December 1997

Order Number: 272731-002

EMBEDDED ULTRA-LOW POWER

Intel486

SX PROCESSOR

Figure 1. Embedded Ultra-Low Power Intel486TM SX Processor Block Diagram

Ultra-Low Power Version of the Intel486TM
SX Processor
-- 32-Bit RISC Technology Core
-- 8-Kbyte Write-Through Cache
-- Four Internal Write Buffers
-- Burst Bus Cycles
-- Dynamic Bus Sizing for 8- and 16-bit

Data Bus Devices

-- Intel System Management Mode (SMM)
-- Boundary Scan (JTAG)

176-Lead Thin Quad Flat Pack (TQFP)

Separate Voltage Supply for Core Circuitry

Fast Core-Clock Restart

Auto Clock Freeze

Ideal for Embedded Battery-Operated and
Hand-Held Applications

A5850-01

Paging

Unit

Prefetcher

32-Byte Code

Queue

2x16 Bytes

Code

Stream

Barrel

Shifter

Cache Unit

Burst Bus

Control

Bus Control

Write Buffers

4 x 32

64-Bit Interunit Transfer Bus

File

ALU

Segmentation

Unit

Descriptor

Registers

Limit and

Attribute PLA

Base/

Index

Bus

Translation

Lookaside

Buffer

8 Kbyte

Cache

Clock

Control

Control &

Protection

Test Unit

Control

ROM

Address

Drivers

CLK Input

Core

Clock

Data Bus

Transceivers

Request

Sequencer

Bus Size

Control

Cache

Control

Boundary

Scan

Control

Bus Interface

D31-D0

A31-A2
BE3#- BE0#

ADS# W/R# D/C# M/IO#
PCD PWT RDY# LOCK#
PLOCK# BOFF# A20M#
BREQ HOLD HLDA
RESET SRESET INTR
NMI SMI# SMIACT#
STPCLK#

BRDY# BLAST#

BS16# BS8#

KEN# FLUSH#
AHOLD EADS#

TCK TMS
TDI TD0

Instruction

Decode

Decoded

Instruction

Path

PCD

PWT

Physical
Address

32-Bit Data Bus

Linear Address

Micro-

Instruction

Displacement Bus

128

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 Embedded Ultra-Low Power Intel486TM SX 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.

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.

Contents

iii

Embedded Ultra-Low Power

Intel486

SX Processor

1.0 INTRODUCTION ........................................................................................................................................ 1

1.1 Features ............................................................................................................................................. 1

1.2 Family Members ................................................................................................................................. 2

2.0 HOW TO USE THIS DOCUMENT ............................................................................................................. 3

3.0 PIN DESCRIPTIONS ................................................................................................................................. 3

3.1 Pin Assignments ................................................................................................................................. 3

3.2 Pin Quick Reference ........................................................................................................................... 7

4.0 ARCHITECTURAL AND FUNCTIONAL OVERVIEW ............................................................................. 15

4.1 Separate Supply Voltages ................................................................................................................ 15

4.2 Fast Clock Restart ............................................................................................................................ 17

4.3 Level-Keeper Circuits ....................................................................................................................... 18

4.4 Low-Power Features ........................................................................................................................ 19

4.4.1 Auto Clock Freeze ................................................................................................................. 19

4.5 CPUID Instruction ............................................................................................................................. 19

4.5.1 Operation of the CPUID Instruction ....................................................................................... 19

4.6 Identification After Reset .................................................................................................................. 20

4.7 Boundary Scan (JTAG) .................................................................................................................... 21

4.7.1 Device Identification ............................................................................................................... 21

4.7.2 Boundary Scan Register Bits and Bit Order ........................................................................... 21

5.0 ELECTRICAL SPECIFICATIONS ........................................................................................................... 22

5.1 Maximum Ratings ............................................................................................................................. 22

5.2 DC Specifications ............................................................................................................................. 22

5.3 AC Specifications ............................................................................................................................. 25

5.4 Capacitive Derating Curves .............................................................................................................. 32

6.0 MECHANICAL DATA .............................................................................................................................. 33

6.1 Package Dimensions ........................................................................................................................ 33

6.2 Package Thermal Specifications ...................................................................................................... 34

FIGURES

Figure 1.

Embedded Ultra-Low Power Intel486TM SX Processor Block Diagram ...................................... i

Figure 2.

Package Diagram for 176-Lead TQFP Package Embedded ULP Intel486TM SX Processor .... 4

Figure 3.

Example of Supply Voltage Power Sequence ......................................................................... 16

Figure 4.

Stop Clock State Diagram with Typical Power Consumption Values ...................................... 17

Figure 5.

CLK Waveform ........................................................................................................................ 28

Figure 6.

Input Setup and Hold Timing ................................................................................................... 28

Figure 7.

Input Setup and Hold Timing ................................................................................................... 29

Figure 8.

Output Valid Delay Timing ....................................................................................................... 29

Figure 9.

Maximum Float Delay Timing .................................................................................................. 30

Contents

Figure 10.

TCK Waveform ........................................................................................................................ 30

Figure 11.

Test Signal Timing Diagram ..................................................................................................... 31

Figure 12.

Typical Loading Delay versus Load Capacitance under Worst-Case Conditions
for a Low-to-High Transition ..................................................................................................... 32

Figure 13.

Typical Loading Delay versus Load Capacitance under Worst-Case Conditions
for a High-to-Low Transition ..................................................................................................... 32

Figure 14.

Package Mechanical Specifications for the 176 Lead TQFP Package .................................... 33

TABLES

Table 1.

The Embedded Ultra-Low Power Intel486

SX Processor ....................................................... 2

Table 2.

Pin Assignment for 176-Lead TQFP Package Embedded ULP Intel486TM SX Processor ........ 5

Table 3.

Pin Cross Reference for 176-Lead TQFP Package Embedded ULP
Intel486TM SX Processor ............................................................................................................ 6

Table 4.

Embedded ULP Intel486TM SX Processor Pin Descriptions ...................................................... 7

Table 5.

Output Pins .............................................................................................................................. 12

Table 6.

Input/Output Pins ..................................................................................................................... 13

Table 7.

Test Pins .................................................................................................................................. 13

Table 8.

Input Pins ................................................................................................................................. 14

Table 9.

CPUID Instruction Description ................................................................................................. 19

Table 10.

Boundary Scan Component Identification Code ...................................................................... 21

Table 11.

Absolute Maximum Ratings ..................................................................................................... 22

Table 12.

Operating Supply Voltages ...................................................................................................... 22

Table 13.

DC Specifications ..................................................................................................................... 23

Table 14.

Active I

Values ..................................................................................................................... 24

Table 15.

Clock Stop, Stop Grant, and Auto HALT Power Down I

Values .......................................... 24

Table 16.

AC Characteristics ................................................................................................................... 25

Table 17.

AC Specifications for the Test Access Port ............................................................................. 27

Table 18.

Thermal Resistance ................................................................................................................. 34

Table 19.

Maximum Ambient Temperature (T

) ...................................................................................... 34

Embedded Ultra-Low Power Intel486TM SX Processor

1.0

INTRODUCTION

This data sheet describes the embedded Ultra-Low
Power (ULP) Intel486TM SX processor. It is intended
for embedded battery-operated and hand-held appli-
cations. The embedded ULP Intel486 SX processor
provides all of the features of the Intel486 SX
processor except for the external data-bus parity
logic and the processor-upgrade pin. The processor
typically uses 20% to 50% less power than the
Intel486 SX processor. Additionally, the embedded
ULP Intel486 SX processor external data bus has
level-keeper circuitry and a fast-recovery core clock
which are vital for ultra-low-power system designs.
The processor is available in a Thin Quad Flat
Package (TQFP) enabling low-profile component
implementation.

The embedded ULP Intel486 SX processor consists
of a 32-bit integer processing unit, an on-chip cache,
and a memory management unit. The design
ensures full instruction-set compatibility with the
8086, 8088, 80186, 80286, Intel386TM SX, Intel386
DX, and all versions of Intel486 processors.

1.1

Features

The embedded ULP Intel486 SX processor offers
these features of the Intel486 SX processor:

· 32-bit RISC-Technology Core -- The embedded

ULP Intel486 SX processor performs a complete
set of arithmetic and logical operations on 8-, 16-,
and 32-bit data types using a full-width ALU and
eight general purpose registers.

