Intel® 41110 Serial to Parallel PCI
Bridge
Design Guide
March 2006
Order Number: 310335-001
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Contents
Contents
About This Document ...................................................................................................................7
1.1 Terminology and Definitions .................................................................................................7
Introduction....................................................................................................................................9
PCI Express Interface Features............................................................................................9
PCI-X Interface Features......................................................................................................9
SMBus Interface .................................................................................................................10
JTAG...................................................................................................................................12
Intel® 41110 Serial to Parallel PCI Bridge Applications .....................................................13
Package Information ...................................................................................................................15
3.1 Package Specification ........................................................................................................15
Power Plane Layout ....................................................................................................................17
41110 Decoupling Guidelines.............................................................................................17
41110 Reset and Power Timing Considerations.......................................................................21
A_RST# and PERST# Timing Requirements.....................................................................21
VCC15 and VCC33 Voltage Requirements........................................................................21
General Routing Guidelines .......................................................................................................23
General Routing Guidelines................................................................................................23
Crosstalk.............................................................................................................................23
Power Distribution and Decoupling.....................................................................................25
Trace Impedance................................................................................................................25
Board Layout Guidelines............................................................................................................27
7.1 Adapter Card Topology.......................................................................................................27
PCI-X Layout Guidelines.............................................................................................................29
Interrupts.............................................................................................................................29
PCI Arbitration ....................................................................................................................30
PCI General Layout Guidelines ..........................................................................................31
PCI Clock Layout Guidelines..............................................................................................32
PCI-X Topology Layout Guidelines.....................................................................................35
41110 Layout Analysis........................................................................................................35
PCI Express Layout.....................................................................................................................41
General recommendations .................................................................................................41
PCI-Express Layout Guidelines..........................................................................................42
Circuit Implementations..............................................................................................................45
10.1 41110 Analog Voltage Filters..............................................................................................45
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10.2 41110 Reference and Compensation Pins.........................................................................48
41110 Customer Reference Boards...........................................................................................51
11.1 Board Stack-up...................................................................................................................51
11.2 Material...............................................................................................................................52
11.3 Impedance..........................................................................................................................52
11.4 Board Outline......................................................................................................................53
Design Guide Checklist ..............................................................................................................55
Figures
Microcontroller Block Diagram....................................................................................................11
41110 Microcontroller Connections............................................................................................12
41110 Block Diagram .................................................................................................................13
41110 Adapter Card Block Diagram...........................................................................................14
41110 Bridge Package Dimensions (Top View).........................................................................15
41110 Bridge Package Dimensions (Side View)........................................................................16
Decoupling Placement for Core and PCI Express Voltage Planes ............................................17
Decoupling Placement for PCI/PCI-X 1.5V and 3.3V Voltage Planes........................................18
41110 Bridge Single-Layer Split Voltage Plane..........................................................................20
10 Crosstalk Effects on Trace Distance and Height ........................................................................24
11 PCB Ground Layout Around Connectors ...................................................................................24
12 Cross Section of Differential Trace.............................................................................................26
13 Two-by-two Differential Impedance Matrix .................................................................................26
14 Adapter Card Stackup ................................................................................................................28
15 PCI RCOMP ...............................................................................................................................31
16 PCI Clock Distribution and Matching Requirements...................................................................33
17 Embedded PCI-X 133 MHz Topology ........................................................................................36
18 Embedded PCI-X 100 MHz Topology ........................................................................................37
19 PCI-X 66 MHz Embedded Routing Topology.............................................................................38
20 PCI 66 MHz Embedded Topology..............................................................................................39
21 PCI 33 MHz Embedded Mode Routing Topology.......................................................................40
22 PCI Analog Voltage Filter Circuit................................................................................................46
23 PCI Express Analog Voltage Filter Circuit..................................................................................47
24 Bandgap Analog Voltage Filter Circuit........................................................................................48
25 Reference and Compensation Circuit Implementations .............................................................49
26 Mechanical Outline of the 41110................................................................................................53
Tables
Terminology and Definitions.........................................................................................................7
41110 Decoupling Guidelines.....................................................................................................19
Adapter Card Stack Up, Microstrip and Stripline ........................................................................27
INTx Routing Table.....................................................................................................................29
Interrupt Binding for Devices Behind a Bridge...........................................................................30
PCI-X Signals .............................................................................................................................32
PCI/PCI-X Frequency/Mode Straps............................................................................................32
PCI-X Clock Layout Requirements Summary ............................................................................34
PCI-X Slot Guidelines.................................................................................................................35
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Contents
10 Embedded PCI-X 133 MHz Routing Recommendations............................................................36
11 Embedded PCI-X 100 MHz Routing Recommendations............................................................37
12 PCI-X 66 MHz Embedded Routing Recommendations..............................................................38
13 PCI 66 MHz Embedded Table....................................................................................................39
14 PCI 33 MHz Embedded Routing Recommendations..................................................................40
15 Adapter Card Routing Recommendations..................................................................................42
16 Recommended R, L and C Values for 41110 Analog Filter Circuits...........................................45
17 SMBUs Address Configuration...................................................................................................49
18 CRB Board Stackup....................................................................................................................51
19 PCI Express Interface Signals....................................................................................................55
20 PCI/PCI-X Interface Signals .......................................................................................................56
21 Miscellaneous Signals ................................................................................................................57
22 SMBus Interface Signals ............................................................................................................58
23 Reset Pins ..................................................................................................................................59
24 Power and Ground Signals.........................................................................................................60
25 JTAG Signals..............................................................................................................................61
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Contents
Revision History
Date
Revision
Description
March 2006
001
Initial release.
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About This Document
1
This document provides layout information and guidelines for designing platform or add-in board
applications with the Intel® 41110 Serial to Parallel PCI Bridge (also called the 41110 Bridge). It is
recommended that this document be used as a guideline. Intel recommends employing best-known
design practices with board level simulation, signal integrity testing and validation for a robust
design.
Designers should note that this guide focuses upon specific design considerations for the 41110
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 provides a list of terms and definitions that may be useful when working with the 41110
Bridge product.
Table 1. Terminology and Definitions (Sheet 1 of 2)
Term
Definition
Stripline in a PCB is composed of the
conductor inserted in a dielectric with GND
planes to the top and bottom.
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
Microstrip
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
Material 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.
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About This Document
Table 1. Terminology and Definitions (Sheet 2 of 2)
Term
Definition
Printed circuit board.
Layer 1: copper
Prepreg
Example manufacturing process consists of
the following steps:
Layer 2: GND
•
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: VCC15
Prepreg
Layer 4: copper
Plating covers holes and outer surfaces
Etching removes unwanted copper
Board is tinned, coated with solder mask
and silk screened
Example of a Four-Layer Stack
SSTL_2
JEDEC
Series Stub Terminated Logic for 2.5 V
Provides standards for the semiconductor industry.
A network that transmits a coupled signal to another network is aggressor network.
Zo
Zo
Aggressor
Zo
Zo
Victim Network
Aggressor Network
Victim
Network
Stub
A network that receives a coupled cross-talk signal from another network is a victim network.
The trace of a PCB that completes an electrical connection between two or more components.
Branch from a trunk terminating at the pad of an agent.
CRB
Customer Reference Board
Downstream refers either to the relative position of an interconnect/system element (Link/
Downstream device) as something that is farther from the Root Complex, or to a direction of information
flow, i.e., when information is flowing away from the Root Complex.
Upstream
®
Memory subsystem on the Intel XScale processor DDR SDRAM or Peripheral Bus Interface
Local memory
busses.
DWORD
32-bit data word.
