®
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Intel IXP45X and Intel IXP46X
Product Line of Network Processors
Hardware Design Guidelines
February 2007
Document No:305261; Revision:004
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Contents—Intel IXP45X and Intel IXP46X Product Line of Network Processors
Contents
1.0 Introduction..............................................................................................................9
Content Overview................................................................................................9
Related Documentation...................................................................................... 10
Acronyms and Abbreviations............................................................................... 11
2.0 System Architecture ................................................................................................ 15
System Architecture Description.......................................................................... 15
3.0 General Hardware Design Considerations................................................................ 17
3.2.1 Signal Interface ..................................................................................... 18
3.2.2 DDR SDRAM Memory Interface................................................................. 20
3.2.3 DDR SDRAM Initialization ........................................................................ 20
3.3.1 Signal Interface ..................................................................................... 21
3.3.2 Reset Configuration Straps ...................................................................... 21
3.3.3 8-Bit Device Interface............................................................................. 23
3.3.4 16-Bit Device Interface ........................................................................... 23
3.3.5 32-Bit Device Interface ........................................................................... 24
3.3.6 Flash Interface....................................................................................... 27
3.3.7 SRAM Interface...................................................................................... 28
3.3.8 Design Notes ......................................................................................... 28
3.4.1 Signal Interface ..................................................................................... 29
3.5.1 Signal Interface MII................................................................................ 31
3.5.2 Device Connection, MII ........................................................................... 33
3.5.3 Signal Interface, SMII............................................................................. 34
3.5.4 Device Connection, SMII ......................................................................... 35
GPIO Interface.................................................................................................. 35
3.6.1 Signal Interface ..................................................................................... 36
3.6.2 Design Notes ......................................................................................... 36
2
I C Interface .................................................................................................... 37
3.7.1 Signal Interface ..................................................................................... 37
3.7.2 Device Connection.................................................................................. 37
3.8.1 Signal Interface ..................................................................................... 39
3.8.2 Device Connection.................................................................................. 40
3.9.1 Signal Interface ..................................................................................... 42
3.9.2 Device Connection.................................................................................. 42
3.10 HSS Interface................................................................................................... 43
3.10.1 Signal Interface ..................................................................................... 44
3.10.2 Device Connection.................................................................................. 46
3.11 SSP Interface ................................................................................................... 46
3.11.1 Signal Interface ..................................................................................... 47
3.11.2 Device Connection.................................................................................. 47
3.12 PCI Interface .................................................................................................... 48
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—Contents
3.12.1 Signal Interface......................................................................................48
3.12.2 PCI Interface Block Diagram.....................................................................49
3.12.3 Supporting 5 V PCI Interface....................................................................50
3.12.4 PCI Option Interface................................................................................51
3.12.5 Design Notes..........................................................................................53
3.13 JTAG Interface ..................................................................................................53
3.13.1 Signal Interface......................................................................................54
3.14 Input System Clock............................................................................................54
3.14.1 Clock Signals .........................................................................................54
3.14.2 Clock Oscillator.......................................................................................54
3.14.3 Device Connection ..................................................................................55
3.15 Power ..............................................................................................................55
3.15.2 VCC De-Coupling....................................................................................56
3.15.3 VCCP De-Coupling ..................................................................................56
3.15.4 VCCM De-Coupling..................................................................................56
3.15.5 Power Sequence.....................................................................................56
3.15.6 Reset Timing..........................................................................................56
4.0 General PCB Guide ...................................................................................................59
5.0 General Layout and Routing Guide...........................................................................63
Overview..........................................................................................................63
5.2.1 General Component Spacing ....................................................................64
5.2.2 Clock Signal Considerations......................................................................66
5.2.3 SMII Signal Considerations ......................................................................67
5.2.4 MII Signal Considerations ........................................................................67
5.2.5 USB Considerations.................................................................................67
5.2.6 Cross-Talk .............................................................................................68
5.2.7 EMI-Design Considerations.......................................................................68
5.2.8 Trace Impedance....................................................................................69
5.2.9 Power and Ground Plane..........................................................................69
PCI Interface Design Considerations.......................................................................71
Electrical Interface.............................................................................................71
6.3.1 Trace Length Limits.................................................................................73
6.3.2 Routing Guidelines..................................................................................74
6.3.3 Signal Loading........................................................................................74
7.0 DDR-SDRAM.............................................................................................................75
Introduction......................................................................................................75
7.1.1 Selecting VTT Power Supply .....................................................................80
7.1.2 Signal-Timing Analysis ............................................................................81
7.1.3 Printed Circuit Board Layer Stackup ..........................................................84
7.1.5 Timing Relationships ...............................................................................87
7.1.7 Routing Guidelines..................................................................................88
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7.2.1 Clock Group........................................................................................... 90
7.2.2 Data Group ........................................................................................... 92
7.2.3 Control Group........................................................................................ 98
7.2.4 Command Group.................................................................................. 100
7.2.5 RCVENIN and RCVENOUT ...................................................................... 105
Figures
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Intel IXP465 Component Block Diagram.................................................................... 13
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Intel IXP465 Example System Block Diagram ............................................................ 16
2
10 I C EEPROM Interface Example.................................................................................. 38
11 USB Host Down Stream Interface Example.................................................................. 40
12 USB Device Interface Example................................................................................... 41
13 UTOPIA Interface Example ........................................................................................ 43
14 HSS Interface Example............................................................................................. 46
15 Serial Flash and SSP Port (SPI) Interface Example........................................................ 47
16 PCI Interface........................................................................................................... 50
17 PCI 3.3 V to 5 V Logic Translation Interface................................................................. 51
18 Clock Oscillator Interface Example.............................................................................. 55
19 Component Placement on a PCB................................................................................. 60
20 8-Layer Stackup ...................................................................................................... 62
21 6-Layer Stackup ...................................................................................................... 62
22 Signal Changing Reference Planes.............................................................................. 64
23 Good Design Practice for VIA Hole Placement............................................................... 65
24 Poor Design Practice for VIA Placement....................................................................... 65
25 Pad-to-Pad Clearance of Passive Components to a PGA or BGA....................................... 66
26 PCI Address/Data Topology ....................................................................................... 72
27 PCI Clock Topology .................................................................................................. 73
28 Processor-DDR Interface........................................................................................... 76
29 Processor-DDR Interface: x16 Devices with ECC........................................................... 79
30 VTT Terminating Circuitry.......................................................................................... 80
31 DDR Command and Control Setup and Hold................................................................. 81
32 DDR Data to DQS Read Timing Parameters.................................................................. 82
33 DDR-Data-to-DQS-Write Timing Parameters ................................................................ 83
34 DDR-Clock-to-DQS-Write Timing Parameters ............................................................... 83
35 Printed Circuit Board Layer Stackup............................................................................ 85
36 Printed Circuit Board Controlled Impedance................................................................. 86
37 DDR Clock Topology: Two-Bank x16 Devices ............................................................... 91
38 DDR Clock Simulation Results: Two-Bank x16 Devices .................................................. 92
39 DDR Data Topology: Two-Bank x16 Devices ................................................................ 94
40 DDR Data Write Simulation Results: Two-Bank x16 Devices........................................... 95
41 DDR Data Read Simulation Results: Two-Bank x16 Devices
43 DDR Control (CS0) Topology: Two-Bank x16 Devices.................................................... 98
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44 DDR RAS Simulation Results: Two-Bank x16 Devices ....................................................99
45 DDR Command (MA3) Topology: Two-Bank x16 Devices..............................................101
46 DDR Address Simulation Results: Two-Bank x16 Devices .............................................102
47 DDR Command (RAS) Topology: Two-Bank x16 Devices ..............................................103
48 DDR RAS Simulation Results: Two-Bank x16 Devices ..................................................104
49 DDR RCVENIN/RCVENOUT Topology..........................................................................105
Tables
MII NPE A Signal Recommendations............................................................................31
MII NPE B Signal Recommendations............................................................................31
10 MII NPE C Signal Recommendations............................................................................32
11 MAC Management Signal Recommendations NPE A,B,C..................................................33
12 SMII Signal Recommendations: NPE A, B, C.................................................................34
13 GPIO Signal Recommendations...................................................................................36
14 I2C Signal Recommendations.....................................................................................37
15 USB Host/Device Signal Recommendations ..................................................................39
16 UTOPIA Signal Recommendations ...............................................................................42
17 High-Speed, Serial Interface 0 ...................................................................................44
18 High-Speed, Serial Interface 1 ...................................................................................45
19 Synchronous Serial Peripheral Port Interface................................................................47
20 PCI Controller ..........................................................................................................48
21 PCI Host/Option Interface Pin Description ....................................................................51
22 Synchronous Serial Peripheral Port Interface................................................................54
23 Clock Signals ...........................................................................................................54
24 Power Interface........................................................................................................55
25 PCI Address/Data Routing Guidelines ..........................................................................72
26 PCI Clock Routing Guidelines......................................................................................73
27 DDR Signal Groups...................................................................................................75
28 Supported Memory Configurations ..............................................................................78
29 DDR Command and Control Setup and Hold Values.......................................................81
30 DDR Data to DQS Read Timing Parameters ..................................................................82
31 DDR Data to DQS Write Timing Parameters..................................................................83
32 DDR-Clock-to-DQS-Write Timing Parameters................................................................84
33 Timing Relationships.................................................................................................87
34 Clock Signal Group Routing Guidelines ........................................................................89
35 Data, Command, and Control Group Routing Guidelines.................................................89
36 Clock Group Topology Transmission Line Characteristics ................................................90
37 Data Group Topology Transmission Line Characteristics .................................................93
38 Control Group Topology Transmission Line Characteristics..............................................98
39 Command Group Topology Transmission Line Characteristics........................................100
40 Control Group Topology Transmission Line Characteristics............................................105
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Revision History—Intel IXP45X and Intel IXP46X Product Line of Network Processors
Revision History
Date
Revision
Description
•
•
of supported SMII ports from six to three.
UTP_OP_ADDR[4:0], UTP_IP_ADDR[4:0], and ETH_MDC.
•
•
•
Section 7.0, “DDR-SDRAM” : Updated design information.
Removed SS-SMII references since this feature is not supported.
Incorporated specification changes, specification clarifications and
February 2007
004
®
document changes from the Intel IXP4XX Product Line of
Network Processors Specification Update (306428-006)
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•
Updated Intel product branding.
The following changes were made in this release:
•
•
recommendations.
•
Section 3.3.6: changed pull-down resistor value from 10K to 4.7K.
•
•
•
Section 3.12.2: clarified description.
Added new information: Section 3.12.3, “Supporting 5 V PCI
August 2005
003
•
•
Section 3.12.5: clarified 5V support.
speed processor.
•
•
tables.
Section 7.1.7.1: enhanced clock group routing guidelines.
®
Updated to add support for Intel IXP455 Network Processor.
May 2005
002
001
Section 3.2.1: enhanced signal descriptions for DDRI_CK[2:0] and
DDRI_CB[7:0].
March 2005
Initial release of document.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—Revision History
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Introduction—Intel IXP45X and Intel IXP46X Product Line of Network Processors
1.0
Introduction
This design guide provides recommendations for hardware and system designers who
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are developing with the Intel IXP45X and Intel IXP46X Product Line of Network
®
Processors. This document should be used in conjunction with the Intel IXP45X and
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Intel IXP46X Product Line of Network Processors Datasheet and sample schematics
®
provided for the Intel IXDP465 Development Platform in that platform’s
documentation kit.
Design Recommendations are necessary to meet the timing and signal quality
specifications.
The guidelines recommended in this document are based on experience and simulation
®
work done at Intel while developing the Intel IXDP465 Development Platform. These
recommendations are subject to change.
®
Note:
This document discusses all features supported on the Intel IXP465 Network
Processor. A subset of these features is supported by certain processors in the IXP45X/
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IXP46X product line, such as the Intel IXP460 or Intel IXP455 network processors.
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For details on feature support listed by processor, see the Intel IXP45X and Intel
IXP46X Product Line of Network Processors Datasheet.
1.1
Content Overview
Chapter Name
Description
Conventions used in this manual and related documentation
System architectural block diagram and system memory map
Graphical representation of most common peripheral interfaces.