· Single Cycle Execution -- Many instructions

execute in a single clock cycle.

· Instruction Pipelining -- Overlapped instruction

fetching, decoding, address translation and
execution.

· On-Chip Cache with Cache Consistency

Support -- An 8-Kbyte, write-through, internal
cache is used for both data and instructions.
Cache hits provide zero wait-state access times
for data within the cache. Bus activity is tracked to
detect alterations in the memory represented by
the internal cache. The internal cache can be
invalidated or flushed so that an external cache
controller can maintain cache consistency.

· External Cache Control -- Write-back and flush

controls for an external cache are provided so the
processor can maintain cache consistency.

· On-Chip Memory Management Unit -- Address

management and memory space protection
mechanisms maintain the integrity of memory in a
multitasking and virtual memory environment. Both
segmentation and paging are supported.

· Burst Cycles -- Burst transfers allow a new

double word to be read from memory on each bus
clock cycle. This capability is especially useful for
instruction prefetch and for filling the internal
cache.

· Write Buffers -- The processor contains four

write buffers to enhance the performance of
consecutive writes to memory. The processor can
continue internal operations after a write to these
buffers, without waiting for the write to be
completed on the external bus.

· Bus Backoff -- When another bus master needs

control of the bus during a processor initiated bus
cycle, the embedded ULP Intel486 SX processor
floats its bus signals, then restarts the cycle when
the bus becomes available again.

· Instruction Restart -- Programs can continue

execution following an exception generated by an
unsuccessful attempt to access memory. This
feature is important for supporting demand-paged
virtual memory applications.

· Dynamic Bus Sizing -- External controllers can

dynamically alter the effective width of the data
bus. Bus widths of 8, 16, or 32 bits can be used.

· Boundary Scan (JTAG) -- Boundary Scan

provides in-circuit testing of components on
printed circuit boards. The Intel Boundary Scan
implementation conforms with the IEEE Standard
Test Access Port and Boundary Scan Architecture.

· Intel System Management Mode (SMM) -- A

unique Intel architecture operating mode provides
a dedicated special purpose interrupt and address
space that can be used to implement intelligent
power management and other enhanced functions
in a manner that is completely transparent to the
operating system and applications software.

· I/O Restart -- An I/O instruction interrupted by a

System Management Interrupt (SMI#) can
automatically be restarted following the execution
of the RSM instruction.

· Stop Clock -- The embedded ULP Intel486 SX

processor has a stop clock control mechanism that
provides two low-power states: a Stop Grant state
(4085 mW typical, depending on input clock
frequency) and a Stop Clock state (~60 µW typical,
with input clock frequency of 0 MHz).

Embedded Ultra-Low Power Intel486TM SX Processor

· Auto HALT Power Down -- After the execution of

a HALT instruction, the embedded ULP Intel486
SX processor issues a normal Halt bus cycle and
the clock input to the processor core is automati-
cally stopped, causing the processor to enter the
Auto HALT Power Down state (4085 mW typical,
depending on input clock frequency).

The embedded ULP Intel486 SX processor differs
from the Intel486 SX processor in the following
areas:

· Processor Upgrade Removed -- The UP# signal

is not provided.

· Parity Signals Removed -- The DP3-DP0 and

PCHK# signals are not provided.

· Separate Processor-Core Power -- While the

embedded ULP Intel486 SX processor requires a
supply voltage of 3.3 V, the processor core has
dedicated V

pins and operates with a supply

voltage as low as 2.4 V.

· Small, Low-Profile Package -- The 176-Lead

Thin Quad Flat Pack (TQFP) package is approxi-
mately 26 mm square and only 1.5 mm in height.
This is approximately the diameter and thickness
of a U.S. quarter. The embedded ULP Intel486 SX
processor is ideal for embedded hand-held and
battery-powered applications.

· Level Keeper Circuits -- The embedded ULP

Intel486 SX processor has level-keeper circuits for
its 32-bit external data bus signals. They retain
valid high and low logic voltage levels when the
processor is in the Stop Grant and Stop Clock
states. This is a power-saving improvement from
the floating data bus of the Intel486 SX processor.

· Auto Clock Freeze -- The embedded ULP

Intel486 SX processor monitors bus events and
internal activity. The Auto Clock Freeze feature
automatically controls internal clock distribution,
turning off clocks to internal units when they are
idle. This power-saving function is transparent to
the embedded system.

· Fast Clock Restart -- The embedded ULP

Intel486 SX processor requires only eight clock
periods to synchronize its internal clock with the
CLK input signal. This provides for faster transition
from the Stop Clock State to the Normal State. For
33-MHz operation, this synchronization time is
only 240 ns compared with 1 ms (PLL startup
latency) for the Intel486 processor.

1.2

Family Members

Table 1 shows the embedded ULP Intel486 SX
processor and briefly describes its characteristics.

Table 1. The Embedded Ultra-Low Power Intel486

SX Processor

Product

Supply

Voltage

CCP

)

Processor

Core Supply

Voltage

)

Processor

Frequency

(MHz)

Package

FA80486SXSF-33

3.3 V

2.4 V to 3.3 V

176-Lead

TQFP

2.7 V to 3.3 V

Embedded Ultra-Low Power Intel486TM SX Processor

2.0

HOW TO USE THIS DOCUMENT

The embedded ULP Intel486 SX processor has
characteristics similar to the Intel486 SX processor.
This document describes the new features of the
embedded ULP Intel486 SX processor. Some
Intel486 SX processor information is also included to
minimize the dependence on the reference
documents.

For a complete set of documentation related to the
embedded ULP Intel486 SX processor, use this
document in conjunction with the following reference
documents:

Embedded Intel486TM Processor Family
Developer's Manual

-- Order No. 273021

Embedded Intel486TM Processor Hardware
Reference Manual

-- Order No. 273025

· Intel Application Note AP-485 --

Intel Processor

Identification with the CPUID Instruction

Order No. 241618

3.0

PIN DESCRIPTIONS

3.1

Pin Assignments

The following figures and tables show the pin assign-
ments for the 176-pin Thin Quad Flat Pack (TQFP)
package of the embedded ULP Intel486 SX
processor. Included are:

· Figure 2, Package Diagram for 176-Lead TQFP

Package Embedded ULP Intel486TM SX Processor
(pg. 4)

· Table 2, Pin Assignment for 176-Lead TQFP

Package Embedded ULP Intel486TM SX Processor
(pg. 5)

· Table 3, Pin Cross Reference for 176-Lead TQFP

Package Embedded ULP Intel486TM SX Processor
(pg. 6)

· Table 4, Embedded ULP Intel486TM SX Processor

Pin Descriptions (pg. 7)

· Table 5, Output Pins (pg. 13)

· Table 6, Input/Output Pins (pg. 13)

· Table 7, Test Pins (pg. 14)

· Table 8, Input Pins (pg. 14)

The tables and figures show "no-connects" as "N/C."
These pins should always remain unconnected.
Connecting N/C pins to V

, V

CCP

, V

, or any other

signal pin can result in component malfunction or
incompatibility with future steppings of the
embedded ULP Intel486 SX processor.

