A80486DX4WB100/SK096 [INTEL]
RISC Microprocessor, 32-Bit, 100MHz, CMOS, CPGA168;型号: | A80486DX4WB100/SK096 |
厂家: | INTEL |
描述: | RISC Microprocessor, 32-Bit, 100MHz, CMOS, CPGA168 外围集成电路 |
文件: | 总49页 (文件大小:1342K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
EMBEDDED WRITE-BACK ENHANCED
IntelDX4™ PROCESSOR
■ Up to 100 MHz Operation
■ SL Technology
■ Integrated Floating-Point Unit
■ Speed-Multiplying Technology
■ 32-Bit RISC Technology Core
■ 16-Kbyte Write-Back Cache
■ Data Bus Parity Generation and Checking
■ Boundary Scan (JTAG)
■ 3.3-Volt Processor, 75 MHz, 25 MHz CLK
— 208-Lead Shrink Quad Flat Pack (SQFP)
■ 3.3-Volt Processor, 100 MHz, 33 MHz CLK
— 208-Lead Shrink Quad Flat Pack (SQFP)
— 168-Pin Pin Grid Array (PGA)
■ 3.3 V Core Operation with 5 V Tolerant
I/O Buffers
■ Burst Bus Cycles
■ Binary Compatible with Large Software
■ Dynamic Bus Sizing for 8- and 16-bit
Base
Data Bus Devices
64-Bit Interunit Transfer Bus
32-Bit Data Bus
CLKMUL
Core
Clock
CLK
Clock
Multiplier
32-Bit Data Bus
Linear Address
32
PCD
PWT
Bus Interface
Base/
Index
Bus
A31-A2 BE3#- BE0#
Barrel
Shifter
Segmentation
2
Cache Unit
Unit
Paging
Unit
Address
Drivers
20
Descriptor
Registers
Register
File
32
Write Buffers
4 x 32
Physical
Address
16 Kbyte
Cache
32
D31-D0
Translation
Lookaside
Buffer
Limit and
Attribute PLA
Data Bus
Transceivers
ALU
ADS# W/R# D/C# M/IO# PCD
PWT RDY# LOCK# PLOCK#
BOFF# A20M# BREQ HOLD
HLDA RESET SRESET INTR
NMI SMI# SMIACT# FERR#
IGNNE# STPCLK#
Bus Control
Displacement Bus
32
Request
Sequencer
Prefetcher
Micro-
Instruction
BRDY# BLAST#
BS16# BS8#
Burst Bus
Control
32-Byte Code
Queue
Bus Size
Control
Code
Stream
KEN# FLUSH# AHOLD EADS#
CACHE# HITM# INV WB/WT#
2 x 16 Bytes
Control &
Protection
Test Unit
Cache
Control
Floating
Point Unit
Instruction
Decode
24
Parity
Generation
and Control
PCHK# DP3-DP0
Floating
Point
Register File
Decoded
Instruction
Path
Control
ROM
Boundary
Scan
TCK TMS TDI TDO
Control
A3232-01
Figure 1. Embedded Write-Back Enhanced IntelDX4™ Processor Block Diagram
© INTEL CORPORATION, 2004 August 2004 Order Number: 272771-003
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 Write-Back Enhanced IntelDX4™ 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.
Copyright © Intel Corporation, 1997, 2004
*Third-party brands and names are the property of their respective owners.
Contents
EMBEDDED WRITE-BACK ENHANCED
IntelDX4™ 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 ......................................................................................................................... 16
4.0 ARCHITECTURAL AND FUNCTIONAL OVERVIEW ............................................................................. 26
4.1 CPUID Instruction ............................................................................................................................. 26
4.1.1 Operation of the CPUID Instruction ....................................................................................... 26
4.2 Identification After Reset .................................................................................................................. 28
4.3 Boundary Scan (JTAG) .................................................................................................................... 28
4.3.1 Device Identification ............................................................................................................... 28
4.3.2 Boundary Scan Register Bits and Bit Order ........................................................................... 29
5.0 ELECTRICAL SPECIFICATIONS ........................................................................................................... 30
5.1 Maximum Ratings ............................................................................................................................. 30
5.2 DC Specifications ............................................................................................................................. 30
5.3 AC Specifications ............................................................................................................................. 33
5.4 Capacitive Derating Curves .............................................................................................................. 40
6.0 MECHANICAL DATA .............................................................................................................................. 42
6.1 Package Dimensions ........................................................................................................................ 42
6.2 Package Thermal Specifications ...................................................................................................... 44
FIGURES
Figure 1.
Embedded Write-Back Enhanced IntelDX4™ Processor Block Diagram ................................... i
Figure 2.
Package Diagram for 208-Lead SQFP Embedded Write-Back Enhanced
IntelDX4™ Processor ................................................................................................................ 4
Figure 3.
Package Diagram for 168-Pin PGA Embedded Write-Back Enhanced
IntelDX4™ Processor .............................................................................................................. 10
Figure 4.
Figure 5.
Figure 6.
Figure 7.
Figure 8.
Figure 9.
Figure 10.
Figure 11.
CLK Waveform ........................................................................................................................ 36
Input Setup and Hold Timing ................................................................................................... 36
Input Setup and Hold Timing ................................................................................................... 37
PCHK# Valid Delay Timing ...................................................................................................... 37
Output Valid Delay Timing ....................................................................................................... 38
Maximum Float Delay Timing .................................................................................................. 38
TCK Waveform ........................................................................................................................ 39
Test Signal Timing Diagram .................................................................................................... 39
iii
Contents
Figure 12.
Figure 13.
Typical Loading Delay versus Load Capacitance under Worst-Case Conditions
for a Low-to-High Transition .....................................................................................................40
Typical Loading Delay versus Load Capacitance under Worst-Case Conditions
for a High-to-Low Transition .....................................................................................................40
Figure 14.
Figure 15.
Figure 16.
Typical Loading Delay versus Load Capacitance in Mixed Voltage System ...........................41
208-Lead SQFP Package Dimensions .................................................................................... 42
Principal Dimensions and Data for 168-Pin Grid Array Package .............................................43
TABLES
Table 1.
Table 2.
Table 3.
Table 4.
Table 5.
Table 6.
Table 7.
Table 8.
Table 9.
Table 10.
Table 11.
Table 12.
Table 13.
Table 14.
Table 15.
Table 16.
Table 17.
Table 18.
Table 19.
Table 20.
Table 21.
Table 22.
Table 23.
Table 24.
Table 25.
Table 26.
The Embedded Write-Back Enhanced IntelDX4™ Processor Family .......................................2
Pinout Differences for 208-Lead SQFP Package ......................................................................5
Pin Assignment for 208-Lead SQFP Package ...........................................................................6
Pin Cross Reference for 208-Lead SQFP Package ...................................................................8
Pinout Differences for 168-Pin PGA Package .........................................................................11
Pin Assignment for 168-Pin PGA Package ..............................................................................12
Pin Cross Reference for 168-Pin PGA Package ......................................................................14
Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions .............................16
Output Pins ..............................................................................................................................24
Input/Output Pins .....................................................................................................................24
Test Pins ..................................................................................................................................25
Input Pins .................................................................................................................................25
CPUID Instruction Description .................................................................................................26
Boundary Scan Component Identification Code (Write-Through/Standard Bus Mode) ...........28
Boundary Scan Component Identification Code (Write-Back/Enhanced Bus Mode) ...............29
Absolute Maximum Ratings .....................................................................................................30
Operating Supply Voltages ......................................................................................................30
DC Specifications .....................................................................................................................31
I
CC Values ................................................................................................................................32
AC Characteristics ...................................................................................................................33
AC Specifications for the Test Access Port .............................................................................35
168-Pin Ceramic PGA Package Dimensions ...........................................................................43
Ceramic PGA Package Dimension Symbols ...........................................................................44
Thermal Resistance, θJA (°C/W) .............................................................................................45
Thermal Resistance, θJC (°C/W) .............................................................................................45
Maximum Tambient, TA max (°C) ...............................................................................................45
iv
Embedded Write-Back Enhanced IntelDX4™ Processor
1.0 INTRODUCTION
1.1 Features
The embedded Write-Back Enhanced IntelDX4™
processor provides high performance to 32-bit,
embedded applications. Designed for applications
that need a floating-point unit, the processor is ideal
for embedded designs running DOS*, Microsoft
Windows*, OS/2*, or UNIX* applications written for
the Intel architecture. Projects can be completed
quickly using the wide range of software tools,
utilities, assemblers and compilers that are available
for desktop computer systems. Also, developers can
find advantages in using existing chipsets and
peripheral components in their embedded designs.
The Embedded Write-Back Enhanced IntelDX4
processor offers these features:
• 32-bit RISC-Technology Core — The Embedded
Write-Back Enhanced IntelDX4 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.
The Embedded Write-Back Enhanced IntelDX4
processor is binary compatible with the Intel386™
and earlier Intel processors. Compared with the
Intel386 processor, it provides faster execution of
many commonly-used instructions. It also provides
the benefits of an integrated, 16-Kbyte, write-back
cache for code and data. Its data bus can operate in
burst mode which provides up to 106-Mbyte-per-
second transfers for cache-line fills and instruction
prefetches.
• On-Chip Floating-Point Unit — Intel486™
processors support the 32-, 64-, and 80-bit formats
specified in IEEE standard 754. The unit is binary
compatible with the 8087, Intel287™, Intel387™
coprocessors, and Intel OverDrive® processor.
• On-Chip Cache with Cache Consistency
Support — A 16-Kbyte internal cache is used for
both data and instructions. It is configurable to be
write-back or write-through on a line-by-line basis.
