Embedded Pentium

Processor

100 MHz, 133 MHz, 166 MHz

Datasheet

Product Features

The embedded Pentium

processor provides high performance for embedded applications. The

Pentium processor is compatible with the entire installed base of applications for DOS*,
Windows*, OS/2*, and UNIX*.

The Pentium processor superscalar architecture can execute two instructions per clock cycle.
Branch prediction and separate code and data caches also increase performance. The pipelined
floating-point unit delivers a high level of performance. Separate code and data caches reduce
cache conflicts while remaining software transparent. The Pentium processor has 3.3 million
transistors and is built on Intel's advanced 3.3 V BiCMOS silicon technology. The Pentium
processor has on-chip dual processing support, a local multiprocessor interrupt controller, and
SL power management features.

Compatible with Large Software Base

-- MS-DOS*, Windows*, OS/2*, UNIX*

32-Bit Processor with 64-Bit Data Bus

Superscalar Architecture

-- Two Pipelined Integer Units are Capable

of Two Instructions/Clock

-- Pipelined Floating-Point Unit

Separate Code and Data Caches

-- 8-Kbyte Code, 8-Kbyte Write-Back Data

-- MESI Cache Protocol

Advanced Design Features

-- Branch Prediction

-- Virtual Mode Extensions

3.3 V BiCMOS Silicon Technology

4-Mbyte Pages for Increased TLB Hit Rate

IEEE 1149.1 Boundary Scan

Dual Processing Configuration

Functional Redundancy Checking Support

Internal Error Detection Features

Multiprocessor Support

-- Multiprocessor Instructions

-- Support for Second-level Cache

On-Chip Local APIC Controller

-- Multiprocessor Interrupt Management

-- 8259 Compatible

Power Management Features

-- System Management Mode

-- Clock Control

Fractional Bus Operation

-- 166-MHz Core/66-MHz Bus

-- 133-MHz Core/66-MHz Bus

-- 100-MHz Core/66-MHz Bus

iCOMP

Index 2.0 Rating

-- 127 at 166 MHz

-- 111 at 133 MHz

-- 90 at 100 MHz

Contact Intel Corporation for more information about iCOMP

Index 2.0 ratings.

Order Number: 273202-001

November 1998

Datasheet

Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or otherwise, to any intellectual
property rights is granted by this document. Except as provided in Intel's Terms and Conditions of Sale for such products, Intel assumes no liability
whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to
fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not
intended for use in medical, life saving, or life sustaining applications.

Intel may make changes to specifications and product descriptions at any time, without notice.

Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for
future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.

The Pentium

processor may contain design defects or errors known as errata which may cause the product to deviate from published specifications.

Current characterized errata are available on request.

MPEG is an international standard for video compression/decompression promoted by ISO. Implementations of MPEG CODECs, or MPEG enabled
platforms may require licenses from various entities, including Intel Corporation.

Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.

Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800-
548-4725 or by visiting Intel's website at http://www.intel.com.

*Third-party brands and names are the property of their respective owners.

Datasheet

Embedded Pentium

Processor

Contents

1.0

Architecture Overview

............................................................................................. 7

1.1

Pentium

Processor Family Architecture .............................................................. 8

1.2

Pentium

Processors with Voltage Reduction Technology................................. 10

2.0

Packaging Information

........................................................................................... 11

2.1

Pentium

Processor Pinout................................................................................. 11

2.1.1

Pin Cross Reference .............................................................................. 13

2.1.2

Design Notes.......................................................................................... 15

2.1.3

Pin Quick Reference .............................................................................. 15

2.1.4

Pin Reference Tables............................................................................. 21

2.1.5

Pin Grouping According to Function....................................................... 24

2.2

Mechanical Specifications ................................................................................... 25

2.3

Thermal Specifications ........................................................................................ 26
2.3.1

Measuring Thermal Values .................................................................... 26

2.3.2

Thermal Equations And Data ................................................................. 27

3.0

Electrical Specifications

........................................................................................ 29

3.1

3.3 V Power Supply............................................................................................. 29

3.2

3.3 V Inputs and Outputs..................................................................................... 29

3.3

Absolute Maximum Ratings................................................................................. 29

3.4

DC Specifications ................................................................................................ 30

3.5

AC Specifications ................................................................................................ 31
3.5.1

Private Bus ............................................................................................. 31

3.5.2

Power and Ground ................................................................................. 31

3.5.3

Decoupling Recommendations .............................................................. 32

3.5.4

Connection Specifications ...................................................................... 32

3.5.5

AC Timing Tables................................................................................... 32

Embedded Pentium

Processor

Datasheet

Figures

Embedded Pentium

Processor Block Diagram ................................................... 9

Pentium

Processor SPGA Package Pinout (Top Side View) ............................ 11

Pentium

Processor SPGA Package Pinout (Pin Side View) ............................. 12

SPGA Package Dimensions ............................................................................... 25

Technique for Measuring Case Temperature (T

).............................................. 27

Clock Waveform .................................................................................................. 38

Valid Delay Timings ............................................................................................ 38

Float Delay Timings ............................................................................................ 38

Setup and Hold Timings...................................................................................... 39

Reset and Configuration Timings........................................................................ 39

Test Timings........................................................................................................ 40

Test Reset Timings ............................................................................................. 40

50% V

Measurement of Flight Time................................................................ 41

Tables

Pin Cross-Reference by Pin Name -- Address and Data Pins ........................... 13

Pin Cross-Reference by Pin Name -- Control Pins ............................................ 14

Pin Cross-Reference by Pin Name -- Power, Ground and No Connect Pins .... 15

Pin Quick Reference ......................................................................................... 16

Bus Frequency Selections .................................................................................. 21

Output Pins ......................................................................................................... 21

Input Pins ............................................................................................................ 22

Input/Output Pins ................................................................................................ 23

Inter-processor Input/Output Pins ....................................................................... 23

Pin Functional Grouping...................................................................................... 24

Package Information Summary for Pentium

Processor .................................... 25

SPGA Package Dimensions Key ........................................................................ 25

Power Dissipation Requirements for Thermal Solution Design .......................... 26

Thermal Resistances for Embedded Pentium

Processors................................ 28

Absolute Maximum Ratings ................................................................................ 30

3.3 V DC Specifications ...................................................................................... 30

3.3 V (5 V-Safe) DC Specifications ..................................................................... 30

Input and Output Characteristics......................................................................... 31

AC Specifications ................................................................................................ 33

Dual Processor Mode AC Specifications ............................................................ 36

Notes for Tables 19 and 20 ................................................................................. 37

Embedded Pentium

Processor

Datasheet

1.0

Architecture Overview

The Intel

embedded Pentium

processor is binary compatible with the 8086/88, 80286,

Intel386TM DX, Intel386 SX, Intel486TM DX, Intel486 SX, IntelDX2TM, IntelDX4TM and
60/66 MHz Pentium processors.

The embedded Pentium processor family consists of the following products:

Embedded Pentium processors (described in this document).

-- Pentium processor at 166 MHz, iCOMP Index 2.0 rating = 127

-- Pentium processor at 133 MHz, iCOMP Index 2.0 rating = 111

-- Pentium processor at 100 MHz, iCOMP Index 2.0 rating = 90

Pentium processor with Voltage Reduction Technology (described in a separate datasheet,
order number 273203).

-- Pentium processor with Voltage Reduction Technology at 133 MHz, iCOMP Index 2.0

rating = 111

Pentium processor features include:

Superscalar architecture

Dynamic branch prediction

Pipelined floating-point unit

Improved instruction execution time

Separate 8-Kbyte code and 8-Kbyte data caches

Writeback MESI protocol in the data cache

64-Bit data bus

Bus cycle pipelining

Address parity

Internal parity checking

Functional redundancy checking

Execution tracing

Performance monitoring

IEEE 1149.1 boundary scan

System Management Mode

Virtual Mode extensions

Fractional bus operation allowing higher core frequency operation

Dual processing support

SL power management features

On-chip local APIC device

Embedded Pentium

Processor

Datasheet

1.1

Pentium

Processor Family Architecture

The application instruction set of the Pentium processor family includes the complete Intel486
processor family instruction set with extensions to accommodate some of the additional
functionality of the Pentium processor. All application software written for the Intel386 and
Intel486 family microprocessors runs on Pentium processors without modification. The on-chip
memory management unit is completely compatible with the Intel386 family and Intel486 family
of processors.

Pentium processors implement several enhancements to increase performance. The two instruction
pipelines and the floating-point unit are capable of independent operation. Each pipeline issues
frequently used instructions in a single clock. Together, the dual pipes can issue two integer
instructions in one clock, or one floating-point instruction (under certain circumstances, two
floating-point instructions) in one clock.

Branch prediction is implemented in Pentium processors. To support this, the processor has two
prefetch buffers: one prefetches code in a linear fashion and the other prefetches code according to
the BTB so the needed code is almost always prefetched before it is needed for execution.

The floating-point unit (FPU) is up to ten times faster than the FPU used on the Intel486 processor
for common operations including add, multiply, and load.

Pentium processors include separate code and data caches integrated on-chip to meet performance
goals. Each cache is 8 Kbytes with a 32-byte line size, and is two-way set associative. Each cache
has a dedicated Translation Lookaside Buffer (TLB) to translate linear addresses to physical
addresses. The data cache is configurable to be write back or write through on a line-by-line basis
and follows the MESI protocol. The data cache tags are triple-ported to support two data transfers
and an inquire cycle in the same clock. The code cache is an inherently write-protected cache. The
code cache tags are also triple-ported to support snooping and split-line accesses. Individual pages
can be configured as cacheable or non-cacheable by software or hardware. The caches can be
enabled or disabled by software or hardware.