General PCB design practice and layer stack-up description
More specific layout and routing recommendations for board
designers
Board-design recommendations when implementing PCI
interface
Board-design recommendations when implementing
DDRI memory interface
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—Introduction
1.2
Related Documentation
The reader of this design guide should also be familiar with the material and concepts
presented in the following documents:
Title
Document #
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Hardware-Assisted IEEE 1588* Implementation in the Intel IXP46X
Product Line White Paper
305068
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Intel IXP45X and Intel IXP46X Product Line of Network Processors
Developer’s Manual
306262
306261
306428
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Intel IXP45X and Intel IXP46X Product Line of Network Processors
Datasheet
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Intel IXP4XX Product Line of Network Processors Specification
Update
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Intel IXP400 Software Programmer’s Guide
252539
273795
273473
N/A
®
Intel IXP400 Software Specification Update
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Intel XScale™ Core Developer’s Manual
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Intel IXDP465 Development Platform Documentation Kit
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Intel XScale Microarchitecture Technical Summary
—
Intel StrataFlash® Memory (J3) to Intel® Embedded Memory (J3
v.D) Conversion Guide - Application Note 835
308555
306667
Migration Guide for Intel StrataFlash® Synchronous Memory (J3) to
Intel StrataFlash® Embedded Memory (P30 and P33) - Application
Note 812
Migration Guide for Intel StrataFlash® Synchronous Memory (K3/
K18) to Intel StrataFlash® Embedded Memory (P30) - Application
Note 825
306669
Double Data Rate (DDR) SDRAM Specification, 2004; JEDEC Solid
State Technology Association
JESD79D
2
I C-Bus Specification from Philips Semiconductors*
Available at http://www.nxp.com
IEEE 802.3 Specification
N/A
N/A
N/A
N/A
N/A
IEEE 1149.1 Specification
PCI Local Bus Specification, Rev. 2.2
Universal Serial Bus Specification, Revision 1.1
UTOPIA Level 2 Specification, Revision 1.0
Note: For Intel documentation, see the Intel Technical Documentation Center, available through the
following link:
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Introduction—Intel IXP45X and Intel IXP46X Product Line of Network Processors
1.3
Acronyms and Abbreviations
Table 1.
List of Acronyms and Abbreviations
Term
Explanation
AHB
APB
ATM
DDR
EMI
Advanced High-Performance Bus
Advanced Peripheral Bus
Asynchronous Transfer Mode
Double Data Rate
Electro-Magnetic Interference
General Purpose Input/Output
High Speed Serial
GPIO
HSS
I2C
Inter-Integrated Circuit
IP
Internet Protocol
ISA
Instruction Set Architecture
Local Area Network
LAN
MII
Media-Independent Interface
Network Processor Engine
Printed Circuit Board
NPE
PCB
PCI
Peripheral Component Interface
Physical Layer Interface
PHY
PLL
Phase-Locked Loop
PMU
SDRAM
SME
SMII
SSP
UART
USB
VTT
Performance Monitoring Unit
Synchronous Dynamic Random Access Memory
Small-to-Medium Enterprise
Serial Media-Independent Interface
Synchronous Serial Protocol
Universal Asynchronous Receiver-Transmitter
Universal Serial Bus
Termination Voltage Supply
1.4
Overview
The IXP45X/IXP46X network processors are highly integrated devices, capable of
interfacing with most common industry standard peripherals, required for high-
performance control applications.
®
Note:
This document discusses all features supported on the Intel IXP465 Network
Processor. A subset of these features is supported by certain processors in the IXP45X/
®
®
IXP46X product line, such as the Intel IXP460 or Intel IXP455 network processors.
®
®
For details on feature support listed by processor, see the Intel IXP45X and Intel
IXP46X Product Line of Network Processors Datasheet.
Some of the key features of the IXP45X/IXP46X network processors, when used as a
single-chip solution for embedded applications, are as follows:
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®
*
• Intel XScale Processor (compliant with Intel StrongARM architecture) — Up to
667 MHz
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—Introduction
• 32-bit PCI interface Master/Target 33/66 MHz
• Device Universal Serial Bus (USB) Controller
• Host Universal Serial Bus (USB) Controller
• DDRI-266 SDRAM (133-MHz Clock, 266-Mbps per data line) — User-enabled ECC,
supports up to 1 Gbyte of external memory
• 32-bit Expansion Bus Interface — Master/Target interface
• Two UART ports
• Up to three Ethernet ports (consult device part number for enabled features) MII/
SMII
• Up to three NPEs
• UTOPIA Level 2 Interface
• Synchronous Serial Port Interface (SSP)
• Two High-Speed Serial Port Interfaces (HSS)
• Inter-Integrated Circuit (IIC or I2C) Interface
• 16 GPIO (General Purpose Input Output)
• Packaging
— 544-pin PBGA package
— Commercial temperature (0° to +70° C)
— Extended temperature (-40° to +85° C)
®
For a complete features list and block diagram description, see the Intel IXP45X and
®
Intel IXP46X Product Line of Network Processors Datasheet.
Note:
Some features require Intel-supplied software. To determine if a feature is enabled in a
®
particular software release, refer to the Intel IXP400 Software Specification Update.
A block diagram of all major internal hardware components of the IXP465 network
interface with each other through the various bus interfaces such as the North AHB,
South AHB, and APB.
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Introduction—Intel IXP45X and Intel IXP46X Product Line of Network Processors
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Figure 1.
Intel IXP465 Component Block Diagram
HSS 0
HSS 1
NPE A
UTOPIA 2/MII/SMII
MII/SMII
NPE B
NPE C
North AHB 133.32 MHz x 32 bits
MII/SMII
AES/DES/SHA/
MD-5
North AHB
Arbiter
IEEE 1588
I2C
Cryptography
SSP
Unit
Queue
Manager
AHB/AHB
Bridge
DDRI Memory
Controller Unit
USB Device
Version 1.1
Hardware RNG
Hashing SHA1
Exponentiation Unit
32 Bit + ECC
UART 0
921 KBaud
AHB Slave/
APB
Master
Bridge
South AHB 133.32 MHz x 32 bits
UART 1
921 KBaud
South AHB
Arbiter
16 GPIO
GPIO
USB-Host
Controller V. 2.0
High-Speed is not
Supported
Expansion Bus
PCI Controller
Controller
Interrupt
Controller
Intel XScale® Processor
32-Kbyte I-Cache
32-Kbyte D-Cache
2-Kbyte Mini D-Cache
IBPMU
Timers
8/16/32 bit + Parity 32 bit at 33/66 MHz
Master on North AHB
Slave Only
Master on South AHB
Bus Arbiters
AHB Slave / APB Master
B3777-007
®
Note:
®
®
listed by processor, see the Intel IXP45X and Intel IXP46X Product Line of Network
Processors Datasheet.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—Introduction
1.5
Typical Applications
• High-performance DSL modem
• High-performance cable modem
• Residential gateway
• SME router
• Integrated access device (IAD)
• Set-top box
• DSLAM
• Access points — 802.11a/b/g
• Industrial controllers
• Network printers
• VoIP Gateways
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System Architecture—Intel IXP45X and Intel IXP46X Product Line of Network Processors
2.0
System Architecture
2.1
System Architecture Description
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The Intel IXP45X and Intel IXP46X Product Line of Network Processors are multi-
®
function processors that integrate the Intel XScale Processor (ARM* architecture
compliant) with highly integrated peripheral controllers and intelligent network
processor engines.
The processor is a highly integrated design, manufactured with Intel’s 0.18-micron
production semiconductor process technology. This process technology — along with
numerous, dedicated-function peripheral interfaces and many features with the Intel
XScale processor — addresses the needs of many system applications and helps reduce
system costs. The processors can be configured to meet many system application and
implementation needs.
Figure 2 illustrates one of many applications for which the IXP45X/IXP46X network
®
processors can be implemented. For detailed functional descriptions, see the Intel
®
IXP45X and Intel IXP46X Product Line of Network Processors Developer’s Manual.
2.2
System Memory Map
For a complete memory map and register description of each individual module, refer
®
®
to the Intel IXP45X and Intel IXP46X Product Line of Network Processors
Developer’s Manual.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—System Architecture
®
Figure 2.
Intel IXP465 Example System Block Diagram
JTAG
Header
Flash
32 Mbyte
CB[7:0]
D[31:0]
BA[1:0]
A[13:0]
DDR
CS_N0
SDRAM
Max 1 Gbyte
D[31:0]
RAS, CAS, WE, CS,CLK
Board
A[24:0]
Configuration
Reset Logic
HSS 1
HSS 0
Intel®IXP46X Product
Line of Network
Processors
SLIC/CODEC or
T1/E1/J1 Framer
LCD/LED
Diagnostics
Buff
SSP
CODEC or
A/D
Display
xDSL
RS232
Serial Port 0
UTOPIA Level 2
DB9
DB9
RS 232
Serial Port 1
PLL
OSC
Clock Buffer
RJ45
Port 0
3-MII/
3-SMII/
10/100
PHYs
Ethernet
Clocks
PCI
Clock
Up to 3Ports
RJ45
Port 2
USB Host
Connector
USB v2.0
USB v1.1
I2C
3.3 V
2.5 V
1.3 V
Power Supply
USB Device
Connector
Transparent PCI Bridge
I2C
cPCI Bus
B4835-002
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
3.0
General Hardware Design Considerations
This chapter contains information for implementing and interfacing to major hardware
®
®
blocks of the Intel IXP45X and Intel IXP46X Product Line of Network Processors.
Such blocks include DDR SDRAM, Flash, SRAM, Ethernet PHYs, UART and most other
peripherals interfaces. Signal definition tables list resistor recommendations for pull-
ups and pull-downs.
Features disabled by a specific part number, do not require pull-ups or pull-downs.
Therefore, all pins can be left unconnected. Features enabled by a specific part number
and required to be Soft Fuse-disabled, only require pull-ups or pull-downs in the clock-
input signals. Other conditions may require pull-up or pull-down resistors for
configuration purposes at power on or reset. Likewise, open-collector outputs must be
pulled-high.
Warning:
The IXP45X/IXP46X network processors’ I/O pins are 3.3 V only, except for DDR
SDRAM which is 2.5 V. None of the I/Os are 5-V tolerant.
definition tables.
Table 2.
Signal Type Definitions
Symbol
Description
I
Input pin only
O
Output pin only
I/O
OD
TRI
PWR
GND
Pin can be either an input or output
Open-drain pin
Tri-State pin
Power pin
Ground pin
3.1
Soft Fusible Features
Soft Fuse Enable/Disable is a method to enable or disable features in hardware,
virtually disconnecting the hardware modules from the processor.
Some of the features offered in the IXP45X/IXP46X product line can be Soft Fuse
Enabled/Disabled during boot. It is recommended that if a feature is not used in the
design, the feature be Soft disabled. This helps reduce power and maintain the part
running at a cooler temperature. When Soft Fuse Disabled, a pull-up resistor must be
connected to each clock input pins of the disabled feature interface. All other signals
can be left unconnected.
Soft Fuse Enable/Disable can be done by writing to EXP_UNIT_FUSE_RESET register,
®
®
for more information refer to the Intel IXP45X and Intel IXP46X Product Line of
Network Processors Developer’s Manual and review the register description.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
Table 3.
Soft Fusible Features
Name
Description
The complete bus must be enabled or disable.
PCI
HSS0/1
Can only be disable as a pair.
If enabling UTOPIA, MACs on NPE A are disabled.
If enabling MACs on NPE A, UTOPIA are disabled.
UTOPIA
Can Enable either MII MACs or SMII MACs, but not both at the same time. Enable of MACs
can be separately done per each NPE.
ETHERNET
USB Host
USB Device
DDR ECC
Each USB can be Enable separately.
Each USB can be Enable separately.
DDR can be disabled separately form the rest of the DDR interface.
3.2
DDR-266 SDRAM Interface
The IXP45X/IXP46X network processors support unbuffered, DDR-266 SDRAM
technology, capable of addressing two memory banks (one bank per CS). Each bank
can be configured to support 32/64/128/256/512-Mbyte for a total combined memory
support of 1 Gbyte.
The device supports non-ECC and ECC for error correction, which can be enable or
disable by software as required. Banks have a bus width of 32 bits for non ECC or
40 bits for ECC enable (32-bit data + 8-bit ECC).
®
®
For a complete feature list, see the Intel IXP45X and Intel IXP46X Product Line of
Network Processors Datasheet.
