should contact their Renesas technical support representative. 7. The data hold time includes time that the power supply is off or the clock is not supplied. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 16 of 27 R8C/13 Group 5. Electrical Characteristics Table 5.5 Flash Memory (Data flash Block A, Block B) Electrical Characteristics(4) Symbol Parameter Standard Min. Typ. Measuring condition Program/Erase endurance(2) – Byte program time(program/erase endurance ≤1000 times) 50 – Byte program time(program/erase endurance >1000 times) 65 – Block erase time(program/erase endurance ≤1000 times) Block erase time(program/erase endurance >1000 times) 0.2 td(SR-ES) – – – – – 10000(3) 400 µs µs 9 0.3 Time delay from Suspend Request until Erase Suspend Unit times – – Max s s 8 ms 10 Erase Suspend Request Interval Program, Erase Voltage 2.7 5.5 ms V Read Voltage 2.7 5.5 V -20(-40)(8) Program/Erase Temperature Data hold time(9) Ambient temperature = 55 °C 20 85 °C year NOTES: 1. Referenced to VCC=AVcc=2.7 to 5.5V at Topr = -20°C to 85°C / -40°C to 85°C unless otherwise specified. 2. Definition of Program/Erase The endurance of Program/Erase shows a time for each block. If the program/erase number is “n” (n = 1000, 10000), “n” times erase can be performed for each block. For example, if performing one-byte write to the distinct addresses on Block A of 2K-byte block 2048 times and then erasing that block, the number of Program/Erase cycles is one time. However, performing multiple writes to the same address before an erase operation is prohibited (overwriting prohibited). 3. Numbers of Program/Erase cycles for which all electrical characteristics is guaranteed. 4. Table 5.5 applies for Block A or B when the Program/Erase cycles are more than 1000. The byte program time up to 1000 cycles are the same as that of the program area (see Table 5.4). 5. To reduce the number of Program/Erase cycles, a block erase should ideally be performed after writing in series as many distinct addresses (only one time each) as possible. If programming a set of 16 bytes, write up to 128 sets and then erase them one time. This will result in ideally reducing the number of Program/Erase cycles. Additionally, averaging the number of Program/Erase cycles for Block A and B will be more effective. It is important to track the total number of block erases and restrict the number. 6. If error occurs during block erase, attempt to execute the clear status register command, then the block erase command at least three times until the erase error disappears. 7. Customers desiring Program/Erase failure rate information should contact their Renesas technical support representative. 8. -40 °C for D version. 9. The data hold time includes time that the power supply is off or the clock is not supplied. Erase-suspend request (interrupt request) FMR46 td(SR-ES) Figure 5.2 Time delay from Suspend Request until Erase Suspend Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 17 of 27 R8C/13 Group 5. Electrical Characteristics Table 5.6 Voltage Detection Circuit Electrical Characteristics Symbol Vdet Measuring condition Parameter Voltage detection level Min. Voltage detection interrupt request generating time(2) Microcomputer operation voltage minimum value Unit V µs nA 600 VC27=1, VCC=5.0V Vccmin 4.3 40 Voltage detection circuit self consumption current Waiting time until voltage detection circuit operation starts(3) Max. 3.8 3.3 td(E-A) Standard Typ. 20 µs V 2.7 