Pentium processors have a 64-bit data bus for fast data transfer. Burst read and burst write back
cycles are supported. In addition, bus cycle pipelining allows two bus cycles to occur
simultaneously. The Memory Management Unit contains optional extensions to the architecture
which allow 2-Mbyte and 4-Mbyte page sizes.

Pentium processors have added significant data integrity and error detection capability. Data parity
checking is still supported on a byte-by-byte basis. Address parity checking and internal parity
checking features have been added along with a new exception, the machine check exception.

Pentium processors offer functional redundancy checking to provide maximum error detection of
the processor and the interface to the processor. When functional redundancy checking is used, a
second processor, the "checker" executes in lock-step with the "master" processor. The checker
samples the master's outputs, compares those values with the values it computes internally, and
asserts an error signal when a mismatch occurs.

As more and more functions are integrated on-chip, the complexity of board level testing is
increased. To address this, Pentium processors provide test and debug capability. Pentium
processors implement IEEE Boundary Scan (Standard 1149.1). In addition, Pentium processors
provide four breakpoint pins that correspond to each of the debug registers and externally indicate a
breakpoint match. Execution tracing provides external indications when an instruction has
completed execution in either of the two internal pipelines, or when a branch has been taken.

Embedded Pentium

Processor

Datasheet

System Management Mode (SMM) has been implemented along with some extensions to the SMM
architecture. Enhancements to the virtual 8086 mode have been made to increase performance by
reducing the number of times it is necessary to trap to a virtual 8086 monitor.

Figure 1 is a block diagram of the embedded Pentium processor.

The block diagram shows the two instruction pipelines, the "u" pipe and the "v" pipe. The u-pipe
can execute all integer and floating-point instructions. The v-pipe can execute simple integer
instructions and the FXCH floating-point instructions.

The separate code and data caches are shown in the block diagram. The data cache has two ports,
one for each of the two pipes (the tags are triple-ported to allow simultaneous inquire cycles). The
data cache has a dedicated Translation Lookaside Buffer (TLB) to translate linear addresses to the
physical addresses used by the data cache.

The code cache, branch target buffer and prefetch buffers are responsible for getting raw
instructions into the execution units. Instructions are fetched from the code cache or from the
external bus. Branch addresses are remembered by the branch target buffer. The code cache TLB
translates linear addresses to physical addresses used by the code cache.

Figure 1. Embedded Pentium

Processor Block Diagram

A6053-01

Logic

Control

ROM

Control Unit

Address

Generate

(U Pipeline)

Address

Generate

(V Pipeline)

Control

Bus
Unit

64-Bit

Data Bus

32-Bit

Address

Bus

Control

APIC

TLB

Data Cache

8 Kbytes

Data

Control

Branch

Target

Buffer

Prefetch

Address

Instruction

Pointer

Prefetch Buffers

Instruction Decode

Code Cache

8 Kbytes

TLB

256

Control

Add

Floating Point

Unit

64-Bit

Data Bus

32-Bit
Addr. Bus

Integer Register File

ALU

(U Pipline)

ALU

(V Pipline)

Barrel Shifter

Branch Verification

and Target Address

Divide

Multiply

Page

Unit

Embedded Pentium

Processor

Datasheet

The decode unit decodes the prefetched instructions so the processor can execute the instruction.
The control ROM contains microcode to control the sequence of operations that must be performed
to implement the Pentium processor architecture. The control ROM unit has direct control over
both pipelines.

Pentium processors contain a pipelined floating-point unit that provides a significant floating-point
performance advantage over previous generations of processors.

Symmetric dual processing in a system is supported with two Pentium processors. The two
processors appear to the system as a single processor. Operating systems with dual processing
support properly schedule computing tasks between the two processors. This scheduling of tasks is
transparent to software applications and the end-user. Logic built into the processors supports a
"glueless" interface for easy system design. Through a private bus, the two Pentium processors
arbitrate for the external bus and maintain cache coherency. Dual processing is supported in a
system only if both processors are operating at identical core and bus frequencies.

In this document, in order to distinguish between two Pentium processors in dual processing mode,
one processor is the "Primary" processor and the other is the "Dual" processor. Note that this is a
different concept than that of "master" and "checker" processors described in the discussion on
functional redundancy on page 8.

The Pentium processor supports clock control. When the clock to the processor is stopped, power
dissipation is virtually eliminated. This makes the Pentium processor a good choice for energy-
efficient designs.

The Pentium processor supports fractional bus operation. This allows the processor core to operate
at high frequencies, while communicating with the external bus at lower frequencies.

The Pentium processor contains an on-chip Advanced Programmable Interrupt Controller (APIC).
This APIC implementation supports multiprocessor interrupt management (with symmetric
interrupt distribution across all processors), multiple I/O subsystem support, 8259A compatibility,
and inter-processor interrupt support.

Pentium processor architectural features are described in more detail in the Embedded Pentium

Processor Family Developer's Manual (order number 273204).

1.2

Pentium

Processors with Voltage Reduction Technology

The Embedded Pentium processor with Voltage Reduction Technology is described in the
Embedded Pentium

Processor with Voltage Reduction Technology datasheet (order number

273203).

Embedded Pentium

Processor

Datasheet

2.0

Packaging Information

2.1

Pentium

Processor Pinout

Figure 2. Pentium

Processor SPGA Package Pinout (Top Side View)

A5498-01

27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10

BE6#

CPUTYP

STPCLK#

FRCMC# BF0

BF1

PEN#

IGNNE# INIT

NA#

BRDYC#

WB/WT# PHIT#

BRDY#

BOFF#

PRDY PHITM#

R/S#

NMI

HOLD

SMI#

APCHK# PBREQ# V

D/P#

A23

PBGNT#

INTR

PCD SMIACT# V

A24

A27

PCHK#

A21

ADS#

HLDA

BREQ

A25

A31

LOCK#

A22

A26

BE2#

HITM#

BE0# BUSCHK#

BE4#

PWT

INC

A11

SCYC

A12

A14

A16

A18

A20

BE7#

BE3#

HIT#

BE1# A20M#

BE5#

D/C#

RESET

CLK

A28

A29

A13

A15

A17

A19

View of Component

as Mounted on Board

(Pins Down)

INC

FLUSH#

INC

27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10

A10

W/R#

EADS# ADSC#

A30

PICD0

PICCLK

PICD1

TCK

TDI

TDO

TMS

TRST#

DP0

DP7

D63

FERR# PM0BP0

D62

IERR#

BP3

BP2

PM1BP1

INV

CACHE#

MI/O#

KEN# EWBE#

AHOLD

D49

D52

D54

D53

D55

D48

D50

D51

DP6

D58

D57

D56

D60

D61

D59

DP5

D42

D46

D30

D33

D40

D44

DP3

DP1

D26

D28

D12

D19

D23

D37

D39

D35

D10

D14

D47

INC

D29

D32

DP4

D45

D31

D21

D25

D27

D17

D24

DP2

D36

D38

D34

D11

D13

D43

INC

D20

D16

D15

D18

D41

INC

D22

Embedded Pentium

Processor

Datasheet

Figure 3. Pentium

Processor SPGA Package Pinout (Pin Side View)