General DDR SDRAM routing guidelines can be found in Section 7.1.7, “Routing
Guidelines” on page 88. For more detailed information, see the PC266 DDR SDRAM
specification.
3.2.1
Signal Interface
Table 4.
DDR SDRAM Interface Pin Description (Sheet 1 of 2)
Input
Outpu
t
VTT
Terminatio
n
Name
Device-Pin Connection
Description
Connect a pair of differential clock
signals to every device; When
using both banks, daisy chain
devices with same data bit
sequence.
DDR SDRAM Clock Out — Provides the positive
differential clocks to the external SDRAM
memory subsystem.
DDRI_CK[2:0]
O
No
DDR SDRAM Clock Out — Provides the
negative differential clocks to the external
SDRAM memory subsystem.
DDRI_CK_N[2:0]
DDRI_CS_N[1:0]
DDRI_RAS_N
O
O
O
O
Same as above
No
Yes
Yes
Yes
Chip Select — Must be asserted for all
transactions to the DDR SDRAM device. One
per bank.
Use the same CS to control 32-bit
data + 8-bit ECC, per bank
The RAS signal must be connected
to each device in a daisy chain
manner
Row Address Strobe — Indicates that the
current address on DDRI_MA[13:0] is the row.
The CAS signal must be connected
to each device in a daisy chain
manner
Column Address Strobe — Indicates that the
current address on DDRI_MA[13:0] is the
column.
DDRI_CAS_N
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Table 4.
DDR SDRAM Interface Pin Description (Sheet 2 of 2)
Input
Outpu
t
VTT
Terminatio
n
Name
Device-Pin Connection
Description
The WE signal must be connected
to each device in a daisy chain
manner
Write Strobe — Defines whether or not the
current operation by the DDR SDRAM is to be
a read or a write.
DDRI_WE_N
O
O
Yes
Yes
Data Bus Mask — Controls the DDR SDRAM
data input buffers. Asserting DDRI_WE_N
causes the data on DDRI_DQ[31:0] and
DDRI_CB[7:0] to be written into the DDR
SDRAM devices.
DDRI_DM[4:0] controls this operation on a
per-byte basis. DDRI_DM[3:0] are intended to
correspond to each byte of a word of data.
DDRI_DM[4] is intended to be utilized for the
ECC byte of data.
Connect to each DM device pin.
For the 8-bit devices connect one
DM signal per device.
For the 16-bit devices connect two
DM signal per device (depending
on how many data bits are being
used).
DDRI_DM[4:0]
DDR SDRAM Bank Selects — Controls which of
the internal DDR SDRAM banks to read or
write. DDRI_BA[1:0] are used for all
technology types supported.
The BA signals must be connected
to each device in a daisy chain
manner.
DDRI_BA[1:0]
O
Yes
All address signals need to be
connected to each device in a
daisy chain manner.
Address bits 13 through 0 — Indicates the row
or column to access depending on the state of
DDRI_RAS_N and DDRI_CAS_N.
DDRI_MA[13:0]
DDRI_DQ[31:0]
O
Yes
Yes
Need to be connected in parallel
to achieve a 32-bit bus width.
I/O
Data Bus — 32-bit wide data bus.
ECC Bus — Eight-bit error correction code
which accompanies the data on
DDRI_DQ[31:0].
When ECC is disabled and not being used in a
system design, these signals can be left un-
connected.
DDRI_CB[7:0]
I/O
I/O
Connect to ECC memory devices.
Yes
Yes
Data Strobes Differential — Strobes that
accompany the data to be read or written from
the DDR SDRAM devices. Data is sampled on
the negative and positive edges of these
strobes. DDRI_DQS[3:0] are intended to
correspond to each byte of a word of data.
DDRI_DQS4] is intended to be utilized for the
ECC byte of data.
Connect DQS[3:0] to devices with
data signals and DQS[4] to
devices with ECC signals.
DDRI_DQS[4:0]
Clock enables — One clock after
DDRI_CKE[1:0] is de-asserted, data is latched
on DQ[31:0] and DDRI_CB[7:0]. Burst
counters within DDR SDRAM device are not
incremented. De-asserting this signal places
the DDR SDRAM in self-refresh mode. For
normal operation, DDRI_CKE[1:0] must be
asserted.
Use one CKE per bank, never mix
the CKE on the same bank. Use
CKE[0] for bank0 and CKE[1] for
bank1
DDRI_CKE[1:0]
O
Yes
RECEIVE ENABLE OUT must be connected to
DDRI_RCVENIN_N signal of the IXP45X/
IXP46X product line and the propagation delay
of the trace length must be matched to the
clock trace plus the average DQ Traces.
Connect RCVEOUT to RCVENIN
and follow note on pin description
in this table.
DDRI_RCVENOUT_N
DDRI_RCVENIN_N
O
I
No
No
RECEIVE ENABLE IN provides delay
information for enabling the input receivers
and must be connected to the
Same as above
DDRI_RCVENOUT_N signal of the IXP45X/
IXP46X network processors.
Tied off to a 20 Ohm Resistor connected to ground used for
DDRI_RCOMP
DDRI_VREF
O
I
Tied off to a resistor
VCCM/2
resistor
process/temperature adjustments.
DDR SDRAM Voltage Reference — is used to
supply the reference voltage to the differential
inputs of the memory controller pins.
VCCM/2
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.2.2
DDR SDRAM Memory Interface
The IXP45X/IXP46X network processors support compatible DDR-266 SDRAM, 8- and
16-bit wide devices, with a total bus width of 32 bits. Only 32-bit-wide accesses are
supported.
The maximum supported memory is 1 Gbyte, configured by enabling both physical
banks of DDR-266 SDRAM devices. Each bank can be composed of four 1-Gbit (32 Mbit
X 8 X 4) devices and use one chip-selects per bank. The minimum supported memory
is 32 Mbyte, configured by enabling a single physical bank of DDR-266 SDRAM devices.
The bank would consist of two 128-Mbit (2 Mbit X 16 X 4) devices and using a single
chip-select.
these are all non-buffer devices, as the IXP45X/IXP46X network processors only
support non-buffer memory devices.
For a complete description on how the IXP45X/IXP46X network processors interface to
3.2.3
3.3
DDR SDRAM Initialization
®
®
For instructions on DDR SDRAM initialization, refer to the Intel IXP45X and Intel
IXP46X Product Line of Network Processors Developer’s Manual and its section titled
“DDR SDRAM Initialization.”
Expansion Bus
The Expansion Bus of the IXP45X/IXP46X network processors is specifically designed
for compatibility with Intel- and Motorola*-style microprocessor interfaces and Texas
Instruments* DSP standard Host-Port Interfaces* (HPI).
The expansion bus controller includes a 25-bit address bus and a 32-bit wide data path,
running at a maximum speed of 80 MHz from an external clock oscillator. The bus can
be configure to support the following target devices:
• Intel multiplexed
• Intel non-multiplexed
®
®
• Intel StrataFlash
• Synchronous Intel StrataFlash Memory
• Motorola multiplexed
• Micron* Flow-Through ZBT
• Motorola non multiplexed
• Texas Instruments* Host Port Interface
(HPI)
The expansion bus controller also has an arbiter that supports up to four external
devices that can master the expansion bus. External masters can be used to access
external slave devices that reside on the expansion bus, including access to internal
memory mapped regions within the IXP45X/IXP46X network processors.
All supported modes are seamless and no additional glue logic is required. Other cycle
types may be supported by configuring the Timing and Control Register for Chip Select.
Applications having less than 32 data bits may connect to less than the full 32 bits.
Devices with wider than 32-bit data bus are not supported. A total of eight chip selects
are supported with an address space of up to 32 Mbytes per chip select.
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®
General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
3.3.1
Signal Interface
Table 5.
Expansion Bus Signal Recommendations
Pull
Input
Output
Name
Up
Recommendations
Down
EX_CLK
EX_ALE
I
No
No
Use series termination resistor, 10Ω to 33Ω at the source.
TRI O
Use series termination resistor, 10Ω to 33Ω at the source.
Use 4.7-KΩ resistors for pull-downs; required for boot strapping for initial configuration of
Configuration Register 0. Pull-ups are not required as for when the system comes out of
EX_ADDR[24:0]
I/O
Yes
®
®
For additional details on address strapping, see the Intel IXP45X and Intel IXP46X
Product Line of Network Processors Developer’s Manual.
EX_WR_N
EX_RD_N
I/O
I/O
No
No
Use series termination resistor, 10Ω to 33Ω at the source.
Use series termination resistor, 10Ω to 33Ω at the source.
Use series termination resistor, 10Ω to 33Ω at the source.
Use 10KΩ resistors pull-ups to ensure that the signal remains de-asserted.
EX_CS_N[7:0]
I/O
Yes
EX_DATA[31:0]
EX_BE_N[3:0]
EX_IOWAIT_N
EX_RDY_N[3:0]
EX_PARITY[3:0]
EX_REQ_N[3:1]
EX_REQ_GNT_N
EX_GNT_N[3:1]
EX_GNT_REQ_N
EX_SLAVE_CS_N
EX_BURST
I/O
No
No
I/O
I
Yes
Yes
No
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
I/O
I
Yes
Yes
No
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
O
O
No
I
I
Yes
Yes
No
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
EX_WAIT_N
TRI O
3.3.2
Reset Configuration Straps
At power up or whenever RESET_IN_N is asserted, the Expansion-bus address outputs
are switched to inputs and the state of the inputs are captured and stored in
Configuration Register 0, bits 24 through 0. This occurs when PLL_LOCKED is de-
asserted.
The strapping of Expansion-bus address pins can be done by placing external pull-down
resistors at the required address pin. It is not required to use external pull-up resistors,
by default upon reset all bits on Configuration Register 0 are set High, unless an
external pull down is used to set them Low. For example to register a bit low or high in
the Configuration Register 0, do the following:
Place an external 4.7-KΩ pull-down resistor to set a bit LOW.
No external pull-up is required, by default upon reset, bits are set HIGH.
The state of the boot-strapping resistor is register on the first cycle after the
synchronous de-assertion of the reset signal. These bits can be read or written as
needed for desired configurations. It is recommended that only Bit 31, Memory Map, be
changed from 1 to 0 after execution of boot code from external flash.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
®
For a complete bit description of Configuration Register 0, see the Intel IXP45X and
®
Intel IXP46X Product Line of Network Processors Developer’s Manual.
Table 6.
Boot/Reset Strapping Configuration (Sheet 1 of 2)
Name
Function
Description
EX_ADDR[24]
(Reserved)
(Reserved)
®
Intel XScale
Processor
®
Allows changing Intel XScale Processor clock speed. This overrides device fuse
settings. However cannot be used to over-clock core speed.
EX_ADDR[23:21]
Clock Set[2:0]
EX_ADDR[20:17]
EX_ADDR[16:11]
Customer
Customer-defined bits. (Might be used for board revision.)
(Reserved)
(Reserved)
1 = EX_IOWAIT_N is sampled during the read/write expansion bus cycles for Chip
Select 0.
0 = EX_IOWAIT_N is ignored for read and write cycles to Chip select 0 if
EXP_TIMING_CS0 is configured to Intel mode.
Typically, IOWAIT_CS0 must be pulled down to Vss when attaching a Synchronous
®
Intel StrataFlash on Chip Select 0 since the default mode for EXP_TIMING_CS0 is
Intel mode and EX_IOWAIT_N is an unknown value for Synchronous Intel
StrataFlash.
EX_ADDR[10]
IOWAIT_CS0
If the board does not connect the Synchronous Intel StrataFlash WAIT pin to
EX_WAIT_N (and the board guarantees EX_IOWAIT_N is pulled up), the value of
IOWAIT_CS0 is a don’t-care, since EX_IOWAIT_N will not be asserted.
When EXP_TIMING_CS0 is reconfigure to Intel Synchronous mode during boot-up
(for synchronous Intel chips), the expansion bus controller ignores EX_IOWAIT_N
during read and write cycles since the WAIT functionality is determined from the
EXP_SYNCINTEL_COUNT and EXP_TIMING_CS registers.
EX_ADDR[9]
EX_ADDR[8]
EXP_MEM_DRIVE
USB Clock
Refer to table found in EX_ADDR[5].
Controls the USB clock select.
1 = USB Host/Device clock is generated internally
0 = USB Device clock is generated from GPIO[0].