FC-BGA (flip chip-ball grid array) chip packages are designed with processor core flipped up
on the back of the chip, facing away from the PCB. This allows more efficient cooling of the
package.
Flip Chip
Mode
Conversion
Mode Conversions are due to imperfections on the interconnect which transform differential
mode voltage to common mode voltage and common mode voltage to differential voltage.
PCI-E
PCI-Express
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Introduction
2
The Intel® 41110 Serial to Parallel PCI Bridge integrates a PCI Express-to-PCI bridge. The bridge
follows the PCI-to-PCI Bridge programming model. The PCI Express port is compliant to the PCI
Express Specification, Revision 1.0. The PCI bus interface is fully compliant to the PCI Local Bus
Specification, Revision 2.3.
2.1
PCI Express Interface Features
• PCI Express Specification, Revision 1.0b compliant.
• Support for single x8, single x4 or single x1 PCI Express operation.
• 64-bit addressing support.
• 32-bit CRC (cyclic redundancy checking) covering all transmitted data packets.
• 16-bit CRC on all link message information.
• Raw bit-rate on the data pins of 2.5 Gbit/s, resulting in a raw bandwidth per pin of 250 MB/s.
• Maximum realized bandwidth on PCI Express interface is 2 GB/s (in x8 mode) in each
direction simultaneously, for an aggregate of 4 GB/s.
2.2
PCI-X Interface Features
• PCI Local Bus Specification, Revision 2.3 compliant.
• PCI-to-PCI Bridge Specification, Revision 1.1 compliant.
• PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a compliant.
• 64-bit 66 MHz, 3.3 V, NOT 5 V tolerant.
• On Die Termination (ODT) with 8.2KΩ pull-up to 3.3V for PCI signals.
• Six external REQ/GNT Pairs for internal arbiter on the PCIX bus segment respectively.
• Programmable bus parking on either the last agent or always on Intel® 41110 Serial to Parallel
PCI Bridge.
• 2-level programmable round-robin internal arbiter with Multi-Transaction Timer (MTT)
• External PCI clock-feed support for asynchronous primary and secondary domain operation.
• 64-bit addressing for upstream and downstream transactions
• Downstream LOCK# support.
• No upstream LOCK# support.
• PCI fast Back-to-Back capable as target.
• Up to four active and four pending upstream memory read transactions
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Introduction
• Up to two downstream delayed (memory read, I/O read/write and configuration read/write)
transaction.
• Tunable inbound read prefetch algorithm for PCI MRM/MRL commands
• Local initialization via SMBus
• Secondary side initialization via Type 0 configuration cycles.
2.3
Power Management
• Support for PCI Express Active State Power Management (ASPM) L0s link state
• Support for PCI PM 1.1 compatible D0, D3hot and D3cold device power states
• Support for PME# event propagation on behalf of PCI devices
2.4
SMBus Interface
• Compatible with System Management Bus Specification, Revision 2.0
• Slave mode operation only.
• Full read/write access to all configuration registers
2.4.1
SMBus for configuration register initialization
• Support for local initialization of the configuration registers can be implemented using a
the 41110 and the microcontroller.
• Configuration Register information is stored internally in a microcontroller and the
information is transferred to the product via System Managed Bus (SMBus) protocols when
the device receives power or reset.
• The requirements of the microcontroller are as follows:
— Supports I2C and SMBus Protocols
— Has at least 256 Byte of internal EEprom space
— To facilitate this programming on the Customer Reference Board a Microchip part
PIC16F876A was used.
— Code space: estimated code size is ~2K words of program space and 32 words of RAM
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Introduction
Figure 1. Microcontroller Block Diagram
Serial to Parallel
PCI Bridge
2.4.2
Microcontroller Connections to the 41110
Figure 2 shows the SMB interface from the 41110 to the microcontroller.
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Introduction
Figure 2. 41110 Microcontroller Connections
Serial to
Parallel PCI
Bridge
2.5
2.6
JTAG
• Compliant with IEEE Standard Test Access Port and Boundary Scan Architecture 1149.1a
Related Documents
• .
• PCI Express Design Guide, Revision 0.5
• IEEE Standard Test Access Port and Boundary Scan Architecture 1149.1a
• System Management Bus Specification, Revision 2.0
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Introduction
Figure 3. 41110 Block Diagram
Serial to Parallel
PCI Bridge
2.7
Intel® 41110 Serial to Parallel PCI Bridge
Applications
This section provides a block diagram for a typical the 41110 application. This application shows a
PCI-E adapter card with two Dual 2Gb Fibre Channel controllers. Each of the PCI-X bus segments
is connected to the Dual 2Gb Fibre Channel chip running at 133MHz. The two Dual FC chips
provides the four 2Gb/s outputs.
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Package Information
3
3.1
Package Specification
The 41110 Bridge is in a 567-ball FCBGA package, 31mm X 31mm in size, with a 1.27mm ball
Figure 5.
41110 Bridge Package Dimensions (Top View)
Die
Keepout
Area
Handling
Exclusion
Area
0. 491in.
0. 291in.
0. 247in.
17. 00mm 21. 00mm 31. 00mm
0. 547in.
0. 200in.
17. 00mm
21. 00mm
31. 00mm
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Package Information
Figure 6.
41110 Bridge Package Dimensions (Side View)
0.84±0.05 mm
Substrate
2.445±0.102 mm
2.010±0.099 mm
Decoup
Cap
Die
0.7 mm Max
0.20
See Note 4.
-C-
0.20
Seating Plane
0.435±0.025 mm
See Note 3
See Note 1
Notes:
1. Primary datum -C- and seating plan are defined by the spherical crowns of the solder balls (shown before motherboard attach).
2. All dimensions and tolerances conform to ANSI Y14.5M-1994
3. BGA has a pre-SMT height of 0.5 mmand post-SMT height of 0.41-0.46 mm
4. Shown before motherboard attach; FCBGA has a convex (dome shape) orientation before reflow and is expected to have a slightly
concave (bowl shaped) orientation after reflow.
Note:
Note:
Primary datum -C- and seating plane are defined by the spherical crowns of the solder balls.
All dimensions and tolerances conform to ANSI Y14.5M-1982
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Power Plane Layout
4
This chapter provides details on the decoupling and voltage planes needed to bias the 41110
package.
4.1
41110 Decoupling Guidelines
capacitors around the 41110 ball grid pins.
Figure 7. Decoupling Placement for Core and PCI Express Voltage Planes
B2713-01
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Power Plane Layout
Table 2. 41110 Decoupling Guidelines
41110
Bridge
Pins
C
(uF)
ESR
(mΩ) (nH)
ESL
# of
Caps
Voltage Plane
Voltage
Package
Location
PCI/PCI-X
Voltage
50-
300
1.0-
3.0
Beneath 41110
Bridge BGA
3.3V
3.3V
VCC33
VCC33
0.1
1.0
0603
0603
5
As close as design
rules will allow to
41110 Bridge BGA
PCI/PCI-X
Voltage
50-
300
1.0-
3.0
2
As close as design
rules will allow to
41110 Bridge BGA
PCI/PCI-X
Voltage
50-
300
1.0-
3.0
3.3V
1.5V
1.5V
VCC33
VCC15
VCC15
10
0.1
1.0
1206
0603
0805
3
5
5
Beneath 41110
Bridge BGA
Core Voltage
Core Voltage
200
200
2.0
2.3
As close as design
rules will allow to
41110 BridgeBGA
As close as design
rules will allow to
41110 Bridge BGA
Core Voltage
1.5V
1.5V
1.5V
VCC15
VCCPE
VCCPE
10
0.1
1
1206
0603
0805
200
200
200
1.9
2.0
2.3
2
3
4
PCI Express
Voltage
Beneath41110
Bridge BGA
As close as design
rules will allow to
41110 Bridge BGA
PCI Express
Voltage
As close as design
rules will allow to
41110 Bridge BGA
PCI Express
Voltage
1.5V
VCCPE
10
1206
200
1.9
2
4.2
Split Voltage Planes
There are two 1.5V voltage planes that supply power to the 41110:
• VCC15:1.5V ±5% (1.5V core voltage)
• VCCPE:1.5V ±3% (1.5V PCI Express voltage)
The 41110 Bridge core (VCC15), PCI-Express (VCCPE) voltages should be supplied by two
separate voltage regulators or a single regulator. If VCC15 and VCCPE is supplied by a single
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Power Plane Layout
Note: Linear voltage regulators are recommended when using 1.5 Volt power supplies.
