PIC16C63T-04E/SO [MICROCHIP]

8-BIT, OTPROM, 4 MHz, RISC MICROCONTROLLER, PDSO28, 0.300 INCH, PLASTIC, SO-28;


型号：	PIC16C63T-04E/SO
厂家：	MICROCHIP
描述：	8-BIT, OTPROM, 4 MHz, RISC MICROCONTROLLER, PDSO28, 0.300 INCH, PLASTIC, SO-28 可编程只读存储器时钟微控制器光电二极管外围集成电路
文件：	总12页 (文件大小：412K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

MPLAB^®ICE 2000

Processor Module and Device Adapter Specification

CONTENTS

2.0

MPLAB ICE 2000 SYSTEM

1.0 Introduction......................................................... 1

2.0 MPLAB ICE 2000 System................................... 1

3.0 Emulator-Related Issues .................................... 2

4.0 Processor Modules............................................. 2

5.0 Device Adapter Issues........................................ 4

A brief overview of the different components of the

system is shown in the figure below. Each component

is discussed in the following subsections.

FIGURE 2-1: MPLAB ICE 2000 EMULATOR

SYSTEM

Host to Pod Cable

Emulator Pod

1.0

INTRODUCTION

Processor Module

The processor modules for MPLAB ICE 2000 are

interchangeable personality modules that allow

MPLAB ICE 2000 to be reconfigured for emulation of

Flexible Circuit

Cable

Logic Probe

different PICmicro microcontrollers (MCUs). This

Connector

modularity allows the emulation of many different

devices with the addition of a processor module and

device adapter, which provides a very cost effective

multiprocessor emulation system.

Device

Adapter

Transition

Socket

The device adapters for MPLAB ICE 2000 are inter-

changeable assemblies that allow the emulator system

to interface to a target application system. device

adapters also have control logic that allows the target

application to provide a clock source and power to the

processor module. The device adapters support

PICmicro MCUs in DIP, SDIP and PLCC packages.

2.1

Host to Pod Cable

This is a standard parallel interface cable. MPLAB ICE

2000 is tested with a 6-foot cable. A longer cable may

work, but is not guaranteed. The cable connects to a

parallel port on the PC. If a PC has a printer connected

to an LPT device, it is recommended that an additional

interface card be installed, rather than using a splitter

or an A/B switch.

Transition Sockets, used along with a device adapter,

provide a method of accommodating all PICmicro MCU

packages, including SOIC, SSOP, PQFP and TQFP

packages.

2.2

Emulator Pod

The Emulator Pod contains emulator memory and

control logic. MPLAB ICE 2000 contains a main board

and an additional board for expanded trace memory

and complex control logic. There are no field service-

able parts in the pod. For more information on the pod,

see the MPLAB ICE 2000 on-line help file in MPLAB

IDE (Help>Topics) or the MPLAB ICE 2000 User’s

Guide (DS51488).

The MPLAB ICE 2000 processor module is inserted

into the pod for operation.

2.3

Processor Module

The processor module contains the emulator chip, logic

and low-voltage circuitry. There are no field serviceable

parts mounted on the printed circuit board housed

within the processor module enclosure.

 2004 Microchip Technology Inc.

DS51140J-page 1

MPLAB^®ICE 2000

2.4

Flex Circuit Cable

3.0

EMULATOR-RELATED ISSUES

General limitations that apply to the MPLAB ICE 2000

emulator may be found in the on-line help. Select

Help>Topics and then select “MPLAB ICE 2000” under

“Debuggers”.

Once the processor module is inserted into the

emulator pod, the flex circuit cable extends the

emulator system to the target application. This is a

custom cable that is attached inside the processor

module enclosure and can be replaced in the field by

removing the end cap of the processor module

enclosure.

Device-specific limitations can be found as above or by

selecting Debugger>Settings, clicking the Limitations

tab, and then clicking the Details button.

Please, DO NOT PULL on the flex circuit cable to

remove the processor module from the pod. Use the

fins of the processor module end cap to leverage the

module from the pod.

4.0

PROCESSOR MODULES

Processor modules are identified on the top of the

assembly (e.g., PCM18XA0). To determine which

processors are supported by a specific module, refer to

the file “Readme for MPLAB ICE 2000.txt” in the

MPLAB IDE installation directory or the latest Product

Selector Guide (DS00148), which can be found on the

Microchip web site at www.microchip.com.