USB Host clock is generated from GPIO[1]. When generating a spread spectrum
clock on OSC_IN, GPIO[0] can be driven from the system board to generate a
48-MHz clock for the USB Device and GPIO[1] can be driven from the system board
to generate a 60-MHz clock for the USB Host.
EX_ADDR[7]
EX_ADDR[6]
32_FLASH
EXP_ARB
Refer to table found in EX_ADDR[0]
Configures the Expansion bus arbiter.
0 = External arbiter for Expansion bus.
1 = Expansion bus controller arbiter enabled
Expansion bus low/medium/high drive strength. The drive strength depends on
EXP_DRIVE and EXP_MEM_DRIVE configuration bits.
B9. B5
---------------------------------------------------------------------------------------
EX_ADDR[5]
EXP_DRIVE
0
. . 0 Reserved
0
1
1
. . 1 Medium Drive
. . 0 Low Drive
. . 1 High Drive
Sets the clock speed of the PCI Interface
0 = 33 MHz
1 = 66 MHz
EX_ADDR[4]
EX_ADDR[3]
PCI_CLK
(Reserved)
(Reserved). EX_ADDR[3] must not be pulled down during address strapping.
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Table 6.
Boot/Reset Strapping Configuration (Sheet 2 of 2)
Name
Function
Description
Enables the PCI Controller Arbiter
0 = PCI arbiter disabled
1 = PCI arbiter enabled
EX_ADDR[2]
EX_ADDR[1]
PCI_ARB
Configures the PCI Controller as PCI Bus Host
0 = PCI as non-host
PCI_HOST
1 = PCI as host
Specifies the data bus width of the FLASH memory device found on Chip Select 0.
The data bus is based upon bits 0 and 7 of Configuration Register 0.
32_FLASH 8/16_FLASH Data bus size
B7 . B0
-------------------------------------------------------------------------------------
EX_ADDR[0]
8/16_FLASH
0
0
1
1
. . 0 16-bit
. . 1 8-bit
. . 0 (Reserved)
. . 1 32-bit
3.3.3
8-Bit Device Interface
The IXP45X/IXP46X network processors support 8-bit-wide data bus devices (byte
mode). For Intel interface cycles, the data lines and control signals can be connected as
the remaining data signals not being used EX_DATA[31:8], are driven by the processor
to an unpredictable state on WRITE cycles and tri-stated during READ cycles.
When booting an 8-bit flash device, the expansion bus must be configured during reset
to the 8-bit mode (see Configuration Register 0). To accomplish this, boot-strapping is
required in certain address pins of the Expansion bus. For example, as in this case
when booting of an 8-bit flash device, bit 0 and 7 of Configuration Register 0 must be
set as follows:
Bit 0 = 1. By default this bit is set high when coming off reset or any time reset is
asserted.
Bit 7 = 0. This can be done by placing an external 4.7-KΩ pull-down resistor to pin
EX_ADDR[7].
If it is required to change access mode, after the system has booted, and during
normal operation; the Timing and Control Register for Chip Select must be configured
to perform the desired mode access. For a complete description on accomplishing this
®
®
refer to the “Expansion Bus” chapter in the Intel IXP45X and Intel IXP46X Product
Line of Network Processors Developer’s Manual.
3.3.4
16-Bit Device Interface
The IXP45X/IXP46X network processors support 16-bit wide data bus devices (16-bit
word mode). For Intel interface cycles, the data lines and control signals can be
mode accesses, the remaining data signals not being used EX_DATA[31:16], are driven
by the processor to an unpredictable state on WRITE cycles and tri-stated during READ
cycles.
When booting a 16-bit flash device, the expansion bus must be configured during reset
to the 16-bit mode (see Configuration Register 0). To accomplish this, boot-strapping is
required in certain address pins of the Expansion bus.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
For example, as in this case when booting of a 16-bit flash device, bit 0 and 7 of
Configuration Register 0 must be set as follows:
• Bit 0 = 0.
This can be done by placing an external 4.7-KΩ pull-down resistor to pin
EX_ADDR[0].
• Bit 7 = 0.
This can be done by placing an external 4.7-KΩ pull-down resistor to pin
EX_ADDR[7].
If it is required to change access mode, after the system has booted, and during
normal operation; the Timing and Control Register for Chip Select must be configured
to perform the desired mode access. For a complete description on accomplishing this
®
®
refer to the “Expansion Bus” chapter in the Intel IXP45X and Intel IXP46X Product
Line of Network Processors Developer’s Manual.
3.3.5
32-Bit Device Interface
The IXP45X/IXP46X network processors support 32-bit wide data bus devices (32-bit
word mode). For Intel interface cycles, the data lines and control signals can be
When booting a 32-bit flash device, the expansion bus must be configured during reset
to the 32-bit mode (see Configuration Register 0). To accomplish this, boot-strapping is
required in certain address pins of the Expansion bus. For example, as in this case
when booting of a 32-bit flash device, bit 0 and 7 of Configuration Register 0 must be
set as follows:
• Bit 0 = 1.
By default this bit is set high when coming off reset or any time reset is asserted.
• Bit 7 = 1.
By default this bit is set high when coming off reset or any time reset is asserted.
If it is required to change access mode, after the system has booted, and during
normal operation; the Timing and Control Register for Chip Select must be configured
to perform the desired mode access. For a complete description on accomplishing this
®
®
refer to the “Expansion Bus” chapter in the Intel IXP45X and Intel IXP46X Product
Line of Network Processors Developer’s Manual.
®
®
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®
General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Figure 3.
8/16/32-Bit Device Interface: No Byte-Enable
EX_DATA[31:0]
EX_DATA[7:0]
DATA[7:0]
Intel® IXP46X
Product Line of
8-Bit Device
Byte Access
Network Processors
EX_ADDR[24:0]
EX_ADDR[24:0]
ADDR[24:0]
EX_CS_N
EX_RD_N
EX_WR_N
CS
OE
WR
CS_N
OE_N
WR_N
EX_DATA[31:0]
EX_DATA[15:0]
DATA[15:0]
Intel® IXP46X
Product Line of
Network Processors
EX_ADDR[24:0]
16-Bit Device
16-Bit-Word Access
ADDR[24:0]
EX_ADDR[24:0]
EX_CS_N
EX_RD_N
EX_WR_N
CS
OE
WR
CS_N
OE_N
WR_N
EX_DATA[31:0]
Intel® IXP46X
Product Line of
EX_DATA[31:0]
EX_ADDR[24:0]
DATA[31:0]
32-Bit Device
32-Bit-Word Access
ADDR[24:0]
Network Processors
EX_ADDR[24:0]
EX_CS_N
EX_RD_N
EX_WR_N
CS
OE
WR
CS_N
OE_N
WR_N
B4095-002
®
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Intel IXP45X and Intel IXP46X Product Line of Network Processors
February 2007
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
Figure 4.
8/16/32-Bit Device Interface: Byte Enable
EX_DATA[31:0]
EX_DATA[7:0]
DATA[7:0]
Intel® IXP46X
Product Line of
Network Processors
EX_ADDR[24:0]
8-Bit Device
Byte Access
EX_ADDR[24:0]
ADDR[24:0]
EX_CS_N
EX_RD_N
EX_BE_N0
CS
OE
WR0
CS_N
OE_N
WR_N
EX_DATA[31:0]
EX_DATA[15:0]
EX_ADDR[24:0]
DATA[15:0]
Intel® IXP46X
Product Line of
Network Processors
EX_ADDR[24:0]
16-Bit Device
16-Bit-Word Access
ADDR[24:0]
EX_CS_N
EX_RD_N
EX_BE_N0
EX_BE_N1
CS
OE
WR0
WR1
CS_N
OE_N
WR_N0
WR_N1
EX_DATA[31:0]
Intel® IXP46X
Product Line of
Network Processors
EX_DATA[31:0]
EX_ADDR[24:0]
DATA[31:0]
32-Bit Device
32-Bit-Word Access
ADDR[24:0]
EX_ADDR[24:0]
EX_CS_N
EX_RD_N
EX_BE_N0
EX_BE_N1
EX_BE_N2
EX_BE_N3
CS
OE
WR0
WR1
WR2
WR3
CS_N
OE_N
WR_N0
WR_N1
WR_N2
WR_N3
B4096-003
®
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
3.3.6
Flash Interface
Figure 5 illustrates how a boot ROM is connected to the expansion bus. The flash (ROM)
®
used in the block diagram is the Intel StrataFlash memory device TE28F256J3D —
32-Mbyte, 16-bit, flash in the 56-TSOP package. The Intel StrataFlash memory
TE28F256J3D is part of the 0.13-micron, 3.3-V Intel StrataFlash memory.
The E28F256J3D supports common flash interface (CFI). For information on migrating
®
from J3 to J3D Intel StrataFlash memory, see the Intel StrataFlash Memory J3 to
®
Intel Embedded Flash Memory (J3 v.D) Conversion Guide - Application Note 835
(document 308555).
For information on migrating from J3 to P30 Intel StrataFlash memory, see the
®
®
Migration Guide for Intel StrataFlash Memory (J3) to Intel StrataFlash Embedded
Memory (P30 and P33) - Application Note 835 (document 308555).
IXP46X network processors. Boot-strapping is required in the address bus, both
EX_ADDR[0] and EX_ADDR[7] need external, 4.7-KΩ pull-down resistors (not shown
on diagram). The pull-down resistors sets Bits 0 and 7 low in the Configuration Register
0. This in turn sets the processor into a 16-bit-mode access.
Figure 5.
Flash Interface Example
EX_DATA[31:0]
Intel® IXP46X
Product Line of
Network Processors
EX_ADDR[24:0]
DATA[15:0]
EX_DATA[15:0]
EX_ADDR[24:0]
16-Bit Device
16-Bit-Word Access
ADDR[24:0]
EX_CS_N
EX_RD_N
EX_WR_N
CS
OE
WR
CE0
OE_N
WR_N
Intel® Flash
3.3 V
RST#
RP_N
CE1
CE2
4.7 KΩ
4.7 KΩ
BYTE_N
VPEN_N
4.7 KΩ
B4097-003
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.3.7
SRAM Interface
A typical connection between an 8-bit SRAM memory device and the IXP45X/IXP46X
to communicate to this device, the Timing and Control Register for Chip Select must be
®
®
configured for proper access. For more information, see the Intel IXP45X and Intel
IXP46X Product Line of Network Processors Developer’s Manual.
.
Figure 6.
Expansion Bus SRAM Interface
DATA[7:0]
EX_DATA[31:0]
Intel® IXP46X
EX_DATA[7:0]
8-Bit Device
Product Line of
Network Processors
Byte Access
EX_ADDR[18:0]
ADDR[18:0]
EX_ADDR[24:0]
CS
OE
WR
E#
G#
W#
EX_CS_N
EX_RD_N
EX_WR_N
512 Kbyte-x-8
SRAM
Interface
B4098-003
3.3.8
Design Notes
Care must be taken when loading the bus with too many devices. As more devices are
added, the loading capacity adds up — to the point where timing can become critical.
To account for this, timing on the expansion bus may be adjusted in the Timing and
Control Register for Chip Select. If an edge rises slowly due to low drive strength, the
processors should wait an extra cycle before the value is read. For more information,
see the documentation on Timing and Control Register for Chip Select bits [29:16] in
®
®
the Intel IXP45X and Intel IXP46X Product Line of Network Processors Developer’s
Manual.
3.4
UART Interface
The IXP45X/IXP46X network processors provide two dedicated, Universal
Asynchronous Receiver/Transmitter Serial Ports (UARTs). These are high-speed UARTs,
capable of supporting baud rates from 1,200 Baud to 921.6 KBaud.
The hardware supports a four-wire interface:
• Transmit Data
• Receive Data
• Request to Send
• Clear to Send
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Network Processors
Note:
The UART module does not support full modem functionality. However, this can be
implemented, by using GPIO ports to generate DTR, DSR, RI, and DCD and making
some changes to the driver.
3.4.1
Signal Interface
Table 7.
UART Signal Recommendations
Pull
Up
Down
Input
Output
Name
Recommendations
Serial data input Port 0.
RXDATA0
TXDATA0
CTS0_N
RTS0_N
RXDATA1
TXDATA1
CTS1_N
RTS1_N
I
O
I
Yes
No
When signal is not being used in the system, this pin should be pulled high with a 10-KΩ
resistor.
Serial data output Port 0.
Clear-To-Send Port 0.