The internal cache implements a modified MESI
protocol, which is applicable to uniprocessor
Intel’s SL technology is incorporated in the
Embedded
Write-Back
Enhanced
IntelDX4
systems. 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.
processor. Utilizing Intel’s System Management
Mode (SMM) enables designers to develop energy-
efficient systems.
Two component packages are available:
• 168-pin Pin Grid Array (PGA)
• 208-lead Shrink Quad Flat Pack (SQFP)
• External Cache Control — Write-back and flush
controls for an external cache are provided so the
processor can maintain cache consistency.
The processor operates at either two or three times
the external bus frequency. At two times the external
bus frequency the processor operates up to 66 MHz,
(33-MHz CLK). At three times the external bus
frequency the processor operates up to 100 MHz
(33-MHz CLK).
• 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
memory 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. Data written from the processor to memory
can also be burst transfers.
• 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.
1
Embedded Write-Back Enhanced IntelDX4™ Processor
• Bus Backoff — When another bus master needs
control of the bus during a processor initiated bus
cycle, the Embedded Write-Back Enhanced
IntelDX4 processor floats its bus signals, then
restarts the cycle when the bus becomes available
again.
• Stop Clock — The Embedded Write-Back
Enhanced IntelDX4 processor has a stop clock
control mechanism that provides two low-power
states: a Stop Grant state (20–50 mA typical,
depending on input clock frequency) and a Stop
Clock state (~600 µA typical, with input clock
frequency of 0 MHz).
• 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.
• Auto HALT Power Down — After the execution of
a HALT instruction, the Embedded Write-Back
Enhanced IntelDX4 processor issues a normal
Halt bus cycle and the clock input to the processor
core is automatically stopped, causing the
processor to enter the Auto HALT Power Down
state (20–50 mA typical, depending on input clock
frequency).
• 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.
• Auto Idle Power Down — This function allows the
processor to reduce the core frequency to the bus
frequency when both the core and bus are idle.
Auto Idle Power Down is software transparent and
does not affect processor performance. Auto Idle
Power Down provides an average power savings
of 10% and is only applicable to clock multiplied
processors.
• Enhanced Bus Mode — The definitions of some
signals have been changed to support write-back
cache mode.
Intel’s SL technology provides these features:
• 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.
1.2 Family Members
Table 1 shows the Embedded Write-Back Enhanced
IntelDX4 processors and briefly describes their
characteristics.
• 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.
Table 1. The Embedded Write-Back Enhanced IntelDX4™ Processor Family
Maximum
Processor
Frequency
Maximum
External Bus
Frequency
Supply Voltage
Product
Package
V
CC
x80486DX4WB75
x80486DX4WB100
x80486DX4WB100
MHz
75
25 MHz
33 MHz
33 MHz
208-Lead SQFP
208-Lead SQFP
168-Pin PGA
3.3 V
3.3 V
3.3 V
100 MHz
100 MHz
NOTE: To address the fact that many of the package prefix variables have changed, all package prefix variables
in this document are now indicated with an "x".
2
Embedded Write-Back Enhanced IntelDX4™ Processor
2.0 HOW TO USE THIS DOCUMENT
3.0 PIN DESCRIPTIONS
For a complete set of documentation related to the
Embedded
Write-Back
Enhanced
IntelDX4
3.1 Pin Assignments
processor, use this document in conjunction with the
following reference documents:
The following figures and tables show the pin assign-
ments of each package type for the Embedded
Write-Back Enhanced IntelDX4 processor. Tables
are provided showing the pin differences between
the Embedded Write-Back Enhanced IntelDX4
processor and other embedded Intel486 processor
products.
• Embedded Intel486™ Processor Family
Developer’s Manual — Order No. 273021
• Embedded Intel486™ Processor Hardware
Reference Manual — Order No. 273025
• Intel486 Microprocessor Family Programmer’s
Reference Manual — Order No. 240486
208-Lead SQFP - Quad Flat Pack
• Intel Application Note AP-485 — Intel Processor
Identification with the CPUID Instruction —
Order No. 241618
• Figure 2, Package Diagram for 208-Lead SQFP
Embedded Write-Back Enhanced IntelDX4™
Processor (pg. 4)
The information in the reference documents for the
IntelDX4 processor applies to the Embedded Write-
Back Enhanced IntelDX4 processor. Some of the
IntelDX4 processor information is duplicated in this
document to minimize the dependence on the
reference documents.
• Table 2, Pinout Differences for 208-Lead SQFP
Package (pg. 5)
• Table 3, Pin Assignment for 208-Lead SQFP
Package (pg. 6)
• Table 4, Pin Cross Reference for 208-Lead SQFP
Package (pg. 8)
168-Pin PGA - Pin Grid Array
• Figure 3, Package Diagram for 168-Pin PGA
Embedded Write-Back Enhanced IntelDX4™
Processor (pg. 10)
• Table 5, Pinout Differences for 168-Pin PGA
Package (pg. 11)
• Table 6, Pin Assignment for 168-Pin PGA
Package (pg. 12)
• Table 7, Pin Cross Reference for 168-Pin PGA
Package (pg. 14)
3
Embedded Write-Back Enhanced IntelDX4™ Processor
V
V
V
1
156
155
154
153
152
151
150
149
148
147
146
145
144
143
142
141
140
139
138
137
136
135
134
133
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
SS
CC
SS
V
2
CC
CC5
V
3
A25
A26
A27
A28
PCHK#
BRDY#
BOFF#
BS16#
BS8#
4
5
6
V
CC
7
8
A29
A30
A31
V
9
CC
SS
V
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
45
46
47
48
49
50
51
52
V
SS
CLKMUL
RDY#
DP0
D0
D1
D2
D3
D4
KEN#
V
CC
SS
V
HOLD
AHOLD
TCK
V
SS
CC
V
V
CC
208-Lead SQFP
Embedded Write-Back Enhanced
IntelDX4™ Processor
V
V
CC
CC
V
CC
V
SS
V
CC
V
CC
SS
V
CC
V
V
SS
CLK
CC
V
V
CC
V
CC
HLDA
W/R#
D5
V
CC
D6
SS
V
V
CC
BREQ
BE0#
BE1#
BE2#
BE3#
NC
D7
Top View
DP1
D8
D9
V
V
CC
SS
V
CC
SS
V
V
SS
M/IO#
V
CC
D10
D11
D12
D13
D/C#
PWT
PCD
V
V
CC
SS
V
CC
SS
V
V
D14
CC
V
D15
CC
V
SS
EADS#
A20M#
RESET
FLUSH#
INTR
CC
V
DP2
D16
V
CC
SS
V
NMI
V
SS
V
SS
A3230-01
Figure 2. Package Diagram for 208-Lead SQFP Embedded Write-Back Enhanced IntelDX4™ Processor
4
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 2. Pinout Differences for 208-Lead SQFP Package
Embedded
Intel486™ SX
Processor
Embedded
IntelDX2™
Processor
Embedded Write-Back
Enhanced IntelDX4™
Processor
Pin #
1
3
VCC
INC
VCC5
CLKMUL
HITM#
V
CC
2
11
INC
63
64
INC
INC
INC
INC
INC
INC
INC
INC
WB/WT#
FERR#
CACHE#
INV
66
FERR#
INC
70
71
INC
72
IGNNE#
IGNNE#
NOTES:
1. This pin location is for the VCC5 pin on the embedded IntelDX4 processor. For compatibility with 3.3V processors that
have 5V-tolerant input buffers (i.e., embedded IntelDX4 processors), this pin should be connected to a VCC trace, not to
the VCC plane.
2. INC. Internal No Connect. These pins are not connected to any internal pad. However, signals are defined for the loca-
tion of the INC pins in the embedded IntelDX4 processor. One system design can accommodate any one of these pro-
cessors provided the purpose of each INC pin is understood before it is used.
5
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 3. Pin Assignment for 208-Lead SQFP Package (Sheet 1 of 2)
Pin#
1
Description
Pin#
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
Description
Pin#
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
Description
Pin#
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
Description
VSS
VSS
VSS
VSS
A24
A23
A22
A21
2
V
V
V
CC
CC
CC
3
V
VSS
VSS
D16
DP2
VSS
5
CC
4
PCHK#
BRDY#
BOFF#
BS16#
BS8#
V
CC
5
VSS
6
SRESET
SMIACT#
V
CC
CC
7
V
V
CC
8
D15
D14
A20
A19
A18
TMS
TDI
V
CC
9
V
VSS
CC
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
VSS
CLKMUL
RDY#
V
V
CC
CC
HITM#
WB/WT#
SMI#
VSS
D13
D12
D11
D10
VSS
KEN#
V
CC
V
FERR#
NC1
VSS
A17
CC
VSS
HOLD
AHOLD
TCK
TDO
V
CC
V
A16
A15
VSS
V
CC
CC
CACHE#
INV
VSS
D9
V
V
CC
CC
IGNNE#
STPCLK#
D31
D8
V
CC
VSS
DP1
D7
A14
A13
V
CC
V
D30
NC1
V
CC
CC
CLK
VSS
V
A12
VSS
A11
CC
V
D6
D5
V
CC
CC
HLDA
W/R#
VSS
D29
D28
V
V
CC
CC
V
VSS
VSS
CC
V
VSS
V
V
CC
CC
CC
CC
BREQ
BE0#
BE1#
BE2#
BE3#
V
A10
A9
V
CC
D27
D26
D25
VSS
V
V
CC
CC
V
VSS
A8
CC
VSS
V
CC
V
D24
V
V
CC
CC
CC
6
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 3. Pin Assignment for 208-Lead SQFP Package (Sheet 2 of 2)
Pin#
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
Description
VSS
Pin#
88
Description
Pin#
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
Description
Pin#
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
Description
VSS
D4
D3
A7
M/IO#
89
A6
V
CC
V
90
DP3
D23
D22
D21
VSS
D2
RESERVED#
CC
D/C#
PWT
PCD
91
D1
A5
A4
A3
92
D0
93
DP0
VSS
A31
A30
A29
V
94
V
CC
CC
VSS
95
VSS
V
CC
NC1
VSS
V
96
V
CC
CC
V
97
VSS
A2
CC
EADS#
A20M#
RESET
FLUSH#
INTR
98
V
V
CC
CC
99
D20
D19
D18
A28
A27
A26
A25
ADS#
BLAST#
100
101
102
103
104
V
CC
V
PLOCK#
LOCK#
VSS
CC
NMI
D17
VSS
V
CC
VSS
VSS
NOTE:
1. NC. Do Not Connect. These pins should always remain unconnected. Connection of NC pins to VCC, or VSS or to any other
signal can result in component malfunction or incompatibility with future steppings of the Intel486 processors.
