®
Intel 31154 133 MHz PCI Bridge
Design Guide
Design Guide
April 2004
Order Number: 278944-001
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Contents
Contents
About This Document......................................................................................................................7
1.1 Terminology and Definitions .................................................................................................7
Introduction......................................................................................................................................9
Features List.......................................................................................................................10
References .........................................................................................................................11
3.1 Total Signal Count ..............................................................................................................17
Terminations..................................................................................................................................19
PCI/PCI-X Interface .......................................................................................................................29
PCI/PCI-X Voltage Levels...................................................................................................29
Interrupt Routing.................................................................................................................29
IDSEL Lines........................................................................................................................30
5.3.1 Primary IDSEL Line ...............................................................................................30
5.3.2 Secondary IDSEL Lines.........................................................................................30
5.3.3 Secondary IDSEL Masking....................................................................................31
5.3.4 Secondary Clock Control .......................................................................................31
CompactPCI* Hot Swap Mode Select ................................................................................31
Opaque Memory Region Enable ........................................................................................31
PCI-X Initialization Clocking Modes....................................................................................32
5.6.1 Primary PCI Clocking Mode...................................................................................32
5.6.2 Secondary PCI Clocking Mode..............................................................................32
5.6.3 Primary-to-Secondary Frequency Limits................................................................34
Routing Guidelines ........................................................................................................................35
Crosstalk.............................................................................................................................36
EMI Considerations ............................................................................................................37
6.3.1 Decoupling Recommendations..............................................................................38
Trace Impedance................................................................................................................39
PCI Clock Layout Guidelines..............................................................................................42
7.2.1 Single Slot at 133 MHz ..........................................................................................45
®
7.2.2 Dual-Slot at 100 MHz.............................................................................................47
®
7.2.3 Quad-Slots at 66 MHz ...........................................................................................49
®
7.2.4 PCI-X at 33 MHz....................................................................................................52
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7.2.4.2 PICMG 1.2 System Overview ................................................................52
Power Considerations ...................................................................................................................57
Analog Power Pins .............................................................................................................57
Power Sequencing..............................................................................................................58
Customer Reference Board...........................................................................................................59
Debug Connectors and Logic Analyzer Connectivity ....................................................................61
10.1 Probing PCI-X Signals........................................................................................................61
Thermal Solutions..........................................................................................................................69
References....................................................................................................................................71
12.1 Related Documents ............................................................................................................71
Figures
®
Intel 31154 133 MHz PCI Bridge Applications............................................................................ 9
®
Intel 31154 133 MHz PCI Bridge Package...............................................................................14
®
Intel 31154 133 MHz PCI Bridge Ball Map—Top View, Left Side ............................................15
®
Intel 31154 133 MHz PCI Bridge Ball Map—Top View, Right Side..........................................16
IDSEL Mapping ..........................................................................................................................30
Crosstalk Effects on Trace Distance and Height........................................................................36
PCB Ground Layout Around Connectors ...................................................................................37
PCI Clock Distribution and Matching Requirements...................................................................43
Single-Slot Point-to-Point Topology............................................................................................45
®
11 Dual-Slot Configuration ..............................................................................................................47
®
13 Quad-Slots 66 MHz Topology ....................................................................................................49
®
14 Embedded Intel 31154 133 MHz PCI Bridge Wiring for 66 MHz..............................................51
15 An Example of an ePCI-X System..............................................................................................53
16 PCI-X Data Bus PICMG 1.2 Style Backplane.............................................................................54
17 PCI-X Clock PICMG 1.2 Style Backplane ..................................................................................55
18 P_VCCA Filter ............................................................................................................................57
19 S_VCCA Filter ............................................................................................................................57
20 PVIO Voltage Protection Diode ..................................................................................................58
®
21 Intel IQ31154 Customer Reference Board Block Diagram.......................................................59
Tables
Terminology and Definition........................................................................................................... 7
Features List...............................................................................................................................10
Total Signal Count......................................................................................................................17
Pull-Up/Pull-Down Terminations.................................................................................................19
PCI/PCI-X Voltage Levels ..........................................................................................................29
HS_FREQ Encoding...................................................................................................................31
PCI-X Clocking Modes ...............................................................................................................33
®
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Contents
Secondary Bus Frequency Initialization......................................................................................33
10 PCI-X Initialization Pattern..........................................................................................................34
®
11 Intel 31154 133 MHz PCI Bridge Decoupling Recommendations............................................38
12 Add-in Card Routing Parameters................................................................................................41
13 PCI-X Slot Guidelines.................................................................................................................44
14 Wiring Lengths for 133 MHz Slot................................................................................................45
15 Wiring Lengths for Embedded 133 MHz Design.........................................................................46
16 Wiring Lengths for 100 MHz Dual-Slot .......................................................................................47
17 Wiring Lengths for Embedded 100 MHz Design.........................................................................48
18 Wiring Lengths for 66 MHz Quad-Slot........................................................................................49
19 Wiring Lengths for Embedded 66 MHz Design...........................................................................51
20 Wiring Lengths for PICMG 1.2 Backplane..................................................................................54
21 PCI-X Clock Wiring Lengths for PICMG Backplane ...................................................................55
22 Customer Reference Board Stackup..........................................................................................60
23 Logic Analyzer Pod 1..................................................................................................................62
24 Logic Analyzer Pod 2..................................................................................................................63
25 Logic Analyzer Pod 3..................................................................................................................64
26 Logic Analyzer Pod 4..................................................................................................................65
27 Logic Analyzer Pod 5..................................................................................................................66
28 Logic Analyzer Pod 6..................................................................................................................67
29 Operational Power......................................................................................................................69
30 Design Reference Material .........................................................................................................71
®
31 Intel Related Documentation ....................................................................................................71
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Contents
Revision History
Date
Revision
001
Description
April 2004
Initial release
®
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About This Document
About This Document
1
This document provides layout information and guidelines for designing platform or add-in board
®
applications with the Intel 31154 133 MHz PCI Bridge.
This document is intended to be used as a guideline only. Intel recommends that you employ best-
known design practices with board-level simulation, signal-integrity testing, and validation for a
robust design. Please note that this design guide focuses on specific design considerations for the
31154 Bridge and is not intended to be an all-inclusive list of all good design practices. Use this
guide as a starting point, and use empirical data to optimize your particular design.
1.1
Terminology and Definitions
Table 1.
Terminology and Definition (Sheet 1 of 2)
Term
Definition
31154
Intel® 31154 133 MHz PCI Bridge
Stripline in a PCB is composed of the
conductor inserted in a dielectric with GND
planes to the top and bottom, as shown in the
cross-section diagram at left.
Stripline
NOTE: An easy way to distinguish stripline
from microstrip is that you need to
strip away layers of the board to view
the trace on stripline.
Microstrip in a PCB is composed of the
conductor on the top layer above the
dielectric with a ground plane below, as
shown in the cross-section diagram at left.
Microstrip
Prepreg is material used for the lamination process of manufacturing PCBs. It consists of a
layer of epoxy material that is placed between two cores. This layer melts into epoxy when
heated and forms around adjacent traces.
Prepreg
Core
Core material is used for the lamination process of manufacturing PCBs. This material is two-
sided laminate with copper on each side. The core is an internal layer that is etched.
Printed circuit board: An example PCB
manufacturing process consists of the
following steps:
Layer 1: copper
Prepreg
Layer 2: GND
•
A PCB consists of alternating layers of
core and prepreg stacked.
Core
•
•
•
•
•
The finished PCB is heated and cured.
The via holes are drilled.
PCB
Layer 3: VCC
Prepreg
Layer 4: copper
Plating covers holes and outer surfaces.
Etching removes unwanted copper.
Example of a cross-section of
a four-layer stack
The PCB is tinned, coated with solder
mask, and silk-screened.
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About This Document
Table 1.
Terminology and Definition (Sheet 2 of 2)
Term
Definition
An aggressor network is a network that transmits a coupled signal to another network.
Zo
Zo
Aggressor
Victim Network
Zo
Zo
Aggressor Network
B3337-01
A network that receives a coupled cross-talk signal from another network is a called the victim
network.
Victim
A network is the trace of a PCB that completes an electrical connection between two or more
components.
Network
Stub
A stub is a branch from a trunk terminating at the pad of an agent.
Inter-Symbol Interference (ISI) occurs when a transition that has not been completely
dissipated interferes with a signal being transmitted down a transmission line. ISI can impact
both timing and signal integrity. It is dependent on frequency, time delay of the line, and the
refection coefficient at the driver and receiver. Examples of ISI patterns that can be used in
testing at the maximum allowable frequencies are the sequences shown below:
ISI
0101 0101 0101 0101
0011 0011 0011 0011
000 1110 0011 1000 1111
A device is a component of a PCI system that connects to a PCI bus. As defined by PCI 2.3,
a device can be a single-function or a multi-function device.
Device
Downstream A transaction that targets the secondary side of the bridge is a downstream transaction.
Upstream
SHB
A transaction that targets the primary side of the bridge is an upstream transaction.
SHB is a system host board in a PICMIG 1.2 backplane. The removable CPU board provides
clocks and arbitration signals as well as an optional ATX power supply control.
ePCI-X
CRB
Embedded PCI-X specification
Customer Reference Board
§ §
®
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Introduction
Introduction
2
2.1
Product Overview
®
The Intel 31154 133 MHz PCI Bridge (called hereafter the “31154”) is a PCI component that
functions as a highly concurrent, low-latency transparent bridge between two PCI buses. The
Table 2.
PCI-to-PCI Bridge Configurations
Primary Bus Interface
Secondary Bus Interface
PCI 2.3
PCI 2.3
PCI-X
PCI 2.3
PCI-X
PCI 2.3
PCI-X
PCI-X
The 31154 is used on motherboards to provide additional I/O expansion slots. It is also used on PCI
add-in cards to mitigate the restrictive electrical loading constraints imposed on an expansion slot,
enabling multiple conventional PCI or multiple PCI-X devices to reside on a single PCI I/O
PCI bus speeds.