\When signal is not being used in the system, this pin should be pulled high with a 10-KΩ
resistor.
Yes
No
O
I
Request-To-Send Port 0.
Serial data input Port 1.
When signal is not being used in the system, this pin should be pulled high with a 10-KΩ
resistor.
Yes
No
O
I
Serial data output Port 1.
Clear-To-Send Port 1.
Yes
No
When signal is not being used in the system, this pin should be pulled high with a 10-KΩ
resistor.
O
Request-To-Send Port 1.
The following figure contain a typical four signal interface between the UART and an
RS-232 transceiver driver, required to interface with external devices. Unused inputs to
the RS-232 driver can be connected to ground. This avoids signals floating to
undetermined states which can cause over heating of the driver leading to permanent
damage.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
Figure 7.
UART Interface Example
DB9
Connector
1 DCD
1
CTS1_N
OUT4
IN3
2 RX
3 TX
6
7
RTS1_N
RXDATA1
TXDATA1
IN1
OUT3
OUT2
2
3
OUT1
IN2
4 DTR
5 GND
IN4
8
9
6 DSR
7 RTS
Intel® IXP46X
4
5
Intel® IXP46X
NC
Product Line of
RS-232
Transceiver
Product Line of
Network Processors
Network Processors
8 CTS
9 RI
B4099-003
3.5
MII/SMII Interface
The IXP45X/IXP46X network processors support a maximum of three Ethernet MACs.
Depending on the IXP45X/IXP46X network processors part number used, various
combinations can be used. For the various features that can be enable a variety of
®
®
needs, see the Intel IXP45X and Intel IXP46X Product Line of Network Processors
Datasheet.
All MACs contained in the NPEs are compliant to the IEEE 802.3 specification and
handle flow control for the IEEE 802.3Q VLAN specification.
The Management Data Interface (MDI) supports a maximum of 32 PHY addresses. MDI
signals are required to be connected to every PHY chip. Each PHY port is assign a
unique address in the external PHY chip from 0 to 31, totaling a maximum of 32 PHY
addresses. The maximum number of MACs supported by the IXP45X/IXP46X network
processors is three.
The MII interface supports clock rates of 25 MHz for 100-Mbps operation or 2.5 MHz for
10-Mbps operation.
SMII interface supports clock rate of 125 MHz for 10/100-Mbps operation.
General PHY Ethernet devices routing guidelines can be found in Section 5.2.3, “SMII
Signal Considerations” on page 67. For more detailed information, see the IEEE 802.3
specification.
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
3.5.1
Signal Interface MII
Table 8.
MII NPE A Signal Recommendations
Pull
Input/
Up
Name
Recommendations
Output
Down
Transmit Clock.
ETHA_TXCLK
I
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
ETHA_TXDATA[3:0]
ETHA_TXEN
O
O
No
No
Transmit Data.
Transmit Enable.
Receive Clock.
ETHA_RXCLK
ETHA_RXDATA[3:0]
ETHA_RXDV
I
I
I
I
I
Yes
Yes
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive Data.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive Data Valid.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Collision Detect.
ETHA_COL
If operating in a full duplex mode and there is no requirement to use the Collision
Detect signal, then the pin must be pulled low with a 10-KΩ resistor.
Carrier Sense.
ETHA_CRS
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
Table 9.
MII NPE B Signal Recommendations (Sheet 1 of 2)
Pull
Input/
Output
Name
Up/
Recommendations
Down
Transmit Clock.
ETHB_TXCLK
I
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
ETHB_TXDATA[3:0]
ETHB_TXEN
O
O
No
No
Transmit Data.
Transmit Enable.
Receive Clock.
ETHB_RXCLK
I
I
I
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive Data.
ETHB_RXDATA[3:0]
ETHB_RXDV
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive Data Valid.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
Table 9.
MII NPE B Signal Recommendations (Sheet 2 of 2)
Pull
Input/
Output
Name
Up/
Recommendations
Down
Collision Detect.
ETHB_COL
I
Yes
Yes
If operating in a full duplex mode and there is no requirement to use the Collision
Detect signal, then the pin must be pulled low with a 10-KΩ resistor.
Carrier Sense.
ETHB_CRS
I
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
Table 10.
MII NPE C Signal Recommendations
Pull
Input/
Up/
Name
Recommendations
Output
Down
Transmit Clock.
ETHC_TXCLK
I
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
ETHC_TXDATA[3:0]
ETHC_TXEN
O
O
No
No
Transmit Data.
Transmit Enable.
Receive Clock.
ETHC_RXCLK
ETHC_RXDATA[3:0]
ETHC_RXDV
I
I
I
I
I
Yes
Yes
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive Data.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive Data Valid.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Collision Detect.
ETHC_COL
If operating in a full duplex mode and there is no requirement to use the Collision
Detect signal, then the pin must be pulled low with a 10-KΩ resistor.
Carrier Sense.
ETHC_CRS
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in note 1 — only require
pull-ups or pull-downs in the clock-input signals.
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Network Processors
Table 11.
MAC Management Signal Recommendations NPE A,B,C
Pull
Input/
Output
Name
Up/
Recommendations
Down
NPE A,B,C
Management data output.
An external pull-up resistor of 1.5 KΩ is required on ETH_MDIO to properly quantify the
external PHYs used in the system. For specific implementation, see the IEEE 802.3
specification.
ETH_mdio
I/O
Yes
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
NPE A,B,C
Management data clock.
ETH_mdc
I/O
No
3.5.2
Device Connection, MII
Figure 8 is a typical example of an Ethernet PHY device interfacing to one of the MACs
via the MII hardware protocol.
Figure 8.
MII Interface Example
Intel®IXP46X
Product Line of
Network Processors
10/100
PHY
TXEN
ETH_TXEN
ETH_TXCLK
TXCLK
TXDATA[3:0]
ETH_TXDATA[3:0]
ETH_RXDV
ETH_RXCLK
RXDV
Magnetics
RJ45
RXCLK
ETH_RXDATA[3:0]
RXDATA[3:0]
ETH_COL
ETH_CRS
COL
CRS
25 MHz
VCC (3.3 V)
1.5 KΩ
MDIO
MDC
ETH_MDIO
ETH_MDC
MII Interface
B4101-003
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.5.3
Signal Interface, SMII
Serial Media Independent Interface (SMII) is a hardware feature to convey complete
MII interface between a MAC and 10/100 PHY interface with two data pins per port and
one synchronizing signal for multi PHYs.
Table 12.
SMII Signal Recommendations: NPE A, B, C
Pull
Input/
Output
Name
Up/
Recommendations
Down
NPE A
Transmit Data Port 4.
SMII_TXDATA[4]
SMII_RXDATA[4]
O
No
NPE A
Received Data Port 4.
When this interface/signal is enabled and is not being used in a system design, the
I
Yes
interface/signal should be pulled high with a 10-KΩ resistor.
NPE A,B,C
Reference Clock, 125-MHz.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
SMII_CLK
I
Yes
No
SMII_TXDATA[0] /
SMII_TXDATA[1] /
SMII_TXDATA[2] /
SMII_TXDATA[3]
NPE B
O
Transmit Data Ports 3,2,1,0.
NPE B
Transmit Data Ports 3,2,1,0.
SMII_RXDATA[0] /
SMII_RXDATA[1] /
SMII_RXDATA[2] /
SMII_RXDATA[3]
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
I
Yes
One special configuration exists for the board designer. When NPE B is configured in SMII
mode of operation and a subset of the four SMII ports are utilized (i.e. All four are enabled
but only two are being connected). The unused inputs must be tied high with a 10-KΩ
resistor.
NPE B
Synchronous pulse.
SMII_SYNC
ETH_MDIO
O
No
NPE A,B,C
Management data output.
An external pull-up resistor of 1.5 KΩ is required on ETH_MDIO to properly quantify the
external PHYs used in the system. For specific implementation, see the IEEE 802.3
specification.
I/O
Yes
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
NPE A,B,C
Management data clock.
ETH_MDC
I/O
O
No
No
NPE C
Transmit Data Ports 5.
SMII_TXDATA[5]
NPE C
SMII_RXDATA[5]
I
Yes
Receive Data Ports 5.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
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3.5.4
Device Connection, SMII
Figure 9.
SMII Interface Example
Intel® IXP46X
Product Line
Network Processor
10/100
PHY
SMII_TXSYNC
SMII_TXDATA
SMII_RXDATA
TXSYNC
TXDATA
RXDATA
Magnetics
RJ45
VCC (3.3 V)
1.5 KΩ
ETH_MDIO
ETH_MDC
MDIO
MDC
125 MHz
REF CLK
SMII_CLK
SMII Interface
B4103-002
3.6
GPIO Interface
The IXP45X/IXP46X network processors provide 16 general-purpose input/output pins
for use in generating and capturing application specific input and output signals. Each
individual pin can be programmed as either an input or output.
When programmed as an input, GPIO0 through GPIO12 can be configured to be an
interrupt source. Interrupt sources can be configured to detect either active high,
active low, rising edge, falling edge, or transitional. In addition, GPIO14 and GPIO15
can be programmed to provide a user-programmable clock out.
During reset, all pins are configured as inputs and remain in this state until configured
otherwise, with the exception of GPIO15, which by default provides a clock output. The
driver strength of GPIO pins is sufficient to drive external LEDs with a proper limiting
resistor.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.6.1
Signal Interface
Table 13.
GPIO Signal Recommendations
Pull
Input/
Name
Up/
Recommendations
Output
Down
General Purpose Input/Output.
If used as an input interrupt, should be pull-up or pull-down, depending on the level of
activation. For example:
Active high, use a 10-KΩ pull-down resistor.
GPIO[12:0]
I/O
Yes
Active low, use a 10-KΩ pull-up resistor.
Should be pulled high through a 10-KΩ resistor when not used.
General Purpose Input/Output.
Same recommendations as GPIO[12:0]
GPIO[13]
GPIO[14]
I/O
I/O
Yes
Yes
General Purpose Input/Output.
Same recommendations as GPIO[12:0]. An additional feature includes Clock generation, max
clock out 33.33 MHz., set as input by default.
General Purpose Input/Output.
GPIO[15]
I/O
Yes
Same recommendations as GPIO[12:0]. An additional feature includes Clock generation, max
clock out 33.33 MHz., set as output by default.
3.6.2
Design Notes
The drive strength for GPIO[15:14] is limited to 8 mA, while GPIO [13:0] can output up
to 16 mA. When used for driving high current devices such as LEDs or relays, make
sure to place current-limiting resistor or permanent damage to the IXP45X/IXP46X
network processors driver might be done.
It is recommended that a 10-KΩ pull-up resistor be used when a GPIO port is
configured as an input and not being used.
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
2
3.7
I C Interface
2
The IXP45X/IXP46X network processors support I C interface and protocol. The
hardware-embedded block supports transfer rates in Standard-mode at up to 100 Kbps
or Fast-mode at up to 400 Kbps, 7-bit addressing, and Master or Slave mode.
Note:
The I2C block does not support 10-bit addressing mode.
2
2
Figure 10 shows the schematic for connecting the I C interface to a 256-byte I C
EEPROM, 7-bit addressing mode (Philips* PC8582C-2T/03).
3.7.1
Signal Interface
Table 14.
I2C Signal Recommendations
Pull
Up
Down
Input
Name
Recommendations
Output
I/O
Serial Data.
I2C_SCL
I2C_SDA
Yes
Yes
Use a 4.7-KΩ pull-up resistor.
Serial Clock.
I/O
Use a 4.7-KΩ pull-up resistor.
3.7.2
Device Connection
®
®
®
®
More information is available from the Intel IXP45X and Intel IXP46X Product Line of
Network Processors Datasheet and the Intel IXP45X and Intel IXP46X Product Line
of Network Processors Developer’s Manual.
Note:
Because of the characteristics of the I2C bus (Open Drain/Collector) pull-up resistors
are required. Use 2 KΩ to 10 KΩ. resistors.
2
The I C-Bus Specification, available from Philips Semiconductors*, states:
The external pull-up resistor connected to the bus lines must be adapted to
2
accommodate the shorter maximum permissible rise time for the Fast-mode I C-bus.
For bus loads up to 200 pF, the pull-up device for each bus line can be a resistor; for
bus loads between 200 pF and 400 pF, the pull-up device can be a current source
(3 mA max.) or a switched resistor circuit. The actual value of the pull-up is system
2
dependent and a guide is presented in the I C-Bus Specification on determining the
maximum and minimum resistors to use when the system is intended for standard or
2
fast-mode I C bus devices.