7
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 4. Pin Cross Reference for 208-Lead SQFP Package (Sheet 1 of 2)
Address
A2
Pin #
202
197
196
195
193
192
190
187
186
182
180
178
177
174
173
171
166
165
164
161
160
159
158
154
153
152
151
149
148
147
Data
D0
Pin #
144
143
142
141
140
130
129
126
124
123
119
118
117
116
113
112
108
103
101
100
99
Control
A20M#
ADS#
AHOLD
BE0#
Pin #
47
203
17
31
32
33
34
204
6
NC
67
VCC5
VCC
2
VSS
1
3
A3
D1
96
9
10
A4
D2
127
14
19
20
22
23
25
29
35
38
42
44
45
54
56
60
62
69
77
80
82
86
89
95
98
102
106
111
114
121
128
131
15
A5
D3
21
A6
D4
BE1#
28
A7
D5
BE2#
36
A8
D6
BE3#
43
A9
D7
BLAST#
BOFF#
BRDY#
BREQ
BS16#
BS8#
52
A10
A11
A12
A13
A14
A15
A16
A17
A18
A19
A20
A21
A22
A23
A24
A25
A26
A27
A28
A29
A30
A31
D8
53
D9
5
55
D10
D11
D12
D13
D14
D15
D16
D17
D18
D19
D20
D21
D22
D23
D24
D25
D26
D27
D28
D29
D30
D31
30
7
57
61
8
76
CACHE#
CLK
70
24
11
39
145
125
109
90
46
66
49
63
26
16
72
50
71
13
207
37
81
88
CLKMUL
D/C#
94
97
DP0
104
105
107
110
115
120
122
132
135
138
146
156
157
170
175
181
DP1
DP2
DP3
93
EADS#
FERR#
FLUSH#
HITM#
HLDA
HOLD
IGNNE#
INTR
92
91
87
85
84
83
79
78
INV
75
KEN#
LOCK#
M/IO#
74
8
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 4. Pin Cross Reference for 208-Lead SQFP Package (Sheet 2 of 2)
Address
Pin #
Data
Pin #
Control
NMI
Pin #
51
NC
VCC5
VCC
133
134
136
137
139
150
155
162
163
169
172
176
179
183
185
188
191
198
200
205
VSS
184
189
199
201
208
PCD
41
PCHK#
PLOCK#
PWT
4
206
40
RDY#
12
RESERVED#
RESET
SMI#
194
48
65
SMIACT#
SRESET
STPCLK#
TCK
59
58
73
18
TDI
168
68
TDO
TMS
167
64
WB/WT#
W/R#
27
9
Embedded Write-Back Enhanced IntelDX4™ Processor
A
B
C
D
E
F
G
H
J
K
L
M
N
P
Q
R
S
V
V
V
V
V
V
D9
DP1
V
D20
D19
D11
A28
A27
D2
D0
A31
SS
SS
SS
CC5
SS
SS
D6
D7
SS
1
2
3
4
5
6
7
1
2
3
4
V
V
D8
V
V
D22
D21
D18
CLK
D13
D17
D3
V
A25
VCC
VSS
A26
D1
A29
A30
D5
CC
CC
CC
SS
CC
V
D15
D12
D4
DP0
A17
A19
TCK
D23
DP3
D24
D10
DP2
D16
D14
A23
SS
V
V
VOLDET
SS
CC
V
V
A18
A14
A21
A24
SS
CC
5
6
7
V
V
D25
D27
CC
SS
V
V
A22
A20
A15
A12
D26
D28
D30
SS
CC
168-Pin PGA
Embedded Write-Back Enhanced
IntelDX4™ Processor
D29
VSS
D31
VCC
V
V
CC
SS
8
9
8
V
V
A16
A13
CC
SS
9
INV
SMI# SRESET
VCC
V
V
CC
SS
10
11
12
13
14
15
10
Pin Side View
VSS
V
V
RESERVED#
A9
A5
A7
A2
CC
SS
11
12
13
SMIACT#
NC
V
HITM#
CACHE#
A11
A8
SS
A10
VSS
A6
INC WB/WT#
TDI
VCC
A3
TMS FERR#
14
15
IGNNE# NMI FLUSH# A20M# HOLD KEN# STPCLK# BRDY# BE2#
D/C# LOCK# HLDA BREQ
BE0#
PWT
V
RDY#
BE3#
V
V
V
V
V
V
V
CC
A4
INTR
TDO RESET BS8#
M/IO#
W/R#
PLOCK# BLAST#
BE1#
PCD
CC
CC
CC
CC
CC
CC
16
17
16
17
V
V
V
V
V
V
SS
BOFF#
D
AHOLD EADS# BS16#
CLKMUL ADS#
PCHK#
Q
SS
SS
SS
H
SS
SS
SS
A
B
C
E
F
G
J
K
L
M
N
P
R
S
A3231-01
Figure 3. Package Diagram for 168-Pin PGA Embedded Write-Back Enhanced IntelDX4™ Processor
10
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 5. Pinout Differences for 168-Pin PGA Package
Embedded Write-Back Enhanced
IntelDX4™ Processor
Pin #
Embedded IntelDX2™ Processor
A10
A12
B12
B13
J1
INC
INC
INC
INC
VCC
INC
NC
INV
HITM#
CACHE#
WB/WT#
VCC5
R17
S4
CLKMUL
VOLDET
11
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 6. Pin Assignment for 168-Pin PGA Package (Sheet 1 of 2)
Pin #
A1
Description
D20
Pin #
D17
E1
Description
BOFF#
VSS
Pin #
P2
Description
A29
A2
D22
P3
A30
A3
TCK
D23
E2
V
P15
P16
P17
Q1
HLDA
CC
A4
E3
D10
V
CC
VSS
A31
VSS
A5
DP3
D24
E15
E16
E17
F1
HOLD
A6
V
CC
VSS
VSS
DP1
D8
A7
Q2
A8
D29
Q3
A17
A19
A21
A24
A22
A20
A16
A13
A9
VSS
A9
F2
Q4
A10
A11
A12
A13
A14
A15
A16
A17
B1
INV
F3
D15
Q5
VSS
F15
F16
F17
G1
KEN#
RDY#
BE3#
VSS
Q6
HITM#
INC
Q7
Q8
TDI
Q9
IGNNE#
INTR
AHOLD
D19
G2
V
Q10
Q11
Q12
Q13
Q14
Q15
Q16
Q17
R1
CC
G3
D12
G15
G16
G17
H1
STPCLK#
A5
V
A7
CC
VSS
VSS
B2
D21
A2
VSS
B3
BREQ
PLOCK#
PCHK#
A28
A25
VSS
B4
H2
D3
VSS
B5
H3
DP2
BRDY#
B6
D25
H15
H16
H17
J1
B7
V
V
R2
CC
CC
VSS
B8
D31
R3
V
CC
VSS
B9
V
V
R4
CC
CC5
B10
B11
B12
B13
B14
B15
B16
B17
C1
SMI#
J2
D5
R5
A18
V
J3
D16
BE2#
BE1#
PCD
VSS
R6
V
CC
CC
CACHE#
WB/WT#
TMS
J15
J16
J17
K1
R7
A15
R8
V
V
V
V
CC
CC
CC
CC
R9
NMI
R10
R11
R12
R13
R14
R15
R16
R17
TDO
K2
V
CC
EADS#
D11
K3
D14
A11
A8
K15
K16
K17
L1
BE0#
C2
D18
V
V
CC
CC
VSS
VSS
D6
C3
CLK
A3
C4
V
V
BLAST#
CLKMUL
CC
CC
C5
L2
12
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 6. Pin Assignment for 168-Pin PGA Package (Sheet 2 of 2)
Pin #
C6
Description
D27
Pin #
L3
Description
D7
Pin #
S1
Description
A27
C7
D26
L15
L16
L17
M1
PWT
S2
A26
C8
D28
V
S3
A23
CC
VSS
VSS
C9
D30
S4
VOLDET
A14
C10
C11
C12
C13
C14
C15
C16
C17
D1
SRESET
RESERVED#
SMIACT#
NC
S5
VSS
M2
V
S6
CC
M3
D4
S7
A12
VSS
VSS
VSS
VSS
VSS
M15
M16
M17
N1
D/C#
S8
FERR#
FLUSH#
RESET
BS16#
D9
V
S9
CC
VSS
D2
S10
S11
S12
S13
S14
S15
S16
S17
N2
D1
N3
DP0
LOCK#
M/IO#
W/R#
D0
A10
VSS
D2
D13
N15
N16
N17
P1
D3
D17
A6
A4
D15
D16
A20M#
BS8#
ADS#
13
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 7. Pin Cross Reference for 168-Pin PGA Package (Sheet 1 of 2)
Addres
s
Pin #
Data
Pin #
Control
Pin #
NC
INC
Vcc5
Vcc
Vss
A2
Q14
R15
S16
Q12
S15
Q13
R13
Q11
S13
R12
S7
D0
D1
P1
N2
N1
H2
M3
J2
A20M#
ADS#
AHOLD
BE0#
D15
S17
A17
K15
J16
J15
F17
R16
D17
H15
Q15
C17
D16
C3
C13
A13
J1
B7
B9
A7
A9
A3
A4
D2
B11
C4
A11
B3
A5
D3
A6
D4
BE1#
C5
B4
A7
D5
BE2#
E2
B5
A8
D6
L2
L3
F2
D1
E3
C1
G3
D2
K3
F3
J3
BE3#
E16
G2
E1
A9
D7
BLAST#
BOFF#
BRDY#
BREQ
BS16#
BS8#
E17
G1
A10
A11
A12
A13
A14
A15
A16
A17
A18
A19
A20
A21
A22
A23
A24
A25
A26
A27
A28
A29
A30
A31
D8
G16
H16
K2
D9
G17
H1
D10
D11
D12
D13
D14
D15
D16
D17
D18
D19
D20
D21
D22
D23
D24
D25
D26
D27
D28
D29
D30
D31
Q10
S5
K16
L16
M2
H17
K1
R7
CLK
K17
L1
Q9
CLKMUL
CACHE#
D/C#
R17
B12
M15
N3
M16
P16
R3
Q3
L17
M1
M17
P17
Q2
R5
Q4
D3
C2
B1
A1
B2
A2
A4
A6
B6
C7
C6
C8
A8
C9
B8
DP0
R6
Q8
DP1
F1
R8
Q5
DP2
H3
R9
Q7
DP3
A5
R10
R11
R14
R4
S3
EADS#
FERR#
FLUSH#
HITM#
HLDA
HOLD
IGNNE#
INTR
B17
C14
C15
A12
P15
E15
A15
A16
A10
F15
N15
N16
S6
Q6
S8
R2
S9
S2
S10
S11
S12
S14
S1
R1
P2
P3
Q1
INV
KEN#
LOCK#
M/IO#
14
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 7. Pin Cross Reference for 168-Pin PGA Package (Sheet 2 of 2)
Addres
s
Pin #
Data
Pin #
Control
Pin #
NC
INC
Vcc5
Vcc
Vss
NMI
PCD
B15
J17
Q17
Q16
L15
F16
C11
C16
B10
C12
C10
G15
A3
PCHK#
PLOCK#
PWT
RDY#
RESERVED#
RESET
SMI#
SMIACT#
SRESET
STPCLK#
TCK
TDI
A14
B16
B14
S4
TDO
TMS
VOLDET
WB/WT#
W/R#
B13
N17
15
Embedded Write-Back Enhanced IntelDX4™ 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 Intel486™ Processor Family Developer’s Manual, order No. 273021.
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 1 of 8)
Symbol
CLK
Type
Name and Function
I
Clock provides the fundamental timing and internal operating frequency for the
Embedded Write-Back Enhanced IntelDX4 processor. All external timing
parameters are specified with respect to the rising edge of CLK.
ADDRESS BUS
A31-A4
A3–A2
I/O
O
Address Lines A31–A2, together with the byte enable signals, BE3#–BE0#,
define the physical area of memory or input/output space accessed. Address lines
A31–A4 are used to drive addresses into the Embedded Write-Back Enhanced
IntelDX4 processor to perform cache line invalidation. Input signals must meet
setup and hold times t22 and t23. A31–A2 are not driven during bus or address