®
Figure 1.
Intel 31154 133 MHz PCI Bridge Applications
Legacy
33 MHz
Legacy
66 MHz
Multi PCI-X
Devices
High-End
Application
CPU Host
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Introduction
The 31154 has additional hardware support for CompactPCI* Hot Swap and Redundant System
Slot via queue flush, arbiter lock, and clock output tristating.
The 31154 supports any combination of 32-bit and 64-bit data transfers on its primary and
secondary bus interfaces. The 31154 is 33/66 MHz capable in conventional PCI mode, and can run
at 66 MHz, 100 MHz, or 133 MHz when operating in PCI-X mode, depending upon its
surrounding environment.
2.2
Features List
Table 3.
Features List
• PCI bus interfaces (2):
• Secondary bus arbitration:
— PCI Local Bus Specification,
— Internal arbiter supports nine agents in
addition to the 31154.
Revision 2.3 compliant
— PCI-to-PCI Bridge Architecture
Specification, Revision 1.2 compliant
— Internal arbiter can be disabled.
— Optimized for PCI-X mode
— PCI Bus Power Management
Interface Specification, Revision 1.1
compliant
— Bus parking on bridge or last master
• Improved buffer architecture:
— PCI-X Addendum to the PCI Local
Bus Specification, Revision 1.0b
compliant
— 8 KBytes data buffers in each
direction
— Improved level of concurrency:
— External SROM support
— Vital Products Data (VPD) support
— 64-bit initiator/target capable
— 64-bit addressing
Up to nine outstanding transactions on
each bus simultaneously
• Scalability and flexibility:
— Conventional PCI 32/64-bit
33/66 MHz, 3.3 V
• Hardware support for dual-host cPCI
configurations
— 5 V tolerant inputs
— PCI-X 32/64-bit 66/100/133 MHz,
3.3 V
• Compact PCI Hot Swap Specification,
Revision 2.1 R2.0 support
• JTAG interface
• GPIO interface:
• Secondary clock generation with 10 clock
outputs
— Allows simple software-controlled
signaling protocols
®
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Introduction
2.3
2.4
Related External Specifications
• PCI Local Bus Specification, Revision 2.3
• PCI-to-PCI Bridge Architecture Specification, Revision 1.1
• PCI Bus Power Management Interface Specification, Revision 1.1
• Compact PCI Hot Swap Specification, Revision 2.1 R2.0
• PCI-X Addendum to the PCI Local Bus Specification, Revision 1.1
• Embedded PCI-X Specification PICMG 1.2 R1.0
References
This section lists references that can be useful with a 31154 application. These documents are
®
• Intel 31154 133 MHz PCI Bridge Datasheet (278821)
®
• Intel 31154 133 MHz PCI Bridge Developer’s Manual (278848)
®
• Intel 31154 133 MHz PCI Bridge Specification Update (300826)
®
• Intel 31154 133 MHz PCI Bridge Design Checklist (300959)
®
• Intel 31154 133 MHz PCI Bridge Evaluation Board Schematics (278839)
§ §
®
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®
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Package Information
Package Information
3
®
The Intel 31154 133 MHz PCI Bridge is offered in a 421-lead PBGA package. The mechanical
These figures are helpful in placing components around the 31154 for the layout of a PCB. To
simplify routing and minimize the number of cross traces, keep this layout in mind when placing
components on your board. The signals, by design, are located on the PBGA package to simplify
Figure 4 shows the right side of the ball map.
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Package Information
®
Figure 2.
Intel 31154 133 MHz PCI Bridge Package
Notes:
1. All dimensions and tolerances conform to ANSI Y14.5M-1982.
PIN #1
CORNER
Dimension is measured at the maximum solder ball
diameter, parallel to primary datum
0.90
0.60
Ø
2
3
22
23 21
20 18
19
16 14 12 10
17 15 13 11
8
6
4
2
2
9
7
5
3
1
Primary datum
and seating plane are defined by the
Ø
0.30
C
A
B
S
S
S
A
B
C
D
E
F
spherical crowns of the solder balls.
1.27
4. All dimensions, unless otherwise specified, are in millimeters.
G
H
J
K
L
M
N
P
R
T
1.27
// 0.127
A
U
V
W
Y
AA
AB
AC
31.00 ± 0.10
26.00 ± 0.20
1.53 REF
SEE DETAIL "A"
1.53 REF
1.27
-B-
BOTTOM VIEW
31.00 ± 0.10
(22.10 REF)
26.00 ± 0.20
0.127
A
3 X Ø1.00 THRU
45˚ CHAMFER
4 PLACES
(22.10 REF)
PIN #1 CORNER
NO RADIUS
TOP VIEW
Au GATE
1.70
2.38 ± 0.21
1.17 ± 0.05
30˚
PIN #1 I.D. (SHINY)
90.0˚
1.0 DIA. X 0.15 DEPTH
9.0 X 9.0 FROM CENTER LINE
// 0.15
0.15
C
-C-
0.61 ± 0.06
0.60 ± 0.10
3
SEATING PLANE
SIDE VIEW
DETAIL "A"
NOT TO SCALE
B1290-01
®
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Package Information
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Figure 3.
Intel 31154 133 MHz PCI Bridge Ball Map—Top View, Left Side
1
2
3
4
5
6
7
8
VCCP
P_
9
10
VSS
P_
11
VSS
P_
12
VCCP
P_
P_
P_
P_
P_
P_
CBE7#
P_
PAR64
VSS
VSS
A
B
ACK64# AD56
AD60 CBE4#
P_
AD43
P_
P_ P_
P_
AD50
P_
P_
VSS
AD54 SERR# AD49
AD52 AD55
AD57 AD59
AD63 CBE6#
SCAN_
EN
P_
AD48
P_
STOP#
S_CLK
P_ P_
P_ P_
P_ P_
VSS
VCCP
VCCP
C
D
E
OEN3 AD53 PERR# AD58 AD61 CBE5# REQ64#
S_CLK
OEN2 AD47
P_
P_
AD51
P_
AD62
QE
P_
VSS
VCCP
VSS
HS_
VCC
HS_
VCC
VSS
HS_
HS_
LED_
OUT
P_
S_CLK
S_TRI
VCCP R_REF VSS
VSS
VCC
AD38 OEN1 AD45
LSTAT ENUM#
STATE FREQ0
P_
AD42
P_
AD44
P_
AD46
VSS
VSS
VCC
VSS
VCC
VSS
VCC
VSS
VCC
VSS
F
G
H
P_
S_CLK
P_
HS_
SM
VCCP
AD36 OEN0 AD41
P_
AD35
P_
AD39
P_
AD40
P_
M66EN
VSS
VCC
P_
AD33
P_
AD34
P_
AD37
SR_
CLK
J
K
L
M
N
P
R
T
S_
AD34
S_
AD33
S_
AD32
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
P_
AD32
S_
AD36
S_
AD35
VCC SR_CS
VSS SR_DO
VCC SR_DI
S_
AD39
S_
AD38
VCCP
S_
AD41
S_
AD40
VSS
VSS
S_
AD47
S_
AD45
S_
VSS
AD43
VSS
VCC
VSS
VCC
S_
AD37
S_
AD49
S_
AD48
S_
VCC
GNT7#
S_
AD51
S_
AD50
S_
VSS
S_VIO
REQ7#
S_
AD42
S_
AD53
S_
AD52
S_
VCCP
U
GNT6#
S_
AD55
S_MAX
100
S_
VSS
VSS
AD54
VSS
VSS
VCC
VSS
VSS
VSS
VCC
VSS
VSS
VSS
V
W
Y
S_
S_
S_CLK
S_
VCCP
VSS
VSS
AD44 REQ2# STABLE
REQ6#
S_ S_ S_
S_
AD57
S_
CBE7#
VSS
VCCP
VCCP
VSS
VCC
VCC
VSS
AD46 GNT2# AD56
S_
S_
AD58
S_
AD59
S_
S_
S_
S_
S_
S_
TMODE
2
VSS
NC
AA
AB
AC
REQ1#
AD61 ACK64# AD00 PAR64 CBE5# AD06
S_
GNT1#
S_
S_
S_
S_
S_
S_
S_
S_
S_
S_
REQ3#
VSS
GNT4# REQ4# AD60
AD62 AD63
AD01 CBE6# AD04 CBE0#
S_
S_
S_
CRS
TEN
S_
S_
S_
AD03
VSS
VCCP
VSS
VSS
VCCP
REQ5# GNT5# GNT3#
CBE4# AD02
1
2
3
4
5
6
7
8
9
10
11
12
B2240-01
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Figure 4.