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Design Considerations
2
Figure 10.
I C EEPROM Interface Example
3.3 V
Intel® IXP46X
Product Line
Network Processor
0.1 µF
8
VCC
1
2
7
6
A0
A1
A2
WP
I2C_SCL
I2C_SDA
I2C_SCL
I2C_SDA
SCL
5
3
SDA
I2C EEPROM
GND
I2C Interface
4
I2C Interface
B4104-002
3.8
USB Interface
There are two USB controllers in the IXP45X/IXP46X network processors — one is a
Host controller and the other a Device controller.
The Host controller is a USB v2.0 module. It supports Low-Speed, 1.5 Mbps and Full-
Speed, 12 Mbps, however, it does not support the High-Speed, 480 Mbps rate.
The Device controller supports USB v1.1 module. It supports most standard device
requests issued by any USB host controller. It is an USB device-only controller. The
interface supports Low-Speed, 1.5 Mbps and Full-Speed, 12 Mbps.
There are:
• Six isochronous endpoints (three input and three output)
• One control endpoint
• Three interrupt endpoints
• Six bulk endpoints (three input and three output)
Revision 1.1.
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
3.8.1
Signal Interface
Table 15.
USB Host/Device Signal Recommendations
Pull
Input/
Output
Name
Up/
Recommendations
Down
Positive signal of the differential USB receiver/driver for the USB device interface.
Use an 18Ω series termination resistor at the source.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled low with a 10-KΩ resistor.
USB_DPOS
I/O
Yes
Yes
Yes
Yes
Negative signal of the differential USB receiver/driver for the USB device interface.
Use an 18Ω series termination resistor at the source.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled low with a 10-KΩ resistor.
USB_DNEG
USB_HPOS
USB_HNEG
I/O
I/O
I/O
Positive signal of the differential USB receiver/driver for the USB host interface.
Use a 20Ω series termination resistor at the source.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled low with a 10-KΩ resistor.
Negative signal of the differential USB receiver/driver for the USB host interface.
Use a 20Ω series termination resistor at the source.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled low with a 10-KΩ resistor.
USB_HPEN
USB_HPWR
Notes:
O
I
No
Enable to the external VBUS power source
External VBUS power.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Yes
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only required
pull-ups or pull-downs in the clock-input signals.
The Host controller can not be used as a Device controller; however there is a second
USB module with a Device controller capability that can be implementation for this
speed or Full-speed, the 1.5K resistor shown near the device interface must be
connected, either on the D+ or D-.
Speed configuration at the Device can be set as stated in note 1 and 2 bellow. For more
details, refer to the Universal Serial Bus Specification, Revision 1.1.
Note:
1. If a 1.5-KΩ, pull-up resistor is connected to USB_DPOS line, the USB port is
identified as Full-speed (12 Mbps).
2. If a 1.5-KΩ, pull-up resistor is connected to USB_DNEG line, the USB port is
identified as Low-speed (1.5 Mbps).
3. The processors’ USB drivers are CMOS. They require series termination resistors on
both signals of the differential pair USB_DPOS and USB_DNEG. The value of the
series resistor depends upon the variation of the driver’s impedance.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
To maintain signal integrity and minimize end-users termination mismatch, the
IXP45X/IXP46X network processors require external series termination resistors. The
value of terminating resistors is based on the operational speed and length of the
transmission line. It is recommended to start with a 18-Ω resistor and adjust the value
if required.
Note:
recommends using 18 Ω for the Device port.
3.8.2
Device Connection
Figure 11.
USB Host Down Stream Interface Example
USB_VDD
Host
Device
Intel® IXP46X
Product Line
Network Processor
200 mA
0.1 µF
FERRITE
47 µF
0.1 µF
V_BUS USB_3V3
USB_HPEN
USB_HPWR
4.7 µF
1.5 KΩ
Look at
Note 1&2
20 Ω
USB_HPOS
(D+)
D
+
FERRITE
Device
22 pF 22 pF
D-
15 KΩ
USB
Port
20 Ω
USB_HNEG
(D-)
FERRITE
22 pF 22 pF
15 KΩ
B4105-002
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®
General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Figure 12.
USB Device Interface Example
Device
Host
Intel® IXP46X
Product Line
Network Processor
V_BUS
USB_3V3
V_BUS
1.5 KΩ
Look at
Note 1&2
18 Ω
USB_DPOS
(D+)
D
+
FERRITE
HOST
22 pF 22 pF
D-
USB
Port
15 KΩ
15 KΩ
18 Ω
USB_DNEG
(D-)
FERRITE
22 pF 22 pF
B4106-003
3.9
UTOPIA Level 2 Interface
The IXP45X/IXP46X network processors support the industry-standard UTOPIA Level 2
bus interface. A dedicated Network Processor Engine (NPE) handles segmentation and
reassembly of ATM cells, CRC checking/generation, and transfer of data to/from
memory. This allows parallel processing of data traffic on the UTOPIA interface, off-
loading processor overhead required by the Intel XScale processor.
The UTOPIA module is configured as a master and can support single-PHY (SPHY) or
multi-PHY (MPHY).
The IXP45X/IXP46X network processors are in compliance with the ATM Forum, UTOPIA
Level 2 Specification, Revision 1.0. For optimal design results, the guidelines of the
specification should be followed.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.9.1
Signal Interface
Table 16.
UTOPIA Signal Recommendations
Pull
Input/
Up/
Name
Recommendations
Output
Down
UTOPIA Transmit clock input. Also known as UTP_TX_CLK.
UTP_OP_CLK
UTP_OP_FCO
I
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
UTOPIA flow control output signal. Also known as the TXENB_N signal.
When this interface/signal is enabled and is not being used in a system design, the
O
interface/signal should be pulled high with a 10-KΩ resistor.
Start of Cell. Also known as TX_SOC.
UTP_OP_SOC
O
O
Yes
No
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled low with a 10-KΩ resistor.
UTP_OP_DATA[7:0]
UTP_OP_ADDR[4:0]
UTOPIA output data.
Transmit PHY address bus.
When this interface/signal is enabled and is not being used in a system design, the
I/O
Yes
interface/signal should be pulled high with a 10-KΩ resistor.
UTOPIA Output data flow control input: Also known as the TXFULL/CLAV signal.
UTP_OP_FCI
UTP_IP_CLK
UTP_IP_FCI
UTP_IP_SOC
I
I
I
I
Yes
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
UTOPIA Receive clock input. Also known as UTP_RX_CLK.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
UTOPIA Input Data flow control input signal. Also known as RXEMPTY/CLAV.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Start of Cell. Also known as RX_SOC
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
UTOPIA input data. Also known as RX_DATA.
UTP_IP_DATA[7:0]
UTP_IP_ADDR[4:0]
UTP_IP_FCO
I
Yes
No
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
I/O
O
Receive PHY address bus.
UTOPIA Input Data Flow Control Output signal: Also known as the RX_ENB_N.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Yes
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
3.9.2
Device Connection
via the UTOPIA bus. Notice that depending on the framer used some control signals
might be required which can be derived from the Expansion bus or the GPIO signals.
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Figure 13.
UTOPIA Interface Example
Intel® IXP45X/46X
Product Line
Network Processor
Control Signals
EX_BUS
Analog Front
End
25 MHz
ATM Layer Device
ADSL Framer
Multi-Channel
AFE
RJ11
UTP_OP_CLK
UTP_OP_FCO
UTP_OP_ADDR[4:0]
TXCLK
TXENB#
TXADDR[4:0]
TXCLAV
TXSOC
UTP_OP_FCI
UTP_OP_SOC
TXDATA[7:0]
UTP_OP_DATA[7:0]
RXENB#
UTP_IP_FCO
UTP_IP_ADDR[4:0]
RXADDR[4:0]
UTP_IP_FCI
RXCLAV
RXSOC
UTP_IP_SOC
UTP_IP_DATA[7:0]
RXDATA[7:0]
AFE
RJ11
UTP_IP_CLK
RXCLK
UTOPIA Level 2
Interface
25 MHz
SDRAM
Local Memory
B4107-003
3.10
HSS Interface
NPE A has an integrated High-Speed Serial (HSS) module, whose primary function is to
provide connectivity between the internal NPE A and the external HSS interface. There
are two HSS ports that can directly interface to SLIC/CODEC devices for voice
applications, or serial DSL framers. The HSS ports are software configurable to support
various serial protocols, such as T1/ E1/J1, and MVIP. For a list of supported protocols,
®
see the Intel IXP400 Software Programmer’s Guide.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.10.1
Signal Interface
Table 17.
High-Speed, Serial Interface 0
Pull
Input
Name
HSS_TXFRAME0
HSS_TXDATA0
HSS_TXCLK0
Up
Recommendations
Output
Down
Transmit frame.
I/O
OD
I/O
I/O
I
Yes
Yes
Yes
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Transmit data out. Open Drain Output.
When this interface/signal is enabled and is either used or not used in a system design,
the interface/signal should be pulled high with a 10-KΩ resistor to V
.
CCP
Transmit clock.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive frame.
HSS_RXFRAME0
HSS_RXDATA0
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive data input.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive clock.
HSS_RXCLK0
I/O
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features Enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Table 18.
High-Speed, Serial Interface 1
Pull
Input
Output
Down
Name
Up
Recommendations
Transmit frame.
HSS_TXFRAME1
HSS_TXDATA1
HSS_TXCLK1
I/O
OD
I/O
I/O
I
Yes
Yes
Yes
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Transmit data out. Open Drain output.
When this interface/signal is enabled and is either used or not used in a system design,
the interface/signal should be pulled high with a 10-KΩ resistor to V
.
CCP
Transmit clock.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive frame.
HSS_RXFRAME1
HSS_RXDATA1
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive data input.
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Receive clock.
HSS_RXCLK1
I/O
When this interface/signal is enabled and is not being used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.10.2
Device Connection
Figure 14 shows a typical interface between the IXP45X/IXP46X product line and a
SLIC CODEC, via the SSP and HSS ports, and a couple of GPIO signals.
Figure 14.
HSS Interface Example
Intel®IXP46X
Vccp (3.3 V)
Product Line of
External Oscillator
10 KΩ
Network Processors
GPIO_0
GPIO_1
Clock derived internally
from 3.6864 MHz
or external oscilator
SSP_EXTCLK
33 MHz
RESET_N INT_N
SSP_SCLK
SSP_SFRM
SSP_TXD
CLK
CS_N
D I
SSP_RXD
DO
Vccp (3.3 V)
SSP Interface
10 KΩ
HSS_TX_FRAME0
HSS_TXDATA0
HSS_TXCLK0
RJ11
DTX
AFE
HSS_RXFRAME0
HSS_RXDATA0
HSS_RXCLK0
FSYNC
RXD
PCLK
Vccp (3.3 V)
Clock derived from
SLIC/CODEC
or external oscilator
SLIC CODEC
10 KΩ
HSS_TX_FRAME1
HSS_TXDATA1
HSS_TXCLK1
HSS_RXFRAME1
512 KHz to
8.192 MHz
Unused
HSS
HSS_RXDATA1
HSS_RXCLK1
HSS Interface
Vccp (3.3 V)
B4108-003
3.11
SSP Interface
The IXP45X/IXP46X network processors have a Synchronous Serial Peripheral Interface
(SSP) module. Its primary function is to provide connectivity between the Intel XScale
processor and an external SSP interface.
The SSP module supports National Microwire*, Texas Instruments* synchronous serial
protocol (SSP), and Motorola* serial peripheral interface (SPI).
The clock rate can be selected from an internal, 3.6864-MHz source or external source
fed at input pin SSP_EXTCLK. The clock can then be divided down anywhere from
7.2 KHz to 1.84 MHz by setting bits 15:08 in Control Register 0. For more information,
®
®
see the SSP configuration registers in the Intel IXP45X and Intel IXP46X Product
Line of Network Processors Developer’s Manual.
®
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
3.11.1
Signal Interface
Table 19.
Synchronous Serial Peripheral Port Interface
Pull
Input/
Output
Name
Up/
Recommendations
Down
SSP_SCLK
SSP_SFRM
SSP_TXD
O
O
O
No
No
No
Serial bit clock.
Serial frame indicator.
Transmit data (serial data out).