hold.
BE3#
BE2#
BE1#
BE0#
O
O
O
O
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 D31–D24
BE2# applies to D23–D16
BE1# applies to D15–D8
BE0# applies to D7–D0
DATA BUS
D31–D0
I/O
I/O
Data Lines. D7–D0 define the least significant byte of the data bus; D31–D24
define the most significant byte of the data bus. These signals must meet setup
and hold times t22 and t23 for proper operation on reads. These pins are driven
during the second and subsequent clocks of write cycles.
DATA PARITY
DP3–DP0
There is one Data Parity pin for each byte of the data bus. Data parity is generated
on all write data cycles with the same timing as the data driven by the Embedded
Write-Back Enhanced IntelDX4 processor. Even parity information must be driven
back into the processor on the data parity pins with the same timing as read
information to ensure that the correct parity check status is indicated by the
Embedded Write-Back Enhanced IntelDX4 processor. The signals read on these
pins do not affect program execution.
Input signals must meet setup and hold times t22 and t23. DP3–DP0 must be
connected to VCC through a pull-up resistor in systems that do not use parity.
DP3–DP0 are active HIGH and are driven during the second and subsequent
clocks of write cycles.
PCHK#
O
Parity Status is driven on the PCHK# pin the clock after ready for read operations.
The parity status is for data sampled at the end of the previous clock. A parity error
is indicated by PCHK# being LOW. Parity status is only checked for enabled bytes
as indicated by the byte enable and bus size signals. PCHK# is valid only in the
clock immediately after read data is returned to the processor. At all other times
PCHK# is inactive (HIGH). PCHK# is never floated.
16
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 2 of 8)
Symbol
Type
Name and Function
BUS CYCLE DEFINITION
M/IO#
D/C#
O
O
O
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
W/R#
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
I/O Write
Code Read
Reserved
Memory Read
Memory Write
HALT/Special Cycle
BE3# - BE0#
Cycle Name
Shutdown
A4-A2
000
1110
1011
1011
HALT
000
Stop Grant bus cycle
100
LOCK#
O
O
Bus Lock indicates that the current bus cycle is locked. The Embedded Write-
Back Enhanced IntelDX4 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 Write-Back Enhanced IntelDX4
processor, examples of such operations are segment table descriptor reads (64
bits) and cache line fills (128 bits). For Intel486 processors with on-chip Floating-
Point Unit, floating-point long reads and writes (64 bits) also require more than one
bus cycle to complete.
The Embedded Write-Back Enhanced IntelDX4 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.
Normally PLOCK# and BLAST# are inverse of each other. However, during the
first bus cycle of a 64-bit floating-point write (for Intel486 processors with on-chip
Floating-Point Unit) both PLOCK# and BLAST# are asserted.
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#
O
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.
17
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 3 of 8)
Symbol
Type
Name and Function
RDY#
I
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 Write-Back Enhanced IntelDX4 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 Write-
Back Enhanced IntelDX4 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 t16 and t17 for proper chip operation.
BURST CONTROL
BRDY#
I
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 Write-Back Enhanced
IntelDX4 processor when BRDY# is sampled active. If RDY# is returned simulta-
neously 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 t16 and t17
.
BLAST#
O
I
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 Write-Back Enhanced IntelDX4 processorto
begin execution at a known state. The processor cannot begin executing instruc-
tions until at least 1 ms after VCC, and CLK have reached their proper DC and AC
specifications. 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 t20 and t21 for recognition in any specific clock.
INTR
I
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 Write-Back Enhanced IntelDX4 processorgenerates 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 t20 and t21 for recognition in
any specific clock.
NMI
I
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 t20 and t21 for recognition in any specific clock.
18
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 4 of 8)
Symbol
Type
Name and Function
SRESET
I
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 t20 and t21 for recognition in any
specific clock.
SMI#
I
System Management Interrupt input invokes System Management Mode (SMM).
SMI# is a falling-edge triggered signal which forces the Embedded Write-Back
Enhanced IntelDX4 processorinto 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 Write-Back Enhanced IntelDX4 proces-
sorlatches 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#
STPCLK#
O
I
System Management Interrupt Active, an active LOW output, indicates that the
Embedded Write-Back Enhanced IntelDX4 processoris 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.
Stop Clock Request input signal indicates a request was made to turn off or
change the CLK input frequency. When the Embedded Write-Back Enhanced
IntelDX4 processorrecognizes 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. STPCLK# must be pulled high via a 10-KW pullup
resistor. STPCLK# is an asynchronous signal, but must remain active until
the Embedded Write-Back Enhanced IntelDX4 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
O
Bus Request signal indicates that the Embedded Write-Back Enhanced IntelDX4
processorhas 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
I
Bus Hold Request allows another bus master complete control of the Embedded
Write-Back Enhanced IntelDX4 processorbus. 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 Write-Back Enhanced IntelDX4 processorremains 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 t18 and t19 for proper
operation.
HLDA
O
Hold Acknowledge goes active in response to a hold request presented on the
HOLD pin. HLDA indicates that the Embedded Write-Back Enhanced IntelDX4
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.
19
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 5 of 8)
Symbol
Type
Name and Function
BOFF#
I
Backoff input forces the Embedded Write-Back Enhanced IntelDX4 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 Write-Back Enhanced IntelDX4 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
t18 and t19 for proper operation.
CACHE INVALIDATION
AHOLD
I
Address Hold request allows another bus master access to the Embedded Write-
Back Enhanced IntelDX4 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
t18 and t19.
EADS#
I
External Address - This signal indicates that a valid external address has been
driven onto the Embedded Write-Back Enhanced IntelDX4 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 t12 and t13 for proper operation.
