PIC16F737-I Datasheet, PDF(47/276 Page) Microchip Technology – 28/40/44-Pin, 8-Bit CMOS Flash Microcontrollers with 10-Bit A/D and nanoWatt Technology

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PIC16F737-I Datasheet, PDF (47/276 Pages) Microchip Technology – 28/40/44-Pin, 8-Bit CMOS Flash Microcontrollers with 10-Bit A/D and nanoWatt Technology

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PIC16F7X7

4.7.3.2

Returning to Primary Oscillator with

a Reset

A Reset will clear SCS<1:0> back to â00â. The

sequence for starting the primary oscillator following a

Reset is the same for all forms of Reset, including

POR. There is no transition sequence from the

alternate system clock to the primary system clock on

a Reset condition. Instead, the device will reset the

state of the OSCCON register and default to the

primary system clock. The sequence of events that

take place after this will depend upon the value of the

FOSC bits in the Configuration register. If the external

oscillator is configured as a crystal (HS, XT or LP), the

CPU will be held in the Q1 state until 1024 clock cycles

have transpired on the primary clock. This is

necessary because the crystal oscillator had been

powered down until the time of the transition.

During the oscillator start-up time, instruction

execution and/or peripheral operation is suspended.

Note:

If Two-Speed Clock Start-up mode is

enabled, the INTRC will act as the system

clock until the Oscillator Start-up Timer has

timed out.

If the primary system clock is either RC, EC or INTRC,

the CPU will begin operating on the first Q1 cycle

following the wake-up event. This means that there is

no oscillator start-up time required because the

primary clock is already stable; however, there is a

delay between the wake-up event and the following

Q2. An internal delay timer of 5-10 Âµs will suspend

operation after the Reset to allow the CPU to become

ready for code execution. The CPU and peripheral

clock will be held in the first Q1.

The sequence of events is as follows:

1. A device Reset is asserted from one of many

sources (WDT, BOR, MCLR, etc.).

2. The device resets and the CPU start-up timer is

enabled if in Sleep mode. The device is held in

Reset until the CPU start-up time-out is

complete.

3. If the primary system clock is configured as an

external oscillator (HS, XT, LP), then the OST

will be active waiting for 1024 clocks of the pri-

mary system clock. While waiting for the OST,

the device will be held in Reset. The OST and

CPU start-up timers run in parallel.

4. After both the CPU start-up timer and the

Oscillator Start-up Timer have timed out, the

device will wait for one additional clock cycle

and instruction execution will begin.

FIGURE 4-10:

Q4

TIMING LP CLOCK TO PRIMARY SYSTEM CLOCK AFTER RESET (HS, XT, LP)

TT1P(1)

Q1

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4

T1OSI

OSC1

OSC2

CPU Start-up

System Clock

TOST(4)

TEPU(3)

TOSC(2)

Peripheral

Clock

Reset

Sleep

OSTS

Program

Counter PC

0000h

0001h

Note 1:

2:

3:

4:

TT1P = 30.52 Âµs.

TOSC = 50 ns minimum.

TEPU = 5-10 Âµs.

Refer to parameter D032 in Section 18.0 âElectrical Characteristicsâ.

0003h

0004h

0005h

ï£© 2004 Microchip Technology Inc.

DS30498C-page 45

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