Intel 31154 133 MHz PCI Bridge Ball Map—Top View, Right Side
13
14
VSS
P_
15
16
17
18
VSS
P_
19
20
21
22
23
P_
CBE0#
P_
P_
P_
P_
P_
P_
VCCP
VSS
A
B
CBE3# IRDY# FRAME#
AD04 AD07 VCCA
P_
AD00
P_ P_ P_
P_ P_ P_
VSS
TDO
AD02 TRDY# AD05
AD08 CBE1# IDSEL AD15 REQ#
P_
AD01
P_
AD03
P_
AD06
P_
AD09
P_
PAR
P_
P_
MT0#
VSS
TDI
TRST#
C
D
E
AD10 GNT#
P_
CBE2#
P_
AD11
P_DEV
SEL#
P_
AD22
VCC
VCC
VSS
VCCP
VCCP
VSS
TMS
HS_
FREQ1
NT_
MASK#
P_
CLK
P_
RST#
P_
AD24
VSS
VSS
GPIO0 GPIO1
VSS
VSS
VCC
GPIO2 VCCP
P_
VSS
P_
AD12
VCC
VSS
VCC
TCK
VSS
F
G
H
J
AD13
P_
AD16
P_
AD14
P_
AD26
VSS
VCCP
VSS
P_
AD18
P_
AD17
VSS
VCC
P_VIO
S_
S_
P_
AD20
P_
AD19
P_
AD31
VCC
CLKO0 CLKO2
S_ S_
P_
P_
AD23
P_
AD21
VSS
VSS
VSS
VSS
VSS
K
L
CLKO1 CLKO4 AD25
S_
CLKO3
P_
AD28
P_
AD27
VCC
VSS
VSS
VSS
VSS
S_
CLKO5
P_
AD30
P_
AD29
S_
AD27
VSS
VSS
VSS
VSS
M
N
P
S_
CLKO6
S_
AD30
S_
AD31
S_
AD25
VCC
S_BRG
S_
S_
S_
AD28
S_
AD29
VSS
CLKO CLK07 AD26
S_
S_
S_
AD22
S_
AD24
S_PCIX
CAP
VCC
VSS
R
T
M66EN CLKO8
S_ARB
_DIS
ABLE
S_
AD20
S_
AD23
VCC
VSS
VCC
VCC
S_
S_
AD18
S_
AD19
S_
RST#
GCLK VCCP
OEN
U
S_
GNT8#
S_
VSS
S_
AD16
S_
AD17
VCC GPIO3 GPIO5
VSS
V
AD14
S_
S_
AD15
S_
AD21
TMODE
0
VCC
VSS
GPIO4 GPIO6 GPIO7
VSS
VCCP
W
Y
REQ8#
VCC
S_
S_
TRDY#
S_
AD11
TMODE DEV_ TMODE
1
VCC
VSS
VCCP
VCCP
VSS
64BIT#
3
S_
S_
S_
S_
PAR
S_
S_
S_
REQ0#
OPAQUE
_EN
VSS RSRV0
AA
AB
AC
AD07 FRAME# CBE3# AD10
GNT0# AD13
S_ S_ S_ S_
REQ64# CBE2# AD09 CBE1# PERR# AD12 SERR# STOP# VCCA
S_
S_
S_ S_
S_
S_
CLKI
VSS
S_
AD05
S_
AD08
S_
IRDY#
S_
DEVSEL#
IDSEL_
MASK
VSS
VSS
VCCP
VSS
MT1#
VSS
13
14
15
16
17
18
19
20
21
22
23
B2241-01
®
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3.1
Total Signal Count
Table 4.
Total Signal Count
Interface
Signals
PCI bus interface
PCI 64-bit extensions
Clock and reset
JTAG
112
78
20
12
4
Serial ROM interface
CompactPCI* Hot Swap
Hardware strap
Miscellaneous
Total
6
5
17
254
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Terminations
Terminations
4
®
This chapter details all the recommended Intel 31154 133 MHz PCI Bridge terminations required
for the different operating modes.
The chapter provides the recommended pull-up and pull-down terminations for a 31154 layout.
Specification, Revision 2.3 requires that the PCI signals provide the termination resistors.
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 1 of 9)
Signal
Comments
PCI Reset
P_RST#
Connect to bus RST# signal on primary PCI bus.
Connect to bus RST# signal on secondary PCI
bus.
S_RST#
Primary PCI Signals
P_AD[31:0]
Connect to primary PCI bus AD[31:0].
For 64-bit primary PCI bus:
•
Connect to the AD[63:32] bits of the primary
PCI bus.
P_AD[63:32]
P_CBE[3:0]
P_CBE[7:4]#
For 32 bit Primary PCI Bus:
•
Pull up through individual external resistors
Connect to the CBE[3:0}# bits of the primary PCI
bus.
For 64-bit primary PCI bus:
•
Connect to the CBE[7:4]# bits of the primary
PCI bus.
For 32-bit primary PCI Bus:
•
Pull up through individual external resistors
P_FRAME#
P_DEVSEL#
P_IRDY#
Connect to FRAME# of the primary PCI bus.
Connect to DEVSEL# of the primary PCI bus.
Connect to IRDY# of the primary PCI bus.
Connect to TRDY# of the primary PCI bus.
Connect to STOP# of the primary PCI bus.
P_TRDY#
P_STOP#
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 2 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
P_GNT#
Connect to GNT# of the primary PCI bus.
Connect to one of the AD lines of the primary PCI
bus or to the IDSEL# signal of the PCI edge
connector (for add-in card applications).
more details.
P_IDSEL#
P_M66EN
Connect to the M66EN signal of the primary PCI
bus of the PCI add-in card finger.
P_PAR
Connect to PAR of the primary PCI bus.
Connect to PERR# of the primary PCI bus.
Connect to PERR# of the primary PCI bus.
P_PAR64
P_PERR#
Connect to one of the PCI bus request signals of
the primary PCI bus.
P_REQ#
P_SERR#
Connect to SERR# of the primary PCI bus.
Secondary PCI Signals
Pull up to VCC33 through external 8.2 KΩ
resistors.
S_AD[63:32]
Pull up to VCC33 through external 8.2 KΩ
S_CBE[7:4]#
S_REQ64#
S_ACK64#
resistors.
Pull up to VCC33 through external 8.2 KΩ
resistors.
Pull up to VCC33 through external 8.2 KΩ
resistors.
S_FRAME#,
S_IRDY#,
S_TRDY#,
S_STOP#,
S_DEVSEL#,
S_PERR#,
S_SERR#
Pull up to VCC33 voltage through external 8.2 KΩ
resistors.
S_REQ[8:1]#,
S_REQ0#/BR_GNT#,
S_GNT0#/BR_REQ#
Pull up to VCC33 voltage through external 8.2 KΩ
resistors.
Pull-up for both internal and external arbiter mode.
Secondary GNT#
S_GNT1#,
S_GNT2#,
S_GNT3#,
S_GNT4#,
S_GNT5#,
S_GNT6#,
S_GNT7#,
S_GNT8#
Connect to GNT# input of the PCI devices on the
secondary PCI bus.
NC when not used.
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
®
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 3 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
These signals can be used as IDSEL lines and are
connected to IDSEL of the secondary PCI bus
through an external series coupling resistor (a
resistor of 2 KΩ is used on the customer reference
board).
S_AD[31:17]
PCI Clocks
P_CLK
Connect to the PCI clock on the primary PCI bus.
•
•
All S_CLKO[8:0] and S_BRGCLKO must
match in length.
When the internal clock of the 31154 is used,
connect to S_CLKI through a 33.2 Ω series
resistor.
When there are PCI slots in the design,
S_BRGCLKO must be 3" longer to
compensate for the 2.5" trace length from the
connector to the PCI device on a PCI add-in
card.
S_BRGCLKO
NC when external clock is used.
•
•
•
These clocks can be disabled by strapping the
S_CLKOEN[3:0] during reset.
When the internal clock of the 31154 is used,
connect to the PCI clock input of the secondary
PCI devices through a 33.2 Ω series resistor.
Each clock can be connected to only one PCI
device.
All S_CLKO[8:0] and S_BRGCLKO must
match in length.
S_CLKO[8:0]
For asynchronous mode, there is no maximum
skew between P_CLK and S_CLKI.
NOTE: These clocks can be disabled by
strapping the S_CLKOEN[3:0] during
reset.
•
When using the internal clock, refer to
S_BRGCLKO (above) for additional
information.
When the internal clock of the 31154 is used,
connect to S_BRGCLKO.
•
•
When using an external clock source, all
secondary clocks must have matching length.
S_CLKI
When an external clock is used, connect to
external clock source.
When using PCI slots in the design,
S_BRGCLKO must be 3" longer to
compensate for the 2.5" trace length from the
connector to the PCI device on a PCI add-in
card.
When the internal clock of the 31154 is used,
S_CLKSTABLE must be tied high to VCC33
through an external 8.2 KΩ resistor.
When an external clock source is used, connect to
logic that outputs high after the secondary clocks
are stable.
S_CLKSTABLE
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
®
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 4 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
When the internal clock of the 31154 is used, pull
high to VCC33 through an external 8.2 KΩ resistor.
When an external clock source is used, tie to GND
through a 330 Ω external resistor. All secondary
clock outputs (S_CLKO[8:0] and S_BRGCLKO)
asynchronously tristate.
S_GCLKOEN
When an external clock source is used, tie
S_CLKOEN[3:0] to a stable value. Refer to
S_CLKOEN[3:0], below.
These are strapping pins to enable or tristate
S_CLKO[8:0] after reset.
NOTE: This strapping is meaningful only when
S_GCLKOEN is pulled high.
•
To enable all S_CLKO[8:0], pull each
S_CLKOEN[3:0] pin to 3.3 V through an
external 8.2 KΩ resistor.
When external clocks are used, tie S_GCLKOEN
low and tie S_CLKOEN[3:0] to some stable value
(0000b, for example).
S_CLKOEN[3:0]
•
To selectively disable some of the
S_CLKO[8:0], refer to 31154 Control
Register 2, bits[8:0].
Hot Swap
For Hot Swap:
•
Connect the interrupt input pin to the host.
HS_ENUM#
When not using Hot Swap:
•
NC (there is a weak internal pull-up).
For Hot Swap:
•
Connect to cPCI ejector switch.
HS_LSTAT
When not using Hot Swap:
•
Tie low to GND.
For Hot Swap:
•
Connect to cPCI blue LED.
HS_LED_OUT
When not using Hot Swap:
•
NC
For Hot Swap:
0 = The 31154 retries any Type 0 configuration
cycles addressed to it until serial ROM
preload has completed (default)
0 = Tie low to GND.
1 = The 31154 ignores (causes master abort) any
Type 0 configuration cycles addressed to it
until its serial ROM preload has completed.
HS_SM
1 = Pull high to 3.3 V through an external 8.2 KΩ
resistor.
When not using Hot Swap:
•
Tie low to GND.
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
®
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 5 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
For Hot Swap:
•
Depending on Primary PCI Bus frequency
00 = PCI Mode, 33 or 66 MHz (default)
01 = PCI-X 66 MHz
Only valid when HS_SM = 1.
0 = Tie low to GND.
HS_FREQ[1:0]
10 = PCI-X 100 MHz
1 = Pull high to 3.3 V through external 8.2 KΩ
resistor.
11 = PCI-X 133 MHz
When not using Hot Swap:
•
Tie low to GND.