NOTES: 1. The measuring condition is Vcc=AVcc=2.7V to 5.5V and Topr=-40°C to 85°C. 2. This shows the time until the voltage detection interrupt request is generated since the voltage passes Vdet. 3. This shows the required time until the voltage detection circuit operates when setting to "1" again after setting the VC27 bit in the VCR2 register to “0”. Table 5.7 Reset Circuit Electrical Characteristics (When Using Hardware Reset 2(1, 3)) Symbol Vpor2 Measuring condition Parameter Power-on reset valid voltage tW(Vpor2Supply voltage rising time when power-on reset is canceled(2) Vdet) Min. Standard Typ. Max. Unit –20°C ≤ Topr < 85°C Vdet V –20°C ≤ Topr < 85°C, tW(por2) ≥ 0s(4) 100 ms NOTES: 1. The voltage detection circuit which is embedded in a microcomputer is a factor to generate the hardware reset 2. Refer to 5.1.2 Hardware Reset 2 of Hardware Manual for details. 2. This condition is not applicable when using VCC ≥ 1.0V. 3. When turning power on after the external power has been held below the valid voltage (Vpor1) for greater than 10 seconds, refer to Table 5.8 Reset Circuit Electrical Characteristics (When Not Using Hardware Reset 2). 4. tw(por2) is time to hold the external power below effective voltage (Vpor2). Table 5.8 Reset Circuit Electrical Characteristics (When Not Using Hardware Reset 2) Symbol Vpor1 Measuring condition Parameter Min. Standard Typ. Max. –20°C ≤ Topr < 85°C Power-on reset valid voltage tW(Vpor1- Supply voltage rising time when power-on reset is canceled Vdet) 0°C ≤ Topr ≤ 85°C, tW(por1) ≥ tW(Vpor1Vdet) Supply voltage rising time when power-on reset is canceled –20°C ≤ Topr < 0°C, tW(por1) ≥ 30s(2) tW(Vpor1Vdet) Supply voltage rising time when power-on reset is canceled tW(Vpor1- Supply voltage rising time when power-on reset is canceled Vdet) –20°C ≤ Topr < 0°C, tW(por1) ≥ 10s(2) 10s(2) 0°C ≤ Topr ≤ 85°C, tW(por1) ≥ 1s(2) NOTES: 1. When not using hardware reset 2, use with Vcc ≥ 2.7V. 2. tw(por1) is time to hold the external power below effective voltage (Vpor1). Vdet(3) Vdet(3) Vcc min Vpor2 Vpor1 Sampling time(1,2) tw(por2) tw(Vpor2 –Vdet) tw(por1) tw(Vpor1–Vdet) Internal reset signal (“L” effective) 1 X 32 fRING-S 1 X 32 fRING-S NOTES: 1. Hold the voltage of the microcomputer operation voltage range (Vccmin or above) within sampling time. 2. A sampling clock is selectable. Refer to “5.4 Voltage Detection Circuit” of Hardware manual for details. 3. Vdet shows the voltage detection level of the voltage detection circuit. Refer to “5.4 Voltage Detection Circuit” of Hardware manual for details. Figure 5.3 Reset Circuit Electrical Characteristics Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 18 of 27 Unit 0.1 V 100 ms 100 ms 1 ms 0.5 ms R8C/13 Group 5. Electrical Characteristics Table 5.9 High-speed On-Chip Oscillator Circuit Electrical Characteristics Symbol Measuring condition Parameter High-speed on-chip oscillator frequency 1 / {td(HRoffset)+td(HR)} when the reset is released td(HRoffset) Settable high-speed on-chip oscillator minimum period td(HR) Min. VCC=5.0V, Topr=25 °C Set "4016" in the HR1 register VCC=5.0V, Topr=25 °C Set "0016" in the HR1 register Differences when setting "0116" and "0016" in the HR register High-speed on-chip oscillator period adjusted unit Standard Typ. Max. Unit 8 MHz 61 ns 1 ns High-speed on-chip oscillator frequency temperature dependence(1) Frequency fluctuation in temperature range of -10 °C to 50 °C ±5 % High-speed on-chip oscillator frequency temperature