Emulator analog functions may not operate within the

performance specifications published in the device

data sheet due to parasitic capacitance (up to 120 pf)

of the flex cable.

2.5

Device Adapter

A typical processor module contains a special bond-out

version of a PICmicro MCU, with device buffers to

control data flow and control logic. It provides the

means of configuring the MPLAB ICE 2000 emulator

for a specific PICmicro MCU family and handles

low-voltage emulation when needed.

The device adapter provides a common interface for

the device being emulated. It is provided in standard

DIP and PLCC styles. The adapter also contains a spe-

cial device that provides an oscillator clock to accu-

rately emulate the oscillator characteristics of the

PICmicro MCU.

Note: When removing the processor module, DO

NOT pull on the flex cable. Use the tabs on

the processor module or damage to the

flex cable may occur.

Due to components on the device adapter, which

require target power, the device adapter should be

removed from the flex circuit cable (see Figure 2-1)

when emulator power is being used and the processor

module is not connected to the target. This will

eliminate any loading effects on I/O pins.

4.1

Power

The operating voltage for most of the control logic and

buffering on the processor module is +5V and is

supplied by the emulator pod. Power to the emulator

processor and some of its surrounding buffers is user-

selectable, and can be powered by the emulator pod

(at +5V only) or the target application system (from

2.0V to 5.5V). This is software selectable and is

configurable through the MPLAB IDE software. At no

time will the emulator system directly power the target

application system. ALWAYS insert the processor

module into the emulator pod before applying power to

the pod.

2.6

Transition Socket

Transition Sockets are available in various styles to

allow a common device adapter to be connected to one

of the supported surface mount package styles. Transi-

tion sockets are available for various pin counts and

pitches for SOIC, QFP and other styles. For more infor-

mation on transition sockets, see the MPLAB ICE

2000/4000 Transition Socket Specification (DS51194).

An emulator system consists of the following

components which can be ordered separately:

• An emulator pod (including the host-to-pod cable

and power supply)

When connecting to a target application system, there

may be a voltage level on the target application even

though power has not yet been applied power to the

target application circuit. This is normal, and is due to

current leakage through V^CCof the device adapter. The

current leakage will typically be less than 20 mA.

However, if the target application is using a voltage

regulator, it should be noted that some regulators

require the use of an external shunt diode between V^IN

and VOUT for reverse-bias protection. Refer to the

manufacturer’s data sheets for additional information.

• A processor module (including the flex circuit

cable)

• A device adapter

• An optional transition socket (for surface mount

emulation)

DS51140J-page 2

 2004 Microchip Technology Inc.

Processor Module and Device Adapter Specification

4.1.1

EMULATOR PROCESSOR POWER

SUPPLIED BY EMULATOR SYSTEM

4.1.4

OPERATING VOLTAGE OF 2.0 TO 4.6

VOLTS

If the emulator system is selected to power the emula-

tor processor in the processor module, the emulator

system can be operated without being connected to a

target application. If the system is being connected to a

target application, the power to the pod should be

applied before applying power to the target application.

If the target application system’s operating voltage is

between 2.0V and 4.55V ( 120 mV), the processor

module will consider this a LOW VOLTAGE condition.

In this mode the processor is limited to its rated speed

at a given voltage level (as indicated in its data sheet).

To minimize the amount of reverse current that the

target system is exposed to, the recommended

power-up sequence is:

The target application system’s V^CCwill experience a

small current load (10 mA typical) when the emulator

system is connected via a device adapter. This is

because the target system must always power the

clock chip in the processor module.

1. Apply power to the PC host.

2. Apply power to the emulator pod and processor

module assembly.

4.1.2

EMULATOR PROCESSOR POWER

SUPPLIED BY TARGET APPLICATION

SYSTEM

3. Invoke MPLAB IDE.

4. Select Debugger > Settings and click the Power

tab. Configure system for “Processor Power

Supplied by Target Board”.

When the MPLAB IDE software is brought up, the

emulator system is first initialized with the emulator

system powering the emulator processor. The

“Processor Power Supplied by Target Board” option

may then be selected using the Power tab of the

Settings dialog (Debugger>Settings) to power the

processor module from the target board.

5. At the error message, apply power to the target

application circuit. Then acknowledge the error.

6. Issue a System Reset (from the debugger

menu) before proceeding.

7. Select Debugger > Settings and click the Power

tab. Verify that the dialog says “Low Voltage

Enabled.” Click Cancel to close the dialog.