Hardware Straps (sampled at the edge of P_RST#)
To disable internal secondary arbiter:
NOTE: S_ARB_LOCK has an effect only when
the internal arbiter is enabled.
•
Pull up to 3.3 V through an external 8.2 KΩ
resistor.
•
S_GNT0# becomes the secondary PCI bus
request output of the 31154, and S_REQ0#
becomes the secondary PCI bus grant input of
the 31154.
To enable internal secondary arbiter:
S_ARB_DISABLE/
S_ARB_LOCK
•
Pull down to GND through an external 220 Ω
resistor (default).
S_ARB_LOCK (after trailing edge of P_RST#):
•
Sampled as 1b, the internal secondary bus
arbiter of the 31154 locks and provides the
grant only to itself.
•
When internal arbiter is used and 1b is
sampled after the trailing edge of P_RST#, the
internal secondary bus arbiter of the 31154
locks and provide grant only to itself.
To limit secondary bus frequency to maximum of
100 MHz:
•
Pull high to 3.3 V through an external 8.2 KΩ
resistor.
S_MAX100
Otherwise:
Pull low to GND through an external 330 Ω
resistor (default).
GND during normal operation
•
S_TRISTATE
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 6 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
To enable Opaque Memory Base/Limit Registers
to establish a private memory space for secondary
bus usage:
•
Pull high to 3.3 V through an external 8.2 KΩ
resistor.
OPAQUE_EN
To disable Opaque Memory Base/Limit Registers:
•
Pull low to GND through an external 220 Ω
resistor (default).
To enable device hiding after reset (in other words,
to hide device numbers 16–21 from the host):
•
Pull high to 3.3 V through an external resistor.
To disable device hiding after reset:
IDSEL_MASK
•
Pull low to GND through an external 220 Ω
resistor (default).
After reset, device hiding can be performed
through software through the Secondary IDSEL
Select Register (Offset 5Ch).
This bit is used by the system management
software to help the user identify the best slot for
an add-in card:
•
When the 31154 is installed on an add-in card
and the add-in card implements a 64-bit PCI
connector, pull up to 3.3 V through an external
8.2 KΩ resistor.
DEV_64BIT#
•
When the 31154 is not installed on an add-in
card or the add-in card implements only a
32-bit PCI connector, pull low to GND through
a 220 Ω external resistor (default).
Serial EEPROM
Serial ROM clock input:
SR_CLK
•
•
Connect to the clock input of the EEPROM.
NC when EEPROM is not required in design.
Serial ROM data input:
SR_DI
•
•
Connect to the DI input of the EEPROM.
NC when EEPROM is not required in design.
Serial ROM data output:
NOTE: When EEPROM is present but register
preload is not desired, bits[7:6] of the first
byte can be any value except the preload
enable value (10b).
•
•
Connect to the DO output of the EEPROM.
SR_DO
Tie high or pull to GND when EEPROM is not
required in design.
Serial ROM chip select:
SR_CS
•
•
Connect to the chip select of the EEPROM.
NC when EEPROM is not required in design.
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
®
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 7 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
JTAG
TCK
Pull low when not used.
When not used, pull up to 3.3 V through an
external 8.2 KΩ resistor.
TDI
TDO
TRST#
NC when not used
When not used, pull low to GND through an
external 1 KΩ resistor.
When not used, pull up to 3.3 V through an
external 8.2 KΩ resistor.
TMS
SCAN_EN
For normal operation, tie low to GND.
For normal operation, tie to 0000 or 0111.
0 = Pull low to GND.
TMODE[3:0]
1 = Pull high to 3.3 V through an external 8.2 KΩ
resistor.
Voltages
•
Ensure that the voltage at the input pin is
within the min./max. range for S_VCCA
(1.235 V and 1.365 V).
Connect to 1.3 V supply through a low-pass filter to
reduce noise-induced jitter. The 4.7 µF capacitor
must be low ESR solid tantalum, the 0.01 µF
capacitor must be of type X7R, and the node
connecting VCCPLL must be as short as possible.
S_VCCA
P_VCCA
•
•
For power sequencing, see Section 8.2,
Ensure that the voltage at the input pin is
within the min./max. range for P_VCCA
(1.235 V and 1.365 V).
Connect to 1.3 V supply through a low-pass filter to
reduce noise-induced jitter. The 4.7 µF capacitor
must be low ESR solid tantalum, the 0.01 µF
capacitor must be of type X7R, and the node
connecting VCCPLL must be as short as possible.
•
For power sequencing, see Section 8.2,
VCC
Connect to 1.3 V supply.
Connect to 3.3 V supply.
VCCP
Connect to 5 V or 3.3 V power supply through an
external resistor, depending on the signaling level
PVIO
SVIO
Connect to 5 V or 3.3 V power supply through an
external resistor, depending on the signaling level
Miscellaneous
Pull down to GND through an external 30 Ω 1%
resistor.
R_REF
Pull up to 3.3 V through an external 8.2 KΩ series
resistor.
MT0# and MT1#
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
®
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 8 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
RSTV0
Tie to GND through a 0 Ω external resistor.
Tie to GND through a 0 Ω external resistor.
RSRV1/CRSTEN
S_M66EN is meaningful only when S_PCIXCAP is
connected to GND (that is, when the secondary
PCI bus is in legacy PCI mode).
For designs without secondary PCI slot:
•
When the secondary PCI devices (and
loading) support 66 MHz PCI bus, pull up to
3.3 V through an 8.2 KΩ series resistor.
•
When the secondary PCI devices (and
loading) do not supports 66 MHz PCI bus,
GND this pin.
Refer to PCI-X Addendum to the PCI Local Bus
Specification, Revision 1.0b, Table 6-1.
S_M66EN
For designs with secondary PCI slot:
•
When the on-board PCI device does not
support 66 MHz PCI bus, GND this pin.
•
When the on-board PCI device does support
66 MHz PCI bus, connect this pin to M66EN
(pin 49B) of the PCI connector.
For designs without secondary PCI slot:
•
When there is at least one legacy PCI device
on the secondary PCI bus, tie this pin directly
to GND.
•
When there is at least one PCI-X device that
supports maximum PCI-X of only 66 MHz on
the secondary PCI bus, pull down to GND
through a 10 KΩ series resistor.
•
When all secondary PCI-X devices (and the
bus loading) support PCI-X 133 MHz, leave
this pin unconnected (except for decoupling
capacitor).
Refer to PCI-X Addendum to the PCI Local Bus
Specification, Revision 1.0b, Table 6-1.
S_PCIXCAP
For designs with secondary PCI slot:
•
When there is at least one on-board legacy
PCI device on the secondary PCI bus, tie this
pin directly to GND.
•
Otherwise, connect this pin to PCIXCAP
(pin B38) of the PCI connector (assuming that
the bus loading supports up to PCI-X
133 MHz)
NOTES:
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
®
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Terminations
Table 5.
Pull-Up/Pull-Down Terminations (Sheet 9 of 9)
Signal
Pull-Up/Pull-Down or Termination (See Note 1)
Comments
•
•
When forced retirement of the 31154 internal
request queues and data buffer is not desired
in the application, this pin must be pulled up to
3.3 V through an 8.2 KΩ resistor.
When forced retirement of the 31154 internal
request queues and data buffer is desired in
the application, this pin must be connected to
external logic (or using the GPIO of the 31154)
that drives this pin low when masking new
transactions is desired.
•
As soon as NT_MASK# is asserted, it must
not be de-asserted until the QE pin is
asserted.
•
•
NT_MASK# must not be reasserted until the
QE pin is cleared.
NT_MASK#
Setting the New Transaction Mask bit to 1b in
VCR0 has the same effect as asserting
NT_MASK#.
Connection depends on application. This is an
output signal that indicates the state of the 31154
internal request and data queues. When high, this
signal indicates that the 31154 internal queues are
completely empty.
NOTE: The state of this output is valid only when
the NT_MASK# pin is asserted.
QE
SCAN_EN
TMODE[3:0]
NOTES:
For normal operation, tie low to GND.
For normal operation, tie to 0000 or 0111.
0 = Pull low to GND.
1 = Pull high to 3.3 V through an external 8.2 KΩ
resistor.
1. The recommended value for pull-up resistors for PCI applications is 5.6 KΩ (note that the minimum value for PCI 3.3 V
signaling RMIN = 2.42 KΩ, RTYP = 8.2 KΩ, as per the PCI Local Bus Specification, Revision 2.3, section 4.3.3).
2. The recommended value for pull-up resistors for PCI-X applications is 8.2 KΩ. For PCI-X, the minimum pull-up resistor value
is 5 KΩ, as per the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, section 9.7.
3. For plug-in card implementations, the pull-up must be on the motherboard.
4. Connect PVIO and SVIO pull-up resistors to 5 V or 3.3 V power supply through an external resistor—25 Ω (5 V) or
0 Ω (3.3 V), depending on the signaling level of the primary/secondary PCI bus. Refer to the power-sequencing guidelines in
Section 8.2 on page 58.
§ §
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Terminations
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PCI/PCI-X Interface
PCI/PCI-X Interface
5
®
This chapter provides guidelines for designing with the Intel 31154 133 MHz PCI Bridge
PCI/PCI-X bus interface in your application.
5.1
PCI/PCI-X Voltage Levels
®
The Intel 31154 133 MHz PCI Bridge supports the 5 V PCI signaling interface as well as 3.3 V.
website.
Table 6.
PCI/PCI-X Voltage Levels
Symbol
Parameter
Minimum
Maximum
Units
VIL3
VIH3
VIL4
Input low voltage (PCI-X)
Input high voltage (PCI-X/PCI)
Input low voltage (PCI)
-0.5
0.5 × VCC33
-0.5
0.35 × VCC33
VCC33 + 0.5
0.3 × VCC33
0.1 × VCC33
V
V
V
V
V
VOL3
VOH3
Output low voltage (PCI-X)
Output high voltage (PCI-X)
0.9 × VCC33
5.2
Interrupt Routing
The 31154 does not use PCI INT lines (INTA, INTB, INTC and INTD). These pins are usually
routed from the primary to secondary PCI buses, bypassing the bridge.