A5499-01

BE6#

CPUTYP

STPCLK#

FRCMC#

BF0

BF1

PEN#

IGNNE#

INIT

NA#

BRDYC#

WB/WT#

PHIT#

BRDY#

BOFF#

PRDY

PHITM#

R/S#

NMI

HOLD

SMI#

APCHK#

PBREQ#

D/P#

A23

PBGNT#

INTR

PCD

SMIACT#

A24

A27

PCHK#

A21

ADS#

HLDA

BREQ

A25

A31

LOCK#

A22

A26

BE2#

HITM#

BE0#

BUSCHK#

BE4#

PWT

INC

A11

SCYC

A12

A14

A16

A18

A20

BE7#

BE3#

HIT#

BE1#

A20M#

BE5#

D/C#

RESET

CLK

A28

A29

A13

A15

A17

A19

Pin Side View

INC

FLUSH#

INC

A10

W/R#

EADS#

ADSC#

A30

PICD0

PICCLK

PICD1

TCK

TDI

TDO

TMS

TRST#

DP0

DP7

D63

FERR#

PM0BP0

D62

IERR#

BP3

BP2

PM1BP1

INV

CACHE#

MI/O#

KEN#

EWBE#

AHOLD

D49

D52

D54

D53

D55

D48

D50

D51

DP6

D58

D57

D56

D60

D61

D59

DP5

D42

D46

D30

D33

D40

D44

DP3

DP1

D26

D28

D12

D19

D23

D37

D39

D35

D10

D14

D47

INC

D29

D32

DP4

D45

D31

D21

D25

D27

D17

D24

DP2

D36

D38

D34

D11

D13

D43

INC

D20

D16

D15

D18

D41

INC

D22

Embedded Pentium

Processor

Datasheet

2.1.1

Pin Cross Reference

Table 1. Pin Cross-Reference by Pin Name -- Address and Data Pins

Pin

Location

Pin

Location

Pin

Location

Pin

Location

Pin

Location

Address

AL35

AK30

A15

AK26

A21

AF34

A27

AG33

AM34

A10

AN31

A16

AL25

A22

AH36

A28

AK36

AK32

A11

AL31

A17

AK24

A23

AE33

A29

AK34

AN33

A12

AL29

A18

AL23

A24

AG35

A30

AM36

AL33

A13

AK28

A19

AK22

A25

AJ35

A31

AJ33

AM32

A14

AL27

A20

AL21

A26

AH34

Data

K34

D13

B34

D26

D24

D39

D10

D52

E03

G35

D14

C33

D27

C21

D40

D08

D53

G05

J35

D15

A35

D28

D22

D41

A05

D54

E01

G33

D16

B32

D29

C19

D42

E09

D55

G03

F36

D17

C31

D30

D20

D43

B04

D56

H04

F34

D18

A33

D31

C17

D44

D06

D57

J03

E35

D19

D28

D32

C15

D45

C05

D58

J05

E33

D20

B30

D33

D16

D46

E07

D59

K04

D34

D21

C29

D34

C13

D47

C03

D60

L05

C37

D22

A31

D35

D14

D48

D04

D61

L03

D10

C35

D23

D26

D36

C11

D49

E05

D62

M04

D11

B36

D24

C27

D37

D12

D50

D02

D63

N03

D12

D32

D25

C23

D38

C09

D51

F04

Embedded Pentium

Processor

Datasheet

Table 2. Pin Cross-Reference by Pin Name -- Control Pins

Pin

Location

Pin

Location

Pin

Location

Pin

Location

A20M#

AK08

BRDYC#

Y03

FLUSH#

AN07

PEN#

Z34

ADS#

AJ05

BREQ

AJ01

FRCMC#

Y35

PM0/BP0

Q03

ADSC#

AM02

BUSCHK#

AL07

HIT#

AK06

PM1/BP1

R04

AHOLD

V04

CACHE#

U03

HITM#

AL05

PRDY

AC05

AK02

CPUTYP

Q35

HLDA

AJ03

PWT

AL03

APCHK#

AE05

D/C#

AK04

HOLD

AB04

R/S#

AC35

BE0#

AL09

D/P#

AE35

IERR#

P04

RESET

AK20

BE1#

AK10

DP0

D36

IGNNE#

AA35

SCYC

AL17

BE2#

AL11

DP1

D30

INIT

AA33

SMI#

AB34

BE3#

AK12

DP2

C25

INTR/

LINT0

AD34

SMIACT#

AG03

BE4#

AL13

DP3

D18

INV

U05

TCK

M34

BE5#

AK14

DP4

C07

KEN#

W05

TDI

N35

BE6#

AL15

DP5

F06

LOCK#

AH04

TDO

N33

BE7#

AK16

DP6

F02

M/IO#

T04

TMS

P34

BOFF#

Z04

DP7

N05

NA#

Y05

TRST#

Q33

BP2

S03

EADS#

AM04

NMI/LINT1

AC33

W/R#

AM06

BP3

S05

EWBE#

W03

PCD

AG05

WB/WT#

AA05

BRDY#

X04

FERR#

Q05

PCHK#

AF04

APIC

PICCLK

H34

PICD0/

[DPEN#]

J33

PICD1/

[APICEN]

L35

Clock Control

CLK

AK18

BF0

Y33

BF1

X34

STPCLK#

V34

Dual Processor Private Interface

PBGNT#

AD04

PBREQ#

AE03

PHIT#

AA03

PHITM#

AC03

Embedded Pentium

Processor

Datasheet

2.1.2

Design Notes

For reliable operation, always connect unused inputs to an appropriate signal level. Unused active
low inputs should be connected to V

. Unused active high inputs should be connected to GND.

No Connect (NC) pins must remain unconnected. Connection of NC pins may result in component
failure or incompatibility with processor steppings.

2.1.3

Pin Quick Reference

This section gives a brief functional description of each of the pins. For a detailed description, see
the Pentium

Processor Family Developer's Manual (order number 273204).

Note:

All input pins must meet their AC/DC specifications to guarantee proper functional behavior.

The # symbol at the end of a signal name indicates that the active, or asserted state occurs when the
signal is at a low voltage. When a # symbol is not present after the signal name, the signal is active,
or asserted at the high voltage level. Square brackets around a signal name indicate that the signal is
defined only at RESET.

The following pins become I/O pins when two Pentium processors are operating in a dual
processing environment:

ADS#, CACHE#, HIT#, HITM#, HLDA#, LOCK#, M/IO#, D/C#, W/R#, SCYC

Table 3. Pin Cross-Reference by Pin Name -- Power, Ground and No Connect Pins

A07

A19

E37

L33

S01

W01

AC01

AN09

AN21

A09

A21

G01

L37

S37

W37

AC37

AN11

AN23

A11

A23

G37

N01

T34

Y01

AE01

AN13

AN25

A13

A25

J01

N37

U01

Y37

AE37

AN15

AN27

A15

A27

J37

Q01

U33

AA01

AG01

AN17

AN29

A17

A29

L01

Q37

U37

AA37

AG37

AN19

B06

B18

H02

P02

U35

Z36

AF36

AM12

AM24

B08

B20

H36

P36

V02

AB02

AH02

AM14

AM26

B10

B22

K02

R02

V36

AB36

AJ37

AM16

AM28

B12

B24

K36

R36

X02

AD02

AL37

AM18

AM30

B14

B26

M02

T02

X36

AD36

AM08

AM20

AN37

B16

B28

M36

T36

Z02

AF02

AM10

AM22

NC/INC

A03

B02

R34

S35

W35

AL19

AN03

AN35

A37

C01

S33

W33

AL01

AN01

AN05

These pins should be left unconnected. Connection of these pins may result in component failure or
incompatibility with processor steppings.

Embedded Pentium

Processor

Datasheet

Table 4. Pin Quick Reference (Sheet 1 of 5)

Symbol

Type

Name and Function

A20M#

When the address bit 20 mask pin is asserted, the processor emulates the address
wraparound at 1 Mbyte that occurs on the 8086 by masking physical address bit 20
(A20) before performing a lookup to the internal caches or driving a memory cycle
on the bus. The effect of A20M# is undefined in protected mode. A20M# must be
asserted only when the processor is in real mode.

A20M# is internally masked by the processor when configured as a Dual processor.

A31A3

I/O

As outputs, the address lines of the processor along with the byte enables define
the physical area of memory or I/O accessed. The external system drives the inquire
address to the processor on A31A5.

ADS#

The address strobe indicates that a new valid bus cycle is currently being driven by
the processor.

ADSC#

The additional address strobe signal is functionally identical to ADS#. This signal
can be used to relieve tight board timings by easing the load on the ADS# signal.

AHOLD

In response to the assertion of address hold, the processor stops driving the
address lines (A31A3), and AP in the next clock. The rest of the bus remains active
so data can be returned or driven for previously issued bus cycles.

I/O

Address parity is driven by the processor with even parity information on all
processor generated cycles in the same clock in which the address is driven. Even
parity must be driven back to the processor during inquire cycles on this pin in the
same clock as EADS# to ensure that the correct parity check status is indicated by
the processor.

APCHK#

The address parity check status pin is asserted two clocks after EADS# is sampled
active if the processor has detected a parity error on the address bus during inquire
cycles. APCHK# remains active for one clock each time a parity error is detected
(including during dual processing private snooping).

[APICEN]

PICD1

Advanced programmable interrupt controller enable enables or disables the on
chip APIC interrupt controller. If sampled high at the falling edge of RESET, the APIC
is enabled. APICEN shares a pin with the PICD1 signal.

BE7#BE5#
BE4#BE0#

I/O

The byte enable pins determine which bytes must be written to external memory, or
which bytes were requested by the CPU for the current cycle. The byte enables are
driven in the same clock as the address lines (A31A3).

The lower four byte enable pins (BE3#BE0#) are used as APIC ID inputs and are
sampled at RESET.

In dual processing mode, BE4# is used as an input during Flush cycles.

BF1BF0

Bus frequency determines the bus-to-core frequency ratio. BF1BF0 are sampled
at RESET, and cannot be changed until another non-warm (1 ms) assertion of
RESET. Additionally, BF1BF0 must not change values while RESET is active. See
Table 5 for bus frequency selections.

BOFF#

The backoff input is used to abort all outstanding bus cycles that have not yet
completed. In response to BOFF#, the processor floats all pins normally floated
during bus hold in the next clock. The processor remains in bus hold until BOFF# is
negated, at which time the processor restarts the aborted bus cycle(s) in their
entirety.

BP3BP2

PM1/BP1

PM0/BP0

The breakpoint pins (BP3BP0) correspond to the debug registers, DR3DR0.
These pins externally indicate a breakpoint match when the debug registers are
programmed to test for breakpoint matches.

BP1 and BP0 are multiplexed with the performance monitoring pins (PM1 and
PM0). The PB1 and PB0 bits in the Debug Mode Control Register determine if the
pins are configured as breakpoint or performance monitoring pins. The pins come
out of RESET configured for performance monitoring.

The pins are classified as Input or Output based on their function in Master Mode. See the

Pentium

Processor

Family Developer's Manual

(order number 273204) for more information.

Embedded Pentium

Processor

Datasheet

BRDY#

The burst ready input indicates that the external system has presented valid data
on the data pins in response to a read or that the external system has accepted the
processor data in response to a write request. This signal is sampled in the T2, T12
and T2P bus states.