When operating from external power, the processor

module will typically represent a current load equivalent

to the device being emulated (according to its data

sheet) plus approximately 100 mA. Keep in mind that

the target application will affect the overall current load

of the processor module, dependent upon the load

placed upon the processor I/O.

4.2

Operating Frequency

The processor modules will support the maximum

frequency (except where noted in Section 3.0

Emulator-Related Issues) of the device under emula-

tion. The maximum frequency of a PICmicro MCU

device is significantly lower when the operating voltage

is less than 4.5V.

When the processor power is supplied by the target

application system, an external clock (from the target

board) may also be provided. MPLAB IDE will not allow

use of an external clock without the use of external

power.

The processor modules will support a minimum

frequency of 32 kHz. When operating at low

frequencies, response to the screen may be slow.

4.1.3

OPERATING VOLTAGE OF 4.6 TO 5.5

VOLTS

4.3

Clock Options

MPLAB ICE 2000 allows internal and external clocking.

When set to internal, the clock is supplied from the

internal programmable clock, located in the Emulator

Pod. When set to external, the oscillator on the target

application system will be utilized.

If the target application system’s operating voltage is

between 4.55V ( 120 mV) and 5.5V, the processor

module will consider this a STANDARD VOLTAGE

condition. In this mode the processor can run to its

highest rated speed (as indicated in its data sheet).

4.3.1

CLOCK SOURCE FROM EMULATOR

The recommended power-up sequence is:

1. Apply power to the PC host.

Refer to the MPLAB ICE 2000 on-line help file in

MPLAB IDE (Help>Topics) or the MPLAB ICE 2000

User’s Guide (DS51488), “Using the On-Board Clock”,

for configuring MPLAB IDE to supply the clock source.

2. Apply power to the emulator pod and processor

module assembly.

3. Invoke MPLAB IDE.

4. Select Debugger > Settings and click the Power

tab. Configure system for “Processor Power

Supplied by Target Board”.

5. At the error message, apply power to the target

application circuit. Then acknowledge the error.

6. Issue a System Reset (from the debugger

menu) before proceeding.

 2004 Microchip Technology Inc.

DS51140J-page 3

MPLAB^®ICE 2000

4.3.2

CLOCK SOURCE FROM THE TARGET

APPLICATION

4.5

Freeze Mode

The MPLAB ICE 2000 system allows the option of

“freezing” peripheral operation or allowing them to

continue operating when the processor is halted. This

option is configured in the MPLAB IDE. The Freeze

function is available on all processor modules except

the PCM16XA0.

If the Target Application is selected to provide the clock

source, the target board must also be selected to

power the emulator processor (see the MPLAB ICE

2000 on-line help file in MPLAB IDE (Help>Topics) or

the MPLAB ICE 2000 User’s Guide (DS51488), “Using

a Target Board Clock”).

This function is useful to halt an on-board timer while at

a break point. At a break point and while single

stepping, interrupts are disabled.

At low voltage, the maximum speed of the processor

will be limited to the rated speed of the device under

emulation.

An oscillator circuit on the device adapter generates a

clock to the processor module and buffers the clock

circuit on the target board. In this way, the MPLAB ICE

2000 emulator closely matches the oscillator options of

the actual device. All oscillator modes are supported

(as documented in the device’s data sheet) except as

noted in Section 3.0 Emulator-Related Issues. The

OSC1 and OSC2 inputs of the device adapter have a

5 pF to 10 pF load. Be aware of this when using a

crystal in HS, XT, LP or LF modes, or an RC network in

RC mode.

5.0

DEVICE ADAPTER ISSUES

This section details processor-specific considerations

that have been made on device adapters. Only

adapters with special considerations are listed.

There will be a max of 10 mA of current draw from the

target system even when the emulator processor mod-

ule is being powered by the emulator system, and

running internal clock. This is due to components on

the device adapter being powered by the target board.

The frequency of the emulated RC network may vary

relative to the actual device due to emulator circuitry. If

a specific frequency is important, adjust the RC values

to achieve the desired frequency. Another alternative

would be to allow the emulator to provide the clock as

described in Section 4.3.1 Clock Source from

Emulator.

When using the target board clock, the system’s

operating voltage is between 2.5V and 5.5V.

