M30626FJPGP#U3C Renesas Electronics America, M30626FJPGP#U3C Datasheet - Page 111

M30626FJPGP#U3C

Manufacturer Part Number

M30626FJPGP#U3C

Description

IC M16C MCU FLASH 512K 100LQFP

Manufacturer

Renesas Electronics America

Series

M16C™ M16C/60r

Datasheets

1.QSK-62P_PLUS.pdf (103 pages)

2.M30622SAFPU5.pdf (308 pages)

3.M30620SPGPU3C.pdf (423 pages)

Specifications of M30626FJPGP#U3C

Core Processor

M16C/60

Core Size

16-Bit

Speed

24MHz

Connectivity

I²C, IEBus, UART/USART

Peripherals

DMA, WDT

Number Of I /o

Program Memory Size

512KB (512K x 8)

Program Memory Type

FLASH

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

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

Rev.2.41

REJ09B0185-0241

10.4

10.4.1

Normal operating mode, wait mode and stop mode are provided as the power consumption control. All mode

states, except wait mode and stop mode, are called normal operating mode in this document.

10.4.1.1

10.4.1.2

10.4.1.3

10.4.1.4

10.4.1.5

10.4.1.6

Normal operating mode is further classified into seven modes.

In normal operating mode, because the CPU clock and the peripheral function clocks both are on, the CPU and

the peripheral functions are operating. Power control is exercised by controlling the CPU clock frequency. The

higher the CPU clock frequency, the greater the processing capability. The lower the CPU clock frequency, the

smaller the power consumption in the chip. If the unnecessary oscillator circuits are turned off, the power

consumption is further reduced.

Before the clock sources for the CPU clock can be switched over, the new clock source to which switched must

be oscillating stably. If the new clock source is the main clock, sub clock or PLL clock, allow a sufficient wait

time in a program until it becomes oscillating stably.

Note that operating modes cannot be changed directly from low speed or low power dissipation mode to on-

chip oscillator or on-chip oscillator low power dissipation mode. Nor can operating modes be changed directly

from on-chip oscillator or on-chip oscillator low power dissipation mode to low speed or low power dissipation

mode. Where the CPU clock source is changed from the on-chip oscillator to the main clock, change the

operating mode to the medium speed mode (divided by 8 mode) after the clock was divided by 8 (the CM06 bit

in the CM0 register was set to “1”) in the on-chip oscillator mode.

The main clock divided by 1 provides the CPU clock. If the sub clock is on, fC32 can be used as the count

source for Timers A and B.

The main clock multiplied by 2, 4, 6 or 8 provides the PLL clock, and this PLL clock serves as the CPU clock.

If the sub clock is on, fC32 can be used as the count source for Timers A and B. PLL operating mode can be

entered from high speed mode. If PLL operating mode is to be changed to wait or stop mode, first go to high

speed mode before changing.

The main clock divided by 2, 4, 8 or 16 provides the CPU clock. If the sub clock is on, fC32 can be used as the

count source for Timers A and B.

The sub clock provides the CPU clock. The main clock is used as the clock source for the peripheral function

clock when the CM21 bit in the CM2 register is set to “0” (on-chip oscillator turned off), and the on-chip

oscillator clock is used when the CM21 bit is set to “1” (on-chip oscillator oscillating).

The fC32 clock can be used as the count source for Timers A and B.

In this mode, the main clock is turned off after being placed in low speed mode. The sub clock provides the

CPU clock. The fC32 clock can be used as the count source for Timers A and B.

Simultaneously when this mode is selected, the CM06 bit becomes “1” (divided by 8 mode). In the low power

dissipation mode, do not change the CM06 bit. Consequently, the medium speed (divided by 8) mode is to be

selected when the main clock is operated next

The on-chip oscillator clock divided by 1 (undivided), 2, 4, 8 or 16 provides the CPU clock. The on-chip

oscillator clock is also the clock source for the peripheral function clocks. If the sub clock is on, fC32 can be

used as the count source for Timers A and B. When the operating mode is returned to the high and medium

speed modes, set the CM06 bit in the CM0 register to “1” (divided by 8 mode).

Power Control

Jan 10, 2006

Normal Operating Mode

High-speed Mode

Medium-Speed Mode

Low Power Dissipation Mode

Low-Speed Mode

On-chip Oscillator Mode

PLL Operating Mode

Page 94 of 390

10. Clock Generation Circuit

M30626FJPGP#U3C Renesas Electronics America, M30626FJPGP#U3C Datasheet - Page 111

M30626FJPGP#U3C

Specifications of M30626FJPGP#U3C

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