BRDYC#

The additional burst ready signal has the same functionality as BRDY#. This signal
can be used to relieve tight board timings by easing the load on the Burst Ready
signal.

BREQ

The bus request output indicates to the external system that the processor has
internally generated a bus request. This signal is always driven whether or not the
processor is driving its bus.

BUSCHK#

The bus check input allows the system to signal an unsuccessful completion of a
bus cycle. When this pin is sampled active, the processor latches the address and
control signals in the machine check registers. When BUSCHK# is asserted and the
MCE bit in CR4 is set, the processor vectors to the machine check exception.

To ensure that BUSCHK# is always recognized, STPCLK# must be deasserted any
time BUSCHK# is asserted by the system, before the system allows another
external bus cycle. When BUSCHK# is asserted by the system for a snoop cycle
while STPCLK# remains asserted, normally (when MCE=1) the processor vectors to
the exception after STPCLK# is deasserted. When another snoop to the same line
occurs during STPCLK# assertion, the processor can lose the BUSCHK# request.

CACHE#

For processor-initiated cycles, the cacheability pin indicates internal cacheability of
the cycle (if a read), and indicates a burst write back cycle (if a write). When this pin
is driven inactive during a read cycle, the processor does not cache the returned
data, regardless of the state of the KEN# pin. This pin is also used to determine the
cycle length (number of transfers in the cycle).

CLK

The clock input provides the fundamental timing for the processor. Its frequency is
the operating frequency of the processor's external bus, and requires TTL levels. All
external timing parameters except TDI, TDO, TMS, TRST#, and PICD1PICD0 are
specified with respect to the rising edge of CLK.

It is recommended that CLK begin toggling within 150 ms after V

reaches its

proper operating level. This recommendation is to ensure long-term reliability of the
device.

CPUTYP

CPU type distinguishes the Primary processor from the Dual processor. In a single
processor environment, or when the processor is acting as the Primary processor in
a dual processing system, CPUTYP should be strapped to V

. The Dual processor

should have CPUTYP strapped to V

D/C#

The data/code output is one of the primary bus cycle definition pins. It is driven valid
in the same clock in which the ADS# signal is asserted. D/C# distinguishes between
data and code or special cycles.

D/P#

The dual/primary processor indication. The Primary processor drives this pin low
when it is driving the bus, otherwise it drives this pin high. D/P# is always driven.
D/P# can be sampled for the current cycle with ADS# (like a status pin). This pin is
defined only on the Primary processor. Dual processing is supported in a system
only if both processors are operating at identical core and bus frequencies. Within
these restrictions, two processors of different steppings may operate together in a
system.

D63D0

I/O

These are the 64 data lines for the processor. Lines D7D0 define the least
significant byte of the data bus; lines D63D56 define the most significant byte of the
data bus. When the CPU is driving the data lines, they are driven during the T2, T12,
or T2P clocks for that cycle. During reads, the CPU samples the data bus when
BRDY# is returned.

Table 4. Pin Quick Reference (Sheet 2 of 5)

Symbol

Type

Name and Function

The pins are classified as Input or Output based on their function in Master Mode. See the

Pentium

Processor

Family Developer's Manual

(order number 273204) for more information.

Embedded Pentium

Processor

Datasheet

DP7DP0

I/O

These are the data parity pins for the processor. There is one for each byte of the
data bus. They are driven by the Pentium processor with even parity information on
writes in the same clock as write data. Even parity information must be driven back
to the processor on these pins in the same clock as the data to ensure that the
correct parity check status is indicated by the Pentium processor. DP7 applies to
D63D56, DP0 applies to D7D0.

[DPEN#]

PICD0

I/O

Dual processing enable is an output of the Dual processor and an input of the
Primary processor. The Dual processor drives DPEN# low to the Primary processor
at RESET to indicate that the Primary processor should enable dual processor
mode. DPEN# may be sampled by the system at the falling edge of RESET to
determine if the dual-processor socket is occupied. DPEN# shares a pin with PICD0.

EADS#

The external address strobe signal indicates that a valid external address has
been driven onto the processor address pins to be used for an inquire cycle.

EWBE#

The external write buffer empty input, when inactive (high), indicates that a write
cycle is pending in the external system. When the processor generates a write, and
EWBE# is sampled inactive, the processor holds off all subsequent writes to all E- or
M-state lines in the data cache until all write cycles have completed, as indicated by
EWBE# being active.

FERR#

The floating-point error pin is driven active when an unmasked floating-point error
occurs. FERR# is similar to the ERROR# pin on the Intel387TM math coprocessor.
FERR# is included for compatibility with systems using DOS-type floating-point error
reporting. FERR# is never driven active by the Dual processor.

FLUSH#

When asserted, the cache flush input forces the processor to write back all
modified lines in the data cache and invalidate its internal caches. A Flush
Acknowledge special cycle is generated by the processor to indicate completion of
the write back and invalidation.

When FLUSH# is sampled low when RESET transitions from high to low, three-state
test mode is entered.

If two Pentium processors are operating in dual processing mode and FLUSH# is
asserted, the Dual processor performs a flush first (without a flush acknowledge
cycle), then the Primary processor performs a flush followed by a flush acknowledge
cycle.

When the FLUSH# signal is asserted in dual processing mode, it must be
deasserted at least one clock prior to BRDY# of the FLUSH Acknowledge cycle to
avoid DP arbitration problems.

FRCMC#

The functional redundancy checking master/checker mode input is used to
determine whether the processor is configured in master mode or checker mode.
When configured as a master, the processor drives its output pins as required by the
bus protocol. When configured as a checker, the processor three-states all outputs
(except IERR# and TDO) and samples the output pins.

The configuration as a master/checker is set after RESET and may not be changed
other than by a subsequent RESET.

HIT#

The inquire cycle hit/miss indication is driven to reflect the outcome of an inquire
cycle. If an inquire cycle hits a valid line in either the processor data or instruction
cache, this pin is asserted two clocks after EADS# is sampled asserted. If the
inquire cycle misses the processor cache, this pin is negated two clocks after
EADS#. This pin changes its value only as a result of an inquire cycle and retains its
value between the cycles.

HITM#

The inquire cycle hit/miss to a modified line output is driven to reflect the
outcome of an inquire cycle. It is asserted after an inquire cycle that results in a hit to
a modified line in the data cache. It is used to inhibit another bus master from
accessing the data until the line is completely written back.

Table 4. Pin Quick Reference (Sheet 3 of 5)

Symbol

Type

Name and Function

The pins are classified as Input or Output based on their function in Master Mode. See the

Pentium

Processor

Family Developer's Manual

(order number 273204) for more information.

Embedded Pentium

Processor

Datasheet

HLDA

The bus hold acknowledge pin goes active in response to a hold request driven to
the processor on the HOLD pin. It indicates that the processor has floated most of
the output pins and relinquished the bus to another local bus master. When leaving
bus hold, HLDA is driven inactive and the processor resumes driving the bus. When
the processor has a bus cycle pending, it is driven in the same clock in which HLDA
is deasserted.

HOLD

In response to the bus hold request, the processor floats most of its output and
input/output pins and asserts HLDA after completing all outstanding bus cycles. The
processor maintains its bus in this state until HOLD is deasserted. HOLD is not
recognized during LOCK cycles. The processor recognizes HOLD during reset.

IERR#

The internal error pin is used to indicate two types of errors, internal parity errors
and functional redundancy errors. When a parity error occurs on a read from an
internal array, the processor asserts the IERR# pin for one clock and then shuts
down. When the processor is configured as a checker and a mismatch occurs
between the value sampled on the pins and the corresponding value computed
internally, the processor asserts IERR# two clocks after the mismatched value is
returned.

LOCK#

The bus lock pin indicates that the current bus cycle is locked. The processor does
not allow a bus hold when LOCK# is asserted (but AHOLD and BOFF# are allowed).
LOCK# goes active in the first clock of the first locked bus cycle and goes inactive
after the BRDY# is returned for the last locked bus cycle. LOCK# is guaranteed to be
deasserted for at least one clock between back-to-back locked cycles.

M/IO#

The memory/input-output is one of the primary bus cycle definition pins. It is driven
valid in the same clock in which the ADS# signal is asserted. M/IO# distinguishes
between memory and I/O cycles.

NA#

An active next address input indicates that the external memory system is ready to
accept a new bus cycle although all data transfers for the current cycle have not yet
completed. The processor issues ADS# for a pending cycle two clocks after NA# is
asserted. The processor supports up to two outstanding bus cycles.

NMI/LINT1

The non-maskable interrupt request signal indicates that an external non-
maskable interrupt has been generated.

When the local APIC is enabled, this pin becomes LINT1.

PBGNT#

I/O

When two Pentium processors are configured in dual processing mode, Private bus
grant is the grant line that is used to perform private bus arbitration. PBGNT# should
be left unconnected if only one Pentium processor exists in a system.

PBREQ#

I/O

When two Pentium processors are configured in dual processing mode, Private bus
request is the request line that is used to perform private bus arbitration. PBREQ#
should be left unconnected if only one Pentium processor exists in a system.

PCD

The page cacheability disable pin reflects the state of the PCD bit in CR3, the
Page Directory Entry, or the Page Table Entry. The purpose of PCD is to provide an
external cacheability indication on a page-by-page basis.