4.4

ESD Protection and Electrical

Overstress

All CMOS chips are susceptible to electrostatic

discharge (ESD). In the case of the processor modules,

the pins of the CMOS emulator are directly connected

to the target connector, making the chip vulnerable to

ESD. ESD can also induce latch-up in CMOS chips,

causing excessive current through the chip and possi-

ble damage. MPLAB ICE 2000 has been designed to

minimize potential damage by implementing over-

current protection and transient suppressors. However,

care should be given to minimizing ESD conditions

while using the system.

During development, contention on an I/O pin is

possible (e.g., when an emulator pin is driving a ‘1’ and

the target board is driving a ‘0’). Prolonged contention

may cause latch-up and damage to the emulator chip.

One possible precaution is to use current limiting

resistors (~100 Ω) during the development phase on

bidirectional I/O pins. Using limiting resistors can also

help avoid damage to modules, device adapters and

pods that occurs when a voltage source is accidentally

connected to an I/O pin on the target board.

DS51140J-page 4

 2004 Microchip Technology Inc.

Processor Module and Device Adapter Specification

5.1

DVA12XP080

This device adapter is intended for use with PIC12C50X

8-pin DIP devices. It has four mechanical switches that

allow target pins GP2 to GP5 to be routed to the emulator

silicon on the PCM16XA0 processor module or the

oscillator chip on the device adapter, as shown in Table 5-1.

In addition, a 24C00 EEPROM (U1) is connected to

RA0 and RA1 of the emulator silicon to support the

EEPROM capabilities of the PIC12CE51X family devices.

For information on how to use EEPROM memory, see the

MPLAB IDE on-line device-specific limitations for the

PCM16XA0 (PIC12CE518/519) devices by selecting

Debugger>Settings, clicking the Limitations tab, and then

clicking the Details button.

TABLE 5-1:

DVA12XP080 DEVICE ADAPTER SWITCH ASSIGNMENT

Desired Function Switch Positions

RB2

RB3

RB4

RB5

MCLR

Set S4 to RB2

Set S3 to RB3

Set S2 to RB4

Set S1 to RB5

Set S3 to MCLR

External Oscillator Input

Set S1 to OSC1 and

set S2 to OSC2

TIMER0 Clock Input

Set S4 to T0CKI

5.2

DVA12XP081

This device adapter is intended for use with PIC12C67X

8-pin DIP devices. It has two mechanical switches that

allow target pins GP4 and GP5 to be routed to the emulator

silicon on the PCM12XA0 processor module or the

oscillator device on the device adapter, as shown in

Table 5-2.

TABLE 5-2:

DVA12XP081 DEVICE ADAPTER SWITCH ASSIGNMENT

Desired Function Switch Positions

GP4

GP5

Set S2 to GP4

Set S1 to GP5

External Oscillator Input

Set S1 to OSC1 and

set S2 to OSC2

 2004 Microchip Technology Inc.

DS51140J-page 5

MPLAB^®ICE 2000

5.3

DVA14XP280

This device adapter is intended for use with the PIC14000

28-pin DIP device. It has two mechanical switches that

allow target pins OSC1 and OSC2 to be routed to the

emulator silicon on the PCM14XA0 processor module or

the oscillator device on the device adapter, as shown in

Table 5-3.

TABLE 5-3:

DVA14XP280 DEVICE ADAPTER SWITCH ASSIGNMENT

Desired Function Switch Position

IN Mode

Set S1 to OSC2INT

Set S2 to OSC1INT

HS Mode

Set S1 to OSC2EXT

Set S2 to OSC1EXT

5.4

DVA16XP140

This device adapter is intended for use with the PIC16C505

14-pin DIP device. It has four mechanical switches. Two of

the switches allow target pins RB4 and RB5 to be routed to

the emulator silicon on the PCM16XA0 processor module or

the oscillator device on the device adapter. The other two

switches control the routing of RB3 and RC5 signals. RB3

can be a general-purpose input or MCLR. RC5 can be a

general purpose I/O or can drive the TOCKI input, as shown

in Table 5-4.