CACHE CONTROL
KEN#
I
Cache Enable pin is used to determine whether the current cycle is cacheable.
When the Embedded Write-Back Enhanced IntelDX4 processorgenerates 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 t14 and t15 for proper operation.
FLUSH#
I
Cache Flush input forces the Embedded Write-Back Enhanced IntelDX4
processorto 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 t20
and t21 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 Write-Back Enhanced IntelDX4 processorignores 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.
20
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 6 of 8)
Symbol
Type
Name and Function
BUS SIZE CONTROL
BS16#
BS8#
I
I
Bus Size 16 and Bus Size 8 pins (bus sizing pins) cause the Embedded Write-
Back Enhanced IntelDX4 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 t14 and t15 for proper operation.
ADDRESS MASK
A20M#
I
Address Bit 20 Mask pin, when asserted, causes the Embedded Write-Back
Enhanced IntelDX4 processorto 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 Write-Back Enhanced IntelDX4 processoris in real mode. This pin is
asynchronous but should meet setup and hold times t20 and t21 for recognition in
any specific clock. For proper operation, A20M# should be sampled HIGH at the
falling edge of RESET.
TEST ACCESS PORT
TCK
I
Test Clock, an input to the Embedded Write-Back Enhanced IntelDX4 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
TDO
TMS
I
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 Test Access Port (TAP) controller states. During all other TAP controller
states, TDI is a “don’t care.” TDI is provided with an internal pull-up resistor.
O
I
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.
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.
NUMERIC ERROR REPORTING
FERR#
O
The Floating Point Error pin is driven active when a floating point error occurs.
FERR# is similar to the ERROR# pin on the Intel387™ Math CoProcessor. FERR#
is included for compatibility with systems using DOS type floating point error
reporting. FERR# will not go active if FP errors are masked in FPU register.
FERR# is active LOW, and is not floated during bus hold.
21
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 7 of 8)
Symbol
Type
Name and Function
IGNNE#
I
When the Ignore Numeric Error pin is asserted the processor will ignore a
numeric error and continue executing non-control floating point instructions, but
FERR# will still be activated by the processor. When IGNNE# is de-asserted the
processor will freeze on a non-control floating point instruction, if a previous
floating point instruction caused an error. IGNNE# has no effect when the NE bit in
control register 0 is set. IGNNE# is active LOW and is provided with a small
internal pull-up resistor. IGNNE# is asynchronous but setup and hold times t20 and
t21 must be met to ensure recognition on any specific clock.
WRITE-BACK ENHANCED MODE
CACHE#
FLUSH#
O
I
The CACHE# output indicates internal cacheability on read cycles and burst write-
back on write cycles. CACHE# is asserted for cacheable reads, cacheable code
fetches and write-backs. It is driven inactive for non-cacheable reads, I/O cycles,
special cycles, and write-through cycles.
Cache FLUSH# is an existing pin that operates differently if the processor is
configured as Enhanced Bus mode (write-back). FLUSH# causes the processor to
write back all modified lines and flush (invalidate) the cache. FLUSH# is
asynchronous, but must meet setup and hold times t20 and t21 for recognition in any
specific clock.
HITM#
INV
O
The Hit/Miss to a Modified Line pin is a cache coherency protocol pin that is
driven only in Enhanced Bus mode. When a snoop cycle is run, HITM# indicates
that the processor contains the snooped line and that the line has been modified.
Assertion of HITM# implies that the line will be written back in its entirety, unless
the processor is already in the process of doing a replacement write-back of the
same line.
I
The Invalidation Request pin is a cache coherency protocol pin that is used only
in the Enhanced Bus mode. It is sampled by the processor on EADS#-driven
snoop cycles. It is necessary to assert this pin to get the effect of the processor
invalidate cycle on write-through-only lines. INV also invalidates the write-back
lines. However, if the snooped line is modified, the line will be written back and
then invalidated. INV must satisfy setup and hold times t12 and t13 for proper
operation.
PLOCK#
SRESET
O
In the Enhanced bus mode, Pseudo-Lock Output is always driven inactive. In this
mode, a 64-bit data read (caused by an FP operand access or a segment
descriptor read) is treated as a multiple cycle read request, which may be a burst
or a non-burst access based on whether BRDY# or RDY# is returned by the
system. Because only write-back cycles (caused by snoop write-back or
replacement write-back) are write burstable, a 64-bit write will be driven out as two
non-burst bus cycles. BLAST# is asserted during both writes.
I
For the Embedded Write-Back Enhanced IntelDX4 processor, Soft RESET
operates similar to other the Intel486 processors. On SRESET, the internal
SMRAM base register retains its previous value, does not flush, write-back or
disable the internal cache. Because SRESET is treated as an interrupt, it is
possible to have a bus cycle while SRESET is asserted. SRESET is serviced only
on an instruction boundary. SRESET is asynchronous but must meet setup and
hold times t20 and t21 for recognition in any specific clock.
22
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 8. Embedded Write-Back Enhanced IntelDX4™ Processor Pin Descriptions (Sheet 8 of 8)
Symbol
Type
Name and Function
WB/WT#
I
The Write-Back/Write-Through pin enables Enhanced Bus mode (write-back
cache). It also defines a cached line as write-through or write-back. For cache
configuration, WB/WT# must be valid during RESET and be active for at least two
clocks before and two clocks after RESET is de-asserted. To define write-back or
write-through configuration of a line, WB/WT# is sampled in the same clock as the
first RDY# or BRDY# is returned during a line fill (allocation) cycle.
CLKMUL, VCC5, AND VOLDET
CLKMUL
I
The Clock Multiplier input, defined during device RESET, defines the ratio of
internal core frequency to external bus frequency. If sampled low, the core
frequency operates at twice the external bus frequency (speed doubled mode). If
driven high, speed triple mode is selected. CLKMUL has an internal pull-up speed
to VCC. A 10-KΩ pullup resistor is recommended when the pin is tied high.
VCC5
I
The 5V reference voltage input is the reference voltage for the 5V-tolerant I/O
buffers. This signal should be connected to +5V ±5% for use with 5V logic. If all
inputs are from 3V logic, this pin should be connected to 3.3V.
VOLDET
O
A Voltage Detect signal allows external system logic to distinguish between a 5V
Intel486 processor and the 3.3V IntelDX4 processor. This signal is active LOW for
a 3.3V IntelDX4 processor. This pin is available only on the PGA version of the
Embedded Write-Back Enhanced IntelDX4 processor.
RESERVED PINS
RESERVED#
I
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. The pull-up
resistor must be connected only to the RESERVED# pin. Do not share this
resistor with other pins requiring pull-ups.
23
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 9. Output Pins
Output Signal
Floated During Floated During
Name
Active Level
During Stop Grant and
Stop Clock States
Address Hold
Bus Hold
1
BREQ
HLDA
HIGH
HIGH
LOW
Previous State
As per HOLD
Previous State
Previous State
Previous State
HIGH (inactive)
HIGH (inactive)
HIGH (inactive)
Previous State
Previous State
Previous State
Previous State
Previous State
BE3#-BE0#
PWT, PCD
W/R#, M/IO#, D/C#
LOCK#
•
•
•
•
•
•
•
HIGH
HIGH/LOW
LOW
PLOCK#
ADS#
LOW
LOW
BLAST#
PCHK#
LOW
LOW
FERR#
LOW
A3-A2
HIGH
LOW
•
•
SMIACT#
CACHE#
HITM#
2
LOW
•
•
•
•
HIGH
2
LOW
HIGH
VOLDET
NOTES:
LOW
LOW
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.
2. For the case of snoop cycles (via EADS#) during Stop Grant state, CACHE# and HITM# can go active depending on the
snoop hit in the internal cache.
Table 10. Input/Output Pins
Output Signal
Floated During
Address Hold
Floated During
Bus Hold
During Stop Grant and
Stop Clock States
Name
Active Level
D31-D0
DP3–DP0
A31-A4
HIGH
HIGH
HIGH
•
•
•
Floated
Floated
•
Previous State
NOTE:
The term “Previous State” means that the processor maintains the logic level applied to the signal pin just before the
processor entered the Stop Grant state. This conserves power by preventing the signal pin from floating.
24
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 11. Test Pins
Name
TCK
TDI
Input or Output
Input
Sampled/ Driven On
N/A
Input
Rising Edge of TCK
Failing Edge of TCK
Rising Edge of TCK
TDO
TMS
Output
Input
Table 12. Input Pins (Sheet 1 of 2)
Synchronous/
Asynchronous
Internal Pull-Up/
Name
Active Level
Pull-Down
CLK
RESET
SRESET
HOLD
HIGH
HIGH
HIGH
HIGH
LOW
LOW
LOW
LOW
LOW
LOW
LOW
LOW
HIGH
HIGH
LOW
LOW
LOW
LOW
HIGH
Asynchronous
Asynchronous
Synchronous
Synchronous
Synchronous
Synchronous
Asynchronous
Asynchronous
Synchronous
Synchronous
Synchronous
Synchronous
Asynchronous
Asynchronous
Asynchronous
Asynchronous
Asynchronous
Asynchronous
Synchronous
Pull-Down
AHOLD
EADS#
BOFF#
FLUSH#
A20M#
BS16#, BS8#
KEN#
Pull-Down
Pull-Up
Pull-Up
Pull-Up
Pull-Up
Pull-Up
Pull-Up
RDY#
BRDY#
INTR
Pull-Up
NMI
IGNNE#
RESERVED#
SMI#
Pull-Up
Pull-Up
Pull-Up
Pull-Up1
Pull-Up
STPCLK#
INV
NOTE:
1. Even though STPCLK# and CLKMUL have internal pull-up resistors, they cannot be left floating. An external 10-KΩ pull-
up resistor is needed if the STPCLK# pin is unused. CLKMUL must be driven to a valid logic level. If tied HIGH, an external
10-KΩ pull-up resistor is recommended.