PCHK#

The data parity check output indicates the result of a parity check on a data read. It
is driven with parity status two clocks after BRDY# is returned. PCHK# remains low
one clock for each clock in which a parity error was detected. Parity is checked only
for the bytes on which valid data is returned.

When two Pentium processors are operating in dual processing mode, PCHK# may
be driven two or three clocks after BRDY# is returned.

PEN#

The parity enable input (along with CR4.MCE) determines whether a machine
check exception is taken as a result of a data parity error on a read cycle. When this
pin is sampled active in the clock during which a data parity error is detected, the
processor latches the address and control signals of the cycle with the parity error in
the machine check registers. When PEN# is active and the machine check enable
bit in CR4 is set to "1", the processor vectors to the machine check exception before
the beginning of the next instruction.

Table 4. Pin Quick Reference (Sheet 4 of 5)

Symbol

Type

Name and Function

The pins are classified as Input or Output based on their function in Master Mode. See the

Pentium

Processor

Family Developer's Manual

(order number 273204) for more information.

Embedded Pentium

Processor

Datasheet

PHIT#

I/O

Private inquire cycle hit/miss is a hit indication used to maintain local cache
coherency when two Pentium processors are configured in dual processing mode.
PHIT# should be left unconnected if only one Pentium processor exists in a system.

PHITM#

I/O

Private inquire cycle hit/miss to a modified line is a hit indication used to
maintain local cache coherency when two Pentium processors are configured in
dual processing mode. PHITM# should be left unconnected if only one Pentium
processor exists in a system.

PICCLK

The APIC interrupt controller serial data bus clock is driven into the processor
interrupt controller clock input of the processor.

PICD1/[DPEN#]

PICD0/[APICEN]

I/O

Processor interrupt controller data lines 01 of the processor comprise the data
portion of the APIC 3-wire bus. They are open-drain outputs that require external
pull-up resistors. These signals share pins with DPEN# and APICEN respectively.

PM1/BP1

PM0/BP0

These pins function as part of the performance monitoring feature.

The breakpoint 10 pins are multiplexed with the performance monitoring 10
pins. The PB1 and PB0 bits in the Debug Mode Control Register determine whether
the pins are configured as breakpoint or performance monitoring pins. The pins
come out of RESET configured for performance monitoring.

PRDY

The probe ready output pin indicates that the processor has stopped normal
execution in response to the R/S# pin going active, or Probe Mode being entered.

SMIACT#

An active system management interrupt active output indicates that the processor
is operating in System Management Mode.

STPCLK#

Assertion of the stop clock input signifies a request to stop the internal clock of the
processor, which causes the core to consume less power. When the processor
recognizes STPCLK#, the processor stops execution on the next instruction
boundary, unless superseded by a higher priority interrupt, and generates a stop
grant acknowledge cycle. When STPCLK# is asserted, the processor still responds
to interprocessor and external snoop requests.

TCK

The testability clock input provides the clocking function for the Pentium processor
boundary scan in accordance with the IEEE Boundary Scan interface (Standard
1149.1). It is used to clock state information and data into and out of the processor
during boundary scan.

TDI

The test data input is a serial input for the test logic. TAP instructions and data are
shifted into the processor on the TDI pin on the rising edge of TCK when the TAP
controller is in an appropriate state.

TDO

The test data output is a serial output of the test logic. TAP instructions and data
are shifted out of the processor on the TDO pin on TCK's falling edge when the TAP
controller is in an appropriate state.

TMS

The value of the test mode select input signal sampled at the rising edge of TCK
controls the sequence of TAP controller state changes.

TRST#

When asserted, the test reset input allows the TAP controller to be asynchronously
initialized.

The Pentium processor has 53 3.3 V power inputs.

The Pentium processor has 53 ground inputs.

W/R#

Write/read is one of the primary bus cycle definition pins. It is driven valid in the
same clock in which the ADS# signal is asserted. W/R# distinguishes between write
and read cycles.

WB/WT#

The write back/write through input allows a data cache line to be defined as write
back or write through on a line-by-line basis. As a result, it determines whether a
cache line is initially in the S or E state in the data cache.

Table 4. Pin Quick Reference (Sheet 5 of 5)

Symbol

Type

Name and Function

The pins are classified as Input or Output based on their function in Master Mode. See the

Pentium

Processor

Family Developer's Manual

(order number 273204) for more information.

Embedded Pentium

Processor

Datasheet

2.1.4

Pin Reference Tables

Table 5. Bus Frequency Selections

Pentium

Processor Core

Frequency (max)

External Bus

Frequency (max)

Bus/Core Ratio

BF1

BF0

166 MHz

66 MHz

2/5

133 MHz

66 MHz

1/2

100 MHz

66 MHz

2/3

Table 6. Output Pins

Name

Active Level

When Floated

ADS#

Low

Bus Hold, BOFF#

ADSC#

Low

Bus Hold, BOFF#

APCHK#

Low

BE7#BE5#

Low

Bus Hold, BOFF#

BREQ

High

CACHE#

Low

Bus Hold, BOFF#

D/P#

n/a

FERR#

Low

HIT#

Low

HITM#

Low

HLDA

High

IERR#

Low

LOCK#

Low

Bus Hold, BOFF#

M/IO#

, D/C#

, W/R#

n/a

Bus Hold, BOFF#

PCHK#

Low

BP3BP2, PM1/BP1, PM0/BP0

High

PRDY

High

PWT, PCD

High

Bus Hold, BOFF#

SCYC

High

Bus Hold, BOFF#

SMIACT#

Low

TDO

n/a

All states except Shift-DR and Shift-IR

NOTES:

1. All output and input/output pins are floated during three-state test mode and checker mode (except

IERR#).

2. These are I/O signals when two Pentium

processors are operating in dual processing mode.

3. These signals are undefined when the processor is configured as a dual processor.

Embedded Pentium

Processor

Datasheet

Table

7. Input

Pins

Name

Active Level

Synchronous/

Asynchronous

Internal Resistor

Qualified

A20M#

Low

Asynchronous

AHOLD

High

Synchronous

BF1BF0

High

Synchronous/RESET

Pullup

BOFF#

Low

Synchronous

BRDY#

Low

Synchronous

Bus State T2, T12, T2P

BRDYC#

Low

Synchronous

Pullup

Bus State T2, T12, T2P

BUSCHK#

Low

Synchronous

Pullup

BRDY#

CLK

n/a

CPUTYP

High

Synchronous/RESET

EADS#

Low

Synchronous

EWBE#

Low

Synchronous

BRDY#

FLUSH#

Low

Asynchronous

FRCMC#

Low

Asynchronous

HOLD

High

Synchronous

IGNNE#

Low

Asynchronous

INIT

High

Asynchronous

INTR

High

Asynchronous

INV

High

Synchronous

EADS#

KEN#

Low

Synchronous

First BRDY#/NA#

NA#

Low

Synchronous

Bus State T2,TD,T2P

NMI

High

Asynchronous

PEN#

Low

Synchronous

BRDY#

PICCLK

High

Asynchronous

Pullup

R/S#

n/a

Asynchronous

Pullup

RESET

High

Asynchronous

SMI#

Low

Asynchronous

Pullup

STPCLK#

Low

Asynchronous

Pullup

TCK

n/a

Pullup

TDI

n/a

Synchronous/TCK

Pullup

TCK

TMS

n/a

Synchronous/TCK

Pullup

TCK

TRST#

Low

Asynchronous

Pullup

WB/WT#

n/a

Synchronous

First BRDY#/NA#

Undefined when the processor is configured as a dual processor.

Embedded Pentium

Processor

Datasheet

Table 8. Input/Output Pins

Name

Active

Level

When Floated

Qualified

(when an input)

Internal

Resistor

A31A3

n/a

Address Hold, Bus Hold, BOFF#

EADS#

n/a

Address Hold, Bus Hold, BOFF#

EADS#

BE4#BE0#

Low

Address Hold, Bus Hold, BOFF#

RESET

Pulldown

D63D0

n/a

Bus Hold, BOFF#

BRDY#

DP7DP0

n/a

Bus Hold, BOFF#

BRDY#

PICD0[DPEN#]

Pullup

PICD1[APICEN]

Pulldown

NOTES:

1. All output and input/output pins are floated during three-state test mode (except TDO) and checker mode

(except IERR# and TDO).

2. BE3#BE0# have pulldowns during RESET only.

Table 9. Inter-processor Input/Output Pins

Name

Active Level

Internal Resistor

PHIT#

Low

Pullup

PHITM#

Low

Pullup

PBGNT#

Low

Pullup

PBREQ#

Low

Pullup

For proper interprocessor operation, the system cannot load these signals.