Figure 9. 41110 Bridge Single-Layer Split Voltage Plane
Core
PCI
Express
B2715-01
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41110 Reset and Power Timing
Considerations
5
This chapter describes the 41110 reset timing considerations.
5.1
5.2
A_RST# and PERST# Timing Requirements
The PCI-X Specification requires that there is a 100ms delay from valid power (PERST#) to reset
deassertion (A_RST#). 41110 will keep A_RST# asserted for a minimum of 320ms after PERST#
is deasserted.
VCC15 and VCC33 Voltage Requirements
The following steps are the power sequencing requirements that must be followed with the
41110:
1. The 41110 requires that the VCC33 voltage rail be no less than 0.5V below VCC15 (absolute
voltage value) at all times during 41110 operation, including during system power up and
power down. In other words, the following must always be true:
VCC33 >= (VCC15 – 0.5V)
This can be accomplished by placing a diode (with a voltage drop <0.5V) between VCC15 and
VCC33. A node will be connected to VCC15 and cathode will be connected to VCC33.
If VCC15 (1.5V PCI-X I/O voltage) and VCC15 (1.5V core voltage) are tied together on the
platform, then both voltages must meet the above rule.
Note: Linear voltage regulators are recommended when using 1.5 Volt power supplies.
2. If a voltage regulator solution is used which shunts VCC15 to ground while VCC33 is
powered, the maximum allowable time that VCC15 can be shunted to ground while VCC33 is
fully powered is 20ms.
3. The maximum allowed time between VCC33 and VCC15 ramping is 525ms.
Note: There is no minimum sequencing time requirement other than requirements in Steps 2 and 3.
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General Routing Guidelines
6
This chapter provides some basic routing guidelines for layout and design of a printed circuit board
using the 41110. The high-speed clocking required when designing with the 41110 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 41110
design. These factors include:
• power distribution
• minimizing crosstalk
• decoupling
• layout considerations when routing the PCI Express bus and PCI-X bus interfaces
6.1
6.2
General Routing Guidelines
This section details general routing guidelines for designing with the 41110. 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.
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
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 Parasitic Parameters from ANSOFT* and XFS from Quad
Design*. Crosstalk problems occur when circuit etch lines run in parallel. When board analysis
software is not available, the layout should be designed to maintain at least the minimum
recommended spacing for bus interfaces.
• A general guideline to use is, that space distance between adjacent signals 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 to specify the height of the above reference plane when laying out
traces and 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.
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General Routing Guidelines
Figure 10. Crosstalk Effects on Trace Distance and Height
Reduce Crosstalk:
- Maximize P
P
H
aggressor
victim
Reference Plane
- Minimize H
A9259-01
• Avoid slots in the ground plane. Slots increases mutual inductance thus increasing crosstalk.
• Make sure that ground plane surrounding connector pin fields are not completely cleared out.
When this area is completely cleared out, around the connector pins, all the return current must
flow together around the pin field increasing crosstalk. The preferred method of laying out a
Figure 11. PCB Ground Layout Around Connectors
Connector
Connector Pins
GND PCB Layer
A. Incorrect method
B. Correct method
A9260-01
6.3
EMI Considerations
It is highly recommended that good EMI design practices be followed when designing with the
41110.
• To minimize EMI on your PCB a useful technique is to not 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 below link can provide some useful general EMI guidelines considerations:
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General Routing Guidelines
6.4
Power Distribution and Decoupling
Have ample decoupling to ground, for the power planes, to minimize the effects of the switching
currents. Three types of decoupling are: the bulk, the high-frequency ceramic, and the inter-plane
capacitors.
• Bulk capacitance 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. The bulk capacitors can be located anywhere on the board.
• 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 minimizes the
parasitic resistance and inductance associated with board traces and vias.
• 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.
6.4.1
Decoupling
Inadequate high-frequency decoupling results in intermittent and unreliable behavior.
A general guideline recommends that you use the largest easily available capacitor in the lowest
inductance package. For specific decoupling requirements for a 41110 application please refer to
6.5
Trace Impedance
All signal layers require controlled impedance 60 Ω +/- 15%, microstrip or stripline for 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. Use wider spaces between traces, since
this can minimize trace-to-trace coupling, and reduce cross talk.
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. The
following Impedance Calculator URL provide approximations for the trace impedance of various
topologies. They may be used to generate the starting point for a full 2D Field solver.
The following website link provides a useful basic guideline for calculating trace parameters:
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General Routing Guidelines
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 cross-talk.
6.5.1
Differential Impedance
The PCI Express standard defines a 100 Ω differential impedance. This section provides some basic
background information on the differential impedance calculations. In the cross section of
Figure 12 shows the cross section of two traces of a differential pair.
Figure 12. Cross Section of Differential Trace
Ground reference plane
B2716 -01
To calculate the coupled impedance requires a 2x2 matrix. The diagonal values in the matrix
represent the impedance of the traces to ground and the off-diagonal values provide a measure of
how tightly the traces are coupled. The “differential impedance is the value of the line-to-line
resistor terminator that optimally terminates pure differential signals.” The two by two matrix is
shown below as:
Figure 13. Two-by-two Differential Impedance Matrix
Z11 Z12
Zo =
Z21 Z22
B2717 -01
For a symmetric trace Z11 = Z22, the differential impedance can be calculated from this equation:
Z
differential = 2(Z11-Z12)
For two traces to be symmetric, they must have the same width, thickness and height above the
ground plane.1 With the traces terminated with the appropriate differential, impedance ringing is
minimized.
1. “Terminating Differential Signals on PCBs”, Steve Kaufer and Kelee Crisafulli, Printed Circuit Design, March 1999
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Board Layout Guidelines
7
This chapter provides details on adapter card stackup suggestions. It is highly recommended that
signal integrity simulations be run to verify each 41110 PCB layout especially if it deviates from
the recommendations listed in these design guidelines.
7.1
Adapter Card Topology
The 41110 will be implemented on PCI-E adapter cards with an eight layer stackup PCB. The
specified impedance range for all adapter card implementations will be 60Ω +/-15%. Adjustments
geometries for eight layer boards.
Table 3.
Adapter Card Stack Up, Microstrip and Stripline
Nominal Minimum Maximum
Variable
Type
Notes
(mils)
(mils)
(mils)
Solder Mask Thickness (mil)
N/A
N/A
N/A
N/A
0.8
0.6
1.0
Solder Mask E
3.65
2.8
3.65
3.0
3.65
3.2
r
Core Thickness (mil)
Core E
4.3
3.75
4.85
2113 material
r
Power
2.7
1.35
3.5
2.5
1.15
3.3
2.9
1.55
3.7
Plane Thickness (mil)
Ground
1
The trace height will be determined to
achieve a nominal 60 Ω.