Receive data (serial data in).
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
SSP_RXD
I
I
Yes
Yes
External clock input.
SSP_EXTCLK
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
3.11.2
Device Connection
There are a number of devices available that can interface to SSP or SPI ports, these
can range from RTC (Real-Time Clock), LCD (Liquid Crystal Displays), Digital Thermal
Sensor to Flash memory devices.
One of the most common usage for SSP or SPI port, is serial flash code storage. Serial
flash devices can be used to store board revision, serial numbers, or assembly
SSP port in the IXP45X/IXP46X network processors. For an additional example of SPI
Figure 15.
Serial Flash and SSP Port (SPI) Interface Example
Intel® IXP46X
Product Line
Network Processors
SPI Flash
SSP_SCLK
CLK
SSP_SFRM
SSP_TXD
SSP_RXD
CS_N
D I
DO
SSP_EXTCLK
7.2 KHz
to 3.6864 MHz
SSP Interface
External Oscillator
B4109-001
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
3.12
PCI Interface
The PCI Controller of the IXP45X/IXP46X network processors is an industry-standard,
32-bit interface, high-performance bus that operates at either 33 or 66 MHz (PCI Local
Bus Specification, Rev. 2.2).
The PCI Controller supports operation as a PCI host and implements a PCI arbiter for a
system containing up to four external PCI devices.
more detailed information, see the PCI Local Bus Specification, Rev. 2.2.
3.12.1
Signal Interface
Table 20.
PCI Controller (Sheet 1 of 2)
Input/ Pull
Name
PCI_AD[31:0]
PCI_CBE_N[3:0]
PCI_PAR
Outpu
t
Up/
Recommendations
Down
PCI Address/Data bus.
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
PCI Command/Byte Enables.
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
PCI Parity.
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
PCI Cycle Frame.
PCI_FRAME_N
PCI_TRDY_N
PCI_IRDY_N
PCI_STOP_N
PCI_PERR_N
PCI_SERR_N
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
PCI Target Ready.
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
Initiator Ready.
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
Stop.
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
Parity Error.
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
System Error.
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
Device Select:
PCI_DEVSEL_N
When this interface/signal is enabled and is either being used or not being used in a system
design, the interface/signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
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Network Processors
Table 20.
PCI Controller (Sheet 2 of 2)
Input/ Pull
Name
Outpu
t
Up/
Recommendations
Down
Initialization Device Select.
PCI_IDSEL
I
I
Yes
Yes
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
Arbitration Request.
PCI_REQ_N[3:1]
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
Arbitration Request:
PCI_REQ_N[0]
PCI_GNT_N[3:1]
PCI_GNT_N[0]
I/O
O
Yes
No
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
Arbitration Grant.
Arbitration Grant.
I/O
Yes
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
Interrupt A.
PCI_INTA_N
O/D
I
Yes
Yes
When this interface/signal is enabled and is either used or not used in a system design, the
interface/signal should be pulled high with a 10-KΩ resistor.
Clock input.
PCI_CLKIN
When this interface/signal is enabled and is not being used in a system design, the interface/
signal should be pulled high with a 10-KΩ resistor.
Notes:
1.
2.
3.
Features disabled/enabled by Soft Fuse must be done during the boot-up sequence. A feature cannot be enabled after
being disabled without asserting a system reset.
Features disabled by a specific part number, do not require pull-ups or pull-downs. Therefore, all pins can be left
unconnected.
Features enabled by a specific part number — and required to be Soft Fuse-disabled, as stated in Note 1 — only require
pull-ups or pull-downs in the clock-input signals.
3.12.2
PCI Interface Block Diagram
When using the IXP45X/IXP46X network processors in Master mode, the PCI module
can interface to up to four PCI cards (devices) at 33 MHz or two PCI cards at 66 MHz.
The limitation to two cards (devices) at 66 MHz is due to load requirements to maintain
signal integrity at the higher frequency.
The PCI-to-PCI bridge must be used in order to address the PCI requirement not to
exceed one load per PCI connector unless it is through a PCI-to-PCI bridge.
The IDSEL signals on the PCI slots can be connected to one of the PCI_AD lines,
preferable to the higher order address signals. Reset support can be accomplished by
using one of the GPIO pins to generate a reset or through an external decoder of the
Expansion bus.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
Figure 16.
PCI Interface
Intel®IXP46X
Product Line
Network Processor
PCI Bus
PCI Slots
B4110-001
3.12.3
Supporting 5 V PCI Interface
It is possible to support 5 V PCI devices with the help of voltage logic translators. One
option can be implemented with voltage level translator. The Texas Instruments* family
of FET bus switches CBT devices can be a good solution. The 10-bit SN74CBT3384A has
®
been proven to work very effectively with the Intel IXP465 Network Processor. All
control and DATA/ADDRESS signals (bidirectional and not) need to be translated before
connecting the 3.3 V to the 5 V logic together. Signals which are not used, do not need
Figure 17 shows a block diagram of the interface required to perform the conversion.
Ensure that all signals connect to either of the two interfacing logic levels.
TPROP (Bus Propagation Delay) is the maximum time for a complete flight. When you
calculate TPROP, you must include in your timing calculation the TPD (Time for
®
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General Hardware Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Figure 17.
PCI 3.3 V to 5 V Logic Translation Interface
Intel®IXP46X
3.3V LOGIC
3.3V Logic
PCI Device_ 1
Product Line
Network Processor
3.3V Logic
PCI Device_2
3.3V LOGIC
3.3V Logic
PCI Device_3
3.3V LOGIC
32-Bit BUS
5.0V
1K
74CBT3384A
OE
4.3V
VCC
10-BIT
PCI
GND
VCC
Interface
5.0V Logic
PCI Device_4
5.0V LOGIC
3.3V LOGIC
2.87K
10-BIT
1K
OE
GND
74CBT3384A
B5197-01
3.12.4
PCI Option Interface
The IXP45X/IXP46X network processors can be used in a design as a host or as an
option device. This section describes how the IXP45X/IXP46X network processors can
be connected as an option device to obtain proper functionality. There are slight
differences in the hardware interface when designing for option mode. All routing and
board recommendations described in previous sections of this document apply,
Table 21.
PCI Host/Option Interface Pin Description (Sheet 1 of 3)
Host
Input
Outpu
t
Option
Input
Outpu
t
Name
Device-Pin Connection
Description
All address/data signals need to be
connected between the two devices.
PCI_AD[31:0]
PCI_CBE_N[3:0]
PCI_PAR
I/O
I/O
I/O
I/O
I/O
I/O
PCI Address/Data bus
Connect signals to same pins between
the two devices.
PCI Command/Byte Enables
PCI Parity
Connect signal to same pin between
the two devices.
Connect signal to same pin between
the two devices.
PCI_FRAME_N
I/O
I/O
PCI Cycle Frame
Connect a 10-KΩ pull-up resistor.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—General Hardware
Design Considerations
Table 21.
PCI Host/Option Interface Pin Description (Sheet 2 of 3)
Host
Input
Outpu
t
Option
Input
Outpu
t
Name
Device-Pin Connection
Description
Connect signal to same pin between
the two devices.
Connect a 10-KΩ pull-up resistor.
PCI_TRDY_N
PCI_IRDY_N
PCI_STOP_N
PCI_PERR_N
PCI_SERR_N
PCI_DEVSEL_N
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
PCI Target Ready
Initiator Ready
Stop
Connect signal to same pin between
the two devices.
Connect a 10-KΩ pull-up resistor.
Connect signal to same pin between
the two devices.
Connect a 10-KΩ pull-up resistor.
Connect signal to same pin between
the two devices.
Connect a 10-KΩ pull-up resistor.
Parity Error
System Error
Device Select
Connect signal to same pin between
the two devices.
Connect a 10-KΩ pull-up resistor.
Connect signal to same pin between
the two devices.
Connect a 10-KΩ pull-up resistor.
Connect one of the higher order PCI
address signals to the Device.
Connect a 10K pull-up resistor to the
Host.
PCI_IDSEL
I
I
I
I
Initialization Device Select
Arbitration Request
On the Option device, these signals are not
used, they should be pulled high with a 10-KΩ
resistor.
Note: The PCI_REQ_N[n] must correspond
to the PCI_GNT_N[n], where “n” must
be the same number in the square
bracket.
From the Option device, connect output
signal PCI_REQ_N[0] to one of the
PCI_REQ_N[3:0] inputs to the Host.
Note: the PCI_REQ_N[n] must
correspond to the PCI_GNT_N[n],
where “n” must be the same number in
the square bracket.
PCI_REQ_N[3:1]
Arbitration Request
From the Option device, connect output
PCI_REQ_N[0] to one of the
On the Option device, this signal is an output
and must be connected to one of the
PCI_REQ_N[3:0] inputs to the Host.
Note: The PCI_REQ_N[n] must correspond
to the PCI_GNT_N[n], where “n” must
be the same number in the square
bracket.
PCI_REQ_N[3:0] inputs to the Host.
PCI_REQ_N[0]
PCI_GNT_N[3:1]
PCI_GNT_N[0]
I
O
O
I
Note: the PCI_REQ_N[n] must
correspond to the PCI_GNT_N[n],
where “n” must be the same number in
the square bracket.
Connect one of the Host outputs
PCI_GNT_N[3:0] to PCI_GNT_N[0]
input to the Option.
Note: the PCI_GNT_N[n] must
correspond to the PCI_GNT_N[n],
where “n” must be the same number in
the square bracket.
Arbitration Grant
On the Option device, these signals are not
used, they should be pulled high with a 10-KΩ
resistor.
O
O
Arbitration Grant
Connect one of the Host outputs
PCI_GNT_N[3:0] to PCI_GNT_N[0]
input to the Option.
Note: the PCI_GNT_N[n] must
correspond to the PCI_GNT_N[n],
where “n” must be the same number in
the square bracket.
On the Option device, this signal is an input
and must be connected to one of the
PCI_GNT_N[3:0] outputs of the Host.
Note: The PCI_REQ_N[n] must correspond
to the PCI_GNT_N[n], where “n” must
be the same number in the square
bracket.
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Table 21.
PCI Host/Option Interface Pin Description (Sheet 3 of 3)
Host
Input
Outpu
t
Option
Input
Outpu
t
Name
Device-Pin Connection
Description
Interrupt A
Connect PCI_INTA_N output from the
Option to one of the GPIO input signals
of the Host. The GPIO signal at the
Host must be configure as an input
interrupt level sensitive.
This interrupt is generated from the Option to
one of the GPIO inputs to the Host.
On the Host this signal is not used, it should
be pulled high with a 10-KΩ resistor.
PCI_INTA_N
O/D
O/D
Clock must be connected to both
devices. Trace lengths must be
matched. Use point to point clock
distribution.
PCI_CLKIN
I
I
Clock input
3.12.5
Design Notes
• The IXP45X/IXP46X network processors do not support the 5 V PCI signal interface
by itself. Only the 3.3 V signal interface is supported without signal level
conversion, however, it is possible to interface to 5 V logic when using a voltage
• The PCI Local Bus Specification, Rev. 2.2 requires that the bus is always “parked”,
as some device is always driving the AD lines. There is need to use pull-ups on
these signals. The specification states that the following control lines should be
pulled up:
— FRAME#
— STOP#
— INTA#
— TRDY#
— SERR#
— INTB#
— IRDY#
— PERR#
— INTC#
— DEVSEL#
— LOCK#
— INTD#
• The processors’ GPIO pins can be used by PCI devices on PCI slots to request an
interrupt from the processors’ PCI controller.
• PCI_INTA_N is used to request interrupts to external PCI Masters. This signal is an
open collector and requires a pull-up resistor.
3.13
JTAG Interface
JTAG is the popular name for IEEE standards 1149.1-1990 and 1149.1a-1993, IEEE
Standard Test Access Port and Boundary-Scan Architecture, which provides support
for:
• Board-level boundary-scan connectivity testing
• Connection to software debugging tools through the JTAG interface
• In-system programming of programmable memory and logic devices on the PCB
The interface is controlled through five dedicated test access port (TAP) pins: TDI, TMS,
TCK, nTRST, and TDO, as described in the IEEE 1149.1 standard. The boundary-scan
test-logic elements include the TAP pins, TAP controller, instruction register, boundary-
scan register, bypass register, device identification register, and data-specific registers.