25
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 12. Input Pins (Sheet 2 of 2)
Synchronous/
Asynchronous
Internal Pull-Up/
Pull-Down
Name
Active Level
WB/WT#
CLKMUL
TCK
HIGH/LOW
HIGH
Synchronous
Pull-Down
Pull-Up1
Pull-Up
HIGH
TDI
HIGH
Pull-Up
TMS
HIGH
Pull-Up
NOTE:
1. Even though STPCLK# and CLKMUL have internal pull-up resistors, they cannot be left floating. An external 10-KΩ pull-
up resistor is needed if the STPCLK# pin is unused. CLKMUL must be driven to a valid logic level. If tied HIGH, an external
10-KΩ pull-up resistor is recommended.
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
4.0 ARCHITECTURAL AND
FUNCTIONAL OVERVIEW
of the ID Flag bit is irrelevant and provides no signifi-
The Embedded Write-Back Enhanced IntelDX4
cance to the hardware. This bit is cleared (reset to
processor architecture is essentially the same as the
zero) upon device reset (RESET or SRESET) for
IntelDX4 processor. Refer to the Embedded
compatibility with Intel486 processor designs that do
Intel486™ Processor Family Developer’s Manual
not support the CPUID instruction.
(273021)
CPUID-instruction details are provided here for the
The Embedded Write-Back Enhanced IntelDX4
Embedded
Write-Back
Enhanced
IntelDX4
processor has one pin reserved for possible future
use. This pin, an input signal, is called RESERVED#
and must be connected to a 10-KΩ pull-up resistor.
The pull-up resistor must be connected only to the
RESERVED# pin. Do not share this resistor with
other pins requiring pull-ups.
processor. Refer to Intel Application Note AP-485
Intel Processor Identification 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.
4.1.1 Operation of the CPUID Instruction
4.1 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.
The Embedded Write-Back Enhanced IntelDX4
processor supports the CPUID instruction (see Table
13). Because not all Intel processors support the
CPUID instruction, a simple test can determine if the
instruction is supported. The test involves the
Table 13. CPUID Instruction Description
Parameter passed in
EAX
Processor
Core Clocks
OP CODE
Instruction
Description
(Input Value)
0F A2
CPUID
9
14
9
0
1
Vendor (Intel) ID String
Processor Identification
Undefined (Do Not Use)
> 1
26
Embedded Write-Back Enhanced IntelDX4™ 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.
31-------------24
23-----------16
15--------------8
7--------------0
High Value (= 1)
EAX
0
0
0
0
0
0
0
0
0
0
0
0
0 0 0 1
Vendor ID String
(ASCII
EBX
EDX
ECX
u (75)
I (49)
l (6C)
n (6E)
e (65)
e (65)
e (65)
n (6E)
t (74)
G (47)
i (69)
n (6E)
Characters)
The values in EBX, EDX and ECX indicate an Intel processor. When taken in the proper order, they decode to
the string “GenuineIntel.”
The state of the WB/WT# input pin is sampled by the processor on the falling edge of the RESET signal. If
WB/WT# is LOW, the processor is configured to operate in Write-Through/Standard Bus mode. If HIGH, it is
configured to operate in Write-Back/Enhanced Bus mode. The value of the “Model” field of the processor
signature register depends on the bus mode for which the processor is configured.
Processor Identification - When the parameter passed to EAX is 1 (one), the register values returned upon
instruction execution are:
31---------------------------14
(Do Not Use)
13,12
0 0
11----8
0 1 0 0
Family
7----4
1 0 0 0
Model
3----0
XXXX
Processor
Signature for
Write-Through/Stan-
dard Bus mode
EAX
Intel Reserved
Processor
Type
Stepping
Processor
Signature for
Write-
(Do Not Use)
0 0
0 1 0 0
Family
1 0 0 1
Model
XXXX
Intel Reserved
Processor
Type
Stepping
Back/Enhanced Bus
mode
(Intel releases information about stepping numbers as needed)
31--------------------------------------------------------------------------------------------------0
Intel Reserved
(Do Not Use)
EBX
ECX
Intel Reserved
Intel Reserved
31----------------------------------------------------------------------------2
0------------------------------------------------------------------------------0
1
0
Feature Flags
EDX
1
0
VME
FPU
27
Embedded Write-Back Enhanced IntelDX4™ Processor
4.2 Identification After Reset
Processor Identification - Upon reset, the EDX register contains the processor signature:
31---------------------------14
13,12
11----8
7----4
3----0
Processor
Signature for
Write-Through/Stan-
dard Bus mode
EDX
(Do Not Use)
0 0
0 1 0 0
Family
1 0 0 0
Model
XXXX
Intel Reserved
Processor
Type
Stepping
Processor
Signature for
Write-
(Do Not Use)
0 0
0 1 0 0
Family
1 0 0 1
Model
XXXX
Intel Reserved
Processor
Type
Stepping
Back/Enhanced Bus
mode
(Intel releases information about stepping numbers as needed)
4.3 Boundary Scan (JTAG)
4.3.1 Device Identification
Tables 14 and 15 show the 32-bit code for the Embedded Write-Back Enhanced IntelDX4 processor. This code
is loaded into the Device Identification Register.
Table 14. Boundary Scan Component Identification Code (Write-Through/Standard Bus Mode)
Version
Part Number
Mfg ID
1
009H = Intel
VCC
1=3.3 V
Family
0100 = Intel486
CPU Family
Model
01000 =
Embedded Write-
Back Enhanced
IntelDX4 processor
Intel
Architecture
Type
31----28
XXXX
27
1
26-----------21
000001
20----17
0100
16--------12
01000
11------------1
00000001001
0
1
(Intel releases information about version numbers as needed)
Boundary Scan Component Identification Code = x828 8013 (Hex)
28
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 15. Boundary Scan Component Identification Code (Write-Back/Enhanced Bus Mode)
Version
Part Number
Mfg ID
1
009H = Intel
VCC
1=3.3 V
Intel
Architecture
Type
Family
0100 = Intel486
CPU Family
Model
01001 =
Embedded Write-
Back Enhanced
IntelDX4 processor
31----28
XXXX
27
1
26-----------21
000001
20----17
0100
16--------12
01001
11------------1
00000001001
0
1
(Intel releases information about version numbers as needed)
Boundary Scan Component Identification Code = x828 9013 (Hex)
4.3.2 Boundary Scan Register Bits and Bit
Order
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,
DP0, D0, D1, D2, D3, D4, D5, D6,
D7, DP1, D8, D9, D10, D11, D12,
D13, D14, D15, DP2, D16, D17,
D18, D19, D20, D21, D22, D23,
DP3, D24, D25, D26, D27, D28,
D29, D30, D31, STPCLK#,
IGNNE#, INV, CACHE#, FERR#,
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
Write-Back
Enhanced
IntelDX4
processor. Control registers WRCTL, ABUSCTL,
BUSCTL, and MISCCTL are used to select the
direction of bidirectional 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 bidirec-
tional.
SMI#,
SMIACT#, SRESET, NMI, INTR,
FLUSH#, RESET, A20M#,
WB/WT#,
HITM#,
• WRCTL controls D31-D0 and DP3–DP0
• ABUSCTL controls A31-A2
EADS#, PCD, PWT, D/C#, M/IO#,
BE3#, BE2#, BE1#, BE0#, BREQ,
W/R#, HLDA, CLK, AHOLD,
HOLD, KEN#, RDY#, CLKMUL,
BS8#, BS16#, BOFF#, BRDY#,
• BUSCTL controls ADS#, BLAST#, PLOCK#,
LOCK#, W/R#, BE0#, BE1#, BE2#, BE3#, M/IO#,
D/C#, PWT, PCD, and CACHE#
• MISCCTL controls PCHK#, HLDA, BREQ, and
HITM#
PCHK#,
LOCK#,
PLOCK#,
BLAST#,
BUSCTL, ABUSCTL, WRCTL
ADS#,
MISCCTL,
The following is the bit order of the Embedded Write-
Back Enhanced IntelDX4 processor boundary scan
register:
← TDI
29
Embedded Write-Back Enhanced IntelDX4™ Processor
5.0 ELECTRICAL SPECIFICATIONS
5.1 Maximum Ratings
5.2 DC Specifications
The following tables show the operating supply
voltages, DC I/O specifications, and component
power consumption for the Embedded Write-Back
Enhanced IntelDX4 processor.
Table 16 is a stress rating only. Extended exposure
to the Maximum Ratings may affect device reliability.
Table 17. Operating Supply Voltages
Furthermore, although the Embedded Write-Back
Enhanced IntelDX4 processorcontains protective
circuitry to resist damage from electrostatic
discharge, always take precautions to avoid high
static voltages or electric fields.
Product
VCC
x80486DX4WB75
x80486DX4WB100
x0486DX4WB100
3.3 V ± 0.3 V
3.3 V ± 0.3 V
3.3 V ± 0.3 V
Functional operating conditions are given in Section
5.2, DC Specifications and Section 5.3, AC Speci-
fications.
NOTE: To address the fact that many of the package prefix
variables have changed, all package prefix variables
in this document are now indicated with an "x".