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PCI/PCI-X Interface
5.3
IDSEL Lines
The IDSEL lines act as chip selects during the configuration cycles. Configuration cycles allow
read and write access to one of the device configuration space registers. As in PCI, the IDSEL lines
can be mapped to upper address lines, which are unused during the configuration cycles.
5.3.1
Primary IDSEL Line
Figure 5 provides an example of the 31154 used as an embedded controller connected to four PCI
devices. Note that AD16 is typically reserved for a PCI/PCI-X bridge.
• When the 31154 is used as the primary interface to a plug-in card, the primary IDSEL line
must be routed from the PCI connector to the P_IDSEL pin.
• When the 31154 is used in an embedded application, PCI AD16 is used for source bridges.
This line (AD16) must be connected to the P_IDSEL line through a 2 KΩ resistor.
Figure 5.
IDSEL Mapping
Intel 31154
I/O Processor
Note:
5.3.2
Secondary IDSEL Lines
The PCI specification recommends a specific resistor value of 2 KΩ ±5%. A smaller value may be
used as long as system analysis ensures that timing and noise budgets for the AD bit are met.
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PCI/PCI-X Interface
5.3.3
Secondary IDSEL Masking
The 31154 supports private devices through the use of IDSEL masking. When the IDSEL_MASK
pin is sampled as 1b on the trailing edge of P_RST#, the default value for the Secondary IDSEL
®
Select Register (SISR) is 001Fh to mask devices 0–4 (refer to the Intel 31154 133 MHz PCI
Bridge Developer’s Manual for more information).
5.3.4
Secondary Clock Control
The 31154 can disable its secondary clock outputs individually or globally. The straps
S_CLKOEN[3:0] determine the number of S_CLKO[8:0] outputs that are enabled. The
S_BRCLKO output is dedicated for the bridge feedback clock and cannot be individually disabled.
When the global clock output enable S_GCLKOEN is sampled as 0b, all secondary clock outputs
are disabled, and an external clock source is required. The 31154 Bridge still drives the PCI-X
initialization pattern, so any external clock source must be consistent with the clock generation
5.4
CompactPCI* Hot Swap Mode Select
Hot Swap Mode Select (HS_SM) must be asserted (1b) to enable hot-swap functionality.
HS_FREQ[1:0] pins allow the bridge to determine the cPCI backplane operating frequency on its
primary interface without needing to see a PCI-X initialization pattern. These pins are valid only
when HS_SM is sampled as 1b during P_RST#.
Table 7.
HS_FREQ Encoding
HS_FREQ[1:0]
P_M66EN
Operating Mode
Bus Frequency
00
00
01
10
11
0
1
–
–
–
PCI
PCI
33 MHz
66 MHz
66 MHz
100 MHz
133 MHz
PCI-X
PCI-X
PCI-X
5.5
Opaque Memory Region Enable
The 31154 supports an opaque memory region to enable private memory space for secondary
devices. When OPAQUE_EN is sampled as 1b at the trailing edge of P_RST#, the Opaque
Memory Enable bit in the “VCR2 Bridge Control Register 2” is set. The default base and limit
reserve the upper half of memory (AD[63] = 1) for the private memory region.
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PCI/PCI-X Interface
5.6
PCI-X Initialization Clocking Modes
Both of the PCI bus interfaces can operate at a variety of frequencies, and in either conventional
PCI mode, or in PCI-X mode. Each interface establishes the bus mode and frequency when coming
out of its corresponding bus segment reset sequence. The resultant mode and frequency is
dependent upon the device capabilities reported, in addition to any system-specific loading
information.
5.6.1
5.6.2
Primary PCI Clocking Mode
The 31154 reports its primary bus operating capabilities to the originating device (typically the host
bridge) of the primary bus segments. The 31154 indicates to the originating device of the primary
bus segments that its primary interface is PCI-X–capable at frequencies of up to 133 MHz. It also
indicates that the 31154 is capable of running at 66 MHz when operating in conventional PCI
mode.
Secondary PCI Clocking Mode
The 31154 is the originating device for its secondary bus, and as such sets the bus mode and
frequency when exiting out of the secondary bus reset sequence. The two key components that
factor into the resultant secondary bus mode and frequency are the PCI-X standard sampling of
downstream device capabilities, and the system-specific physical bus loading characteristics for
which the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b does not provide
any standard means of reporting.
Downstream device capabilities are indicated by the values of S_M66EN and S_PCIXCAP during
S_RST# assertion. Knowledge of the device capabilities alone is insufficient information to
robustly select the bus frequency. In order to know with certainty at what frequency to set the bus,
knowledge of the bus layout (for example, the number of slots) is also necessary. The 31154
provides the S_MAX100 strapping pin for reporting system-specific secondary bus loading
information that is used in determining the maximum operating frequency of the secondary bus.
The 31154 considers S_MAX100 along with S_PCIXCAP and S_M66EN# to determine the
secondary bus mode and frequency when emerging from S_RST#. For example, when a card is
plugged into a two-slot secondary bus, the S_MAX100 strapping of 1b ensures that the bus runs at
no greater than 100 MHz, regardless of the reported downstream device capabilities.
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PCI/PCI-X Interface
Table 8.
PCI-X Clocking Modes
PCIXCAP (pin on
PCI connector)
PCI-X Mode
PCI Mode
P_M66EN
Not capable
Not capable
33 MHz
66 MHz
33 MHz
66 MHz
33 MHz
66 MHz
GND
GND
GND
Not connected
GND
PCI-X/66 MHz
PCI-X/66 MHz
PCI-X/133 MHz
PCI-X/133 MHz
Pull down
Pull down
Not connected
Not connected
Not connected
Ground
Not connected
Table 9.
Secondary Bus Frequency Initialization
Conventional PCI
Frequency
Typical Slot
S_M66EN
S_PCIXCAP
S_MAX100
PCI-X Frequency
Loading1
Ground
Ground
Ground
–
–
33 MHz
66 MHz
Not capable
Not capable
Not connected
Typical setting for
four slots
Ground
Pull-down
–
33 MHz
PCI-X 66 MHz
Not connected
Ground
Pull-down
–
1
66 MHz
33 MHz
PCI-X 66 MHz
PCI-X 100 MHz
Not connected
Typical setting for
two slots
Not Connected
Ground
Not Connected
Not Connected
Not Connected
1
0
0
66 MHz
33 MHz
66 MHz
PCI-X 100 MHz
PCI-X 133 MHz
PCI-X 133 MHz
Typical setting for
one slot
Not Connected
NOTE:
1. Simulation is suggested for any deviation from typical slot loading recommendations.
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PCI/PCI-X Interface
secondary bus when coming out of S_RST#, after having evaluated the above information.
Table 10.
PCI-X Initialization Pattern
Clock Period
(Ns)
Clock Frequency
(MHz)
DEVSEL#
STOP#
TRDY#
Mode
Max.
Min.
30
Min.
62.51
33
Max.
33
PCI 33
PCI 66
PCI-X
PCI-X
PCI-X
PCI-X
PCI-X
PCI-X
PCI-X
62.51
Deasserted Deasserted Deasserted
30
15
66
Deasserted Deasserted
Asserted
Deasserted
Asserted
20
15
50
66
Deasserted
Deasserted
Asserted
Asserted
Asserted
Asserted
NOTE:
Asserted
Asserted
15
10
66
100
133
10
7.5
100
Deasserted Deasserted
Deasserted
Asserted
Asserted
Asserted
Deasserted
Asserted
Reserved
1. When the internal PLLs are operational, the minimum input frequency is 16 MHz. See Section 5.6.3,
“Primary-to-Secondary Frequency Limits” on page 34 for more information.
5.6.3
Primary-to-Secondary Frequency Limits
When operating in PCI 33 MHz mode, the bridge bypasses the PLL to allow the full range of
0–33 MHz operations defined in the PCI specifications.
However, the PLL is used to generate the secondary clock outputs when the secondary side is
operating at a frequency greater than 33 MHz (PCI-66 MHz or PCI-X). The primary clock input
must operate above 25 MHz to ensure that the secondary frequencies are within the ranges defined
in the PCI specifications.
When both the primary and secondary sides are operating in PCI-33 MHz mode, then the
secondary clock equals the primary clock in frequency.
An external clock source can be used on the secondary interface to remove any dependencies on
the primary clock input.
§ §
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Routing Guidelines
Routing Guidelines
6
This chapter provides some basic routing guidelines for layout and design of a printed circuit board
®
(PCB) using the Intel 31154 133 MHz PCI Bridge. The high-speed clocking required when
designing with the 31154 requires special attention to signal integrity. In fact, it is highly
recommended that the board design be simulated to determine optimum layout for signal integrity.
The information in this chapter provides guidelines to aid the designer with board layout. Several
factors influence the signal integrity of a 31154 design, including the following:
• Power distribution
• Decoupling
• Minimizing crosstalk
• Layout considerations when routing the PCI-X bus interfaces
The order in which signals are routed varies from designer to designer. Some designers prefer to
route all clock signals first, while others prefer to route all high-speed bus signals first. Either order
can be used, provided the guidelines listed here are followed.
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Routing Guidelines
6.1
Crosstalk
Crosstalk is caused by capacitive and inductive coupling between signals. Crosstalk is composed of
both backward and forward crosstalk components. Backward crosstalk creates an induced signal on
a victim network that propagates in the opposite direction of the aggressor signal. Forward
crosstalk creates a signal that propagates in the same direction as the aggressor signal.
Circuit-board analysis software is used to analyze your board layout for crosstalk problems.
Examples of 2D analysis tools include Ansoft* Parasitic Parameters* and Quad Design* XFS*.
Crosstalk problems occur when circuit etch lines run in parallel. When board analysis software is
not available, the layout must be designed to maintain at least the minimum recommended spacing
for bus interfaces:
• As a general guideline, the distance between adjacent signals must be a least 3.3 times the
distance from signal trace to the nearest return plane. The coupled noise between adjacent
traces decreases by the square of the distance between the adjacent traces.