Embedded Ultra-Low Power Intel486TM SX Processor

Figure 2. Package Diagram for 176-Lead TQFP Package Embedded ULP Intel486TM SX Processor

1
2
3
4
5
6
7
8
9
10
11
12
13
14

15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44

BLAST#

VCC

PLOCK#

LOCK#

VSS

VCCP

N/C

BRDY#

BOFF#

BS16#

BS8#

VCC

N/C

RDY#
KEN#

VCC

VSS

HOLD

AHOLD

TCK

VCC
VCC

VSS

VCC
VCC

VSS
CLK

HLDA

W/R#

VSS

VCCP
BREQ

BE0#
BE1#
BE2#
BE3#

VCC

M/IO#

D/C#
PWT

PCD

VCCP

VSS

VCC

176-Lead TQFP

(top view)

EADS#

ESET

VSS

USH#

SRESE

IACT

VSS

VCCP

PCL

VCCP

VSS

VCCP

VSS

VCCP

VSS

VCCP

VSS

132
131
130
129
128
127
126
125
124
123
122
121
120

119
118
117
116
115
114
113
112

111

110

109
108
107
106
105
104
103
102
101
100

99
98
97
96
95
94
93
92
91
90
89

VSS
VSS
VCCP
A25
A26
A27
A28
VCCP
A29
A30
A31
VSS
D0
D1
D2
D3
D4
VCC
VSS
VCC
VCC
VSS
VCC
VCC
VSS
VCCP
D5
D6
VCCP
N/C
D7
VSS
D8
D9
VSS
VCC
D10
D11
D12
D13
VSS
VCCP
D14
D15

ADS#

VSS

VCCP

VSS

VCCP

RESERV

VSS

VCC

VCCP

VSS

VCC

VCCP

VSS

VCCP

Embedded Ultra-Low Power Intel486TM SX Processor

Table 2. Pin Assignment for 176-Lead TQFP Package

Embedded ULP Intel486TM SX Processor

Pin #

Description

Pin #

Description

Pin #

Description

Pin #

Description

BLAST#

EADS#

D15

133

A24

A20M#

D14

134

A23

PLOCK#

RESET

CCP

135

A22

LOCK#

136

A21

FLUSH#

D13

137

CCP

INTR

D12

138

CCP

N/C

NMI

D11

139

A20

BRDY#

SRESET

D10

140

A19

BOFF#

SMIACT#

141

A18

BS16#

142

TMS

BS8#

143

TDI

CCP

100

144

CCP

N/C

SMI#

101

145

RDY#

TDO

102

146

A17

KEN#

103

N/C

147

A16

STPCLK#

104

CCP

148

A15

D31

105

149

HOLD

D30

106

150

CCP

AHOLD

D29

107

CCP

151

A14

TCK

D28

108

152

A13

109

153

CCP

110

154

A12

111

155

A11

D27

112

156

D26

113

157

D25

114

158

CCP

CLK

D24

115

159

A10

HLDA

CCP

116

160

W/R#

117

161

D23

118

162

CCP

D22

119

163

BREQ

D21

120

164

BE0#

CCP

121

165

BE1#

122

A31

166

RESERVED#

BE2#

D20

123

A30

167

BE3#

D19

124

A29

168

D18

125

CCP

169

M/IO#

126

A28

170

CCP

D/C#

D17

127

A27

171

PWT

128

A26

172

PCD

129

A25

173

CCP

130

CCP

174

D16

131

175

132

176

ADS#

Embedded Ultra-Low Power Intel486TM SX Processor

Table 3. Pin Cross Reference for 176-Lead TQFP Package

Embedded ULP Intel486TM SX Processor

Address

Pin #

Data

Pin #

Control

Pin #

N/C

CCP

175

120

AHOLD

169

119

BE0#

168

118

BE1#

103

167

117

BE2#

165

116

BE3#

164

106

BLAST#

163

105

BOFF#

160

102

BRDY#

A10

159

100

BREQ

A11

155

BS16#

104

A12

154

D10

BS8#

107

A13

152

D11

CLK

125

A14

151

D12

D/C#

130

A15

148

D13

HLDA

137

A16

147

D14

HOLD

138

109

A17

146

D15

KEN#

144

110

A18

141

D16

LOCK#

150

112

101

A19

140

D17

M/IO#

158

113

108

A20

139

D18

PCD

170

115

111

A21

136

D19

PLOCK#

173

153

114

A22

135

D20

PWT

156

121

A23

134

D21

RESERVED#

166

161

131

A24

133

D22

RDY#

132

A25

129

D23

TCK

145

A26

128

D24

W/R#

149

A27

127

D25

A20M#

157

A28

126

D26

EADS#

162

A29

124

D27

FLUSH#

171

A30

123

D28

INTR

172

A31

122

D29

NMI

174

D30

RESET

D31

SMI#

SMIACT#

SRESET

STPCLK#

TDO

ADS#

176

TDI

143

TMS

142

W/R#

Embedded Ultra-Low Power Intel486TM SX Processor

3.2

Pin Quick Reference

The following is a brief pin description. For detailed signal descriptions refer to Appendix A, "Signal Descrip-
tions," in the

Embedded Intel486TM Processor Family Developer's Manual,

order No. 273021.

Table 4. Embedded ULP Intel486TM SX Processor Pin Descriptions (Sheet 1 of 6)

Symbol

Type

Name and Function

CLK

Clock

provides the fundamental timing and internal operating frequency for the

embedded ULP Intel486 SX processor. All external timing parameters are
specified with respect to the rising edge of CLK.

ADDRESS BUS

A31-A4

A3A2

I/O

Address Lines A31A2, together with the byte enable signals, BE3#BE0#,
define the physical area of memory or input/output space accessed. Address lines
A31A4 are used to drive addresses into the embedded ULP Intel486 SX
processor to perform cache line invalidation. Input signals must meet setup and
hold times t

and t

. A31A2 are not driven during bus or address hold.

BE3#

BE2#

BE1#

BE0#

Byte Enable

signals indicate active bytes during read and write cycles. During the

first cycle of a cache fill, the external system should assume that all byte enables
are active. BE3#BE0# are active LOW and are not driven during bus hold.

BE3# applies to D31D24

BE2# applies to D23D16

BE1# applies to D15D8

BE0# applies to D7D0

DATA BUS

D31D0

I/O

Data Lines. D7D0 define the least significant byte of the data bus; D31D24
define the most significant byte of the data bus. These signals must meet setup
and hold times t

and t

for proper operation on reads. These pins are driven

during the second and subsequent clocks of write cycles.

Embedded Ultra-Low Power Intel486TM SX Processor

BUS CYCLE DEFINITION

M/IO#

D/C#

W/R#

Memory/Input-Output

Data/Control

and Write/Read

lines are the primary bus

definition signals. These signals are driven valid as the ADS# signal is asserted.

M/IO#

D/C#

W/R#

Bus Cycle Initiated

Interrupt Acknowledge

HALT/Special Cycle (see details below)

I/O Read

I/O Write

Code Read

Reserved

Memory Read

Memory Write

HALT/Special Cycle

Cycle Name

BE3# - BE0#

A4-A2

Shutdown 1110 000

HALT 1011

000

Stop Grant bus cycle

1011

100

LOCK#

Bus Lock

indicates that the current bus cycle is locked. The embedded ULP

Intel486 SX processor does not allow a bus hold when LOCK# is asserted
(address holds are allowed). LOCK# goes active in the first clock of the first locked
bus cycle and goes inactive after the last clock of the last locked bus cycle. The
last locked cycle ends when Ready is returned. LOCK# is active LOW and not
driven during bus hold. Locked read cycles are not transformed into cache fill
cycles when KEN# is returned active.

PLOCK#

Pseudo-Lock indicates that the current bus transaction requires more than one
bus cycle to complete. For the embedded ULP Intel486 SX processor, examples of
such operations are segment table descriptor reads (64 bits) and cache line fills
(128 bits).

The embedded ULP Intel486 SX processor drives PLOCK# active until the
addresses for the last bus cycle of the transaction are driven, regardless of
whether RDY# or BRDY# have been returned.

PLOCK# is a function of the BS8#, BS16# and KEN# inputs. PLOCK# should be
sampled only in the clock in which Ready is returned. PLOCK# is active LOW and
is not driven during bus hold.

BUS CONTROL

ADS#

Address Status

output indicates that a valid bus cycle definition and address are

available on the cycle definition lines and address bus. ADS# is driven active in the
same clock in which the addresses are driven. ADS# is active LOW and not driven
during bus hold.

Table 4. Embedded ULP Intel486TM SX Processor Pin Descriptions (Sheet 2 of 6)

Symbol

Type

Name and Function

Embedded Ultra-Low Power Intel486TM SX Processor

RDY#

Non-burst Ready

input indicates that the current bus cycle is complete. RDY#

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 data from the
embedded ULP Intel486 SX processor in response to a write. RDY# is ignored
when the bus is idle and at the end of the first clock of the bus cycle.

RDY# is active during address hold. Data can be returned to the embedded ULP
Intel486 SX processor while AHOLD is active.

RDY# is active LOW and is not provided with an internal pull-up resistor. RDY#
must satisfy setup and hold times t

and t

for proper chip operation.

BURST CONTROL

BRDY#

Burst Ready

input performs the same function during a burst cycle that RDY#

performs during a non-burst cycle. BRDY# indicates that the external system has
presented valid data in response to a read or that the external system has
accepted data in response to a write. BRDY# is ignored when the bus is idle and at
the end of the first clock in a bus cycle.