Table 16. 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 VCC5 + 0.5 V
Supply Voltage V
Respect to VSS
with
-0.5 V to +4.6 V
-0.5 V to +6.5 V
The lesser of:
CC
Reference Voltage VCC5 with
Respect to VSS
Transient Voltage on any
Input
VCC5 + 1.6 V
or
6.5 V
Current Sink on VCC5
55 mA
30
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 18. DC Specifications
Functional Operating Range: VCC = 3.3 V ± 0.3 V; VCC5 = 5 V ± 0.25 V (Note 1); TCASE=0 °C to +85 °C
Symbol
VIL
Parameter
Input LOW Voltage
Min.
-0.3
Typ.
Max.
+0.8
Unit
V
Notes
VIH
Input HIGH Voltage
2.0
VCC5 +0.3
VCC5 +0.3
V
Note 2
VIHC
VOL
Input HIGH Voltage of CLK
Output LOW Voltage
VCC5 -0.6
V
I
I
I
I
OL = 4.0 mA (Address, Data, BEn)
OL = 5.0 mA (Definition, Control)
OL = 2.0 mA
0.45
0.45
0.40
0.20
V
V
V
V
OL = 100 µA
VOH
Output HIGH Voltage
OH = -2.0 mA
I
2.4
V
ICC5
ILI
VCC5 Leakage Current
Input Leakage Current
15
300
15
µA
µA
Note 3
Note 4
IIH
Input Leakage Current
SRESET
200
300
µA
µA
Note 5
Note 5
IIL
ILO
Input Leakage Current
Output Leakage Current
Input Capacitance
400
15
10
14
12
µA
µA
pF
pF
pF
Note 6
CIN
Note 7
Note 7
Note 7
COUT
CCLK
NOTES:
I/O or Output Capacitance
CLK Capacitance
1.
VCC5 should be connected to 3.3 V ± 0.3 V in 3.3 V-only systems.
2. All inputs except CLK.
3. This parameter is for inputs without pull-up or pull-down resistors and 0V ≤ VIN ≤ VCC
4. This parameter is for VCC5 – VCC ≤ 2.25 V. Typical value is not 100% tested.
5. This parameter is for inputs with pull-down resistors and VIH = 2.4V.
6. This parameter is for inputs with pull-up resistors and VIL = 0.4V.
.
7. F =1 MHz. Not 100% tested.
C
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Embedded Write-Back Enhanced IntelDX4™ Processor
Table 19. ICC Values
Functional Operating Range: VCC = 3.3 V ±0.3 V; VCC5 = 5 V ± 0.25 V (Note 1); TCASE = 0°C to +85°C
Operating
Parameter
CC Active
Frequency
Typ.
Maximum
Notes
I
75 MHz
100 MHz
1100 mA
1450 mA
Note 2
(Power Supply)
I
CC Active
75 MHz
100 MHz
825 mA
1075 mA
975 mA
1300 mA
Notes 3, 4, 5
Note 6
(Thermal Design)
ICC Stop Grant
75 MHz
100 MHz
20 mA
50 mA
75 mA
100 mA
ICC Stop Clock
0 MHz
600 µA
2 mA
Note 7
NOTES:
1. VCC5 should be connected to 3.3 V ± 0.3 V in 3.3 V-only systems.
2. This parameter is for proper power supply selection. It is measured using the worst case instruction mix at VCC = 3.6V.
3. The maximum current column is for thermal design power dissipation. It is measured using the worst case instruction mix
at VCC = 3.3V.
4. The typical current column is the typical operating current in a system. This value is measured in a system using a typical
device at VCC = 3.3V, running Microsoft Windows 3.1 at an idle condition. This typical value is dependent upon the specific
system configuration.
5. Typical values are not 100% tested.
6. The ICC Stop Grant specification refers to the ICC value once the Embedded Write-Back Enhanced IntelDX4 processor
enters the Stop Grant or Auto HALT Power Down state.
7. The ICC Stop Clock specification refers to the ICC value once the Embedded Write-Back Enhanced IntelDX4 processor
enters the Stop Clock state. The VIH and VIL levels must be equal to VCC and 0 V, respectively, in order to meet the ICC
Stop Clock specifications.
32
Embedded Write-Back Enhanced IntelDX4™ Processor
5.3 AC Specifications
The AC specifications for the Embedded Write-Back Enhanced IntelDX4 processor are given in this section.
Table 20. AC Characteristics
VCC = 3.3 V ± 0.3 V; VCC5 = 5 V ± 0.25 V (Note 1)
CASE = 0°C to +85°C; CL = 50pF, unless otherwise specified. (Sheet 1 of 2)
T
Product
WB75
WB100
Symbol
Parameter
Min Max Min Max
Unit
MHz
ns
Figure
Notes
CLK Frequency
CLK Period
8
25
8
33
Note 2
t1
40
125
30
125
4
4
t1a
CLK Period Stability
±250
±250
ps
Adjacent
clocks
Note 3
at 2V
t2
t3
t4
t5
t6
CLK High Time
CLK Low Time
CLK Fall Time
CLK Rise Time
14
14
11
11
ns
ns
ns
ns
ns
4
4
4
4
8
at 0.8V
4
4
3
3
2V to 0.8V
0.8V to 2V
A31–A2, PWT, PCD, BE3–BE0#,
M/IO#, D/C#, W/R#, ADS#, LOCK#,
FERR#, CACHE#, HITM#, BREQ,
HLDA Valid Delay
3
19
3
14
t7
A31–A2, PWT, PCD, BE3–BE0#,
M/IO#, D/C#, W/R#, ADS#, LOCK#,
CACHE# Float Delay
28
20
ns
9
Note 3
t8
PCHK# Valid Delay
3
3
24
24
3
3
14
14
ns
ns
7
8
t8a
BLAST#, PLOCK#, SMIACT# Valid
Delay
t9
BLAST#, PLOCK# Float Delay
28
20
20
14
ns
ns
9
8
Note 3
Note 3
t10
D31–D0, DP3–DP0 Write Data Valid
Delay
3
3
t11
D31–D0, DP3–DP0 Write Data Float
Delay
28
20
ns
9
t12
t13
t14
EADS#, INV Setup Time
EADS#, INV Hold Time
8
3
8
5
3
5
ns
ns
ns
5
5
5
KEN#, BS16#, BS8#, WB/WT# Setup
Time
t15
KEN#, BS16#, BS8#, WB/WT# Hold
Time
3
3
ns
5
t16
t17
RDY#, BRDY# Setup Time
RDY#, BRDY# Hold Time
8
3
5
3
ns
ns
6
6
33
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 20. AC Characteristics
VCC = 3.3 V ± 0.3 V; VCC5 = 5 V ± 0.25 V (Note 1)
CASE = 0°C to +85°C; CL = 50pF, unless otherwise specified. (Sheet 2 of 2)
T
Product
WB75
WB100
Symbol
Parameter
Min Max Min Max
Unit
ns
Figure
Notes
t18
t18a
t19
HOLD, AHOLD Setup Time
BOFF# Setup Time
8
8
3
8
6
7
3
5
5
5
5
5
ns
HOLD, AHOLD, BOFF# Hold Time
ns
t20
FLUSH#, A20M#, NMI, INTR, SMI#,
STPCLK#, SRESET, RESET,
IGNNE# Setup Time
ns
Note 4
Note 4
t21
FLUSH#, A20M#, NMI, INTR, SMI#,
STPCLK#, SRESET, RESET,
IGNNE# Hold Time
3
3
ns
5
t22
t23
D31–D0, DP3–DP0,
A31–A4 Read Setup Time
5
3
5
3
ns
ns
6
5
D31–D0, DP3–DP0,
A31–A4 Read Hold Time
6
5
NOTES:
1. VCC5 should be connected to 3.3 V ± 0.3 V in 3.3 V-only systems.
2. 0-MHz operation is guaranteed when the STPCLK# and Stop Grant bus cycle protocol is used.
3. Not 100% tested, guaranteed by design characterization.
4. A reset pulse width of 15 CLK cycles is required for warm resets (RESET or SRESET). Power-up resets (cold resets)
require RESET to be asserted for at least 1 ms after VCC and CLK are stable.
34
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 21. AC Specifications for the Test Access Port
CC = 3.3 V ±0.3 V; VCC5 = 5 V ±0.25 V (Note 1)
TCASE = 0°C to +85°C; CL = 50 pF
V
Symbol
Parameter
Min
Max
Unit
MHz
ns
Figure
Notes
t24
t25
TCK Frequency
TCK Period
25
Note 2
40
10
10
10
10
10
10
10
11
11
11
11
11
11
11
11
t26
TCK High Time
TCK Low Time
TCK Rise Time
TCK Fall Time
ns
@ 2.0V
@ 0.8V
Note 3
Note 3
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
t27
ns
t28
4
4
ns
t29
ns
t30
TDI, TMS Setup Time
8
7
3
ns
t31
TDI, TMS Hold Time
ns
t32
TDO Valid Delay
25
30
25
36
ns
t33
TDO Float Delay
ns
t34
All Outputs (except TDO) Valid Delay
All Outputs (except TDO) Float Delay
All Inputs (except TDI, TMS, TCK) Setup Time
All Inputs (except TDI, TMS, TCK) Hold Time
3
ns
t35
ns
t36
8
7
ns
t37
ns
NOTES:
1.
VCC5 should be connected to 3.3 V ±0.3 V in 3.3 V-only systems. All inputs and outputs are TTL level.
2. TCK period ≤ CLK period.
3. Rise/Fall times are measured between 0.8V and 2.0V. Rise/Fall times can be relaxed by 1 ns per 10-ns increase in TCK
period.