Trace Height (mil)
2
3.5
3.3
3.7
3
10.5
4.30
4.30
9.9
11.1
4.85
4.85
Microstrip
Stripline1
3.75
3.75
2113 material
2113 material
Preg E
r
7628 material. Trace height 3 is composed
of one piece of 2113 and one piece of
7628.
Stripline2
4.3
3.75
4.85
Microstrip
Stripline
1.75
1.4
1.2
1.2
2.3
1.6
Trace Thickness (mil)
Trace Width (mil)
Microstrip
Stripline
FR4
4.0
4.0
2.5
2.5
5.5
5.5
Total Thickness (mil)
62.0
56.0
68.0
Trace Spacing (using
microstrip E2E/C2C)
[12]/[16]
[12]/[16]
Trace Spacing (using
stripline E2E/C2C)
Microstrip
Stripline
60
60
51
51
69
69
Trace Impedance
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Note: Each interface will set the trace spacing based on its signal integrity of differential impedance
requirements. For the purposes of the building the transmission line models, it is assumed the
artwork is very accurate and therefore a constant. All the variability in the trace spacing is the result
of the tolerances of the trace width.
Figure 14. Adapter Card Stackup
Microstrip
Trace
Width
Microstrip
Trace
Spacing
Microstrip Trace Thickness
Solder Mask Thickness
L1
L1
Trace Height 1
L2 (GND)
Trace Height 2
Stripline Trace Thickness
L3
L3
Trace Height 3
L4 (VCC)
L5 (VCC)
Core Thickness
Plane Thickness
L4
L4
L7 (GND)
L8
Stripline
Trace
Stripline
Trace
Width
Spacing
B1436-01
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PCI-X Layout Guidelines
8
This chapter describes several factors to be considered with a 41110 PCI/PCI-X design. These
include the PCI IDSEL, PCI RCOMP, PCI Interrupts and PCI arbitration.
8.1
Interrupts
PCI Express provides interrupt messages that emulate the legacy wired mechanism. This allows IO
devices to signal PCI-style interrupts using a pair of ASSERT and DEASSERT messages This
message pairing preserves the level-sensitive semantics of the PCI interrupts on PCI Express.
The 41110 uses four interrupts - A_INTA:A_INTD on bus A segment corresponding to the four
interrupts defined in the PCI specification. The 41110 routes its PCI interrupt pins and the internal
Table 4. INTx Routing Table
A_INT# Interrupt Pins
PCI Express INTx Message
INTA
A_INTA
A_INTB
A_INTC
A_INTD
INTB
INTC
INTD
The 41110 will use its primary bus number and device number in the Requester ID field for the PCI
Express INTx messages. As stated in the PCI Express specification, the function number is
reserved for interrupt messages and will always be 0.
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Note: PCI Express Assert_INTx/Deassert_INTx messages are not inhibited by the BME bit.
8.1.1
Interrupt Routing for Devices Behind a Bridge
performance (by reducing interrupt sharing), adapter boards have to select the appropriate
A_INTX# (where X is A, B, C or D) input pin to use on the PCI bus segment. The chosen interrupt
input also imposes a PCI device number requirement for the interrupt source as specified in the
Table 5. Interrupt Binding for Devices Behind a Bridge
Device Number on
Interrupt Pin on Device
Secondary Bus
Interrupt on 41110 Bridge
INTA#
INTA#
INTB#
INTB#
INTC#
INTD#
INTB#
INTC#
INTD#
INTA#
INTC#
INTD#
INTA#
INTB#
INTD#
INTA#
INTB#
INTC#
a
b
- . 4, 8 , 12, 16, 20, 24, 28
INTC#
INTD#
INTA#
INTB#
INTC#
INTD#
INTA#
INTB#
INTC#
INTD#
INTA#
INTB#
INTC#
INTD#
b
1, 5, 9 , 13, 17, 21, 25, 29
b
2, 6, 10 , 14, 18, 22, 26, 30
b
3, 7, 11 , 15, 19, 23, 27, 31
a.
b.
Device number 0 is reserved for the Bridge and should not be assigned to secondary devices.
AD[27:24] which correspond to devices 11:8 should not be used for IDSEL# connections as these signals are used
when accessing the extended configuration space in the bridge from the secondary bus.
8.2
PCI Arbitration
The 41110 supports a high-performance internal PCI arbiter that supports up to seven masters on
each PCI segment A and B PCI Buses. The request inputs into the internal arbiter include: six
external request inputs and 1 internal request input. All request inputs to the internal arbiter are
split into two groups, a high priority group and a low priority group. Any master, including the
internal master, can be programmed to be in either of the two groups. This could also mean that all
the request inputs into the arbiter could be in one single group. Within a group, priority is round-
robin. The entire low-priority group represents one slot in the high priority group. The 41110
provides a 16-bit arbiter control register to control two aspects of the internal arbiter behavior:
• Priority group for a master (i.e., whether a master is in low priority group or high priority
group).
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PCI-X Layout Guidelines
• Bus parking on last PCI agent or the bridge.
By default, the arbiter parks the bus on the bridge and drives the A/D, C/BE# and PAR lines to a
known value while the bus is idle.
8.2.1
PCI Resistor Compensation
Figure 15 provides the recommended resistor compensation pin termination for the PCI A bus.
Figure 15. PCI RCOMP
RCOMP
100
Ω
– 1%
B2718 -01
8.3
PCI General Layout Guidelines
For acceptable signal integrity with bus speeds up to 133 MHz it is important to PCB design layout
to have controlled impedance.
• Signal traces should have an unloaded impedance of 60 +/- 10% Ω.
• Signal trace velocity should be roughly 150 – 190 ps/inch
There are a couple of general guidelines which should be used when routing your PCI bus signals:
• Avoid routing signals > 8”.
• The following signals have no length restrictions: A_INTA#, A_INTB#, A_INTC#,
A_INTD#, and TCK, TDI, TDO, TMS and TRST#. Most PCI-X signals are timing critical.
These signals have length restrictions for propagation, setup, and hold requirements. Table 6
shows the PCI-X signals.
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PCI-X Layout Guidelines
Table 6. PCI-X Signals
A PCI Bus Segment:
A_ACK64#, A_AD[63:0], A_CBE_[7:0]#, A_DEVSEL#, A_FRAME#,
A_GNT_[5:0]#, A_IRDY#, A_LOCK#, A_PAR64, A_REQ64#, A_REQ_[5:0]#,
A_STOP#, A_TRDY#, A_CLKO[6:0], A_CLKI
Timing Critical Signals
A PCI Bus Segment:
A_RST#, A_PME#
Reset Signals
A PCI Bus Segment:
Non Timing Critical
Signals
A_133EN, A_IRQ[15:0]#, A_M66EN, A_PCIXCAP, A_PERR#, A_SERR#
Table 7. PCI/PCI-X Frequency/Mode Straps
Bus
Mode/
Freq
A_PCIXCAP
A_M66EN
A_133EN(on
board)
0
0
0
1
X
X
PCI 33
PCI 66
PCI-X 66MHz cards connect this
signal to ground through a 10KΩ
±5% resistor in parallel with a
0.01uF ±10% capacitor.
X
X
PCI-X 66
PCI-X 133 MHz cards connect
PCIXCAP to ground through a
0.01uF ±10% capacitor.
X
X
0
1
PCI-X 100
PCI-X 133
PCI-X 133 MHz cards connect
PCIXCAP to ground through a
0.01uF ±10% capacitor.