BRDY# is sampled in the second and subsequent clocks of a burst cycle. Data
presented on the data bus is strobed into the embedded ULP Intel486 SX
processor when BRDY# is sampled active. If RDY# is returned simultaneously with
BRDY#, BRDY# is ignored and the burst cycle is prematurely aborted.

BRDY# is active LOW and is provided with a small pull-up resistor. BRDY# must
satisfy the setup and hold times t

and t

BLAST#

Burst Last

signal indicates that the next time BRDY# is returned, the burst bus

cycle is complete. BLAST# is active for both burst and non-burst bus cycles.
BLAST# is active LOW and is not driven during bus hold.

INTERRUPTS

RESET

Reset input forces the embedded ULP Intel486 SX processor to begin execution at
a known state. The processor cannot begin executing instructions until at least
1 ms after V

, V

CCP

, and CLK have reached their proper DC and AC specifica-

tions. The RESET pin must remain active during this time to ensure proper
processor operation. However, for warm resets, RESET should remain active for at
least 15 CLK periods. RESET is active HIGH. RESET is asynchronous but must
meet setup and hold times t

and t

for recognition in any specific clock.

INTR

Maskable Interrupt

indicates that an external interrupt has been generated. When

the internal interrupt flag is set in EFLAGS, active interrupt processing is initiated.
The embedded ULP Intel486 SX processor generates two locked interrupt
acknowledge bus cycles in response to the INTR pin going active. INTR must
remain active until the interrupt acknowledges have been performed to ensure
processor recognition of the interrupt.

INTR is active HIGH and is not provided with an internal pull-down resistor. INTR is
asynchronous, but must meet setup and hold times t

and t

for recognition in

any specific clock.

NMI

Non-Maskable Interrupt

request signal indicates that an external non-maskable

interrupt has been generated. NMI is rising-edge sensitive and must be held LOW
for at least four CLK periods before this rising edge. NMI is not provided with an
internal pull-down resistor. NMI is asynchronous, but must meet setup and hold
times t

and t

for recognition in any specific clock.

Table 4. Embedded ULP Intel486TM SX Processor Pin Descriptions (Sheet 3 of 6)

Symbol

Type

Name and Function

Embedded Ultra-Low Power Intel486TM SX Processor

SRESET

Soft Reset pin duplicates all functionality of the RESET pin except that the
SMBASE register retains its previous value. For soft resets, SRESET must remain
active for at least 15 CLK periods. SRESET is active HIGH. SRESET is
asynchronous but must meet setup and hold times t

and t

for recognition in any

specific clock.

SMI#

System Management Interrupt input invokes System Management Mode (SMM).
SMI# is a falling-edge triggered signal which forces the embedded ULP Intel486
SX processor into SMM at the completion of the current instruction. SMI# is
recognized on an instruction boundary and at each iteration for repeat string
instructions. SMI# does not break LOCKed bus cycles and cannot interrupt a
currently executing SMM. The embedded ULP Intel486 SX processor latches the
falling edge of one pending SMI# signal while it is executing an existing SMI#. The
nested SMI# is not recognized until after the execution of a Resume (RSM)
instruction.

SMIACT#

System Management Interrupt Active, an active LOW output, indicates that the
embedded ULP Intel486 SX processor is operating in SMM. It is asserted when the
processor begins to execute the SMI# state save sequence and remains active
LOW until the processor executes the last state restore cycle out of SMRAM.

STPCLK#

Stop Clock Request input signal indicates a request was made to turn off or
change the CLK input frequency. When the embedded ULP Intel486 SX processor
recognizes a STPCLK#, it stops execution on the next instruction boundary (unless
superseded by a higher priority interrupt), empties all internal pipelines and write
buffers, and generates a Stop Grant bus cycle. STPCLK# is active LOW. Though
STPCLK# has an internal pull-up resistor, an external 10-K

pull-up resistor is

needed if the STPCLK# pin is not used. STPCLK# is an asynchronous signal,
but must remain active until the embedded ULP Intel486 SX processor issues
the Stop Grant bus cycle. STPCLK# may be de-asserted at any time after the
processor has issued the Stop Grant bus cycle.

BUS ARBITRATION

BREQ

Bus Request

signal indicates that the embedded ULP Intel486 SX processor has

internally generated a bus request. BREQ is generated whether or not the
processor is driving the bus. BREQ is active HIGH and is never floated.

HOLD

Bus Hold Request allows another bus master complete control of the embedded
ULP Intel486 SX processor bus. In response to HOLD going active, the processor
floats most of its output and input/output pins. HLDA is asserted after completing
the current bus cycle, burst cycle or sequence of locked cycles. The embedded
ULP Intel486 SX processor remains in this state until HOLD is de-asserted. HOLD
is active HIGH and is not provided with an internal pull-down resistor. HOLD must
satisfy setup and hold times t

and t

for proper operation.

HLDA

Hold Acknowledge

goes active in response to a hold request presented on the

HOLD pin. HLDA indicates that the embedded ULP Intel486 SX processor has
given the bus to another local bus master. HLDA is driven active in the same clock
that the processor floats its bus. HLDA is driven inactive when leaving bus hold.
HLDA is active HIGH and remains driven during bus hold.

Table 4. Embedded ULP Intel486TM SX Processor Pin Descriptions (Sheet 4 of 6)

Symbol

Type

Name and Function

Embedded Ultra-Low Power Intel486TM SX Processor

BOFF#

Backoff

input forces the embedded ULP Intel486 SX processor to float its bus in

the next clock. The processor floats all pins normally floated during bus hold but
HLDA is not asserted in response to BOFF#. BOFF# has higher priority than RDY#
or BRDY#; if both are returned in the same clock, BOFF# takes effect. The
embedded ULP Intel486 SX processor remains in bus hold until BOFF# is
negated. If a bus cycle is in progress when BOFF# is asserted the cycle is
restarted. BOFF# is active LOW and must meet setup and hold times t

and t

for

proper operation.

CACHE INVALIDATION

AHOLD

Address Hold

request allows another bus master access to the embedded ULP

Intel486 SX processor's address bus for a cache invalidation cycle. The processor
stops driving its address bus in the clock following AHOLD going active. Only the
address bus is floated during address hold, the remainder of the bus remains
active. AHOLD is active HIGH and is provided with a small internal pull-down
resistor. For proper operation, AHOLD must meet setup and hold times t

and t

EADS#

External Address - This signal indicates that a

valid

external address has been

driven onto the embedded ULP Intel486 SX processor address pins. This address
is used to perform an internal cache invalidation cycle. EADS# is active LOW and
is provided with an internal pull-up resistor. EADS# must satisfy setup and hold
times t

and t

for proper operation.

CACHE CONTROL

KEN#

Cache Enable

pin is used to determine whether the current cycle is cacheable.

When the embedded ULP Intel486 SX processor generates a cycle that can be
cached and KEN# is active one clock before RDY# or BRDY# during the first
transfer of the cycle, the cycle becomes a cache line fill cycle. Returning KEN#
active one clock before RDY# during the last read in the cache line fill causes the
line to be placed in the on-chip cache. KEN# is active LOW and is provided with a
small internal pull-up resistor. KEN# must satisfy setup and hold times t

and t

for proper operation.

FLUSH#

Cache Flush

input forces the embedded ULP Intel486 SX processor to flush its

entire internal cache. FLUSH# is active LOW and need only be asserted for one
clock. FLUSH# is asynchronous but setup and hold times t

and t

must be met

for recognition in any specific clock.

PAGE CACHEABILITY

PWT

PCD

O
O

Page Write-Through

and Page Cache Disable pins reflect the state of the page

attribute bits, PWT and PCD, in the page table entry, page directory entry or
control register 3 (CR3) when paging is enabled. When paging is disabled, the
embedded ULP Intel486 SX processor ignores the PCD and PWT bits and
assumes they are zero for the purpose of caching and driving PCD and PWT pins.
PWT and PCD have the same timing as the cycle definition pins (M/IO#, D/C#, and
W/R#). PWT and PCD are active HIGH and are not driven during bus hold. PCD is
masked by the cache disable bit (CD) in Control Register 0.