• It is also recommended that you specify the height of the above-referenced plane when laying
out traces and that you provide this parameter to the PCB manufacturer. By moving traces
closer to the nearest reference plane, the coupled noise decreases by the square of the distance
to the reference plane.
Figure 6.
Crosstalk Effects on Trace Distance and Height
Reduce Crosstalk:
P
- Maximize P
H
aggressor
victim
Reference Plane
- Minimize H
A9259-01
Additional crosstalk guidelines include the following:
• Avoid slots in the ground plane. Slots increase mutual inductance and thus increase crosstalk.
• Ensure that the ground plane surrounding the connector-pin fields is not completely cleared
out. When the area around the connector pins is completely cleared out, all the return current
must flow together around the pin field, increasing crosstalk. The preferred method of laying
®
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Routing Guidelines
Figure 7.
PCB Ground Layout Around Connectors
Connector
Connector Pins
GND PCB Layer
A. Incorrect method
B. Correct method
A9260-01
6.2
EMI Considerations
It is highly recommended that you follow good EMI design practices when designing with the
31154:
• To minimize EMI on your PCB, a useful technique is not to extend the power planes to the
edge of the board.
• Another technique is to surround the perimeter of your PCB layers with a GND trace. This
helps to shield the PCB with grounds, minimizing radiation.
The AP-711 EMI Design Techniques Application Note discusses how to identify and prevent many
common EMI problems at the design stage. Although the document addresses a range of solutions,
emphasis is on printed circuit board design methods. This document is available at the following
link:
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Routing Guidelines
6.3
Power Distribution and Decoupling
Ensure that there is ample decoupling to ground for the power planes, to minimize the effects of the
switching currents.
Inadequate high-frequency decoupling results in intermittent and unreliable behavior.
As a general guideline, it is recommended that you use the largest easily available capacitor in the
lowest-inductance package. The high-speed decoupling capacitor must be placed as close to the pin
as possible, with a short, wide trace.
Three types of decoupling are described below:
• Bulk capacitor: Bulk capacitors consist of electrolytic or tantalum capacitors. These
capacitors supply large reservoirs of charge, but they are useful only at lower frequencies due
to lead-inductance effects. Bulk capacitors can be located anywhere on the board.
• High-frequency ceramic capacitor: For fast switching currents, high-frequency low-
inductance capacitors are most effective. Place these capacitors as close to the device being
decoupled as possible. This placement minimizes the parasitic resistance and inductance
associated with board traces and vias.
• Inter-plane capacitor: Use an inter-plane capacitor between power and ground planes to
reduce the effective plane impedance at high frequencies. The general guideline for placing
capacitors is to place high-frequency ceramic capacitors as close as possible to the module.
6.3.1
Decoupling Recommendations
This section describes the recommended high-frequency and bulk decoupling for each of the 31154
®
Table 11.
Intel 31154 133 MHz PCI Bridge Decoupling Recommendations
Capacitor Value
Capacitor
Package
Number of
Capacitors
Pins
Voltage
Notes
(µF)
VCC33
3.3 V
3.3 V
22
0.1
150
22
1210
603
3
12
1
VCC33
VCC33
3.3 V
7343
1210
603
VCC
1.3 V
3
VCC
1.3 V
0.1
22
12
1
P_VIO, S_VIO
P_VIO, S_VIO
3.3 V/5.0 V
3.3 V/5.0 V
1210
603
0.1
4
Refer to
Section 8.1 on
P_VCCA,
S_VCCA
1.3 V
–
–
NOTES:
1. Separate capacitor required only when P_VIO and S_VIO are not connected to VCC33.
2. Polymerized organic capacitors are recommended for bulk.
3. X5R, X7R, or COG are recommended for ceramics.
4. Place all capacitors as close as possible to associated pins to minimize inductance.
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Routing Guidelines
6.4
Trace Impedance
The PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0b, recommends that all
signal layers have a controlled impedance of 57 Ω ±10% for add-in card applications. The
characteristic impedance of a signal trace is 60–100 Ω for PCI add-in card applications.
Selecting the appropriate board stack-up to minimize impedance variations is very important.
When calculating flight times, it is important to consider the minimum and maximum trace
impedance based on the switching neighboring traces. The PCI Local Bus Specification,
Revision 2.3, recommends a trace velocity of 150 ps/in to 190 ps/in. Use wider spaces between
traces, since this can minimize trace-to-trace coupling, and reduce crosstalk.
When a different stack-up is used, the trace widths must be adjusted appropriately. When wider
traces are used, the trace spacing must be adjusted accordingly (linearly).
It is highly recommended that a 2D field solver be used to design the high-speed traces. An
trace impedance of various topologies. These approximations may be used to generate the starting
point for a full 2D field solver.
The following website provides a useful basic guideline for calculating trace parameters:
Note: Using stripline transmission lines may give better results than microstrip. This is due to the
difficulty of precisely controlling the dielectric constant of the solder mask, and the difficulty in
limiting the plated thickness of microstrip conductors, which can substantially increase crosstalk.
§ §
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PCI-X Layout Guidelines
PCI-X Layout Guidelines
7
For acceptable signal integrity with bus speeds up to 133 MHz, it is important for the PCB design
layout to have controlled impedance.
The list below provides general guidelines for routing your PCI bus signals:
• Avoid routing signal traces longer than 8".
• All clock nets must be on the top layer.
• All 32-bit interface signals from the PCI edge fingers must be no longer than 1.5" and no
shorter than 0.75".
• All 64-bit extension signals from the PCI edge fingers must be no longer than 2.75" and no
shorter than 1.75".
• P_CLK from the PCI edge finger must be 2.5" ± 0.1".
• P_RST# from the PCI edge finger must be no longer than 3.0" and no shorter than 0.75".
Table 12.
Add-in Card Routing Parameters
PCI-X
Parameter
Minimum
Length
Maximum
Length
(inches)
(inches)
P_CLK
2.40
0.75
1.75
0.75
2.60
1.50
2.75
3.00
P_AD[31:0]
P_AD[63:32]
P_RST#
Note: Do not use more than one via for the primary PCI bus signals.
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PCI-X Layout Guidelines
7.1
PCI Clock Layout Guidelines
The PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a, allows a maximum of
0.5 ns clock skew timing for each of the PCI-X frequencies: 66 MHz, 100 MHz, and 133 MHz.
• Total length of P_CLK for an add-in card is 2.4"–2.6"
• Total length of P_CLK in non-add-in card design is less than 8".
A typical PCI-X application requires separate clock point-to-point connections distributed to each
PCI device. The 31154 clock buffer also provides secondary clock fanout of up to nine PCI-X
of eight secondary clocks going to individual PCI-X devices with S_BRGCLKO fed back into
1. The distance between each series resistor and S_CLKO# output clock buffer must be less
than 0.5".
2. The segment length from secondary output clock buffer S_CLKO# to the end of the series
resistor must be matched less than 0.1".
3. You must match the end of series resistor to the device clock input to less than 0.1" to help
keep the timing within the 0.5 ns maximum budget.
4. You must match the length of S_BRGCLKO to the series resistor to less than 0.1" to all the
5. Match the length of the other end of the series resistor to S_CLKIN to all the other secondary
6. Keep the distance between the clock lines and other signals (“d”) at least 25 mils from each
other.
7. When using a serpentine clock layout, keep the distance between different segments of the
same clock line a minimum of 25 mils apart.
8. When there are PCI devices and PCI slots in the design, an extra 2.5" trace length from
connector to PCI device must be considered in calculating clock lengths going to PCI slots.
9. When there are PCI slots in the design, S_BRGCLKO must be 3" longer to compensate for the
2.5" trace length from connector to PCI device (and 0.5" for the connector skew) on a PCI
add-in card.
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PCI-X Layout Guidelines
Figure 8.
PCI Clock Distribution and Matching Requirements
Device
8
Intel 31154
133 MHz PCI Bridge
Device
7
Device
6
Device
5
Device
4
Device
3
Device
2
Device
1
Notes:
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PCI-X Layout Guidelines
7.2
PCI-X Topology Layout Guidelines
The PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a, recommends the
from these maximum values requires close attention to layout with regard to loading and trace
lengths.
Table 13.
PCI-X Slot Guidelines
Maximum
Number of Slots
Frequency
Maximum Loads
66 MHz
100 MHz
133 MHz
8
4
2
4
2
1
The following PCI-X design layout considerations are compiled from the white paper Design,
Modeling and Simulation Methodology for High Frequency PCI-X Subsystems, available on the
http://www.pcisig.com website.
The following results are compiled from the simulation of system models that included system
board and add-in cards for different slot configurations and bus speeds (discussed in the white
paper mentioned above). This simulation addressed signal-integrity issues including reflective
noise, crosstalk noise, overshoot/undershoot voltage, ring-back voltage, settling time, inter-symbol
interference, input reference voltage offset, and ground-bounce effects. These results for the slot
configurations met the required PCI-X timing characteristics and were within appropriate noise
margins.
• 133 MHz Single-Slot—Included a single connection from the bridge to a single slot.
• 133 MHz Embedded—Included a single connection from the bridge to one additional device
on the system board. Note that this topology was interpolated from the above 133 MHz One-
Slot (not based on actual simulation results).
• 100 MHz Two-Slot Non-Hot-Plug, Balance Star—Included a single connection from the
bridge to two slots without hot-plug devices. The connections to the bridge and to each slot
came together such that each of the three branches is approximately the same length.
• 100 MHz Embedded Non-Hot-Plug, Balance Star—Included a single connection from the
bridge to three devices. The connections to the bridge and to each device came together such
that each of the three branches was approximately the same length. Note that this topology was
interpolated from the above 100 MHz Two-Slot (not based on actual simulation results).
• 66 MHz Four-Slot Non-Hot-Plug—Included a single connection from the bridge to four hot-
plug slots.
