M30626SPGP#U3C Renesas Electronics America, M30626SPGP#U3C Datasheet - Page 230

IC M16C/62P MCU ROMLESS 100LQFP

M30626SPGP#U3C

Manufacturer Part Number

M30626SPGP#U3C

Description

IC M16C/62P MCU ROMLESS 100LQFP

Manufacturer

Renesas Electronics America

Series

M16C™ M16C/60r

Datasheet

1.M30620SPGPU3C.pdf (423 pages)

Specifications of M30626SPGP#U3C

Core Processor

M16C/60

Core Size

16-Bit

Speed

24MHz

Connectivity

I²C, IEBus, UART/USART

Peripherals

DMA, WDT

Number Of I /o

50

Program Memory Type

ROMless

Ram Size

31K x 8

Voltage - Supply (vcc/vdd)

2.7 V ~ 5.5 V

Data Converters

A/D 26x10b; D/A 2x8b

Oscillator Type

Internal

Operating Temperature

-40°C ~ 85°C

Package / Case

100-LQFP

For Use With

867-1000 - KIT QUICK START RENESAS 62PR0K33062PS001BE - R0K33062P STARTER KITR0K33062PS000BE - KIT EVAL STARTER FOR M16C/62PM3062PT3-CPE-3 - EMULATOR COMPACT M16C/62P/30P

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Eeprom Size

-

Program Memory Size

-

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Part Number:

M30626SPGP#U3C

Manufacturer:

Renesas Electronics America

Quantity:

10 000

Company:

Part Number:

M30626SPGP#U3CM30626SPGP#U5C

Manufacturer:

Renesas Electronics America

Quantity:

10 000

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M16C/62P Group (M16C/62P, M16C/62PT)

Rev.2.41

REJ09B0185-0241

17.1.3.4

17.1.3.5

17.1.3.6

17.1.3.7

Data is transmitted/received using a transfer clock like the one shown in Figure 17.26 Transfer to UiRB

Register and Interrupt Timing.

The CSC bit in the UiSMR2 register is used to synchronize the internally generated clock (internal SCLi) and

an external clock supplied to the SCLi pin. In cases when the CSC bit is set to “1” (clock synchronization

enabled), if a falling edge on the SCLi pin is detected while the internal SCLi is high, the internal SCLi goes

low, at which time the value of the UiBRG register is reloaded with and starts counting in the low-level interval.

If the internal SCLi changes state from low to high while the SCLi pin is low, counting stops, and when the

SCLi pin goes high, counting restarts.

In this way, the UARTi transfer clock is comprised of the logical product of the internal SCLi and SCLi pin

signal. The transfer clock works from a half period before the falling edge of the internal SCLi 1st bit to the

rising edge of the 9th bit. To use this function, select an internal clock for the transfer clock.

The SWC bit in the UiSMR2 register allows to select whether the SCLi pin should be fixed to or freed from

low-level output at the falling edge of the 9th clock pulse.

If the SCLHI bit in the UiSMR4 register is set to “1” (enabled), SCLi output is turned off (placed in the high-

impedance state) when a stop condition is detected.

Setting the SWC2 bit in the UiSMR2 register = 1 (0 output) makes it possible to forcibly output a low-level

signal from the SCLi pin even while sending or receiving data. Clearing the SWC2 bit to “0” (transfer clock)

allows the transfer clock to be output from or supplied to the SCLi pin, instead of outputting a low-level signal.

If the SWC9 bit in the UiSMR4 register is set to “1” (SCL hold low enabled) when the CKPH bit in the

UiSMR3 register = 1, the SCLi pin is fixed to low-level output at the falling edge of the clock pulse next to the

9th. Setting the SWC9 bit = 0 (SCL hold low disabled) frees the SCLi pin from low-level output.

The data written to the UiTB register bit 7 to bit 0 (D7 to D0) is sequentially output beginning with D7.

The 9th bit (D8) is ACK or NACK.

The initial value of SDAi transmit output can only be set when IICM = 1 (I

bits in the UiMR register = 000b (Serial interface disabled).

The DL2 to DL0 bits in the UiSMR3 register allow to add no delays or a delay of 2 to 8 UiBRG count source

clock cycles to SDAi output.

Setting the SDHI bit in the UiSMR2 register = 1 (SDA output disabled) forcibly places the SDAi pin in the

high-impedance state. Do not write to the SDHI bit synchronously with the rising edge of the UARTi transfer

clock. This is because the ABT bit may inadvertently be set to “1” (detected).

When the IICM2 bit = 0, the 1st to 8th bits (D7 to D0) of received data are stored in the UiRB register bit 7 to

bit 0. The 9th bit (D8) is ACK or NACK.

When the IICM2 bit = 1, the 1st to 7th bits (D7 to D1) of received data are stored in the UiRB register bit 6 to

bit 0 and the 8th bit (D0) is stored in the UiRB register bit 8. Even when the IICM2 bit = 1, providing the CKPH

bit = 1, the same data as when the IICM2 bit = 0 can be read out by reading the UiRB register after the rising

edge of the corresponding clock pulse of 9th bit.

If the STSPSEL bit in the UiSMR4 register is set to “0” (start and stop conditions not generated) and the ACKC

bit in the UiSMR4 register is set to “1” (ACK data output), the value of the ACKD bit in the UiSMR4 register is

output from the SDAi pin.

If the IICM2 bit = 0, a NACK interrupt request is generated if the SDAi pin remains high at the rising edge of

the 9th bit of transmit clock pulse. An ACK interrupt request is generated if the SDAi pin is low at the rising

edge of the 9th bit of transmit clock pulse.

If ACKi is selected for the factor of DMA1 request, a DMA transfer can be activated by detection of an

acknowledge.

Jan 10, 2006

Transfer Clock

SDA Output

SDA Input

ACK and NACK

Page 213 of 390

2

C mode) and the SMD2 to SMD0

17. Serial Interface

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