Embedded Pentium

Processor

Datasheet

2.1.5

Pin Grouping According to Function

Table 10. Pin Functional Grouping

Function

Pins

Clock

CLK

Initialization

RESET, INIT, BF1BF0

Address Bus

A31A3, BE7#BE0#

Address Mask

A20M#

Data Bus

D63D0

Address Parity

AP, APCHK#

APIC Support

PICCLK, PICD1PICD0

Data Parity

DP7DP0, PCHK#, PEN#

Internal Parity Error

IERR#

System Error

BUSCHK#

Bus Cycle Definition

M/IO#, D/C#, W/R#, CACHE#, SCYC, LOCK#

Bus Control

ADS#, ADSC#, BRDY#, BRDYC#, NA#

Page Cacheability

PCD, PWT

Cache Control

KEN#, WB/WT#

Cache Snooping/Consistency

AHOLD, EADS#, HIT#, HITM#, INV

Cache Flush

FLUSH#

Write Ordering

EWBE#

Bus Arbitration

BOFF#, BREQ, HOLD, HLDA

Dual Processing Private Bus Control

PBGNT#, PBREQ#, PHIT#, PHITM#

Interrupts

INTR, NMI

Floating-point Error Reporting

FERR#, IGNNE#

System Management Mode

SMI#, SMIACT#

Functional Redundancy Checking

FRCMC# (IERR#)

TAP Port

TCK, TMS, TDI, TDO, TRST#

Breakpoint/Performance Monitoring

PM0/BP0, PM1/BP1, BP3BP2

Power Management

STPCLK#

Miscellaneous Dual Processing

CPUTYP, D/P#

Probe Mode

R/S#, PRDY

Embedded Pentium

Processor

Datasheet

2.2

Mechanical Specifications

The embedded Pentium processor is packaged in a 296-pin ceramic staggered pin grid array
(SPGA) package. The pins are arranged in a 37 x 37 matrix and the package dimensions are 1.95"
x 1.95" (Table 11). Figure 4 and Table 12 show the package dimensions.

Table 11. Package Information Summary for Pentium

Processor

Package Type

Total

Pins

Pin Array

Package Size

Ceramic Staggered Pin Grid Array

SPGA

296

37 x 37

1.95" x 1.95"

4.95 cm x 4.95 cm

Figure 4. SPGA Package Dimensions

Table 12. SPGA Package Dimensions Key

Symbol

Millimeters

Inches

Min Max

Notes Min Max Notes

A 2.62

2.97

0.103

0.117

0.69

0.84

Metal Lid

0.027

0.033

Metal Lid

3.31

3.81

Metal Lid

0.130

0.150

Metal Lid

B 0.43

0.51

0.017

0.020

D 49.28

49.78

1.940

1.960

45.59

45.85

1.795

1.805

2.29

2.79

0.090

0.110

L 3.05

3.30

0.120

0.130

296

Lead Count

296

Lead Count

1.52

2.54

0.060

0.100

2.29
1.52

Chamfer

(index corner)

Ref.

01.65

Ref.

Seating Plane

Pin C3

Embedded Pentium

Processor

Datasheet

2.3

Thermal Specifications

The Pentium processor is specified for proper operation when case temperature, T

CASE

), is

within the specified range of 0° C to 70° C.

The power dissipation specification in Table 13 is provided for designing thermal solutions for
operation at a sustained maximum level. This is the worst-case power the device would dissipate in
a system. This number is used for design of a thermal solution for the device.

2.3.1

Measuring Thermal Values

To verify that the proper T

(case temperature) is maintained, it should be measured at the center of

the package top surface (opposite of the pins). The measurement is made in the same way with or
without a heatsink attached. When a heatsink is attached, a hole (0.150" diameter or smaller)
should be drilled through the heatsink to allow a probe to touch the center of the package. See
Figure 5 for an illustration of how to measure T

To minimize the measurement errors, use the following approach:

Use 36-gauge or finer diameter K, T, or J type thermocouples.

Attach the thermocouple bead or junction to the center of the package top surface using high
thermal conductivity cements.

Attach the thermocouple at a 90-degree angle as shown in Figure 5.

The hole size should be 0.150" or less in diameter.

Table 13. Power Dissipation Requirements for Thermal Solution Design

Parameter

Typical

Max

Unit

Notes

Active Power Dissipation

5.4
4.3
3.9

14.5

11.2

10.1

Watts

166 MHz
133 MHz
100 MHz

Stop Grant and Auto Halt Powerdown

Power Dissipation

2.1
1.7

1.55

Watts

166 MHz, Note 4
133 MHz, Note 4
100 MHz, Note 4

Stop Clock Power Dissipation

0.02

<0.3

Watts

Note 5

NOTES:

1. This is the typical power dissipation in a system. This value was the average value measured in a system

using a typical device at nominal V

(3.3 V for 100 and 133 MHz processors and 3.5 V for 166 MHz

processors) running typical applications. This value is highly dependent upon the specific system
configuration.

2. Systems must be designed to thermally dissipate the maximum active power of the device. It is

determined using a worst-case instruction mix with V

=3.5 V, and also takes into account the thermal

time constants of the package.

3. Systems must be designed to thermally dissipate the maximum active power of the device. It is

determined using a worst case instruction mix with V

= 3.3 V and also takes into account the thermal

time constants of the package.

4. Stop Grant/Auto Halt Powerdown power dissipation is determined by asserting the STPCLK# pin or

executing the HALT instruction.

5. Stop Clock power dissipation is determined by asserting the STPCLK# pin and then removing the

external CLK input.

Embedded Pentium

Processor

Datasheet

2.3.2

Thermal Equations And Data

For the Pentium processor, an ambient temperature, T

(air temperature around the processor), is

not specified directly. The only restriction is that the case temperature (T

) is met. To calculate T

values, use the following equations:

= T

(P *

)

where:

and T

ambient and case temperature (

case-to-ambient thermal resistance (

C/W)

junction-to-ambient thermal resistance (

C/W)

junction-to-case thermal resistance (

C/W)

P =

maximum power consumption in Watts (see Table 13)

Table 14 lists the

values for the Pentium processor with passive heatsinks.

Thermal data collection parameters:

Heatsinks are omnidirectional pin aluminum alloy

Features were based on standard extrusion practices for a given height

Pin size ranged from 50 to 129 mils

Pin spacing ranged from 93 to 175 mils

Base thickness ranged from 79 to 200 mils

Heatsink attach was 0.005" of thermal grease

Using an attach thickness of 0.002" improves performance by approximately 0.3

C/W

Figure 5. Technique for Measuring Case Temperature (T

)

Embedded Pentium

Processor

Datasheet

3.0

Electrical Specifications

This section describes the DC and AC specifications for the embedded Pentium processor.

3.1

3.3 V Power Supply

The processor has all V

3.3-V inputs. The CLK and PICCLK inputs can tolerate a 5-V input

signal. This allows the processor to use 5-V or 3.3-V clock drivers.

3.2

3.3 V Inputs and Outputs

The inputs and outputs of the processor are 3.3 V JEDEC standard levels. Both inputs and outputs
are also TTL-compatible, although the inputs cannot tolerate voltage swings above the 3.3 V V

max. The CLK and PICCLK inputs of the processor are 5 V tolerant. This allows a 5-V clock
driver to drive the processor. All other pins are 3.3 V only.

For processor outputs, if the system support components use TTL-compatible inputs, the
components will interface to the processor without extra logic. This is because the processor drives
according to the 5-V TTL specification (but not beyond 3.3 V).

For processor inputs, the voltage must not exceed the 3.3 V V

IH3

maximum specification. System

support components can consist of 3.3 V devices or open-collector devices. In an open-collector
configuration, the external resistor can be biased with the processor's V

. As the processor's V

changes from 5 V to 3.3 V, so does this signal's maximum drive.

3.3

Absolute Maximum Ratings

Functional operating conditions are given in the AC and DC specification tables. Functional
operation at the maximums is not implied or guaranteed. Extended operation beyond the maximum
ratings may affect device reliability. Furthermore, although the Pentium processor contains
protective circuitry to resist damage from static electric discharge, always take precautions to avoid
high static voltages or electric fields.

Warning:

Stressing the device beyond the "Absolute Maximum Ratings" may cause permanent damage.
These are stress ratings only.

Embedded Pentium

Processor

Datasheet

3.4

DC Specifications

Tables 1618 list the DC specifications that apply to the Pentium processor. The Pentium processor
is a 3.3 V part internally. The CLK and PICCLK inputs may be 3.3 V or 5 V inputs. Since the 3.3 V
(5 V-safe) input levels defined in Table 16 are the same as the 5 V TTL levels, the CLK and
PICCLK inputs are compatible with existing 5 V clock drivers.

Table 15. Absolute Maximum Ratings

Parameter

Maximum Rating

Case temperature under bias

C to 110

Storage temperature

C to 150

3 V Supply voltage with respect to V

0.5 V to +4.6 V

3 V Only Buffer DC Input Voltage

0.5 V to V

+ 0.5; not to exceed V

CC3

max

5 V Safe Buffer DC Input Voltage

0.5 V to 6.5 V

2,3

NOTES:

1. Applies to all Pentium

processor inputs except CLK and PICCLK.

2. Applies to CLK and PICCLK.
3. See overshoot/undershoot transient specification.

Table 16. 3.3 V DC Specifications

CASE

= 0 to 70° C; 3.135 V < V

< 3.6 V for 100 and 133 MHz devices

CASE

= 0 to 70° C; 3.4 V < V

< 3.6 V for 166 MHz (VRE device)

Symbol

Parameter

Min

Max

Unit

Notes

IL3

Input Low Voltage

0.3

0.8

TTL Level, Note 1

IH3

Input High Voltage

2.0

+0.3

TTL Level, Note 1

OL3

Output Low Voltage

0.4

TTL Level,

Note 2, Note 1

OH3

Output High Voltage

2.4

TTL Level,

Note 3, Note 1

CC3

Power Supply Current

4250
3400
3250

mA
mA
mA

166 MHz, Note 4
133 MHz, Note 4
100 MHz, Note 4

NOTES:

1. 3.3 V TTL levels apply to all signals except CLK and PICCLK.
2. Parameter measured at 4 mA.
3. Parameter measured at 3 mA.
4. This value should be used for power supply design. It was determined using a worst-case instruction mix

and V

= 3.6 V. Power supply transient response and decoupling capacitors must be sufficient to handle

the instantaneous current changes occurring during transitions from stop clock to full active modes. For
more information, refer to "Decoupling Recommendations" on page 32.