dependence(2) Frequency fluctuation in temperature range of -40 °C to 85 °C ±10 % NOTES: 1. The measuring condition is Vcc=AVcc=5.0 V and Topr=25 °C. Table 5.10 Power Circuit Timing Characteristics Symbol Measuring condition Parameter td(P-R) Time for internal power supply stabilization during powering-on(2) td(R-S) STOP release time(3) Min. Standard Typ. 1 Max. Unit 2000 µs 150 µs NOTES: 1. The measuring condition is Vcc=AVcc=2.7 to 5.5 V and Topr=25 °C. 2. This shows the wait time until the internal power supply generating circuit is stabilized during power-on. 3. This shows the time until BCLK starts from the interrupt acknowledgement to cancel stop mode. Table 5.11 Electrical Characteristics (1) Symbol [Vcc=5V] Measuring condition Parameter "H" output voltage Except XOUT IOH=-5mA IOH=-200µA XOUT Drive capacity HIGH Drive capacity LOW Except P10 to P17, XOUT VOH "L" output voltage VOL P10 to P17 XOUT Hysteresis II H "H" input current VCC-2.0 VCC-0.3 VCC-2.0 VCC-2.0 IOL= 5 mA 2 .0 V IOL= 200 µA 0.45 V 2 .0 Drive capacity HIGH IOH=-1 mA IOH=-500µA I O L= 1 5 m A Drive capacity LOW IOL= 5 mA 2.0 V V Drive capacity LOW IOL= 200 µA 0.45 V Drive capacity HIGH IOL= 1 mA IOL=500 µA 2 .0 V 2 .0 V V 0 .2 INT0, INT1, INT2, INT3, KI0, KI1, KI2, KI3, CNTRo, CNTR1, TCIN, RxD0, RxD1, P45 1.0 0.2 II L "L" input current VI=5V VI=0V RPULLUP Pull-up resistance VI=0V RfXIN Feedback resistance fRING-S Low-speed on-chip oscillator frequency VRAM RAM retention voltage At stop mode NOTES: 1. Referenced to VCC = AVCC = 4.2 to 5.5V at Topr = -20 to 85 °C / -40 to 85 °C, f(XIN)=20MHz unless otherwise specified. 2.2 V 5.0 µA µA -5.0 30 50 40 1.0 125 XIN page 19 of 27 Unit V V V V RESET Rev.1.20 Jan 27, 2006 REJ03B0069-0120 Standard Max. Typ. VCC VC C VCC VC C Drive capacity LOW VT+-VT- Min. 2 .0 167 kΩ MΩ 250 kHz V R8C/13 Group 5. Electrical Characteristics Table 5.12 Electrical Characteristics (2) Symbol [Vcc=5V] Measuring condition Parameter High-speed mode Medium-speed mode ICC Power supply current (VCC=3.3 to 5.5V) In single-chip mode, the output pins are open and other pins are VSS XIN=20 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz No division XIN=16 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz No division XIN=10 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz No division XIN=20 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz Division by 8 XIN=16 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz Division by 8 XIN=10 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz Division by 8 Main clock off High-speed High-speed on-chip oscillator on=8 MHz on-chip oscillator Low-speed on-chip oscillator on=125 kHz mode No division Max. Unit 9 15 mA 8 14 mA 5 mA 4 mA 3 mA 2 mA 4 8 mA 1.5 Main clock off Low-speed High-speed on-chip oscillator off on-chip oscillator Low-speed on-chip oscillator on=125 kHz mode Division by 8 470 900 µA 40 80 µA 38 76 µA 0.8 3.0 µA Wait mode Stop mode Main clock off High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz When a WAIT instruction is executed(1) Peripheral clock operation VC27="0" Main clock off High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz When a WAIT instruction is executed(1) Peripheral clock off VC27="0" Main clock off, Topr=-25 °C High-speed on-chip oscillator off Low-speed on-chip oscillator off CM10="1" Peripheral clock off VC27="0" NOTES: 1. Timer Y is operated with timer mode. 2. Referenced to VCC = AVCC = 4.2 to 5.5V at Topr = -20 to 