TABLE 5-4:

DVA16XP140 DEVICE ADAPTER SWITCH ASSIGNMENT

Desired Function Switch Positions

RC5

RB3

RB4

RB5

MCLR

Set S4 to RC5

Set S3 to RB3

Set S2 to RB4

Set S1 to RB5

Set S3 to MCLR

External Oscillator Input

Set S1 to OSC1 and

set S2 to OSC2

TIMER0 Clock Input

Set S4 to T0CKI

DS51140J-page 6

 2004 Microchip Technology Inc.

Processor Module and Device Adapter Specification

5.5

DVA16XP182

This device adapter is intended for use with

PIC16C712/716 18-pin DIP devices. It has a second

oscillator device that allows TIMER1 oscillator input ranging

from 32-40 kHz. It has four mechanical switches. Target

pins RB1 and RB2 can be routed to the emulator silicon on

the PCM16XE1 processor module or the TIMER1 oscillator

device on the device adapter. Target pin RB1 is routed to

T1CKI. Target pin RB3 can be a general purpose input or

CCP1, as shown in Table 5-5.

TABLE 5-5:

DVA16XP182 DEVICE ADAPTER SWITCH ASSIGNMENT

Desired Function Switch Positions

Set S2-1 to position B

RB1

RB2

Set S2-2 to position B

Set S2-3 to position B

Set S2-3 to position A

RB3

CCP1

TIMER1 Clock Input

Set S2-1 to position A and

set S1 to position B

TIMER1 Oscillator Input

Set S2-1 to position A and

set S2-2 to position A and

set S1 to position A

 2004 Microchip Technology Inc.

DS51140J-page 7

MPLAB^®ICE 2000

5.6

DVA16XP187

This device adapter is intended for use with PIC16F716

18-pin DIP devices. It has a second oscillator device that

allows TIMER1 oscillator input ranging from 32-40 kHz. It

has four mechanical switches. Target pins RB1 and RB2

can be routed to the emulator silicon on the PCM16YJ0

processor module or the TIMER1 oscillator device on the

device adapter. Target pin RB1 is routed to T1CKI. Target

pin RB3 can be a general purpose input or CCP1, as shown

in Table 5-5.

TABLE 5-6:

DVA16XP187 DEVICE ADAPTER SWITCH ASSIGNMENT

Desired Function Switch Positions

Set S2-1 to position B

RB1

RB2

Set S2-2 to position B

Set S2-3 to position B

RB3

CCP1

TIMER1 Clock Input

Set S2-1 to position B and

set S1 to position B

TIMER1 Oscillator Input

Set S2-1 to position A and

set S2-2 to position A and

set S1 to position A

5.7

DVA16XP282, DVA16XP401,

DVA16XL441 and DVA16PQ441

These device adapters are intended for use with PICmicro

MCU devices supported by the PCM16XB0/B1,

PCM16XE0/E1, PCM16XK0 and the PCM16XL0 processor

modules. The device adapters have a second oscillator

device that allows TIMER1 oscillator input ranging from 32

to 40 kHz.

For PCM16XB0/B1, PCM16XE0/E1, PCM16XK0 and

PCM16XL0, configure jumper J1 per Table 5-7.

For all other processor modules supported by these device

adapters, leave the jumper on pins 1-2 (OFF); the Timer1

oscillator enable/disable function is software configurable.

TABLE 5-7:

DVA16XP282, DVA16XP401, DVA16XL441 AND DVA16PQ441 JUMPER SETTINGS

Desired Function

Switch Positions

Results

TIMER1 Oscillator Input enabled

TIMER1 Oscillator Input disabled

Short J1 pins 2-3 (ON)

RC0/T1OSO/T1CKI pin = T1OSO

RC1/T1OSI/CCP2 pin = T1OSI

Short J1 pins 1-2 (OFF)

RC0/T1OSO/T1CKI pin = RC0 or T1CKI

RC1/T1OSI/CCP2 pin = RC1 or CCP2

DS51140J-page 8

 2004 Microchip Technology Inc.

Processor Module and Device Adapter Specification

5.8

DVA17XXXX0

5.10

T1OSC Jumper

These device adapters are intended for use with

PICmicro MCU devices supported by the PCM17XA0

processor module. In all processors in EC mode,

OSC/4 is not supported. OSC/4 in EC mode is

supported in DVA17XXXX1 device adapters.

Some device adapters are equipped with a 3-pin

jumper to force the device adapter to enable/disable

the Timer1 oscillator circuitry.

When in the “ON” position, the device adapter’s Timer1

oscillator circuitry is always enabled regardless of the

T1OSCEN bit in T1CON.

5.9

Emulating a .600 28-Pin Part

When in the “OFF” position, the device adapter’s

Timer1 oscillator circuit is enabled/disabled by software

in application code by the T1OSCEN bit in T1CON.