Note: All signals sampled on the rising edge of PERST#.
8.3.1
PCI Pullup Resistors Not Required
PCI control signals on the 41110 do NOT require pullup resistors on the adapter card to ensure that
they contain stable values when no agent is actively driving the bus. These include:
A_ACK64#, A_AD[63:32], A_CBE#[7:4], A_DEVSEL#, A_FRAME#, A_INTA#, A_INTB#,
A_INTC#, A_INTD#, A_IRDY#, A_PERR#, A_PAR, A_GNT#[5:0], A_REQ#[5:0], A_LOCK#,
A_PAR64, A_REQ64#, A_SERR#, A_STOP#, and A_TRDY#
8.4
PCI Clock Layout Guidelines
The PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a compliant, allows a
maximum of 0.5 ns clock skew timing for each of the PCI-X frequencies: 66 MHz, 100 MHz and
133 MHz. A typical PCI-X application may require separate clock point-to-point connections
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distributed to each PCI device. The 41110 provides seven buffered clocks on the PCI bus to connect
matching requirements. . The recommended clock buffer layout are specified as follows:
• Match each of the used the 41110 output clock lengths A_CLK[6:0] to within 0.1”to help keep
the timing within the 0.5 ns maximum budget.
• Keep the distance between the clock lines and other signals “d” at least 25 mils from each other.
• Keep the distance between the clock line and itself “a” at a minimum of 25 mils apart (for
serpentine clock layout).
• A_CLKIN gets connected to A_CLKO6 through a 22Ω +/- 1% resistor The 22 +/- 1% Ω
resistor is within 500 mils of A_CLKO.
Figure 16.
PCI Clock Distribution and Matching Requirements
Serial to
Parallel PCI
Bridge
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Table 8.
PCI-X Clock Layout Requirements Summary
Parameter
Routing Guidelines
PCI Clocks A_CLK[6:0]
Signal Group
Reference Plane
Route over unbroken ground or power plane
4 mils
Stripline Trace Width
Stripline Trace Spacing: Separation between two
different clock lines, “d” clock lines
25 mils center to center from any other signal
25 mils center to center from any other signal
50 mils center to center from any other signal
Stripline Trace Spacing: Separation between two
segments of the same clock line (on serpentine
layout), “a” dimension
Stripline Trace Spacing: Separation between clocks
and other lines
All 41110 Output Clocks A_CLK[6:0] connected to
devices must be length matched to 0.1 inch of each
other.
Length Matching Requirements
The clock feedback line lengths from A_CLKOUT to
A_CLKIN should be length matched to all other clock
lines within 0.1”.
Total Length of the 41110 PCI CLKs on the adapter
card
10” -14”
Connect A_CLKIN to one end of a 22Ω +/- 1% resistor
A_CLKIN Series Termination
A_CLK[6:0] Series Termination
and the other end connected to A_CLKOUT
Each of the clock outputs A_CLKO[6:0] should have
series 22Ω resistor located within 500 mils of the
41110 clock output.
Point to point signal routing should be used to keep
the reflections low.
Routing Guideline 1
Routing Guideline 2
Minimize number of vias
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PCI-X Layout Guidelines
8.5
PCI-X Topology Layout Guidelines
The PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a compliant, recommends
the following guidelines for the number of loads for your PCI-X designs. Any deviation from these
maximum values requires close attention to layout with regard to loading and trace lengths.
Table 9.
PCI-X Slot Guidelines
Frequency
Maximum Loads
Maximum Number of Slots
66 MHz
100 MHz
133 MHz
8
4
2
4
2
1
8.6
41110 Layout Analysis
The following sections describes layout recommendations based on the signal integrity analysis.
This analysis was conducted using the following parameters:
• Card stack up: 60 Ω +/- 15% single-ended impedance
• Driver Model 41110 IBIS
• Receiver Model: generic models for PCI-X and PCI
• Driver Package Model: 41110 Model
• Cross talk and ISI impact on timing were not modeled
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8.6.1
Embedded PCI-X 133 MHz
Figure 17. Embedded PCI-X 133 MHz Topology
EM1
TL1
EM2
B2719 -01
Table 10.
Embedded PCI-X 133 MHz Routing Recommendations
Parameter
Reference Plane
Routing Guideline for Lower AD Bus
Route over an unbroken ground plane
60 Ω +/- 15%
Board Impedance
Stripline Trace Spacing
Microstrip Trace Spacing
Break Out
12 mils from edge to edge
18 mils, from edge to edge
5 mils on 5 mils spacing. Maximum length of breakout region can be 500 mils
Spacing from other groups: 25 mils min, edge to edge
Group Spacing
Trace Length 1 (TL1): From
41110 signal Ball to first
junction
1.75” min - 4.0” max
Trace Length 3 junction of
TL_EM1 and TL_EM2 to the 1.25” min - 3.25” max
embedded device
Length Matching
Requirements:
Clocks coming form the clock driver must be on the same layer and length
matched to within 25 mils.
Number of vias
3 vias max per path
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8.6.2
Embedded PCI-X 100 MHz
Figure 18. Embedded PCI-X 100 MHz Topology
TL_EM1
EM1
TL_EM3
TL_EM2
EM3
EM2
TL1
B2720 -01
Table 11.
Embedded PCI-X 100 MHz Routing Recommendations
Parameter
Reference Plane
Routing Guideline for Lower AD Bus
Route over an unbroken ground plane
Board Impedance
Stripline Trace Spacing
Microstrip Trace Spacing
Break Out
60 Ω +/- 15%
12 mils from edge to edge
18 mils, from edge to edge
5 mils on 5 mils spacing. Maximum length of breakout region can be 500 mils
Spacing from other groups: 25 mils min, edge to edge
Group Spacing
Trace Length 1 (TL1): From
41110 signal Ball to first
junction
0.5” min - 3.0” max
2.5” min - 3.5” max
Trace Length: TL_EM1: from
41110 signal ball to the first
embedded device
Trace Length TL_EM2 -
TL_EM3: from junction to the 1.5” min - 3.5” max
embedded device
Length Matching
Requirements:
Clocks coming form the clock driver must be on the same layer and length
matched to within 25 mils.
Number of vias
4 vias max per path
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8.6.3
PCI-X 66 MHz Embedded Topology
application.
Figure 19.
PCI-X 66 MHz Embedded Routing Topology
EM1
EM3
EM5
EM7
TL1
TL2
TL3
TL4
EM2
EM4
EM6
EM8
B2721 -01
Table 12.
PCI-X 66 MHz Embedded Routing Recommendations
Parameter
Reference Plane
Routing Guideline for Lower AD Bus
Route over an unbroken ground plane
Board Impedance
Stripline Trace Spacing
Microstrip Trace Spacing
Break Out
60 Ω +/- 15%
12 mils edge to edge
18 mils, edge to edge
5 mils on 5 mils. Maximum length of breakout region can be 500 mils
Spacing from other groups: 25 mils min, edge to edge
Group Spacing
Trace Length 1 (TL1): From
41110 signal Ball to first
junction
1.0” - 5.0” max
Trace Length TL2 to TL4 -
between junctions
1.0” min - 2.5” max
Trace Length TL_EM1 to
TL_EM8 from junction
connector to the embedded
device
2.0” min - 3.0” max
Length Matching
Requirements:
Clocks coming form the clock driver must be length matched to within 25 mils
and routed identical in layers.
Number of vias
4 vias max.
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8.6.4
PCI 66 MHz Embedded Topology
design.
Figure 20. PCI 66 MHz Embedded Topology
EM1
EM3
TL1
TL2
EM2
EM4
B2722 -01
Table 13.