85 °C / -40 to 85 °C, f(XIN)=20MHz unless otherwise specified. page 20 of 27 Standard Typ. Main clock off High-speed on-chip oscillator on=8 MHz Low-speed on-chip oscillator on=125 kHz Division by 8 Wait mode Rev.1.20 Jan 27, 2006 REJ03B0069-0120 Min. mA R8C/13 Group 5. Electrical Characteristics Timing requirements [VCC=5V] (Unless otherwise noted: VCC = 5V, VSS = 0V at Topr = 25 °C) Table 5.13 XIN input Symbol tC(XIN) tWH(XIN) tWL(XIN) Parameter XIN input cycle time XIN input HIGH pulse width XIN input LOW pulse width Standard Min. Max. 50 – 25 – 25 – Unit Standard Min. Max. 100 – 40 – 40 – Unit Standard Max. Min. 400(1) – 200(2) – 200(2) – Unit Standard Min. Max. 200 – 100 – 100 – 80 – 0 – 35 – 90 – Unit Standard Max. Min. 250(1) – 250(2) – Unit ns ns ns ________ Table 5.14 CNTR0 input, CNTR1 input, INT2 input Symbol tC(CNTR0) tWH(CNTR0) tWL(CNTR0) Parameter CNTR0 input cycle time CNTR0 input HIGH pulse width CNTR0 input LOW pulse width ns ns ns ________ Table 5.15 TCIN input, INT3 input Symbol Parameter tC(TCIN) ns TCIN input cycle time tWH(TCIN) ns TCIN input HIGH pulse width tWL(TCIN) ns TCIN input LOW pulse width NOTES: 1. When using the Timer C input capture mode, adjust the cycle time above ( 1/ Timer C count source frequency x 3). 2. When using the Timer C input capture mode, adjust the pulse width above ( 1/ Timer C count source frequency x 1.5). Table 5.5 Serial Interface Symbol tC(CK) tW(CKH) tW(CKL) td(C-Q) th(C-Q) tsu(D-C) th(C-D) Parameter CLKi input cycle time CLKi input HIGH pulse width CLKi input LOW pulse width TxDi output delay time TxDi hold time RxDi input setup time RxDi input hold time ns ns ns ns ns ns ns ________ Table 5.17 External interrupt INT0 input Symbol tW(INH) tW(INL) Parameter ________ INT0 input HIGH pulse width ________ INT0 input LOW pulse width ns ns NOTES: ________ ________ 1. When selecting the digital filter by the INT0 input filter select bit, use the INT0 input HIGH pulse width to the greater value,either ( 1/ digital filter clock frequency x 3) or the minimum value of standard. ________ ________ 2. When selecting the digital filter by the INT0 input filter select bit, use the INT0 input LOW pusle width to the greater value,either ( 1/ digital filter clock frequency x 3) or the minimum value of standard. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 21 of 27 R8C/13 Group 5. Electrical Characteristics VCC = 5V tc(CNTR0) tWH(CNTR0) CNTR0 input tWL(CNTR0) tc(TCIN) tWH(TCIN) TCIN input tWL(TCIN) tc(XIN) tWH(XIN) XIN input tWL(XIN) tc(CK) tW(CKH) CLKi tW(CKL) th(C-Q) TxDi td(C-Q) tsu(D-C) RxDi tW(INL) INTi tW(INH) Figure 5.4 Vcc=5V timing diagram Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 22 of 27 th(C-D) R8C/13 Group 5. Electrical Characteristics Table 5.18 Electrical Characteristics (3) Symbol [Vcc=3V] Measuring condition Parameter "H" output voltage VOH "L" output voltage VOL Except XOUT IOH=-1mA XOUT Drive capacity HIGH Drive capacity LOW Except P10 to P17, XOUT IOL= 1 mA P10 to P17 Drive capacity HIGH Drive capacity LOW XOUT Drive capacity HIGH Drive capacity LOW VT+-VT- Hysteresis II H "H" input current Min. VCC-0.5 V 0 .5 V IOL= 2 mA IOL= 1 mA 0 .5 V 0 .5 V IOL= 0.1 mA IOL=50 µ A 0 .5 0 .5 V V 0.2 0 .8 V 0.2 1 .8 4.0 V µA -4.0 µA IOH=-0.1 mA IOH=-50 µA VCC-0.5 VCC-0.5 RESET II L "L" input current RPULLUP RfXIN Pull-up resistance VI=0V fRING-S Low-speed on-chip oscillator frequency VRAM RAM retention voltage Feedback resistance 66 160 40 3.0 125 XIN At stop mode NOTES: 1. Referenced to VCC = AVCC = 2.7 to 3.3V at Topr = -20 to 85 °C / -40 to 85 °C, f(XIN)=10MHz unless otherwise specified. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 23 of 27 Unit VCC VCC VCC INTo, INT1, INT2, INT3, KI0, KI1, KI2, KI3, CNTR0, CNTR1, TCIN, RxD0, RxD1, P45 VI=3V VI=0V Standard Max. Typ. 2 .0 V V 500 kΩ 250 MΩ kHz V R8C/13 Group 5. Electrical Characteristics Table 5.19 Electrical Characteristics (4) Symbol [Vcc=3V] Measuring condition Parameter High-speed mode Medium-speed mode ICC Power supply current (VCC=2.7 to 3.3V) In single-chip mode, the output pins are open and other pins are VSS XIN=20 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz No division XIN=16 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz No division XIN=10 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz No division XIN=20 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz Division by 8 XIN=16 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz Division by 8 XIN=10 MHz (square wave) High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz Division by 8 Max. 8 13 mA 7 12 mA Unit 5 mA 3 mA 2 .5 mA 1 .6 mA 3 .5 Main clock off High-speed on-chip oscillator on=8 MHz Low-speed on-chip oscillator on=125 kHz Division by 8 1.5 Main clock off Low-speed High-speed on-chip oscillator off on-chip oscillator Low-speed on-chip oscillator on=125 kHz mode Division by 8 420 800 µA Main clock off High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz When a WAIT instruction is executed(1) Peripheral clock operation VC27="0" 37 74 µA Main clock off High-speed on-chip oscillator off Low-speed on-chip oscillator on=125 kHz When a WAIT instruction is executed(1) Peripheral clock off VC27="0" 35 70 µA Main clock off, Topr=-25 °C High-speed on-chip oscillator off Low-speed on-chip oscillator off CM10="1" Peripheral clock off VC27="0" 0.7 3.0 µA Wait mode Stop mode NOTES: 1. Timer Y is operated with timer mode. 2. Referenced to VCC = AVCC = 2.7 to 3.3V at Topr = -20 to 85 °C / -40 to 85 °C, f(XIN)=10MHz unless otherwise specified. page 24 of 27 Standard Typ. Main clock off High-speed High-speed on-chip oscillator on=8 MHz on-chip oscillator Low-speed on-chip oscillator on=125 kHz mode No division Wait mode Rev.1.20 Jan 27, 2006 REJ03B0069-0120 Min. 7 .5 mA mA R8C/13 Group 5. Electrical Characteristics Timing requirements [VCC=3V] (Unless otherwise noted: VCC = 3V, VSS = 0V at Topr = 25 °C) Table 5.20 XIN input Symbol tC(XIN) tWH(XIN) tWL(XIN) Parameter XIN input cycle time XIN input HIGH pulse width XIN input LOW pulse width Standard Min. Max. 100 – 40 – 40 – Unit Standard Min. Max. 300 – 120 – 120 – Unit Standard Min. Max. 1200(1) – 600(2) – 600(2) – Unit Standard Min. Max. 300 – 150 – 150 – 160 – 0 – 55 – 90 – Unit Standard Min. Max. 380(1) – 380(2) – Unit ns ns ns ________ Table 5.21 CNTR0 input, CNTR1 input, INT2 input Symbol tC(CNTR0) tWH(CNTR0) tWL(CNTR0) Parameter CNTR0 input cycle time CNTR0 input HIGH pulse width CNTR0 input LOW pulse width ns ns ns ________ Table 5.22 TCIN input, INT3 input Symbol Parameter tC(TCIN) ns TCIN input cycle time tWH(TCIN) ns TCIN input HIGH pulse width tWL(TCIN) ns TCIN input LOW pulse width NOTES: 1. When using the Timer C input capture mode, adjust the cycle time above ( 1/ Timer C count source frequency x 3). 