HD6417750RF240DV Datasheet, PDF(350/1132 Page) Renesas Technology Corp – Renesas 32-Bit RISC Microcomputer SuperH™ RISC engine Family / SH7750 Series

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HD6417750RF240DV Datasheet, PDF (350/1132 Pages) Renesas Technology Corp – Renesas 32-Bit RISC Microcomputer SuperH™ RISC engine Family / SH7750 Series

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Section 10 Clock Oscillation Circuits

SH7750, SH7750S, SH7750R Group

10.5 Changing the Frequency

There are two methods of changing the internal clock frequency: by changing stopping and

starting of PLL circuit 1, and by changing the frequency division ratio of each clock. In both

cases, control is performed by software by means of the frequency control register. These methods

are described below.

10.5.1 Changing PLL Circuit 1 Starting/Stopping (When PLL Circuit 2 Is Off)

When PLL circuit 1 is changed from the stopped to started state, a PLL stabilization time is

required. The oscillation stabilization time count is performed by the on-chip WDT.

1. Set a value in WDT to provide the specified oscillation stabilization time, and stop the WDT.

The following settings are necessary:

WTCSR register TME bit = 0: WDT stopped

WTCSR register CKS2âCKS0 bits: WDT count clock division ratio

WTCNT counter: Initial counter value

2. Set the PLL1EN bit to 1.

3. Internal processor operation stops temporarily, and the WDT starts counting up. The internal

clock stops and an unstable clock is output to the CKIO pin.

4. After the WDT count overflows, clock supply begins within the chip and the processor

resumes operation. The WDT stops after overflowing.

10.5.2 Changing PLL Circuit 1 Starting/Stopping (When PLL Circuit 2 Is On)

When PLL circuit 2 is on, a PLL circuit 1 and PLL circuit 2 oscillation stabilization time is

required.

1. Make WDT settings as in section 10.5.1.

2. Set the PLL1EN bit to 1.

3. Internal processor operation stops temporarily, PLL circuit 1 oscillates, and the WDT starts

counting up. The internal clock stops and an unstable clock is output to the CKIO pin.

4. After the WDT count overflows, PLL circuit 2 starts oscillating. The WDT resumes its up-

count from the value set in step 1 above. During this time, also, the internal clock is stopped

and an unstable clock is output to the CKIO pin.

5. After the WDT count overflows, clock supply begins within the chip and the processor

resumes operation. The WDT stops after overflowing.

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R01UH0456EJ0702 Rev. 7.02

Sep 24, 2013

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