4. Parameters t30 – t37 are measured from TCK.
35
Embedded Write-Back Enhanced IntelDX4™ Processor
2.0 V
2.0 V
1.5 V
1.5 V
0.8 V
CLK
0.8 V
t2
t3
t4
t5
t1
tx
ty
1.5 V
tx = input setup times
ty = input hold times, output float, valid and hold times
Figure 4. CLK Waveform
Tx
Tx
Tx
CLK
t13
t12
INV, EADS#
t14
t15
t19
t21
t23
BS8#, BS16#,
KEN#, WB/WT#
t18
t20
t22
BOFF#, AHOLD, HOLD
RESET, FLUSH#,
A20M#, INTR, NMI, SMI#,
STPCLK#, SRESET, IGNNE#
A31-A4
(READ)
Figure 5. Input Setup and Hold Timing
36
Embedded Write-Back Enhanced IntelDX4™ Processor
Tx
T2
Tx
CLK
t16
t17
RDY#, BRDY#
1.5 V
1.5 V
t23
t22
D31-D0, DP3–DP0
Figure 6. Input Setup and Hold Timing
T2
Tx
Tx
Tx
CLK
RDY#, BRDY#
D31-D0
DP3-DP0
VALID
MIN
t8
MAX
VALID
PCHK#
Figure 7. PCHK# Valid Delay Timing
37
Embedded Write-Back Enhanced IntelDX4™ Processor
Tx
Tx
Tx
CLK
MIN
MAX
MAX
MAX
t6
A2-A31, PWT, PCD,
BE0-3#, M/IO#,
D/C#, W/R#, ADS#,
VALID n
VALID n+1
VALID n+1
VALID n+1
LOCK#, BREQ, HLDA,
FERR#, CACHE#, HITM#
MIN
t10
D31-D0, DP3–DP0
VALID n
MIN
t8a
SMIACT#, BLAST#,
PLOCK#
VALID n
Figure 8. Output Valid Delay Timing
Tx
Tx
Tx
CLK
MIN
t7
t6
A2-A31, PWT, PCD,
BE0-3#, M/IO#,
D/C#, W/R#, ADS#,
LOCK#, CACHE#
VALID
MIN
MIN
t10
t11
D31-D0, DP3–DP0
VALID
t9
t8a
BLAST#,
PLOCK#
VALID
Figure 9. Maximum Float Delay Timing
38
Embedded Write-Back Enhanced IntelDX4™ Processor
2.0 V
2.0 V
t27
TCK
0.8 V
0.8 V
t26
t28
t29
t25
Figure 10. TCK Waveform
1.5 V
TCK
t31
t30
TMS
TDI
VALID
t33
t32
VALID
TDO
OUTPUT
INPUT
t35
t34
VALID
t37
VALID
t36
VALID
Figure 11. Test Signal Timing Diagram
39
Embedded Write-Back Enhanced IntelDX4™ Processor
5.4 Capacitive Derating Curves
These graphs are the capacitive derating curves for the Embedded Write-Back Enhanced IntelDX4 processor.
nom+7
nom+6
nom+5
nom+4
nom+3
nom+2
nom+1
nom
nom-1
nom-2
25
50
75
100
125
150
Capacitive Load (pF)
Note: This graph will not be linear outside of the capacitive range shown.
nom = nominal value from the AC Characteristics table.
A3238-01
Figure 12. Typical Loading Delay versus Load Capacitance under Worst-Case Conditions
for a Low-to-High Transition
nom+5
nom+4
nom+3
nom+2
nom+1
nom
nom-1
nom-2
25
50
75
100
125
150
Capacitive Load (pF)
Note: This graph will not be linear outside of the capacitive range shown.
nom = nominal value from the AC Characteristics table.
A3237-01
Figure 13. Typical Loading Delay versus Load Capacitance under Worst-Case Conditions
for a High-to-Low Transition
40
Embedded Write-Back Enhanced IntelDX4™ Processor
In a mixed voltage system (processors at 3 volts,
peripherals at 5 volts), the bus is driven to 5 volts by
the peripheral logic. Therefore, the processor must
discharge the capacitance on the bus from 5 volts to
0 volts, which takes more time than the 3 volts to 0
volts transition. Inaccurate capacitive derating
impacts timing margins and may result in system
failures under certain load conditions.
When designing for higher loads in mixed voltage
systems, timing margins should be evaluated based
on the derating curves shown in Figure 14. For more
accurate delay prediction, use I/O buffer models.
Figure 14. Typical Loading Delay versus Load Capacitance in Mixed Voltage System
41
Embedded Write-Back Enhanced IntelDX4™ Processor
6.0 MECHANICAL DATA
This section describes the packaging dimensions and thermal specifications for the Embedded Write-Back
Enhanced IntelDX4 processor.
6.1 Package Dimensions
30.6 ± 0.25
28.0 ± 0.10
25.50 (ref)
1.14
(ref)
.40 Min
157
208
21.20 ± 0.10
0.13 + 0.12-0.08
1
156
0˚ Min
7˚ Max
0.60 ± 0.10
1.30 Ref
0.50
Top View
Metal Heat Spreader
3.37 ± 0.08
3.70 Max
0.13 Min
0.25 Max
52
105
53
104
NOTE: Length measurements same as width measurements
Tolerance Window for
Lead Skew from Theoretical
True Position
1.76 Max
0.10 Max
Units: mm
A3260-01
Figure 15. 208-Lead SQFP Package Dimensions
42
Embedded Write-Back Enhanced IntelDX4™ Processor
Figure 16. Principal Dimensions and Data for 168-Pin Grid Array Package
Table 22. 168-Pin Ceramic PGA Package Dimensions
Millimeters
Max
Inches
Symbol
Min
3.56
0.64
2.8
Notes
Min
Max
Notes
A
A1
A2
A3
B
4.57
0.140
0.025
0.110
0.045
0.017
1.735
1.595
0.090
0.100
0.180
0.045
0.140
0.055
0.020
1.765
1.605
0.110
0.130
1.14
SOLID LID
SOLID LID
SOLID LID
SOLID LID
3.5
1.14
0.43
44.07
40.51
2.29
2.54
1.40
0.51
D
44.83
40.77
2.79
D1
e1
L
3.30
N
168
168
S1
1.52
2.54
0.060
0.100
43
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 23. Ceramic PGA Package Dimension Symbols
Letter or Symbol
Description of Dimensions
Distance from seating plane to highest point of body
Distance between seating plane and base plane (lid)
Distance from base plane to highest point of body
Distance from seating plane to bottom of body
Diameter of terminal lead pin
A
A1
A2
A3
B
D
Largest overall package dimension of length
D1
e1
L
A body length dimension, outer lead center to outer lead center
Linear spacing between true lead position centerlines
Distance from seating plane to end of lead
S1
Other body dimension, outer lead center to edge of body
NOTES:
1. Controlling dimension: millimeter.
2. Dimension “e1” (“e”) is non-cumulative.
3. Seating plane (standoff) is defined by P.C. board hole size: 0.0415–0.0430 inch.
4. Dimensions “B”, “B1” and “C” are nominal.
5. Details of Pin 1 identifier are optional.
Values for θJA and θJC are given in the following
6.2 Package Thermal Specifications
tables for each product at its maximum operating
frequencies. Maximum TA is shown for each product
operating at its maximum processor frequency (three
times the CLK frequency). Refer to the Embedded
Intel486™ Processor Family Developer’s Manual
(273021) for a description of the methods used to
measure these characteristics.
The Embedded Write-Back Enhanced IntelDX4
processoris specified for operation when the case
temperature (TC) is within the range of 0°C to 85°C.
TC may be measured in any environment to
determine whether the processor is within the
specified operating range.
The ambient temperature (TA) can be calculated
from θJC and θJA from the following equations:
TJ = TC + P * θJC
TA = TJ - P * θJA
TC = TA + P * [θJA - θJC
]
TA = TC - P * [θJA - θJC
]
Where TJ, TA, TC equals Junction, Ambient and
Case Temperature respectively. θJC, θJA equals
Junction-to-Case and Junction-to-Ambient thermal
Resistance, respectively. P is defined as Maximum
Power Consumption.
44
Embedded Write-Back Enhanced IntelDX4™ Processor
Table 24. Thermal Resistance, θJA (°C/W)
θJA vs. Airflow — ft/min. (m/sec)
Heat
Sink
0
(0)
200
(1.01)
400
(2.03)
600
(3.04)
800
(4.06)
1000
(5.07)
Package
168-Pin PGA
168-Pin PGA
No
Yes
No
17.5
13.5
12.5
10.5
15.0
8.5
13.0
6.5
11.5
5.5
8.5
4.0
10.0
4.5
9.5
4.25
208-Lead SQFP
208-Lead SQFP
10.0
6.5
9.0
Yes
5.0
Table 25. Thermal Resistance, θJC (°C/W)
Package
Heat Sink
No
θJC
2.0
2.0
1.2
0.8
168-Pin PGA
168-Pin PGA
Yes
208-Lead SQFP
208-Lead SQFP
No
Yes
Table 26. Maximum Tambient, TA max (°C)
Airflow — ft/min. (m/sec)
Freq.
(MHz)
0
(0)
200
(1.01)
400
(2.03)
600
(3.04)
Package
Heat Sink
168-Pin PGA
No
Yes
No
100
100
100
100
75
18.5
35.5
36.5
43.5
29.0
57.0
46.0
60.5
37.5
65.5
50.0
67.0
44.0
70.0
52.5
71.0
168-Pin PGA
208-Lead SQFP
208-Lead SQFP
208-Lead SQFP
208-Lead SQFP
Yes
No
Yes
75
45
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