• 66 MHz Embedded Non-Hot-Plug—Included a single connection from the bridge to four hot-
plug slots. Note that this topology was interpolated from the above 66 MHz Four-Slot (not
based on actual simulation results).
®
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PCI-X Layout Guidelines
7.2.1
Single Slot at 133 MHz
Figure 9 shows one of the chipset PCI AD lines connected through the W1 and W12 line segments
to a single-slot connector through the W13 line segment to the 31154. This AD line is also used as
an IDSEL line from line segment W14 to a resistor through W15 to the PCI connector. The other
end of the PCI connector IDSEL line connects through W16 to the 31154 IDSEL line input buffer.
Figure 9.
Single-Slot Point-to-Point Topology
W1
W12
W13
W16
PCI Agent 1
W14
W15
I/O Buffer
Slot 1
B3057-01
Note: Stub lengths are represented by W#s.
Table 14.
Wiring Lengths for 133 MHz Slot
Lower AD Bus
Segment
Upper AD Bus
Units
Minimum
Length
Maximum
Minimum
Length
Maximum
Length
Length
W1 + W12
W13
5.5
0.75
0.1
10.5
1.5
4.5
1.75
–
9.5
2.75
–
inches
inches
inches
inches
inches
W14
0.1
W15
0.6
0.6
–
–
W16
1.125
1.125
–
–
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®
7.2.1.1
Intel 31154 133 MHz PCI Bridge Embedded Application at 133 MHz
Figure 10 shows the 31154 application in a stand-alone embedded application. In this application
to use as a reference.
®
Figure 10.
Embedded Intel 31154 133 MHz PCI Bridge Design 133 MHz PCI-X Layout
W2
W4
W1
PCI
Agent
IDSEL
I/O Buffer
W3
B3058-01
Table 15.
Wiring Lengths for Embedded 133 MHz Design
Lower AD Bus
Segment
Upper AD Bus
Units
Minimum
Length
Maximum
Length
Minimum
Maximum
Length
Length
W1
W2
W3
W4
5.5
0.75
0.1
10.5
1.5
4.5
1.75
–
9.5
2.75
–
inches
inches
inches
inches
0.1
1.725
1.725
–
–
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PCI-X Layout Guidelines
7.2.2
Dual-Slot at 100 MHz
Figure 11 shows one of the secondary bridge PCI AD lines branching into two segments with each
wiring lengths to use as a reference. This two-slot design uses a balanced-star topology.
Figure 11.
Dual-Slot Configuration
W1
W11
W12
W13
W16
PCI Agent 1
W14
W15
I/O Buffer
Slot 1
W21
W22
W23
PCI Agent 2
Slot 2
B3059-01
Table 16.
Wiring Lengths for 100 MHz Dual-Slot
Lower AD Bus
Segment
Upper AD Bus
Units
Minimum
Length
Maximum
Length
Minimum
Length
Maximum
Length
W1
W21
3.5
2.0
6
4.5
0.5
1.5
0.1
0.6
1.125
4.5
0.5
1.5
3.5
1.0
6
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
3.5
W11+W12
W13
0.5
0.5
0.5
0.75
0.1
1.75
N/A
N/A
N/A
1.0
2.75
N/A
N/A
N/A
3.5
W14
W15
0.6
W16
1.125
2.0
W21
W22
0.5
0.5
0.5
WW23
0.75
1.75
2.75
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PCI-X Layout Guidelines
®
7.2.2.1
Embedded Intel 31154 133 MHz PCI Bridge Application at 100 MHz
Figure 12 shows the PCI-X layout for a embedded 133 MHz design. In this application the 31154
®
Figure 12.
Embedded Intel 31154 133 MHz PCI Bridge Design 100 MHz PCI-X Layout
W1
W2
W3
PCI
Agent 1
I/O Buffer
IDSEL
W5
W4
W6
W7
PCI Agent 2
PCI Agent 3
B3062-02
Table 17.
Wiring Lengths for Embedded 100 MHz Design
Lower AD Bus
Segment
Upper AD Bus
Units
Minimum Length Maximum Length Minimum Length Maximum Length
W1
W2
W3
W4
W5
W6
W7
3.5
2.5
6
5.0
3.5
1.5
1.75
–
6.0
4.0
2.75
–
inches
inches
inches
inches
inches
inches
inches
0.75
0.1
1.5
0.1
1.725
3.25
3.25
1.725
6.5
–
–
3.25
3.25
6.75
6.75
6.5
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PCI-X Layout Guidelines
7.2.3
Quad-Slots at 66 MHz
Figure 13 shows one of the bridge secondary AD lines branching to four segments with each
segment connecting to a slot connector to a buffer on an add-in card. The first segment representing
an upper address line branches to a series resistor to become the IDSEL line for slot 1. Table 18
shows the corresponding wiring lengths to use as a reference.
Figure 13.
Quad-Slots 66 MHz Topology
W1
W13
PCI Agent 1
I/O Buffer
W14
W22
W15
W16
W23
Slot 1
Slot 2
Slot 3
Slot 4
PCI Agent 2
W32
W42
W33
W43
PCI Agent 3
PCI Agent 4
B3060-01
Table 18.
Wiring Lengths for 66 MHz Quad-Slot (Sheet 1 of 2)
Lower AD Bus
Segment
Upper AD Bus
Units
Minimum
Length
Maximum
Length
Minimum
Maximum
Length
Length
W1
W13
W14
5
7
2.5
1.75
–
7
2.75
–
inches
inches
inches
0.75
0.1
1.5
0.1
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PCI-X Layout Guidelines
Table 18.
Wiring Lengths for 66 MHz Quad-Slot (Sheet 2 of 2)
Lower AD Bus
Upper AD Bus
Segment
Units
Minimum
Length
Maximum
Length
Minimum
Length
Maximum
Length
W15
W16
W21
W22
W23
W32
W33
W42
W43
0.6
1.125
0.8
0.6
1.125
1.2
–
–
inches
inches
inches
inches
inches
inches
inches
inches
inches
–
–
0.8
0.1
1.75
0.1
1.75
0.1
1.75
1.2
0.5
2.75
0.5
2.75
0.5
2.75
0.1
0.5
0.75
0.1
1.5
0.5
0.75
0.1
1.5
0.5
0.75
1.5
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PCI-X Layout Guidelines
®
7.2.3.1
Embedded Intel 31154 133 MHz PCI Bridge Application at 66 MHz
Figure 14 shows an 31154 in a stand-alone embedded application. In this application the 31154 is
shows the corresponding wiring lengths to use as a reference.
®
Figure 14.
Embedded Intel 31154 133 MHz PCI Bridge Wiring for 66 MHz
W2
W1
PCI Agent 1
IDSEL
I/O Buffer
W4
W6
W3
W5
PCI Agent 2
W7
W9
W8
PCI Agent 3
PCI Agent 4
W10
B3247-01
Table 19.
Wiring Lengths for Embedded 66 MHz Design
Lower AD Bus
Segment
Upper AD Bus
Units
Minimum Length Maximum Length Minimum Length Maximum Length
W1
W2
W3
W4
W5
W6
W7
W8
W9
W10
5
0.75
0.1
1.725
1
7
1.5
0.1
1.725
1
5
1.75
–
7
2.75
–
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
–
–
1
1
0.75
1
1.5
1
1.75
1
2.75
1
0.75
1
1.5
1
1.75
1
2.75
1
0.75
1.5
1.75
2.75
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PCI-X Layout Guidelines
7.2.4
PCI-X at 33 MHz
The 31154 supports running in an eight-slot PICMG 1.2 style passive backplane environment at
33 MHz. To verify this, simulations were run based on the trace impedance of 57 Ω ± 10%.
7.2.4.1
Embedded PCI-X Specification PICMG 1.2 Overview
The Embedded PCI-X (ePCI-X) Specification PICMG 1.2 is a specification supported by the PCI
Industrial Computer Manufacturers Group. ePCI-X system host boards (SHBs) are defined in two
form factors: full-size and half-size. The full-size SHB length is identical to the ISA long board
length. Half-size SHB form factor is based on the popular half-size ISA board.
7.2.4.2
PICMG 1.2 System Overview
An ePCI-X system is composed of one ePCI-X system host board (SHB) and an ePCI-X
backplane. The SHB provides arbitration, clock distribution, and reset functions for all expansion
boards. The SHB is responsible for performing system initialization by managing the IDSEL signal
of each local board. Physically, the SHB slot can be located at any slot in the backplane.
Electrically, it must be at the end of each of primary PCI/PCI-X bus.
®
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PCI-X Layout Guidelines
Figure 15 shows an example of this system with dual 64-bit buses with four expansion slots on
each bus. The backplane example shows the SHB in an ISA chassis. The SHB slot is in the center
of the board. Figure 16 shows the data bus segments for this eight-slot topology, and Table 20 lists
Figure 15.
An Example of an ePCI-X System
Option Bracket Front Plate
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PCI-X Layout Guidelines
Figure 16.
PCI-X Data Bus PICMG 1.2 Style Backplane
Intel® 31154 133 MHz
PCI Bridge
Slot1
Slot2
Slot3
Slot4
Slot5
Slot6
Slot7
Slot8
Device
W1
W2
W3
W4
W5
W6
W7
W8
Card Stub
Edge Connector
W9
W10
W11
W12
W13
W14
W15
Backplane
B3331-01
Table 20.
Wiring Lengths for PICMG 1.2 Backplane
AD Bus
Segment
Units
Minimum Length Maximum Length
W1
W2
0.75
0.75
0.75
0.75
0.75
0.75
0.75
0.75
1.2
2.75
2.75
2.75
2.75
2.75
2.75
2.75
2.75
1.2
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
inches
W3
W4
W5
W6
W7
W8
W9
W10
W11
W12
W13
W14
W15
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
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PCI-X Layout Guidelines
Figure 17.
PCI-X Clock PICMG 1.2 Style Backplane
Slot1
SlotN
WN
Intel® 31154 133 MHz
PCI Bridge Clock Buffer
Device
S1
39 Ohms
Card Stub
S2
Edge Connector
Backplane
BN
B3332-01
Table 21.