PCI 66 MHz Embedded Table
Parameter
Routing Guideline for Lower AD Bus
Reference Plane
Route over an unbroken ground plane
60 Ω +/- 15%
Board Impedance
Microstrip Trace Spacing
Stripline Trace Spacing
Group Spacing
18 mils center to center
12 mils center to center
Spacing from other groups: 25 mils min, edge to edge
5 mils on 5 mils spacing. Maximum length of breakout
region can be 500 mils.
Breakout
Trace Length 1 TL1: From 41110 signal Ball to first
junction
5.0” max
Trace Length TL2 between junctions
0.5” min - 3.5” max
2.0” min - 3.0” max
Trace Length TL_EM1 to TL_EM4 from junction to
embedded devices
Clocks coming from the clock driver must be length
matched to within 25 mils.
Length Matching Requirements
Number of vias
4 vias max.
P
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8.6.5
PCI 33 MHz Embedded Mode Topology
design.
Figure 21. PCI 33 MHz Embedded Mode Routing Topology
EM1
EM3
EM5
EM7
EM9
TL1
TL2
TL3
TL4
TL5
EM2
EM4
EM6
EM8
EM10
B2723 -01
Table 14.
PCI 33 MHz Embedded Routing Recommendations
Parameter
Reference Plane
Routing Guideline for Lower AD Bus
Route over an unbroken ground plane
Board Impedance
Stripline Trace Spacing
Microstrip Trace Spacing
Group Spacing
60 Ω +/- 15%
12 mils, edge to edge
18 mils edge to edge
Spacing from other groups: 25 mils min, edge to edge
Breakout
5 mils on 5 mils spacing. Maximum length of breakout region can be 500 mils.
Trace Length 1 TL1: From
41110 signal Ball to first
junction
5.0” max
Trace Length TL2 to TL5 -
between junctions
0.5” min - 3.5” max
Trace Length TL_EM1 to
TL_EM10 from junction to
embedded devices
2.0” min - 3.0” max
Length Matching
Requirements
Clocks coming from the clock driver must be length matched to within 25 mils.
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PCI Express Layout
9
This section provides an overview of the PCI-Express stackup recommended based on Intel
presimulation results. For additional information, refer to the Intel® 41110 Serial to Parallel PCI
Bridge Developer’s Manual or the PCI Express Specification, Revision 1.0 from the
www.pcisig.com website.
9.1
General recommendations
PCI Express is a serial differential low-voltage point-to-point interconnect. The PCI Express was
designed to support 20 inches between components with standard FR4. The 41110 supports x8 lanes.
PCI-Express requires special considerations be made for interconnect losses, jitter, crosstalk and
mode conversions. The below list provides some general guidelines for the layout of a PCI-Express
trace:
1. Jitter: Trace lengths of a PCB trace can introduce around 1 to 5 ps of jitter and 0.35 to 0.5 dB
of loss per inch of differential pair. An add-in card the trace length from edge-finger pad to
device is limited to 3 inches.
2. Matching within pair: Trace lengths of matching differential pairs are required to be matched
within +/-5 mil delta. Each net within a differential pair should be length matched on a
segment-by-segment basis at point of discontinuity such as an breakout area, routes between
vias, routes between AC coupling capacitors and connector pins.
3. Trace Symmetry: Trace Symmetry is required between two traces of the same differential pair.
4. Vias: Vias contribute 0.5 to 1.0 dB/via toward the loss budget. Vias on an add-in card should
be limited to one near the breakout section of the pads and one near the edge finger.
5. Bends: Trace bends should be kept to a minimum. If bends are used they should be at a 45-
degree angle or smaller. The number of left and right bends should be matched as closely as
possible to even out the overall lengths of each segment of the differential pair.
6. AC Coupling capacitors: AC coupling capacitor with a value of 75nF to 200nF should line
up at the same location from one trace to the other within the pair. The 0402 size capacitor
with a small pad size is highly recommended. The breakout from the capacitor should be
symmetrical for both signal traces in the differential pair.
7. Connector pins: Length compensation for the connector pins of the differential pair being
offset from each other the PCB trace should be considered.
8. Ground Plane Referencing: Ground plane referencing is required along the entire route of the
differential pair. Traces routed near the edge should maintain a 40 mil air gap to the edge.
Layer switching should also maintain the ground plane. Grounds between planes should be
connected with stitching vias (with one to three recommended per differential pair).
9. Breakout Areas: Breakout areas near a device package should be limited to 500 mils in lengths.
The necking down to a smaller trace width should be symmetrical on the differential pair.
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PCI Express Layout
9.2
PCI-Express Layout Guidelines
The layout guidelines for PCI-Express were developed for an adapter card topologies. The models and
assumptions used in development of these guidelines were as follows:
• Add-In Card Stackup: 60 Ω single-ended impedance
• Target Differential Impedance: 100 Ω +/- 20%.
• Driver Model: 41110 PCI-E IBIS
• Receiver Model: 41110 PCI-E IBIS. Specification model did not meet specifications
• Driver Package Model: Preliminary 41110 model.
• No receiver package model used since specification eye is at package pin.
• Assumed that traces in a lane could be routed totally on microstrip, totally on stripline, or a
mixture of microstrip and stripline.
• AC coupling capacitors were modeled as a parasitic resistor and inductor in series.
• Add-in card was modeled as micro-strip routes only.
• No vias were modeled at this time.
• Only the receiver eye was evaluated. The next revision will evaluate the eye at the transmitter
and connector as well as the receiver.
9.3
Adapter Card Layout Guidelines
Table 15.
Adapter Card Routing Recommendations (Sheet 1 of 2)
Parameter
Reference Plane
Routing Guidelines
Route over an unbroken ground plane
Target Single Ended
Impedance
60 Ω nominal
Target Differential
Impedance
100 Ω +/- 20% Differential Impedance
Microstrip and Stripline Trace
Width
4 mils
Intrapair: 10 mils center-to-center
Interpair: 30 mils center-to-center
22 mils. center to center (pair to pair).
Microstrip Trace Spacing
Group Spacing
Transmit and Receive pairs should be interleaved. If no interleaving, then inter
pair spacing should be increased to 50 mils (c2c). Center to center of inter pair is
defined as center of Positive of one pair to Center of Negative of the next or vice
versa
Spacing from other groups: 25 mils minimum, center to center
Transmit Trace Length
(41110 signal pin to AC
coupling capacitor.)
0.25”- 5.0” max
Transmit Trace Length (AC
coupling capacitor to card
edge finger.)
1.00”- 4.5” max
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PCI Express Layout
Table 15.
Adapter Card Routing Recommendations (Sheet 2 of 2)
Receive Trace Length (Card
edge finger to 41110 receiver 1.0” min - 6.0” max
pin
Total allowable intra-pair length mis-match must not exceed 25 mils. Each
routing segment should be matched as close as possible. Total skew across all
lanes must be less than 20 ns. See the PCI-Express Desktop Design Guidelines
for additional routing requirements
Length Matching
Requirements:
Number of vias
4 max
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Circuit Implementations
Circuit Implementations
10
This chapter describes 41110 circuit implementations.
10.1
41110 Analog Voltage Filters
The 41110 requires several external analog voltage filter circuits to be placed on the system board,
three for the PCI interface, one for the PCI Express interface, and one for the bandgap voltage. The
41110 lists the recommended filter values for these filter circuits -- any one of the filter circuits can
number 4 cannot be used for the PCI Express analog voltage filter.