Table 17. 3.3 V (5 V-Safe) DC Specifications

Symbol

Parameter

Min

Max

Unit

Notes

IL5

Input Low Voltage

0.3

0.8

TTL Level

IH5

Input High Voltage

2.0

5.55

TTL Level

Applies to CLK and PICCLK only.

Embedded Pentium

Processor

Datasheet

3.5

AC Specifications

The AC specifications of the Pentium processor consist of setup times, hold times, and valid delays
at 0 pF.

3.5.1

Private Bus

When two Pentium processor are operating in dual processor mode, a "private bus" exists to
arbitrate for the processor bus and maintain local cache coherency. The private bus consists of two
pinout changes:

1. Five pins are added: PBREQ#, PBGNT#, PHIT#, PHITM#, D/P#.

2. Ten output pins become I/O pins: ADS#, D/C#, W/R#, M/IO#, CACHE#, LOCK#, HIT#,

HITM#, HLDA, SCYC.

The new pins are given AC specifications of valid delays at 0 pF, setup times, and hold times.
Simulate with these parameters and their respective I/O buffer models to guarantee that proper
timings are met.

The AC specification gives input setup and hold times for the ten signals that become I/O pins.
These setup and hold times must only be met when a dual processor is present in the system.

3.5.2

Power and Ground

For clean on-chip power distribution, the Pentium processor has 53 V

(power) and 53 V

(ground) inputs. Power and ground connections must be made to all external V

and V

pins of

the processor. On the circuit board all V

pins must be connected to a V

plane. All V

pins

must be connected to a V

plane.

Table 18. Input and Output Characteristics

Symbol

Parameter

Min

Max

Unit

Notes

Input Capacitance

Guaranteed by design.

Output Capacitance

Guaranteed by design.

I/O

I/O Capacitance

Guaranteed by design.

CLK

CLK Input Capacitance

Guaranteed by design.

TIN

Test Input Capacitance

Guaranteed by design.

TOUT

Test Output Capacitance

Guaranteed by design.

TCK

Test Clock Capacitance

Guaranteed by design.

Input Leakage Current

0 < V

< V

CC3

, This

parameter is for input
without pullup or pulldown.

Output Leakage Current

0 < V

< V

CC3

, This

parameter is for input
without pullup or pulldown.

Input Leakage Current

200

= 2.4 V, This parameter

is for input with pulldown.

Input Leakage Current

400

= 0.4 V, This parameter

is for input with pullup.

Embedded Pentium

Processor

Datasheet

3.5.3

Decoupling Recommendations

Liberal decoupling capacitance should be placed near the processor. Transient power surges can
occur when the processor is driving its address and data buses at high frequencies. This is most
common when driving large capacitive loads.

Low inductance capacitors and interconnects are recommended for best high frequency electrical
performance. Inductance can be reduced by minimizing the length of the circuit board traces
between the processor and the decoupling capacitors.

These capacitors should be evenly distributed around each component on the 3.3 V plane.
Capacitor values should be chosen to ensure that they eliminate both low and high frequency noise
components.

For the Pentium processor, the power consumption can transition from a low power level to a much
higher level (or high-to-low power) very rapidly. A typical example is when entering or exiting the
Stop Grant state. Other examples are when executing a HALT instruction (causing the processor to
enter the Auto HALT Powerdown state) or when transitioning from HALT to the Normal state. All
these examples may cause abrupt changes in the power being consumed by the processor. Note that
the Auto HALT Powerdown feature is always enabled even when other power management
features are not implemented.

Bulk storage capacitors with a low ESR (Effective Series Resistance) in the 10 to 100 µF range are
required to maintain a regulated supply voltage during the interval between the time the current
load changes and the point at which the regulated power supply output reacts to the change in load.
In order to reduce the ESR, it may be necessary to place several bulk storage capacitors in parallel.

These capacitors should be placed near the processor (on the 3.3 V plane) to ensure that the supply
voltage stays within specified limits during changes in the supply current during operation.

3.5.4

Connection Specifications

All NC and INC pins must remain unconnected. For reliable operation, always connect unused
inputs to an appropriate signal level. Unused active low inputs should be connected to V

. Unused

active high inputs should be connected to ground.

3.5.5

AC Timing Tables

The AC specifications given in Table 19 and Table 20 consist of output delays, input setup
requirements and input hold requirements for a 66-MHz external bus. All AC specifications (with
the exception of those for the TAP signals and APIC signals) are relative to the rising edge of the
CLK input.

All timings are referenced to 1.5 V for both "0" and "1" logic levels unless otherwise specified.
Within the sampling window, a synchronous input must be stable for correct processor operation.
Each valid delay is specified for a 0 pF load. The system designer should use I/O buffer models to
account for signal flight time delays.

The following applies to all standard TTL signals used with the Pentium processor family:

TTL input test waveforms are assumed to be 0 to 3 V transitions with 1 V/ns rise and fall
times.

0.3 V/ns

input rise/fall time

5 V/ns.

Embedded Pentium

Processor

Datasheet

Table 19. AC Specifications (Sheet 1 of 3)

CASE

= 0 to 70° C; 3.135 V < V

< 3.6 V for 100 and 133 MHz devices, C

= 0 pF

CASE

= 0 to 70° C; 3.4 V < V

< 3.6 V for 166 MHz (VRE device), C

= 0 pF

Symbol

Parameter

Min

Max

Unit

Figure

Notes

Frequency

33.33

66.6

MHz

CLK Period

15.0

30.0

CLK Period Stability

Adjacent Clocks,

Notes 1, 21

CLK High Time

4.0

2 V, Note 1

CLK Low Time

4.0

0.8 V, Note 1

CLK Fall Time

0.15

1.5

2.0 V0.8 V,

Note 1

CLK Rise Time

0.15

1.5

0.8 V2.0 V,

Note 1

PWT, PCD, CACHE# Valid Delay

1.0

7.0

AP Valid Delay

1.0

8.5

BE7#BE0#, LOCK# Valid Delay

0.9

7.0

ADS# Valid Delay

0.8

6.0

ADSC#, D/C#, W/R#, SCYC, Valid Delay

0.8

7.0

M/IO# Valid Delay

0.8

5.9

A16A3 Valid Delay

0.5

6.3

A31A17 Valid Delay

0.6

6.3

ADS#, ADSC#, AP, A31A3, PWT, PCD,
BE7#BE0#, M/IO#, D/C#, W/R#,
CACHE#, SCYC, LOCK# Float Delay

10.0

APCHK#, IERR#, FERR# Valid Delay

1.0

8.3

PCHK# Valid Delay

1.0

7.0

BREQ Valid Delay

1.0

8.0

SMIACT# Valid Delay

1.0

7.3

HLDA Valid Delay

1.0

6.8

10a

HIT# Valid Delay

1.0

6.8

10b

HITM# Valid Delay

0.7

6.0

11a

PM1PM0, BP3BP0 Valid Delay

1.0

10.0

11b

PRDY Valid Delay

1.0

8.0

D63D0, DP7DP0 Write Data Valid Delay

1.3

7.5

D63D0, DP3DP0 Write Data Float Delay

10.0

A31A5 Setup Time

6.0

A31A5 Hold Time

1.0

16a

INV, AP Setup Time

5.0

16b

EADS# Setup Time

5.0

EADS#, INV, AP Hold Time

1.0

18a

KEN# Setup Time

5.0

18b

NA#, WB/WT# Setup Time

4.5

NOTE: See Table 21 for notes.

Embedded Pentium

Processor

Datasheet

KEN#, WB/WT#, NA# Hold Time

1.0

BRDY#, BRDYC# Setup Time

5.0

BRDY#, BRDYC# Hold Time

1.0

AHOLD, BOFF# Setup Time

5.5

AHOLD, BOFF# Hold Time

1.0

24a

BUSCHK#, EWBE#, HOLD Setup Time

5.0

24b

PEN# Setup Time

4.8

25a

BUSCHK#, EWBE#, PEN# Hold Time

1.0

25b

HOLD Hold Time

1.5

A20M#, INTR, STPCLK# Setup Time

5.0

9, 12

A20M#, INTR, STPCLK# Hold Time

1.0

INIT, FLUSH#, NMI, SMI#, IGNNE# Setup
Time

5.0

9, 12, 13

INIT, FLUSH#, NMI, SMI#, IGNNE# Hold
Time

1.0

INIT, FLUSH#, NMI, SMI#, IGNNE# Pulse
Width, Async

2.0

CLKs

11, 13

R/S# Setup Time

5.0

9, 12, 13

R/S# Hold Time

1.0

R/S# Pulse Width, Async.