2. When using the Timer C input capture mode, adjust the pulse width above ( 1/ Timer C count source frequency x 1.5). Table 5.23 Serial Interface Symbol tC(CK) tW(CKH) tW(CKL) td(C-Q) th(C-Q) tsu(D-C) th(C-D) Parameter CLKi input cycle time CLKi input HIGH pulse width CLKi input LOW pulse width TxDi output delay time TxDi hold time RxDi input setup time RxDi input hold time ns ns ns ns ns ns ns ________ Table 5.24 External interrupt INT0 input Symbol Parameter ________ tW(INH) ns INT0 input HIGH pulse width ________ tW(INL) ns INT0 input LOW pulse width NOTES: ________ ________ 1. When selecting the digital filter by the INT0 input filter select bit, use the INT0 input HIGH pulse width to the greater value,either ( 1/ digital filter clock frequency x 3) or the minimum value of standard. ________ ________ 2 . When selecting the digital filter by the INT0 input filter select bit, use the INT0 input LOW pusle width to the greater value,either ( 1/ digital filter clock frequency x 3) or the minimum value of standard. Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 25 of 27 R8C/13 Group 5. Electrical Characteristics VCC = 3V tc(CNTR0) tWH(CNTR0) CNTR0 input tWL(CNTR0) tc(TCIN) tWH(TCIN) TCIN input tWL(TCIN) tc(XIN) tWH(XIN) XIN input tWL(XIN) tc(CK) tW(CKH) CLKi tW(CKL) th(C-Q) TxDi td(C-Q) tsu(D-C) RxDi tW(INL) INTi tW(INH) Figure 5.5 Vcc=3V timing diagram Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 26 of 27 th(C-D) R8C/13 Group Package Dimensions Package Dimensions JEITA Package Code P-LQFP32-7x7-0.80 RENESAS Code PLQP0032GB-A Previous Code 32P6U-A MASS[Typ.] 0.2g HD *1 D 24 17 NOTE) 1. DIMENSIONS "*1" AND "*2" DO NOT INCLUDE MOLD FLASH. 2. DIMENSION "*3" DOES NOT INCLUDE TRIM OFFSET. 16 25 bp c c1 HE *2 E b1 Reference Symbol 9 1 ZE Terminal cross section 32 8 ZD c A A1 F A2 Index mark L D E A2 HD HE A A1 bp b1 c c1 L1 y e Rev.1.20 Jan 27, 2006 REJ03B0069-0120 page 27 of 27 *3 Detail F bp x e x y ZD ZE L L1 Dimension in Millimeters Min Nom Max 6.9 7.0 7.1 6.9 7.0 7.1 1.4 8.8 9.0 9.2 8.8 9.0 9.2 1.7 0.1 0.2 0 0.32 0.37 0.42 0.35 0.09 0.145 0.20 0.125 0° 8° 0.8 0.20 0.10 0.7 0.7 0.3 0.5 0.7 1.0 REVISION HISTORY Rev. R8C/13 Group Datasheet Date Description Summary Page First edition issued 0.10 Oct 28, 2003 0.20 Dec05, 2003 5 Figure 1.3 revised 10 Chapter 4, NOTES revised 16 Table 5.4 revised Table 5.5 revised 17 Table 5.6 revised Figure 5.3 added 18 Table 5.8 revised Table 5.10 revised 21 Figure 5.3 revised to Figure 5.4 22 Table 5.17 revised 25 Figure 5.4 revised to Figure 5.5 1.00 Sep 30, 2004 All pages Words standardized (on-chip oscillator, serial interface, A/D) 2 Table 1.1 revised Figure 1.3, NOTES 3 added 5 Table 1.3 revised 6 Figure 3.1, NOTES added 9 One body sentence in chapter 4 added ; Titles of Table 4.1 to 4.4 added 10-13 Table 4.3 revised ; Table 4.4 revised 12 Table 5.2 revised 14 Table 5.3 revised 15 Table 5.4 and Table 5.5 revised 16 Table 5.6, 5.7 and 5.8 revised ; Figure 5.3 revised 17 Table 5.9 and 5.11 revised 18 Table 5.12 revised 19 Table 5.13 revised 20 Table 5.18 revised 22 Table 5.19 revised 23 Table 5.20 and Table 5.24 revised 24 1.10 Apr.27.2005 4 5 10 12 15 16 Table 1.2, Figure 1.2 package name revised Figure 1.3 package name revised Table 4.1 revised Table 4.3 revised Table 5.3 partly revised Table 5.4, Table 5.5 partly added A-1 REVISION HISTORY Rev. R8C/13 Group Datasheet Date Description Summary Page 1.10 Apr.27.2005 17 18 22 26 Table 5.7, 5.8 revised Table 5.10, Table 5.11 partly revised Table 5.18 partly revised Package Dimensions revised 1.20 Jan.27.2006 2 3 4 Table 1.1 Performance outline revised Figure 1.1 Block diagram partly