When emulating a .600 wide, 28-pin device, an adapter

will be needed to convert the standard .300 wide

socket on the device adapters to the .600 wide socket

on the target board.

Note: PCM16XB0/B1, PCM16XE0/E1,

PCM16XK0 and PCM16XL0 do not

There are many adapters available for this purpose,

such as Digi-Key part number A502-ND.

support software enable/disable of the

Timer1 circuitry and must use the jumper

to either enable of disable the function (see

Table 5-7 forDVA16XP282, DVA16XP401,

DVA16XL441 and DVA16PQ441).

 2004 Microchip Technology Inc.

DS51140J-page 9

MPLAB^®ICE 2000

NOTES:

DS51140J-page 10

 2004 Microchip Technology Inc.

Note the following details of the code protection feature on Microchip devices:

•

Microchip products meet the specification contained in their particular Microchip Data Sheet.

Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the

intended manner and under normal conditions.

•

There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our

knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data

Sheets. Most likely, the person doing so is engaged in theft of intellectual property.

•

Microchip is willing to work with the customer who is concerned about the integrity of their code.

Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not

mean that we are guaranteeing the product as “unbreakable.”

Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our

products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts

allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.

Information contained in this publication regarding device

applications and the like is provided only for your convenience

and may be superseded by updates. It is your responsibility to

ensure that your application meets with your specifications.

MICROCHIP MAKES NO REPRESENTATIONS OR WAR-

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 2004 Microchip Technology Inc.

DS51140J-page 11

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http://support.microchip.com

Web Address:

China - Chengdu

France - Massy

Japan - Kanagawa

Tel: 81-45-471- 6166

Fax: 81-45-471-6122

Tel: 86-28-8676-6200

Fax: 86-28-8676-6599

Tel: 33-1-69-53-63-20

Fax: 33-1-69-30-90-79

www.microchip.com

Atlanta

China - Fuzhou

Germany - Ismaning

Tel: 49-89-627-144-0

Fax: 49-89-627-144-44

Korea - Seoul

Alpharetta, GA

Tel: 770-640-0034

Fax: 770-640-0307

Tel: 86-591-8750-3506

Fax: 86-591-8750-3521

Tel: 82-2-554-7200

Fax: 82-2-558-5932 or

82-2-558-5934

Italy - Milan

China - Hong Kong SAR

Tel: 852-2401-1200

Boston

Tel: 39-0331-742611

Fax: 39-0331-466781

Singapore

Westford, MA

Tel: 978-692-3848

Fax: 978-692-3821

Fax: 852-2401-3431

Tel: 65-6334-8870

Fax: 65-6334-8850

Netherlands - Drunen

Tel: 31-416-690399

Fax: 31-416-690340

China - Shanghai

Tel: 86-21-5407-5533

Fax: 86-21-5407-5066

China - Shenyang

Tel: 86-24-2334-2829

Fax: 86-24-2334-2393

Taiwan - Kaohsiung

Tel: 886-7-536-4818

Fax: 886-7-536-4803

Chicago

Itasca, IL

England - Berkshire

Tel: 44-118-921-5869

Fax: 44-118-921-5820

Tel: 630-285-0071

Fax: 630-285-0075

Taiwan - Taipei

Tel: 886-2-2500-6610

Fax: 886-2-2508-0102

Dallas

China - Shenzhen

Addison, TX

Tel: 86-755-8203-2660

Fax: 86-755-8203-1760

Tel: 972-818-7423

Fax: 972-818-2924

Taiwan - Hsinchu

Tel: 886-3-572-9526

Fax: 886-3-572-6459

China - Shunde

Detroit

Tel: 86-757-2839-5507

Fax: 86-757-2839-5571

Farmington Hills, MI

Tel: 248-538-2250

Fax: 248-538-2260

China - Qingdao

Tel: 86-532-502-7355

Fax: 86-532-502-7205

Kokomo

Kokomo, IN

Tel: 765-864-8360

Fax: 765-864-8387

Los Angeles

Mission Viejo, CA

Tel: 949-462-9523

Fax: 949-462-9608

San Jose

Mountain View, CA

Tel: 650-215-1444

Fax: 650-961-0286

Toronto

Mississauga, Ontario,

Canada

Tel: 905-673-0699

Fax: 905-673-6509

10/20/04

DS51140J-page 12

 2004 Microchip Technology Inc.

PIC16C63T-04E/SO [MICROCHIP]

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