Table 4. Embedded ULP Intel486TM SX Processor Pin Descriptions (Sheet 5 of 6)

Symbol

Type

Name and Function

Embedded Ultra-Low Power Intel486TM SX Processor

BUS SIZE CONTROL

BS16#

BS8#

I
I

Bus Size 16

and Bus Size 8

pins (bus sizing pins) cause the embedded ULP

Intel486 SX processor to run multiple bus cycles to complete a request from
devices that cannot provide or accept 32 bits of data in a single cycle. The bus
sizing pins are sampled every clock. The processor uses the state of these pins in
the clock before Ready to determine bus size. These signals are active LOW and
are provided with internal pull-up resistors. These inputs must satisfy setup and
hold times t

and t

for proper operation.

ADDRESS MASK

A20M#

Address Bit 20 Mask pin, when asserted, causes the embedded ULP Intel486 SX
processor to mask physical address bit 20 (A20) before performing a lookup to the
internal cache or driving a memory cycle on the bus. A20M# emulates the address
wraparound at 1 Mbyte, which occurs on the 8086 processor. A20M# is active
LOW and should be asserted only when the embedded ULP Intel486 SX processor
is in real mode. This pin is asynchronous but should meet setup and hold times t

and t

for recognition in any specific clock. For proper operation, A20M# should

be sampled HIGH at the falling edge of RESET.

TEST ACCESS PORT

TCK

Test Clock, an input to the embedded ULP Intel486 SX processor, provides the
clocking function required by the JTAG Boundary scan feature. TCK is used to
clock state information (via TMS) and data (via TDI) into the component on the
rising edge of TCK. Data is clocked out of the component (via TDO) on the falling
edge of TCK. TCK is provided with an internal pull-up resistor.

TDI

Test Data Input is the serial input used to shift JTAG instructions and data into the
processor. TDI is sampled on the rising edge of TCK, during the SHIFT-IR and
SHIFT-DR TAP controller states. During all other Test Access Port (TAP) controller
states, TDI is a "don't care." TDI is provided with an internal pull-up resistor.

TDO

Test Data Output is the serial output used to shift JTAG instructions and data out
of the component. TDO is driven on the falling edge of TCK during the SHIFT-IR
and SHIFT-DR TAP controller states. At all other times TDO is driven to the high
impedance state.

TMS

Test Mode Select is decoded by the JTAG TAP to select test logic operation. TMS
is sampled on the rising edge of TCK. To guarantee deterministic behavior of the
TAP controller, TMS is provided with an internal pull-up resistor.

RESERVED PINS

RESERVED#

Reserved is reserved for future use. This pin MUST be connected to an external
pull-up resistor circuit. The recommended resistor value is 10 kOhms.

Table 4. Embedded ULP Intel486TM SX Processor Pin Descriptions (Sheet 6 of 6)

Symbol

Type

Name and Function

Embedded Ultra-Low Power Intel486TM SX Processor

Table 5. Output Pins

Name

Active Level

Output Signal

Floated During

Address Hold

Floated During

Bus Hold

During Stop Grant and

Stop Clock States

BREQ

HIGH

Previous State

HLDA

HIGH

As per HOLD

BE3#-BE0#

LOW

Previous State

PWT, PCD

HIGH

Previous State

W/R#, M/IO#, D/C#

HIGH/LOW

Previous State

LOCK#

LOW

HIGH (inactive)

PLOCK#

LOW

HIGH (inactive)

ADS#

LOW

HIGH (inactive)

BLAST#

LOW

Previous State

A3-A2

HIGH

Previous State

SMIACT#

LOW

Previous State

NOTES:

1. The term "Previous State" means that the processor maintains the logic level applied to the signal pin just before the pro-

cessor entered the Stop Grant state. This conserves power by preventing the signal pin from floating.

Table 6. Input/Output Pins

Name

Active Level

Output Signal

Floated During

Address Hold

Floated During

Bus Hold

During Stop Grant and

Stop Clock States

1,2

D31-D0

HIGH

Level-Keeper

A31-A4

HIGH

Previous State

NOTES:

1. The term "Level-Keeper" means that the processor maintains the most recent logic level applied to the signal pin. This con-

serves power by preventing the signal pin from floating. If a system component, other than the processor, temporarily drives
these signal pins and then floats them, the processor forces and maintains the most recent logic levels that were applied by
the system component.

2. The term "Previous State" means that the processor maintains the logic level applied to the signal pin just before the pro-

cessor entered the Stop Grant state. This conserves power by preventing the signal pin from floating.

Embedded Ultra-Low Power Intel486TM SX Processor

Table 7. Test Pins

Name

Input or Output

Sampled/ Driven On

TCK

Input

N/A

TDI

Input

Rising Edge of TCK

TDO

Output

Failing Edge of TCK

TMS

Input

Rising Edge of TCK

Table 8. Input Pins

Name

Active Level

Synchronous/

Asynchronous

Internal Pull-Up/

Pull-Down

CLK

RESET

HIGH

Asynchronous

SRESET

HIGH

Asynchronous

Pull-Down

HOLD

HIGH

Synchronous

AHOLD

HIGH

Synchronous

Pull-Down

EADS#

LOW

Synchronous

Pull-Up

BOFF#

LOW

Synchronous

Pull-Up

FLUSH#

LOW

Asynchronous

Pull-Up

A20M#

LOW

Asynchronous

Pull-Up

BS16#, BS8#

LOW

Synchronous

Pull-Up

KEN#

LOW

Synchronous

Pull-Up

RDY#

LOW

Synchronous

BRDY#

LOW

Synchronous

Pull-Up

INTR

HIGH

Asynchronous

NMI

HIGH

Asynchronous

RESERVED#

SMI#

LOW

Asynchronous

Pull-Up

STPCLK#

LOW

Asynchronous

Pull-Up

TCK

HIGH

Pull-Up

TDI

HIGH

Pull-Up

TMS

HIGH

Pull-Up

NOTE:

1. Though STPCLK# has an internal pull-up resistor, an external 10-K

pull-up resistor is needed if the STPCLK# pin is not

used.

Embedded Ultra-Low Power Intel486TM SX Processor

4.0

ARCHITECTURAL AND
FUNCTIONAL OVERVIEW

The embedded ULP Intel486 SX processor archi-
tecture is essentially the same as the 3.3 V Intel486
SX processor with a 1X clock (CLK) input. Refer to
the Embedded Intel486TM Processor Family
Developer's Manual, order number 273032, for a
description of the ULP Intel486 SX processor. The
following notes supplement the information in the
manual.

· The information pertaining to parity signals for the

external data bus does not apply. The embedded
ULP Intel486 SX processor does not have DP0#,
DP1#, DP2#, DP3# and PCHK# signal pins.

· References to the Upgrade Power Down Mode do

not apply. The embedded ULP Intel486 SX
processor does not have the UP# signal pin and
does not support the Intel OverDrive

processor.

· References to "V

" are called "V

CCP

" by the

embedded ULP Intel486 SX processor when the
supply voltage pertains to the processor's external
interface drivers and receivers. The term "V

pertains only to the processor core supply voltage
of the embedded ULP Intel486 SX processor.
Information about the split-supply voltage is
provided in this datasheet.

· The Phase-Locked Loop (PLL) of the 1X clock

(CLK) input has been replaced by a proprietary
Differential Delay Line (DDL) that has a faster
startup and recovery time. Datasheet references to
the PLL and its 1 ms recovery time are replaced
with the DDL circuit and its eight-CLK recovery
time. Information about the DDL and startup and
recovery latency is provided in this datasheet.

· The embedded ULP Intel486 SX processor has

level-keeper circuits for its external 32-bit data bus
signals (D31-D0). The Intel486 SX processor
floats its data bus instead. More information about
the level-keeper circuitry is provided in this
datasheet.

· The datasheet describes the processor supply-

current consumption for the Auto HALT Power
Down, Stop Grant, and Stop Clock states. This
supply-current consumption for the embedded
ULP Intel486 SX processor is much less than that
of the Intel486 SX processor. Information about
power consumption and these states is provided in
this datasheet.

· The CPU ID, Boundary-Scan (JTAG) ID, and

boundary-scan register bits for the embedded ULP
Intel486 SX processor are in this datasheet.

· The embedded ULP Intel486 SX processor has

one pin reserved for possible future use. This pin
is an input signal, pin 166. It is called
RESERVED# and must be connected to a 10-K

pull-up resistor.