PCI-X Clock Wiring Lengths for PICMG Backplane
Clock Point to Point
Segment
Units
Minimum Length Maximum Length
S1
S2
0
0.3
inches
inches
inches
inches
0.75
0.75
6.5
2.75
2.75
16.2
WN
BN
§ §
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Power Considerations
Power Considerations
8
8.1
Analog Power Pins
The analog voltage pins S_VCCA and P_VCCA require a low-pass filter. This is implemented by
connecting the P_VCCA and S_VCCA pins to a 10 Ω series resistor and 0.01 µF and 4.7 µF (low-
ESR) capacitors in parallel going to ground. The opposite end of the 10 Ω resistor is connected to
When implementing these circuits, use the following filter circuit layout and component
recommendations:
1. Low-ESR, polymerized organic capacitors are recommended for 4.7 µF.
2. The 0.01 µF capacitor must be a X5R, X7R, or COG.
3. The capacitors must be placed as close as possible to associated pins to minimize inductance.
4. The connections from the P_VCCA and S_VCCA must be kept as short as possible.
Figure 18.
P_VCCA Filter
Figure 19.
S_VCCA Filter
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Power Considerations
8.2
Power Sequencing
When either P_VIO or S_VIO is connected to a power supply other than VCCP, you must perform
one of the following steps (listed in order from most favorably recommended to least favorably
recommended):
1. Ensure that the P_VIO or S_VIO power comes up before or simultaneously with VCCP, and
ensure that the P_VIO or S_VIO power goes down after or simultaneously with VCCP
.
2. Alternatively, when the recommendation in item 1 is not followed, install a Schottky diode, as
sized appropriately for the power environment of the system.
3. Alternatively, when the recommendations in item 1 and item 2 are not followed, connect a
25 Ω current-limiting resistor in series with the P_VIO and S_VIO supply. P_VIO and S_VIO
must never be at a voltage lower than VCCP except in the case of a 25 Ω current-limiting
resistor in series with the P_VIO and S_VIO supply.
Figure 20.
PVIO Voltage Protection Diode
VCP
VIO
Intel® 31154
133 MHz PCI Bridge
§ §
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Customer Reference Board
Customer Reference Board
9
®
This chapter provides information on the customer reference board based on the Intel 31154
®
the block diagram for this CRB. The schematics for this board are provided on the Intel
1
Developer’s website (document number 278839) .
®
Figure 21.
Intel IQ31154 Customer Reference Board Block Diagram
PCI Optional Bus
Logic Analyzer Mictors Logic Analyzer Mictors
Quick
Switch
Enable
Quick Switches
Quick Switches
PCI Secondary Bus - 133 MHz
Serial
EEPROM
Intel® 31154
133 MHz PCI Bridge
Clock
Circuit
Strapping
Options
PCI Primary Bus
B3336-01
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Customer Reference Board
example is provided as a reference; each individual 31154 application may vary.
Table 22.
Customer Reference Board Stackup
Layers
Signal
Top layer
2nd layer
3rd layer
4th layer
5th layer
6th layer
7th layer
8th layer
Signal layer—critical nets (clocks, S/P AD buses)
Ground plane
Signal layer
Power plane—(split voltage plane 3.3 and 1.3 for I/O and core)
Power plane—(also a split voltage plane 5 and 12 V)
Signal—(some minor 25 mil wide power runs included)
Ground plane
Signal layer (critical nets)
FR-4, 0.062 in. ± 0.008, 1.0 oz. copper power/GND; ½ oz. copper signal.
§ §
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Debug Connectors and Logic Analyzer Connectivity
Debug Connectors and Logic Analyzer
Connectivity
10
10.1
Probing PCI-X Signals
To ease the probing and debugging of the PCI-X signals, you are recommended to passively probe
the PCI-X bus signals with a logic analyzer. This can be done by placing six AMP* Mictor-38
connectors on the board or by probing the bus with an interposer card such as the
FuturePlus* Systems* FS2007 that works with an Agilent Technologies* logic analyzer.
For ease of debugging the pinout of the AMP* Mictor-38 connectors, the recommended pin-out
matches the FuturePlus* Systems* configuration setup, which allows ease of viewing the PCI
signals on an Agilent Technologies* logic analyzer. Refer to the following test equipment that is
used for this analysis:
• Two AMP* 2-767004-2 surface-mount connectors mounted on the target board and routed to
the PCI-X local bus
• Two Agilent Technologies* E5346A or E5351A high-density adapter cables from
FuturePlus* Systems or Agilent Technologies
• Four logic analyzer PODS
• FS1104 software from FuturePlus* Systems
Equivalent analyzers can be substituted. A FuturePlus* Systems* configuration file with the
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Debug Connectors and Logic Analyzer Connectivity
Table 23.
Logic Analyzer Pod 1
Mictor-38 #1 Pin Number Odd Pod Logic Analyzer Channel Number
PCI-X Name
6
CLKC/16
CLK
C/BE4
C/BE5
C/BE6
C/BE7
ACK64
REQ64
UNUSED
PME
8
15
14
13
12
11
10
9
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
8
7
C/BEO
M66EN
C/BE1
SERR
PAR
6
5
4
3
2
PERR
LOCK
STOP
1
0
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Debug Connectors and Logic Analyzer Connectivity
Table 24.
Logic Analyzer Pod 2
Mictor-38 #1 Pin Number Odd Pod Logic Analyzer Channel Number
PCI-X Signal Name
5
CLK/16
FRAME
DEVSEL
TRDY
7
15
14
13
12
11
10
9
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
C/BE2
C/BE3
IDSEL
REQ
GNT
8
INTD
7
INTC
6
INTB
5
INTA
4
UNUSED
UNUSED
UNUSED
UNUSED
UNUSED
3
2
1
0
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Debug Connectors and Logic Analyzer Connectivity
Table 25.
Logic Analyzer Pod 3
Mictor-38 #2 Pin Number Odd Pod Logic Analyzer Channel Number
PCI-X Signal Name
6
CLK/16
IRDY
AD15
AD14
AD13
AD12
AD11
AD10
AD09
AD08
AD07
AD06
AD05
AD04
AD03
AD02
AD01
AD00
8
15
14
13
12
11
10
9
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
8
7
6
5
4
3
2
1
0
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Debug Connectors and Logic Analyzer Connectivity
Table 26.
Logic Analyzer Pod 4
Mictor-38 #2 Pin Number Odd Pod Logic Analyzer Channel Number
PCI-X Signal Name
5
CLK/16
UNUSED
AD31
AD30
AD29
AD28
AD27
AD26
AD25
AD24
AD23
AD22
AD21
AD20
AD19
AD18
AD17
AD16
7
15
14
13
12
11
10
9
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
8
7
6
5
4
3
2
1
0
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Debug Connectors and Logic Analyzer Connectivity
Table 27.
Logic Analyzer Pod 5
Mictor-38 #3 Pin Number Odd Pod Logic Analyzer Channel Number
PCI-X Signal Name
6
CLK/16
PAR64
AD47
AD46
AD45
AD44
AD43
AD42
AD41
AD40
AD39
AD38
AD37
AD36
AD35
AD34
AD33
AD32
8
15
14
13
12
11
10
9
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
8
7
6
5
4
3
2
1
0
®
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Debug Connectors and Logic Analyzer Connectivity
Table 28.
Logic Analyzer Pod 6
Mictor-38 Pin Number Even Pod Logic Analyzer Channel Number
PCI-X Signal Name
5
CLK/16
Unused
AD63
AD62
AD60
AD59
AD58
AD57
AD56
AD55
AD54
AD53
AD52
AD51
AD50
AD49
AD48
AD48
7
15
14
13
12
11
10
9
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
8
7
6
5
4
3
2
1
0
The recommended placement of the Mictor connectors is at either end of the bus segment. The
Mictors are placed at the end of a stub that must be as short as possible, and are then daisy-chained
off either end of the bus. When there is not enough room to place the Mictors at least 0.5" from the
target, an alternate method can be used. This alternate method is to place the logic analyzer
termination circuitry on the target and then extend the etch from the end of the termination circuitry
over to the Mictor connectors. The connection from the Mictors to the logic analyzer must then be
made with the E5351A. The E5346A contains the logic analyzer termination circuitry, and the
E5351A does not.
§ §
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Thermal Solutions
Thermal Solutions
11
®
The Intel 31154 133 MHz PCI Bridge is packaged in a 421-lead PBGA package. The mechanical
Table 29.
Operational Power
Voltage
Maximum Power
3.3 V
1.3 V
2.5 W
0.7 W
§ §
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References
References
12
12.1
Related Documents
®
133 MHz PCI Bridge.
Table 30.
Design Reference Material
Design Reference Material
Brian C. Wadell, Transmission Line Design Handbook (Artech House, 1991)
K. C. Gupta, et al., Microstrip Lines and Slotlines (Artech House, 1996)
Moises Cases, Nam Pham, and Dan Neal, Design, Modeling and Simulation Methodology for High Frequency
PCI Local Bus Specification, Revision 2.3, (PCI Special Interest Group, 800-433-5177)
Howard W. Johnson and Martin Graham, High-Speed Digital Design: A Handbook of Black Magic (Prentice
Hall Professional Technical Reference, 1993)
PCI Bus Power Management Interface Specification, Revision 1.1 (PCI Special Interest Group)
Steve Kaufer and Kelee Crisafulli, “Terminating Differential Signals on PCBs” (Printed Circuit Design
magazine, March 1999)
®
®
®
PCI Bridge. This documentation can be found at the Intel website at
®
Table 31.
Intel Related Documentation
Document
Document Title
Number
Intel® 31154 133 MHz PCI Bridge Evaluation Board Schematics
Intel® 31154 133 MHz PCI Bridge Product Brief
Intel® 31154 133 MHz PCI Bridge Datasheet
Intel® 31154 133 MHz PCI Bridge Developer’s Manual
240800
278839
252974
278821
278848
§ §
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