Table 16. Recommended R, L and C Values for 41110 Analog Filter Circuits
Config
1
R
L
C
4.7uH ±25%
PCI, PCI-E: 45mA
Bandgap: 30mA
0.5Ω ±1%
1/16W
33uF ±20%
6.3V
4.7uH ±20
0.5Ω ±1%
1/16W
22uF ±20%
6.3V
2
3
PCI, PCI-E: 45mA
Bandgap: 30mA%
4.7uH ±20%
PCI, PCI-E: 45mA
Bandgap: 30mA
0.5Ω ±1%
1/16W
2x10uF ±20%
6.3V
4.7uH ±20%
PCI: 45mA
1.0Ω ±1%
1/16W
10uF ±20%
6.3V
a
4
Bandgap: 30mA
a.
Configuration number 4 cannot be used for the PCI Express analog voltage filter.
Additional Notes:
• L (Inductor)
— L must be magnetically shielded
— ESR: max < 0.4Ω
— rated at 45mA (or 30mA for bandgap circuit only)
• C (Capacitor)
— ESR: max < 0.5Ω
— ESL < 3.0nH
• R (Resistor)
— 1/16W
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Circuit Implementations
10.1.1
PCI Analog Voltage Filters
The following filter circuit is recommended for the PCI interface. Three separate, identical
versions of this circuit should be placed on the system board, one for each VCCAPCI[2:0] pin on
the 41110.
Figure 22. PCI Analog Voltage Filter Circuit
Serial to
Parallel PCI
Bridge
Note: Three of these PCI filter circuits must be placed on the system board, one for each of the
VCCAPCI[2:0] pins on the 41110.
• Place C as close as possible to package pin.
• R must be placed between VCC15 and L.
• Route VCCPCI[x] and VSS as differential traces.
• VCCPCI[x] and VSS traces must be ground referenced (No VCC15 references).
• Max total board trace length = 1.2”.
• Min trace space to other nets = 30 mils.
10.1.2
PCI Express Analog Voltage Filter
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Circuit Implementations
Figure 23.
PCI Express Analog Voltage Filter Circuit
Serial to
Parallel PCI
Bridge
Additional Notes:
• Place C as close as possible to package pin.
• R must be placed between VCC15 and L.
• Route VCCAPE and VSSAPE as differential traces.
• VCCAPE and VSSAPE traces must be ground referenced (No VCC15 references).
• Max total board trace length = 1.2”.
• Min trace space to other nets = 30 mils.
10.1.3
Bandgap Analog Voltage Filter
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Circuit Implementations
Figure 24.
Bandgap Analog Voltage Filter Circuit
Serial to
Parallel PCI
Bridge
Additional Notes:
• Place C as close as possible to package pin.
• R must be placed between the 2.5V supply and L.
• Route VCCBGPE and VSSBGPE as differential traces.
• VCCBGPE and VSSBGPE traces must be ground referenced (No 2.5V references).
• VSSBGPE should be grounded at the capacitor.
• Max total board trace length = 1.2”.
• Min trace space to other nets = 30 mils.
10.2
41110 Reference and Compensation Pins
There are three compensation pins on 41110.
PE_RCOMP[1:0] are two separate pins that provide voltage compensation for the PCI Express
interface on the 41110. The nominal compensation voltage is 0.5V. An external 24.9Ω ±1% pullup
resistor should be used to connect to VCC15. A single pullup resistor can be used to for both of
these signals.
RCOMP is an analog PCI interface compensation pin, providing 0.75V to the 41110. A 100Ω ±1%
pulldown resistor should be used to connect the RCOMP pin to ground.
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Circuit Implementations
Figure 25. Reference and Compensation Circuit Implementations
Serial to
Parallel PCI
Bridge
10.2.1
SM Bus
The SMBus interface does not have configuration registers. The SMBus address is set by the states
Table 17.
SMBUs Address Configuration
Bit
Value
7
6
5
4
3
2
1
1
1
SMBUS[5]
0
SMBUS[3]
SMBUS[2]
SMBUS[1]
microcontroller.
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41110 Customer Reference Boards 11
This chapter describes the 41110 Customer Reference Board (CRB).
11.1
Board Stack-up
The proposed layout of the PCB is eight layers with the following stackup:
• Signal #1 (Top/Component Side)
• Ground Plane: GND
• Signal #2
• Power Plane
• Power Plane
• Signal #3
• Ground Plane
• Signal #4 (Bottom)
The permittivity constant Er = 4.5
Table 18. CRB Board Stackup (Sheet 1 of 2)
Thickness
(mils)
Layer
Type
Copper Weight
1
Signal
Prepreg
Plane: GND
Core
2.00
4.50
1.20
4.80
1.20
14.00
1.20
3.8
1/2 + plating
2
3
4
5
6
7
1
1
1
1
1
1
Signal
Prepreg
Plane: PWR
Core
Plane: PWR
Prepreg
Signal
1.20
14.00
1.20
4.80
1.20
Core
Plane: Power
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41110 Customer Reference Boards
Table 18. CRB Board Stackup (Sheet 2 of 2)
Thickness
(mils)
Layer
Type
Copper Weight
1
2
3
8
Signal
Prepreg
Plane: GND
Core
2.00
4.50
1.20
4.80
1.20
4.50
2.00
1/2 + plating
1
Signal
1
Prepreg
Signal
1/2 + plating
Est. Total
Thickness
62 +/- 7
11.2
11.3
Material
The following materials are used with the 41110 CRB:
• FR-4, 0.062 in. +/- .007, 1.0 oz Copper Power/GND.
• Full length PCI Raw Card (3.3V Universal) 6.2” high x 7.00” long max with ½ inch cut away.
Impedance
Most signal layers require controlled Impedance of 60 Ω +/- 5% microstrip or stripline where
appropriate.
Differential signals for the PCI-E interface require matched 100 Ω differential termination realized
as matched 50Ω resistances referenced to ground.
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41110 Customer Reference Boards
11.4
Board Outline
Figure 26 provides the mechanical outline of the 41110 CRB.
Figure 26. Mechanical Outline of the 41110
U1
Serial to
Parallel PCI
Bridge
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41110 Customer Reference Boards
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Design Guide Checklist
12
This checklist highlights design considerations that should be reviewed prior to manufacturing an
adapter card that implements the 41110 product. The items contained within this checklist attempt
to address important connections to these devices and any critical supporting circuitry. This is not a
complete list and does not guarantee that a design will function properly.
Table 19. PCI Express Interface Signals
Signals
Recommendations
Reason/Impact
Must be connected to clock from a PCI Express
connector for add-in card designs or to a 100MHz
oscillator for an embedded design.
REFCLKn,
REFCLKp
24.9Ω ±1% pullup resistor to 1.5V. A single resistor can
PE_RCOMP[1:0] be used for both signals. Place resistor as close as
possible to REFCLKn, REFCLKp pins.
PCI Express compensation pin.
0.5V nominal.
For X1 mode, only signals PERp[0] and PERn[0] or
PERp[7] and PERn[7] are used.
PCI Express data serial inputs
(differential data receive
signals).
PERP[7:0]
PERN[7:0]
For X4 mode, only signals PERp[3:0] and PERn[3:0]
are used.
For X8 mode, all of these signals, PERp[7:0] and
PERn[7:0], are used.
For X1 mode, only signals PETp[0] and PETn[0] or
PETp[7] and PETn[7] are used.
PCI Express data serial inputs
(differential data transmit
signals).
PETP[7:0]
PETN[7:0]
For X4 mode, only signals PETP[3:0] and PETN[3:0]
are used.
For X8 mode, all of these signals, PETP[7:0] and
PETN[7:0], are used.