4.1

Separate Supply Voltages

The embedded ULP Intel486 SX processor has
separate voltage-supply planes for its internal core-
processor circuits and its external driver/receiver
circuits. The supply voltage for the internal core
processor is named V

and the supply voltage for

the external circuits is named V

CCP

For a single-supply voltage design, the embedded
ULP Intel486 SX processor is functional at
3.3 V ± 0.3 V. In this type of system design, the
processor's V

and V

CCP

pins must be tied to the

same power plane.

Even though V

CCP

must be 3.3 V ± 0.3 V, the

processor's external-output circuits can drive TTL-
compatible components. However, the processor's
external-input circuits do not allow connection to
TTL-compatible components. Section 5.2, DC Speci-
fications (pg. 22) contains the DC specifications for
the processor's input and output signals.

For lower-power operation, a separate, lower voltage
for V

can be chosen, but V

CCP

must be

3.3 V ± 0.3 V. Any voltage value between 2.4 V and
3.3 V can be chosen for V

for guaranteed

processor operation up to 25 MHz. The embedded
ULP Intel486 SX processor can also operate at
33 MHz, provided the V

value chosen is between

2.7 V and 3.3 V. Section 5.2, DC Specifications (pg.
22) defines supply voltage specifications.

In systems with separate V

and V

CCP

power

planes, the processor-core voltage supply must
always be less than or equal to the processor's
external-interface voltage supply; e.g., the system
design must guarantee:

CCP

Violating this relationship causes excessive power
consumption. Limited testing has shown no
component damage when this relationship is
violated. However, prolonged violation is not recom-
mended and component integrity is not guaranteed.

Embedded Ultra-Low Power Intel486TM SX Processor

4.2

Fast Clock Restart

The embedded ULP Intel486 SX processor has an
integrated proprietary differential delay line (DDL)
circuit for internal clock generation. The DDL is
driven by the CLK input signal provided by the
external system. During normal operation, the
external system must guarantee that the CLK signal
maintains its frequency so that the clock period
deviates no more than 250 ps/CLK. This state,
called the Normal State, is shown in Figure 4.

To increase or decrease the CLK frequency more
quickly than this, the system must interrupt the
processor with the STPCLK# signal. Once the
processor indicates that it is in the Stop Grant State,
the system can adjust the CLK signal to the new
frequency, wait a minimum of eight CLK periods,
then force the processor to return to the normal

operational state by deactivating the STPCLK#
interrupt. This wait of eight CLK periods is much
faster than the 1 ms wait required by earlier Intel486
SX processor products.

While in the Stop Grant State, the external system
may deactivate the CLK signal to the processor. This
forces the processor to the Stop Clock State -- the
state in which the processor consumes the least
power. Once the system reactivates the CLK signal,
the processor transitions to the Stop Grant State
within eight CLK periods.

Normal operation can be resumed by deactivating
the STPCLK# interrupt signal. Here again, the
embedded ULP Intel486 SX processor recovers
from the Stop Clock State much faster than the 1 ms
PLL recovery of earlier Intel486 SX processors.

Figure 4. Stop Clock State Diagram with Typical Power Consumption Values

4 Auto HALT

Power Down State

CLK Running
40 - 85 mWatts

5 Stop Clock Snoop State

1 Normal State

2 Stop Grant State

3 Stop Clock State

EADS#

One Clock PowerUp

Perform Cache Invalidation

Normal Execution

CLK Running
40 - 85 mWatts

Internal Powerdown
CLK Stopped
~ 60 µWatts

STPCLK#

deasserted

Stop CLK

Start CLK
plus DDL Startup
Latency

STPCLK# asserted
and Stop Grant bus

cycle generated

STPCLK# asserted and
Stop Grant bus cycle generated

STPCLK# deasserted and
HALT bus cycle generated

HALT asserted and

HALT bus cycle

generated

INTR, NMI, SMI#
RESET, SRESET

EADS#

Embedded Ultra-Low Power Intel486TM SX Processor

4.3

Level-Keeper Circuits

To obtain the lowest possible power consumption
during the Stop Grant and Stop Clock states, system
designers must ensure that:

· input signals with pull-up resistors are not driven

LOW

· input signals with pull-down resistors are not

driven HIGH

See Table 8, Input Pins (pg. 14) for the list of signals
with internal pull-up and pull-down resistors.

All other input pins except A31-A4 and D31-D0 must
be driven to the power supply rails to ensure lowest
possible current consumption.

During the Stop Grant and Stop Clock states, most
processor output signals maintain their previous
condition, which is the level they held when entering
the Stop Grant state. In response to HOLD driven
active during the Stop Grant state when the CLK
input is running, the embedded ULP Intel486 SX
processor generates HLDA and floats all output and
input/output signals which are floated during the
HOLD/HLDA state. When HOLD is deasserted,
processor signals which maintain their previous state
return to the state they were in prior to the
HOLD/HLDA sequence.

The data bus (D31-D0) also maintains its previous
state during the Stop Grant and Stop Clock states,
but does so differently, as described in the following
paragraphs.

The embedded ULP Intel486 SX processor's data
bus pins (D31-D0) have level keepers which
maintain their previous states while in the Stop Grant
and Stop Clock states. In response to HOLD driven
active during the Stop Grant state when the CLK
input is running, the embedded ULP Intel486 SX
processor generates HLDA and floats D31-D0
throughout the HOLD/HLDA cycles. When HOLD is
deasserted, the processor's D31-D0 signals return to
the states they were in prior to the HOLD/HLDA
sequence.

At all other times during the Stop Grant and Stop
Clock states, the processor maintains the logic
levels of D31-D0. When the external system circuitry
drives D31-D0 to different logic levels, the processor
flips its D31-D0 logic levels to match the ones driven
by the external system. The processor maintains
(keeps) these new levels even after the external
circuitry stops driving D31-D0.

For some system designs, external resistors may not
be required on D31- D0 (they are required on
previous Intel486 SX processor designs). System
designs that never request Bus Hold during the Stop
Grant and Stop Clock states might not require
external resistors. If the system design uses Bus
Hold during these states, the processor disables the
level-keepers and floats the data bus. This type of
design would require some kind of data bus termi-
nation to minimize power consumption. It is strongly
recommended that the D31-D0 pins do not have
network resistors connected. External resistors used
in the system design must be of a sufficient
resistance value to "flip" the level-keeper circuitry
and eliminate potential DC paths.

The level-keeper circuit is designed to allow an
external 27-K

pull-up resistor to switch the D31-D0

circuits to a logic-HIGH level even though the level-
keeper attempts to keep a logic-LOW level. In
general, pull-up resistors smaller than 27 K

can be

used as well as those greater than or equal to 1 M

Pull-down resistors, when connected to D31-D0,
should be least 800 K

Embedded Ultra-Low Power Intel486TM SX Processor

4.4

Low-Power Features

As with other Intel486 processors, the embedded
ULP Intel486 SX processor minimizes power
consumption by providing the Auto HALT Power
Down, Stop Grant, and Stop Clock states (see
Figure 4). The embedded ULP Intel486 SX
processor has an Auto Clock Freeze feature that
further conserves power by judiciously deactivating
its internal clocks while in the Normal Execution
Mode. The power-conserving mechanism is
designed such that it does not degrade processor
performance or require changes to AC timing specifi-
cations.

4.4.1

Auto Clock Freeze

To reduce power consumption, during the following
bus cycles -- under certain conditions -- the
processor slows-up or freezes some internal clocks:

· Data-Read Wait Cycles (Memory, I/O and Interrupt

Acknowledge)

· Data-Write Wait Cycles (Memory, I/O)

· HOLD/HLDA Cycles

· AHOLD Cycles

· BOFF Cycles

Power is conserved during the wait periods in these
cycles until the appropriate external-system signals
are sent to the processor. These signals include:

· READY

· NMI, SMI#, INTR, and RESET

· BOFF#

· FLUSH#

· EADS#

· BS8#, BS16# and KEN# transitions

The embedded ULP Intel486 SX processor also
reduces power consumption by temporarily freezing
the clocks of its internal logic blocks. When a logic
block is idle or in a wait state, its clock is frozen.