2.0

CLKs

11, 13

D63D0, DP7DP0 Read Data Setup Time

2.8

D63D0, DP7DP0 Read Data Hold Time

1.5

RESET Setup Time

5.0

8, 9, 12

RESET Hold Time

1.0

8, 10

RESET Pulse Width, V

& CLK Stable

15.0

CLKs

8, 13

RESET Active After V

& CLK Stable

1.0

Power up

Reset Configuration Signals (INIT,
FLUSH#, FRCMC#) Setup Time

5.0

9, 12, 13

Reset Configuration Signals (INIT,
FLUSH#, FRCMC#) Hold Time

1.0

42a

Reset Configuration Signals (INIT,
FLUSH#, FRCMC#) Setup Time, Async.

2.0

CLKs

To RESET falling

edge, Note 12

42b

Reset Configuration Signals (INIT,
FLUSH#, FRCMC#, BRDYC#, BUSCHK#)
Hold Time, Async.

2.0

CLKs

To RESET falling

edge, Note 23

42d

Reset Configuration Signal BRDYC# Hold
Time, RESET driven synchronously

1.0

To RESET falling

edge, 1, 23

43a

BF, CPUTYP Setup Time

1.0

To RESET falling

edge, Note 18

43b

BF, CPUTYP Hold Time

2.0

CLKs

To RESET falling

edge, Note 18

Table 19. AC Specifications (Sheet 2 of 3)

CASE

= 0 to 70° C; 3.135 V < V

< 3.6 V for 100 and 133 MHz devices, C

= 0 pF

CASE

= 0 to 70° C; 3.4 V < V

< 3.6 V for 166 MHz (VRE device), C

= 0 pF

Symbol

Parameter

Min

Max

Unit

Figure

Notes

NOTE: See Table 21 for notes.

Embedded Pentium

Processor

Datasheet

43c

APICEN, BE4# Setup Time

2.0

CLKs

To RESET falling

edge

43d

APICEN, BE4# Hold Time

2.0

CLKs

To RESET falling

edge

TCK Frequency

16.0

MHz

TCK Period

62.5

TCK High Time

25.0

2 V, Note 1

TCK Low Time

25.0

0.8 V, Note 1

TCK Fall Time

5.0

2.0 V0.8 V,

Notes 1,5,6

TCK Rise Time

5.0

0.8 V2.0 V,

Notes 1,5,6

TRST# Pulse Width

40.0

Asynchronous,

Note 1

TDI, TMS Setup Time

5.0

TDI, TMS Hold Time

13.0

TDO Valid Delay

3.0

20.0

TDO Float Delay

25.0

1, 5

All Non-Test Outputs Valid Delay

3.0

20.0

2, 5, 7

All Non-Test Outputs Float Delay

25.0

1, 2, 5, 7

All Non-Test Inputs Setup Time

5.0

2, 4, 7

All Non-Test Inputs Hold Time

13.0

2, 4, 7

APIC AC Specifications

60a

PICCLK Frequency

2.0

16.66

MHz

60b

PICCLK Period

60.0

500.0

60c

PICCLK High Time

15.0

60d

PICCLK Low Time

15.0

60e

PICCLK Rise Time

0.15

2.5

60f

PICCLK Fall Time

0.15

2.5

60g

PICD1PICD0 Setup Time

3.0

To PICCLK

60h

PICD1PICD0 Hold Time

2.5

To PICCLK

60i

PICD1PICD0 Valid Delay (LtoH)

4.0

38.0

From PICCLK,

Notes 24, 25

60j

PICD1PICD0 Valid Delay (HtoL)

4.0

22.0

From PICCLK,

Notes 24, 25

PICCLK Setup Time

5.0

To CLK, Note 26

PICCLK Hold Time

2.0

To CLK, Note 26

PICCLK Ratio (CLK/PICCLK)

Table 19. AC Specifications (Sheet 3 of 3)

CASE

= 0 to 70° C; 3.135 V < V

< 3.6 V for 100 and 133 MHz devices, C

= 0 pF

CASE

= 0 to 70° C; 3.4 V < V

< 3.6 V for 166 MHz (VRE device), C

= 0 pF

Symbol

Parameter

Min

Max

Unit

Figure

Notes

NOTE: See Table 21 for notes.

Embedded Pentium

Processor

Datasheet

Table 20. Dual Processor Mode AC Specifications

CASE

= 0 to 70° C; 3.135 V < V

< 3.6 V for 100 and 133 MHz devices, C

= 0 pF

CASE

= 0 to 70° C; 3.4 V < V

< 3.6 V for 166 MHz (VRE device), C

= 0 pF

Symbol

Parameter

Min

Max

Unit

Figure

Notes

80a

PBREQ#, PBGNT#, PHIT# Flight Time

2.0

20, 25

80b

PHITM# Flight Time

1.8

20, 25

83a

A31A5 Setup Time

3.7

14, 17, 22

83b

D/C#, W/R#, CACHE#, LOCK#, SCYC
Setup Time

83c

ADS#, M/IO# Setup Time

5.8

14, 17

83d

HIT#, HITM# Setup Time

6.0

14, 17

83e

HLDA Setup Time

6.0

14, 17

ADS#, D/C#, W/R#, M/IO#, CACHE#,
LOCK#, A31A5, HLDA, HIT#, HITM#,
SCYC Hold Time

1.0

14, 17

DPEN# Valid Time

10.0

CLKs

14, 15, 19

DPEN# Hold Time

2.0

CLKs

14, 16, 19

APIC ID (BE3#BE0#) Setup Time

2.0

CLKs

To RESET falling

edge, Note 19

APIC ID (BE3#BE0#) Hold Time

2.0

CLKs

From RESET

falling edge,

Note 19

D/P# Valid Delay

1.0

8.0

Primary

Processor Only

NOTE: See Table 21 for table notes.

Embedded Pentium

Processor

Datasheet

Table 21. Notes for Tables 19 and 20

1. Not 100% tested. Guaranteed by design/characterization.
2. Non-test outputs and inputs are the normal output or input signals (besides TCK, TRST#, TDI, TDO, and

TMS). These timings correspond to the response of these signals due to boundary scan operations.

3. APCHK#, FERR#, HLDA, IERR#, LOCK#, and PCHK# are glitch-free outputs. Glitch-free signals

monotonically transition without false transitions.

4. Referenced to TCK rising edge.
5. Referenced to TCK falling edge.
6. 1 ns can be added to the maximum TCK rise and fall times for every 10 MHz of frequency below 33 MHz.
7. During probe mode operation, do not use the boundary scan timings (t

55-58

8. FRCMC# should be tied to V

(high) to ensure proper operation of the Pentium processor as a primary

processor.

9. Setup time is required to guarantee recognition on a specific clock. The Pentium processor must meet this

specification for dual processor operation for the FLUSH# and RESET signals.

10.Hold time is required to guarantee recognition on a specific clock. The Pentium processor must meet this

specification for dual processor operation for the FLUSH# and RESET signals.

11. To guarantee proper asynchronous recognition, the signal must have been deasserted (inactive) for a

minimum of two clocks before being returned active and must meet the minimum pulse width.

12.This input may be driven asynchronously. However, when operating two processors in dual processing

mode, FLUSH# and RESET must be asserted synchronously to both processors.

13.When driven asynchronously, RESET, NMI, FLUSH#, R/S#, INIT, and SMI# must be deasserted (inactive)

for a minimum of two clocks before being returned active.

14.Timings are valid only when dual processor is present.
15.Maximum time DPEN# is valid from rising edge of RESET.
16.Minimum time DPEN# is valid after falling edge of RESET.
17.The D/C#, M/IO#, W/R#, CACHE#, and A31A5 signals are sampled only on the CLK during which ADS#

is active.

18.BF and CPUTYP should be strapped to V

or V

19.RESET is synchronous in dual processing mode and functional redundancy checking mode. All signals

that have a setup or hold time with respect to a falling or rising edge of RESET in UP mode should be
measured with respect to the first processor clock edge in which RESET is sampled either active or
inactive in dual processing and functional redundancy checking modes.

20.The PHIT# and PHITM# signals operate at the core frequency.
21.These signals are measured on the rising edge of adjacent CLKs at 1.5 V. To ensure a 1:1 relationship

between the amplitude of the input jitter and the internal and external clocks, the jitter frequency spectrum
should not have any power spectrum peaking between 500 KHz and 1/3 of the CLK operating frequency.
The amount of jitter present must be accounted for as a component of CLK skew between devices.

22.In dual processing mode, timing t

is replaced by t

83a

. Timing t

is required for external snooping (e.g.,

address setup to the CLK in which EADS# is sampled active) in both uniprocessor and dual processor
modes.

23.BRDYC# and BUSCHK# are used as reset configuration signals to select buffer size.
24.This assumes an external pullup resistor to V

and a lumped capacitive load. The pullup resistor must be

between 300 Ohms and 1 KOhms, the capacitance must be between 20 pF and 120 pF, and the RC
product must be between 3 ns and 36 ns. V

for PICD1PICD0 is 0.55 V.

25.This is a flight time specification that includes both flight time and clock skew. The flight time is the time

from when the unloaded driver crosses 1.5 V (50% of min. V

), to when the receiver crosses the 1.5 V

level (50% of min. V

). See Figure 13.

26.This is for the lock-step operation of the component only. This guarantees that APIC interrupts will be

recognized on specific clocks to support two processors running in a lock step fashion, including FRC
mode. FRC on the APIC pins is not supported but mismatches on these pins will result in a mismatch on
other pins of the CPU.

27.The CLK to PICCLK ratio for lock-step operation must be an integer and the ratio (CLK/PICCLK) cannot be

smaller than 4:1.

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