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Table 20. PCI/PCI-X Interface Signals (Sheet 1 of 2)
Signals
Recommendations
Reason/Impact
A_AD[63:32]
A_CBE[7:4]#
A_DEVSEL#
A_FRAME#
A_IRDY#
A_TRDY#
A_STOP#
A_PERR#
A_SERR#
A_REQ[5:0]#
A_GNT[5:0]#
A_LOCK#
A_PAR
41110 has internal pullup resistors
on these signals.
No external pullup resistors required on system board.
X_AD[31:0] and X_CBE#[3:0]
signals do not require pullups
according to the PCI Specification.
A_PAR64
A_ACK64#
A_REQ64#
Only relevant when running in PCI-X Mode
(X_PCIXCAP = 1).
Determines the max PCI-X Mode 1 frequency for a
particular segment (100 MHz or 133 MHz):
A_133EN
Sampled on the rising edge of
PERST#.
0 = 100 MHz PCI-X max frequency
1 = 133 MHz PCI-X max frequency
Use an 8.2KΩ pullup resistor to VCC33. This resistor is
located on the system board.
A_INTA#
A_INTB#
A_INTC#
A_INTD#
The 41110 has internal pullup
resistors on these signals.
No pullup resistors required on these signals.
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Table 20. PCI/PCI-X Interface Signals (Sheet 2 of 2)
Signals
Recommendations
Reason/Impact
Controls frequency of the PCI segment when running
in conventional PCI mode (33 MHz or 66 MHz):
0 = 33 MHz PCI
1 = 66 MHz PCI
A_M66EN
Sampled on the rising edge of
PERST#.
•
Pull-up using a 8.2KΩ resistor when the PCI bus is
to operate at 66 MHz and not already pulled up by
system board. This signal is grounded for 33 MHz
operation.
•
Design without secondary PCI/PCI-
X Slot
—
If there is at least one legacy
PCI device on the PCI/PCI-X
bus, tie this pin directly to
GND.
—
If all devices are PCI-X
capable and there is at least
one PCI-X device that only
supports maximum PCI-X
66MHz on the secondary PCI
bus, pull down to GND
through 10KΩ series resistor
parallel with a 0.01uF
A_PCIXCAP
Connects directly to the PCIXCAP pin on the PCI slot.
Connect to VCC33 through an 8.2KΩ pullup resistor.
capacitor.
—
If all secondary PCI-X
devices (and the bus loading)
support PCI-X 133MHz,
connect PCIXCAP to 3.3V
through an 8.2K Ω resistor
The series resistor on IDSEL should be 200Ω ±5% if it
is exclusively PCIX mode. If it is PCI mode or mixed
PCI/ PCIX mode is intended, 510 ohms is
recommended.
IDSEL
Table 21. Miscellaneous Signals
Signals
Recommendations
Reason/Impact
Used for debug purposes. Connect to VCC33 through
an 8.2KΩ pullup resistor for normal operation.
RSTIN#
A_STRAP0,
A_STRAP1,
A_STRAP2,
A_STRAP6,
These signals REQUIRE external pull-downs to GND
on the board 8.2KΩ unless otherwise stated.
RESERVED [8:1]
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Table 21. Miscellaneous Signals
Signals
Recommendations
Reason/Impact
Input pin to configure 41110 to retry configuration
accesses on it's PCI Express interface.
CFGRETRY
•
To retry configuration accesses to the 41110, pull high to
3.3V through a 2K Ω resistor.
•
To allow configuration accesses to the 41110, ground
this pin through a 2K Ω resistor.
A_TEST1,
A_TEST2,
A_PME#,
A_STRAP[3],
A_STRAP[4],
A_STRAP[5],
These signals REQUIRE an external pull-up, 8.2KΩ to
3.3V.
In normal operating mode, this
pin must be tied high.
CMODE
This signal requires an external pull-up, 8.2KΩ to 3.3V.
Table 22. SMBus Interface Signals
Signal
Recommendations
Reason/Impact
SMBCLK
SMBDAT
Connect to VCC33 through an 8.2KΩ pullup resistor.
Connect to VCC33 through an 8.2KΩ pullup resistor.
SMBus addressing:
Bit 7----------------’1’
Bit 6----------------’1’
Bit 5---------------SMBUS[5]
Bit 4----------------’0’
SMBUS[5],
SMBUS[3:1]
Sampled on the rising edge of
PERST#.
Bit 3---------------SMBUS[3]
Bit 2---------------SMBUS[2]
Bit 1---------------SMBUS[1]
Use 8.2KΩ resistors as pullups to VCC33 for a ‘1’ and
as pulldowns to ground for a ‘0’ to set the SMBus
address.
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Table 23. Reset Pins
Ballout
Pin Name
STRAP_V_1
Usage
E6
B5
B3
A3
B4
D4
F5
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull up to VCC33
Pull down to GND
STRAP_V_2
STRAP_V_3
STRAP_V_4
STRAP_V_5
STRAP_V_6
STRAP_V_7
STRAP_V_8
STRAP_V_9
STRAP_V_10
STRAP_V_11
STRAP_V_12
STRAP_V_13
STRAP_V_14
STRAP_V_15
P2
C3
D1
U1
D7
U10
R5
A19
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Table 24. Power and Ground Signals
Signal
Recommendations
Reason/Impact
100Ω ±1% (1/4 W) pulldown resistor to ground.
Analog compensation pin for
PCI. 0.75V nominal.
RCOMP
The trace impedance of this signal should be < 0.1Ω.
Connect to 1.5V power supply.
Note: Linear voltage regulators are recommended
when using 1.5 Volt power supplies.
Decoupling:
VCC15
1.5V ±5% core voltage.
5 0.1uF caps beneath package (backside of board)
2 1.0 uF caps as close as design rules permit to
package
3 10 uF caps as close as design rules permit to
package
Connect to 3.3V power supply.
Decoupling: TBD
The platform must insure that the VCC33 voltage rail
be greater than to (or no less than 0.5V below) VCC15
(absolute voltage value at all times during 41110
operation, including during system power up, power
down or any other time during system operation. This
can be accomplished by placing a diode (with a voltage
drop < 0.5V) between VCC15 and VCC33. Anode will
be connected to VCC15 and cathode will be connected
to VCC33.
VCC33
3.3V ±5% PCI I/O voltage.
Connect to 1.5V power supply.
1.5V ±3% Analog PCI Express
voltage.
VCCAPE
VCCAPCI[2:0]
Analog PCI voltage pins.
Voltage output of the bandgap filter circuit into 41110,
VCCBGPE
VCCPE
for circuit.
Connect to 1.5V power supply.
Decoupling:
•
•
3 0.1uF caps beneath package (backside of board)
1.5V ±3% PCI Express voltage.
4 1.0 uF caps as close as design rules permit to
package
•
2 10 uF caps as close as design rules permit to
package
Ground reference for all
supplies.
VSS
Connect to ground.
VSSAPE
VSSBGPE
Analog ground for PCI Express.
Ground for the bandgap filter circuit, separated from
Ground for analog bandgap
voltage.
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Table 25. JTAG Signals
Signal
Recommendations
Reason/Impact
Internal pull-up
TCK
TDI
If not used for JTAG, leave as No Connect
If not used for JTAG, leave as No Connect
If not used for JTAG, leave as No Connect
If not used for JTAG, leave as No Connect
Internal pull-up
Internal pull-up
Internal pull-up
TDO
TMS
If TAP interface is not used this
should be tied to ground.
TRST#
Connect to ground via a 1KΩ pulldown resistor.
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