4.5

CPUID Instruction

The embedded ULP Intel486 SX processor supports
the CPUID instruction (see Table 9). Because not all
Intel processors support the CPUID instruction, a
simple test can determine if the instruction is
supported. The test involves the processor's ID Flag,
which is bit 21 of the EFLAGS register. If software
can change the value of this flag, the CPUID
instruction is available. The actual state of the ID
Flag bit is irrelevant and provides no significance to
the hardware. This bit is cleared (reset to zero) upon
device reset (RESET or SRESET) for compatibility
with Intel486 processor designs that do not support
the CPUID instruction.

CPUID-instruction details are provided here for the
embedded ULP Intel486 SX processor. Refer to Intel
Application Note AP-485

Intel Processor Identifi-

cation with the CPUID Instruction

(Order No.

241618) for a description that covers all aspects of
the CPUID instruction and how it pertains to other
Intel processors.

4.5.1

Operation of the CPUID Instruction

The CPUID instruction requires the software
developer to pass an input parameter to the
processor in the EAX register. The processor
response is returned in registers EAX, EBX, EDX,
and ECX.

Table 9. CPUID Instruction Description

OP CODE

Instruction

Processor

Core Clocks

Parameter passed in

EAX

(Input Value)

Description

0F A2

CPUID

Vendor (Intel) ID String

Processor Identification

> 1

Undefined (Do Not Use)

Embedded Ultra-Low Power Intel486TM SX Processor

Vendor ID String - When the parameter passed in EAX is 0 (zero), the register values returned upon
instruction execution are shown in the following table.

The values in EBX, EDX and ECX indicate an Intel processor. When taken in the proper order, they decode to
the string "

GenuineIntel

Processor Identification - When the parameter passed to EAX is 1 (one), the register values returned upon
instruction execution are:

4.6

Identification After Reset

Processor Identification - Upon reset, the EDX register contains the processor signature:

31-------------24

23-----------16

15--------------8

7--------------0

High Value (= 1)

EAX

0 0 0 0

0 0 0 1

Vendor ID String

EBX

(75)

(6E)

(65)

(47)

(ASCII

EDX

(49)

(65)

(6E)

(69)

Characters)

ECX

(6C)

(65)

(74)

(6E)

31---------------------------14

13,12

11----8

7----4

3----0

Processor

Signature

EAX

(Do Not Use)

Intel Reserved

0 0

Processor

Type

0 1 0 0

Family

0 0 1 0

Model

XXXX

Stepping

(Intel releases information about stepping numbers as needed)

31--------------------------------------------------------------------------------------------------0

Intel Reserved

EBX

Intel Reserved

(Do Not Use)

ECX

Intel Reserved

31----------------------------------------------------------------------------2

Feature Flags

EDX

0------------------------------------------------------------------------------0

VME

FPU

31---------------------------14

13,12

11----8

7----4

3----0

Processor

Signature

EDX

(Do Not Use)

Intel Reserved

0 0

Processor

Type

0 1 0 0

Family

0 0 1 0

Model

XXXX

Stepping

(Intel releases information about stepping numbers as needed)

Embedded Ultra-Low Power Intel486TM SX Processor

4.7

Boundary Scan (JTAG)

4.7.1

Device Identification

Table 10 shows the 32-bit code for the embedded ULP Intel486 SX processor which is loaded into the Device
Identification Register.

Table 10. Boundary Scan Component Identification Code

Version

Part Number

Mfg ID

009H = Intel

0=5V

1=3.3 V

Intel

Architecture

Type

Family

0100 = Intel486

CPU Family

Model

00010 =

embedded ULP

Intel486 SX

processor

31----28

26-----------21

20----17

16--------12

11------------1

XXXX

000001

0100

00010

00000001001

(Intel releases information about version numbers as needed)
Boundary Scan Component Identification Code = x828 2013 (Hex)

4.7.2

Boundary Scan Register Bits and Bit
Order

The boundary scan register contains a cell for each
pin as well as cells for control of bidirectional and
three-state pins. There are "Reserved" bits which
correspond to no-connect (N/C) signals of the
embedded ULP Intel486 SX processor. Control
registers WRCTL, ABUSCTL, BUSCTL, and
MISCCTL are used to select the direction of bidirec-
tional or three-state output signal pins. A "1" in these
cells designates that the associated bus or bits are
floated if the pins are three-state, or selected as
input if they are bidirectional.

· WRCTL controls D31-D0

· ABUSCTL controls A31-A2

· BUSCTL controls ADS#, BLAST#, PLOCK#,

LOCK#, W/R#, BE0#, BE1#, BE2#, BE3#, M/IO#,
D/C#, PWT, and PCD

· MISCCTL controls HLDA, and BREQ

The following is the bit order of the embedded ULP
Intel486 SX processor boundary scan register:

TDO

A2, A3, A4, A5, RESERVED#, A6,
A7, A8, A9, A10, A11, A12, A13,
A14, A15, A16, A17, A18, A19,
A20, A21, A22, A23, A24, A25,
A26, A27, A28, A29, A30, A31,
Reserved, D0, D1, D2, D3, D4,
D5, D6, D7, Reserved, D8, D9,
D10, D11, D12, D13, D14, D15,
Reserved, D16, D17, D18, D19,
D20, D21, D22, D23, Reserved,
D24, D25, D26, D27, D28, D29,
D30, D31, STPCLK#, Reserved,
Reserved, SMI#, SMIACT#,
SRESET, NMI, INTR, FLUSH#,
RESET, A20M#, EADS#, PCD,
PWT, D/C#, M/IO#, BE3#, BE2#,
BE1#, BE0#, BREQ, W/R#,
HLDA, CLK, Reserved, AHOLD,
HOLD, KEN#, RDY#, BS8#,
BS16#, BOFF#, BRDY#,
Reserved, LOCK#, PLOCK#,
BLAST#, ADS#, MISCCTL,
BUSCTL, ABUSCTL, WRCTL

TDI

Embedded Ultra-Low Power Intel486TM SX Processor

5.0

ELECTRICAL SPECIFICATIONS

5.1

Maximum Ratings

Table 11 is a stress rating only. Extended exposure
to the Maximum Ratings may affect device reliability.

Furthermore, although the embedded ULP Intel486
SX processor contains protective circuitry to resist
damage from electrostatic discharge, always take
precautions to avoid high static voltages or electric
fields.

Functional operating conditions are given in Section
5.2, DC Specifications and Section 5.3, AC Speci-
fications.

5.2

DC Specifications

The following tables show the operating supply
voltages, DC I/O specifications, and component
power consumption for the embedded ULP Intel486
SX processor.

Table 11. Absolute Maximum Ratings

Case Temperature under
Bias

-65 °C to +110 °C

Storage Temperature

-65 °C to +150 °C

DC Voltage on Any Pin
with Respect to Ground

-0.5 V to V

CCP

+ 0.5 V

Supply Voltage V

with

Respect to V

-0.5 V to +4.6 V

Supply Voltage V

CCP

with Respect to V

-0.5 V to +4.6 V

Table 12. Operating Supply Voltages

Product

CCP

Range

Max. CLK

Frequency

Range

Fluctuation

FA80486SXSF-33

3.3 V

3 V

2.4 V min

3.3 V max

0.2 V

+0.3 V/-0.2 V

0.3 V

at 2.4 V

2.7 V

at 2.7 V

< 3.0 V

at 3.0 V

3.3 V

2.7 V min

3.3 V max

NOTES:

1. In all cases, V

CCP

must be

2. V

may be set to any voltage within the V

Range. The setting determines the allowed V

Fluctuation.

Embedded Ultra-Low Power Intel486TM SX Processor

Table 13. DC Specifications

CASE

=0 °C to +85 °C

Symbol

Parameter

Min.

Max.

Unit

Notes

Input LOW Voltage

-0.3

+0.8

Input HIGH Voltage

2.0

CCP

+0.3

Note 1

IHC

Input HIGH Voltage of CLK

CCP

-0.6

CCP

+0.3

Output LOW Voltage

= 2.0 mA

= 100 µA

0.4

0.2

Output HIGH Voltage

= -2.0 mA

= -100 µA

2.4

CCP

-0.2

Input Leakage Current

Note 2

Input Leakage Current

200

Note 3

Input Leakage Current

400

Note 4

Output Leakage Current

Input Capacitance

Note 5

OUT

I/O or Output Capacitance

Note 5

CLK

CLK Capacitance

Note 5

NOTES:

1. All inputs except CLK.

2. This parameter is for inputs without pull-up or pull-down resistors and 0V

CCP

3. This parameter is for inputs with pull-down resistors and V

= 2.4V, and for level-keeper pins at V=0.4V.