revised 1.4 Product Information, title of Table 1.2 “Product List” → “Product Informaton” revised ROM capacity; “Program area” → “Program ROM”, “Data area” → “Data flash” revised Figure 1.2 Type No., Memory Size, and Package partly revised Table 1.3 Pin description revised 2 Central Processing Unit (CPU) revised Figure 2.1 CPU register revised 3 Memory, Figure 3.1 Memory Map; “Program area” → “Program ROM”, “Data area” → “Data flash” revised Table 4.1 SFR Information(1) NOTES:1 revised Table 4.2 SFR Information(2) NOTES:1 revised Table 4.3 SFR Information(3); 008116: “Prescaler Y” → “Prescaler Y Register” 008216: “Timer Y Secondary” → “Timer Y Secondary Register” 008316: “Timer Y Primary” → “Timer Y Primary Register” 008516: “Prescaler Z” → “Prescaler Z Register” 008616: “Timer Z Secondary” → “Timer Z Secondary Register” 008716: “Timer Z Primary” → “Timer Z Primary Register” 008C16: “Prescaler X” → “Prescaler X Register” revised NOTES:1, 2 revised Table 4.4 SFR Information(4) NOTES:1 revised Table 5.2 Recommended Operating Conditions; NOTES: 1, 2, 3 revised Table 5.3 A/D Conversion Characteristics; “A/D operation clock frequency” → “A/D operating clock frequency” revised NOTES: 1, 2, 3, 4 revised Table 5.4 Flash Memory (Program ROM) Electrical Characteristics; “Data retention duration” → “Data hold time” revised “Topr” → “Ambient temperature” NOTES: 1 to 7 added Measuring condition of byte program time and block erase time deleted Table 5.5 Flash Memory (Data flash Block A, Block B) Electrical characteristics “Data retention duration” → “Data hold time” revised “Topr” → “Ambient temperature” NOTES: 1, 3 revised, NOTES: 9 added Measuring condition of byte program time and block erase time deleted Table 5.7 Reset Circuit Electrical Characteristics (When Using Hardware Reset 2) NOTES: 3 revised Table 5.9 High-speed On-Chip Oscillator Circuit Electrical Characteristics; “High-speed on-chip oscillator temperature dependence” → “High-speed on-chip oscillator frequency temperature dependence” revised Table 5.11 Electrical Characteristics (1) [VCC=5V]; “P10 to P17 Except XOUT” → “Except P10 to P17, XOUT” revised 6 7-8 9 10 11 12 13 14 15 16 17 18 19 A-2 REVISION HISTORY Rev. R8C/13 Group Datasheet Date Description Summary Page 1.20 Jan.27.2006 20 23 24 Table 5.12 Electrical Characteristics (2) [VCC=5V]; NOTES: 1, 2 revised Measuring condition Stop mode: “Topr=-25 °C” added Table 5.18 Electrical Characteristics (3) [VCC=3V] “P10 to P17 Except XOUT” → “Except P10 to P17, XOUT” revised Table 5.19 Electrical Characteristics (4) [VCC=3V] NOTES: 1, 2 revised Measuring condition Stop mode: “Topr=-25 °C” added A-3 Sales Strategic Planning Div. Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan Keep safety first in your circuit designs! 1. Renesas Technology Corp. puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap. Notes regarding these materials 1. These materials are intended as a reference to assist our customers in the selection of the Renesas Technology Corp. product best suited to the customer's application; they do not convey any license under any intellectual property rights, or any other rights, belonging to Renesas Technology Corp. or a third party. 2. Renesas Technology Corp. assumes no responsibility for any damage, or infringement of any third-party's rights, originating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples contained in these materials. 3. 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