4. This parameter is for inputs with pull-up resistors and V

= 0.4V, and for level-keeper pins at V=2.4V.

5. F

=1 MHz. Not 100% tested.

Embedded Ultra-Low Power Intel486TM SX Processor

Table 14. Active I

Values

CASE

=0 °C to +85 °C

Symbol

Parameter

Frequency

Supply Voltage

Typical I

Max. I

Notes

CC1

Active

pins)

25 MHz

= 2.4

0.2 V

120 mA

195 mA

= 3.3

0.3 V

165 mA

260 mA

33 MHz

= 2.7

0.2 V

180 mA

280 mA

= 3.3

0.3 V

220 mA

345 mA

CC2

Active

CCP

pins)

25 MHz

CCP

= 3.3

0.3 V

9 mA

30 mA

33 MHz

CCP

= 3.3

0.3 V

12 mA

40 mA

NOTES:

1. These parameters are for C

= 50 pF

Table 15. Clock Stop, Stop Grant, and Auto HALT Power Down I

Values

CASE

= 0 °C to +85 °C

Symbol

Parameter

Frequency

Supply Voltage

Typical I

Max. I

Notes

CCS0

Stop Clock

pins)

0 MHz

= 2.4

0.2 V

120

Note 1

= 2.7

0.2 V

130

= 3.3

0.3 V

150

CCS2

Stop Clock

CCP

pins)

0 MHz

CCP

= 3.3

0.3 V

CCS1

Stop Grant,

Auto HALT

Power Down

pins)

25 MHz

= 2.4

0.2 V

14 mA

25 mA

= 3.3

0.3 V

20 mA

30 mA

33 MHz

= 2.7

0.2 V

20 mA

30 mA

= 3.3

0.3 V

25 mA

35 mA

CCS3

Stop Grant,

Auto HALT

Power Down

CCP

pins)

25 MHz

CCP

= 3.3

0.3 V

425

1.5 mA

33 MHz

CCP

= 3.3

0.3 V

610

2.0 mA

NOTES:

1. The I

Stop Clock specification refers to the I

value once the processor enters the Stop Clock state. For all input signals,

the V

and V

levels must be equal to V

CCP

and 0V, respectively, to meet the I

Stop Clock specifications.

Embedded Ultra-Low Power Intel486TM SX Processor

5.3

AC Specifications

The AC specifications for the embedded ULP Intel486 SX processor are given in this section.

Table 16. AC Characteristics (Sheet 1 of 2)

valid over the operating supply voltages listed in Table 12, Operating Supply Voltages (pg. 22).

CASE

= 0 °C to +85 °C; C

= 50 pF

Symbol

Parameter

2.4V

2.7V

3.3V

Min

Max

Min

Max

Unit

Notes

Frequency

MHz

Note 1

CLK Period

Note 1

CLK Period Stability

250

ps/CLK

Note 2

CLK High Time

at 2V

CLK Low Time

at 0.8V

CLK Fall Time

2V to 0.8V

Note 3

CLK Rise Time

0.8V to 2V

Note 3

A2-A31, PWT, PCD, BE0#-
BE3#, M/IO#, D/C#, W/R#,
ADS#, LOCK#, BREQ, HLDA,
SMIACT# Valid Delay

A2-A31, PWT, PCD, BE0#-
BE3#, M/IO#, D/C#, W/R#,
ADS#, LOCK#, BREQ, Float
Delay

Note 3

BLAST#, PLOCK# Valid Delay

BLAST#, PLOCK# Float Delay

Note 3

D0-D31 Write Delay

D0-D31 Float Delay

Note 3

EADS# Setup Time

EADS# Hold Time

BS16#, BS8#, KEN# Setup
Time

BS16#, BS8#, KEN# Hold
Time

RDY#, BRDY# Setup Time

RDY#, BRDY# Hold Time

HOLD, AHOLD Setup Time

18a

BOFF# Setup Time

Embedded Ultra-Low Power Intel486TM SX Processor

HOLD, AHOLD, BOFF# Hold
Time

FLUSH#, A20M#, NMI, INTR,
SMI#, STPCLK#, SRESET,
RESET Setup Time

FLUSH#, A20M#, NMI, INTR,
SMI#, STPCLK#, SRESET,
RESET Hold Time

D0-D31, A4-A31 Read Setup
Time

D0-D31, A4-A31 Read Hold
Time

NOTES:

1. 0 Hz operation is tested and guaranteed by the STPCLK# and Stop Grant bus cycle protocol. 0 Hz < CLK < 8 MHz opera-

tion is confirmed by design characterization, but not 100% tested in production.

2. Specification t1a is applicable only when CLK frequency is changed without STPCLK# / STOP GRANT bus cycle protocol.

3. Not 100% tested, guaranteed by design characterization.

4. CLK reference voltage for timing measurement is 1.5 V except t2 through t5. Other signals are measured at 1.5 V.

Table 16. AC Characteristics (Sheet 2 of 2)

valid over the operating supply voltages listed in Table 12, Operating Supply Voltages (pg. 22).

CASE

= 0 °C to +85 °C; C

= 50 pF

Symbol

Parameter

2.4V

2.7V

3.3V

Min

Max

Min

Max

Unit

Notes

Embedded Ultra-Low Power Intel486TM SX Processor

Table 17. AC Specifications for the Test Access Port

Symbol

Parameter

2.2 V

Vcc

3.0 V

Vcc = 3.3 ± 0.3 V

Unit

Figure

Notes

Min

Max

Min

Max

TCK Frequency

MHz

TCK Period

200

125

Note 1

TCK High Time

@ 2.0V

TCK Low Time

@0.8V

TCK Rise Time

Note 2

TCK Fall Time

Note 2

TDI, TMS Setup Time

Note 3

TDI, TMS Hold Time

Note 3

TDO Valid Delay

Note 3

TDO Float Delay

Notes 3, 4

All Outputs (except
TDO) Valid Delay

Note 3

All Outputs (except
TDO) Float Delay

Notes 3, 4

All Inputs (except TDI,
TMS, TCK) Setup Time

Note 3

All Inputs (except TDI,
TMS, TCK) Hold Time

Note 3

NOTES:

1. TCK period

CLK period.

2. Rise/Fall Times are measured between 0.8 V and 2.0 V. Rise/Fall times can be relaxed by 1 ns per 10 ns increase in TCK

period.

3. Parameter measured from TCK.

4. Not 100% tested, guaranteed by design characterization.

Embedded Ultra-Low Power Intel486TM SX Processor

6.2

Package Thermal Specifications

The embedded ULP Intel486 SX processor is
specified for operation when the case temperature
(T

) is within the range of 0°C to 85°C. T

may be

measured in any environment to determine whether
the processor is within the specified operating range.

The ambient temperature (T

) can be calculated

from

and

from the following equations:

= T

+ P *

= T

- P *

= T

+ P * [

]

= T

- P * [

]

Where T

, T

equals Junction, Ambient and

Case Temperature respectively.

equals

Junction-to-Case and Junction-to-Ambient thermal
Resistance, respectively. Maximum Power
Consumption (P) is defined as

P =

V (typ) * I

(max)

P =

(typ) * I

CC1

(max)] +

CCP

(typ) * I

CC2

(max)]

where:

CC1

is the V

supply current

CC2

is the V

CCP

supply current

Values for

and

are given in the following

tables for each product at its maximum operating
frequencies.

The following table shows maximum ambient temperatures of the embedded ULP Intel486 SX processor for
each product and maximum operating frequencies. These temperatures are calculated using I

CC1

and I

CC2

values measured during component-validation testing using V

CCP

=3.6 V and worst-case V

values.

Table 18. Thermal Resistance

(°C/W)

and

for the 176-Lead TQFP Package

(°C/W)

(°C/W) with no airflow

4.3

33.6

Table 19. Maximum Ambient Temperature (T

)

176-Lead TQFP Package

Frequency

(°C) with no airflow

25 MHz

2.4 V

3.3 V

33 MHz

2.7 V

3.3 V

Document Outline

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Document Outline

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