®
®
These are described in the Intel IXP45X and Intel IXP46X Product Line of Network
Processors Developer’s Manual.
The IXP45X/IXP46X network processors may be controlled during debug through a
JTAG interface to the processor, the debug tools such as the Macraigor* Raven*, EPI*
Majic*, Wind River Systems* visionPROBE* / visionICE* or various other JTAG tools
plug into the JTAG interface through a connector.
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3.13.1
Signal Interface
Table 22.
Synchronous Serial Peripheral Port Interface
Pull
Input/
Output
Name
Up/
Recommendations
Down
Test mode select.
JTG_TMS
I
Yes
When the JTAG interface is not being used, the signal must be pulled high using a 10-kΩ
resistor.
Test Input data.
JTG_TDI
JTG_TDO
I
O
I
Yes
O
When the JTAG interface is not being used, the signal must be pulled high using a 10-kΩ
resistor.
Test Output data.
Test Reset.
JTG_TRST_N
Yes
When the JTAG interface is not being used, the signal must be pulled low using a 10-kΩ
resistor.
Test Clock.
JTG_TCK
I
Yes
When the JTAG interface is not being used, the signal must be pulled high using a 10-kΩ
resistor.
3.14
Input System Clock
The IXP45X/IXP46X network processors require a 33.33-MHz reference clock to
generate all internal clocks required — including core clock — and the various buses
running internally within the system.
3.14.1
Clock Signals
Table 23.
Clock Signals
Name
Type*
Description
Source must be a clock input of 33.33-MHz.
Use a series termination resistor, 10 Ω to 33 Ω at the source.
OSC_IN
I
OSC_OUT
O
No connect
3.14.2
Clock Oscillator
When using an external clock oscillator to supply the 33.33-MHz reference system
clock, connect the clock oscillator output to OSC_IN pin through a series termination of
of the clock and eliminate ringing. Leave the OSC_OUT pin un-connected.
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3.14.3
Device Connection
Figure 18.
Clock Oscillator Interface Example
3.3 V
OUT
33 Ω
VDD
ON
OSC_IN
10 KΩ
0.01 µF
33.33 MHz
OSC_OUT
Intel® IXP46X
Product Line of
Network Processors
B4111-001
3.15
Power
To enable low power system design, the IXP45X/IXP46X network processors have
separate power supply domains for the processor core, DDR SDRAM memory, and
input/output peripherals.
Table 24.
Power Interface (Sheet 1 of 2)
Nominal
Voltage
Name
Description
Core supply voltage.
Note: If operating at 667MHz, core supply voltage must be increased to VCC = 1.5 V. For details, see
VCC
1.3 V
®
®
the Intel IXP45X and Intel IXP46X Product Line of Network Processors Datasheet.
VCCP
VCCM
VSS
3.3 V
2.5 V
GND
I/O supply voltage.
DDR memory interface supply voltage.
Ground for supply voltages 3.3 V, 2.5 V, and 1.3/1.5 V.
Supply voltage for peripheral (I/O) logic of analog oscillator circuitry.
Require special power filtering circuitry. See the Intel IXP45X and Intel IXP46X Product Line of
Network Processors Datasheet.
®
®
OSC_VCCP
OSC_VSSP
3.3 V
GND
Ground for peripheral (I/O) logic of analog oscillator circuitry. Used in conjunction with the OSC_VCCP
pins.
Require special power filtering circuitry. See the Intel IXP45X and Intel IXP46X Product Line of
Network Processors Datasheet.
®
®
Supply voltage for internal logic of the analog oscillator circuitry. Requires special power filtering
circuitry. If operating at 667 MHz, this voltage must be increased to 1.5 V.
OSC_VCC
OSC_VSS
1.3 V
GND
®
®
See the Intel IXP45X and Intel IXP46X Product Line of Network Processors Datasheet.
Ground for internal logic of the analog oscillator circuitry. Used in conjunction with the OSC_VCC pins.
®
®
Require special power filtering circuitry. See the Intel IXP45X and Intel IXP46X Product Line of
Network Processors Datasheet.
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Table 24.
Power Interface (Sheet 2 of 2)
Nominal
Voltage
Name
Description
Supply voltage for internal logic of analog phase lock-loop circuitry. Requires special power filtering
circuitry. If operating at 667 MHz, this voltage must be increased to 1.5 V.
VCCPLL1
VCCPLL2
VCCPLL3
1.3 V
1.3 V
1.3 V
®
®
See the Intel IXP45X and Intel IXP46X Product Line of Network Processors Datasheet.
Supply voltage for internal logic of analog phase lock-loop circuitry. Requires special power filtering
circuitry. If operating at 667 MHz, this voltage must be increased to 1.5 V.
®
®
See the Intel IXP45X and Intel IXP46X Product Line of Network Processors Datasheet.
Supply voltage for internal logic of analog phase lock-loop circuitry. Requires special power filtering
circuitry. If operating at 667 MHz, this voltage must be increased to 1.5 V.
®
®
See the Intel IXP45X and Intel IXP46X Product Line of Network Processors Datasheet.
3.15.1
De-Coupling Capacitance Recommendations
It is common practice to place de-coupling capacitors between the supply voltages and
ground. Placement can be near the input supply pins and ground, with one 100-nF
capacitor per pin. Additional de-coupling capacitors can be place all over the board
every 0.5” to 1.0”. This ensures good return path for currents and reduce power surges
and high-frequency noise.
It is also recommended that 4.7-µF to 10-µF capacitors be placed every 2” to 3”.
3.15.2
3.15.3
3.15.4
VCC De-Coupling
Connect one 100-nF capacitor per each VCC pin. Placement should be as close as
possible to the pin. It is also recommended to place a 4.7-µF capacitor near the device.
Use traces as thick as possible to eliminate voltage drops in the connection.
VCCP De-Coupling
Connect one 100-nF capacitor per each VCCP pin. Placement should be as close as
possible to the pin. It is also recommended to place a 4.7-µF capacitor near the device.
Use traces as thick as possible to eliminate voltage drops in the connection.
VCCM De-Coupling
Connect one 100-nF capacitor per each VCCM pin. Placement should be as close as
possible to the pin. It is also recommended to place a 4.7-µF capacitor near the device.
Use traces as thick as possible to eliminate voltage drops in the connection.
3.15.5
3.15.6
Power Sequence
Power sequence is crucial for proper functioning of the IXP45X/IXP46X network
®
processors. For a complete description of power sequencing, see the Intel IXP45X and
®
Intel IXP46X Product Line of Network Processors Datasheet.
Reset Timing
Proper reset timing is also a crucial requirement for proper functioning of the IXP45X/
IXP46X network processors. There are two reset signal PWRON_RESET_N and
RESET_IN_N which required assertion sequence.
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For a complete description of their functionality, see the Intel IXP45X and Intel
IXP46X Product Line of Network Processors Datasheet and its section titled “Reset
Timings.” PWRON_RESET_N is used as a Power Good and RESET_IN_N is used for
resetting internal registers.
The IXP45X/IXP46X network processors can be configured at reset de-assertion via
external, pull-down resistors on the address expansion bus signals EX_ADDR[23:21].
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4.0
General PCB Guide
4.1
PCB Overview
Beginning with components selection, this chapter presents general PCB guidelines. In
cases where it is too difficult to adhere to a guideline, engineering judgment must be
used. The methods are listed as simple DOs and DON’Ts.
This chapter does not discuss the functional aspects of any bus, or layout guides for
any interfaced devices.
4.2
4.3
General Recommendations
It is recommended that boards based on the IXP45X/IXP46X network processors
employ a PCB stackup yielding a target impedance of 50 Ω ± 10% with 5 mil nominal
trace width. That is, the impedance of the trace when not subjected to the fields
created by changing current in neighboring traces.
When calculating flight times, it is important to consider the minimum and maximum
impedance of a trace based on the switching of neighboring traces. Using wider spaces
between the traces can minimize this trace-to-trace coupling. In addition, these wider
spaces reduce cross-talk and settling time.
Component Selection
• Do not use components faster than necessary
Clock rise (fall) time should be as slow as possible, as the spectral content of the
waveform decreases
• Use components with output drive strength (slew-rate) controllable if available
• Use SMT components (not through-hole components) as through-hole (leaded)
components have more stub inductance due to the protruding leads.
• Avoid sockets when possible
• Minimize number of connectors
4.4
Component Placement
• High-frequency components in the middle
• Medium-frequency around the high-frequency components
• Low-frequency components around the edge of the printed circuit board
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Figure 19.
Component Placement on a PCB
C
O
N
N
E
C
T
Medium Frequency
High Frequency
Components
O
R
Analog Circuit
Low Frequency
PCB
B2264-01
• Place noisy parts (clock, processor, video, etc.) at least 1.5 – 3 inches away from
the edge of the printed circuit board.
• Do not place noisy components close to internal/external cables
— Any loose cables picks up noise and act as an antenna to radiate that noise
— Be aware of the peak in-rush surge current into the device pins. This surge
current may inject high-frequency switching noise into power planes of the
printed circuit board.
• Place high-current components near the power sources.
• Do not share the same physical components (such as buffers and inverters)
between high-speed and low-speed signals. Use separate parts.
• Place clock drivers and receivers such that clock trace length is minimized.
• Place clock generation circuits near a ground stitch location. Place a localized
ground plane around the clock circuits and connect the localized plane to system
ground plane.
• Install clock circuits directly on the printed circuit board, not on sockets.
• Clock crystals should lie flat against the board to provide better coupling of
electromagnetic fields to the board.
4.5
Stack-Up Selection
Stack-up selection directly affects the trace geometry which, in turn, affects the
characteristic impedance requirement for the printed-circuit board. Additionally, the
“clean,” noise-free-planes design and placement is significantly important as
components run at higher speeds requiring more power.
Considerations include:
• Low-speed, printed-circuit-board construction — for example two-layer boards:
— Advantages:
• Inexpensive
• Manufactured by virtually all printed-circuit-board vendors
— Disadvantages:
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• Poor routing density
• Uncontrolled signal trace impedance
• Lack of power/ground planes, resulting in unacceptable cross-talk
• Relatively high-impedance power distribution circuitry, resulting in
noise on the power and ground rails
• High-speed circuits require multi-layer printed circuit boards:
— Advantages:
• Controlled-impedance traces
• Low-impedance power distribution
— Disadvantages:
• Higher cost
• More weight
• Manufactured by fewer vendors
• Symmetry is essential to keep the board stack-up symmetric about the center
This minimizes warping
• For best impedance control, have:
— No more than two signal layers between every power/ground plane pair
— No more than one embedded micro-strip layer under the top/bottom layers
• For best noise control, route adjacent layers orthogonally. Avoid layer-to-layer
parallelism.
• Fabrication house must agree on design rules, including:
— Trace width, trace separation
— Drill/via sizes
• The distance between the signal layer and ground (or power) should be minimized
to reduce the loop area enclosed by the return current
— Use 0.7:1 ratio as a minimum.
For example: 5-mil traces, 7-mil prepreg thickness to adjacent power/ground.
Figure 20 gives an example for a six-layer and eight-layer board. For stripline (signals
between planes), the stackup should be such that the signal line is closer to one of the
planes by a factor of five or more. Then the trace impedance is controlled
predominantly by the distance to the nearest plane.
boards.
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Figure 20.
8-Layer Stackup
4.5 mil
5 mil
7 mil
Legend
Component (Top) Side
SIGNAL
Data
Data
Data
L1
L2
L3
L4
GND
17.8 mil
7 mil
5 mil
4.5 mil
62 mil
POWER
Data
Data
L5
L6
L7
L8
Solder (Bottom) Side
B2244-02
Figure 21.
6-Layer Stackup
Legend
4.5 mil
SIGNAL
GND
7 mil
Component (Top) Side
L1
~40 mil
L2
L3
7 mil
62 mil
POWER
4.5 mil
L4
L5
L6
Solder (Bottom) Side
B2275-02
• Fast and slow transmission line networks must be considered
• PCB-board velocities
• Board FR4 ~ 4.3
• Target impedance of 50 Ω ± 10%
• Trace width: 5 mils
• Signal Layers (1/2 oz. Copper)
• Power Layer (1 oz. Copper)
• Ground (GND) Layer (1 oz. Copper)
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Processors
5.0
General Layout and Routing Guide
5.1
Overview
This chapter provides routing and layout guides for hardware and systems based on the
®
®
Intel IXP45X and Intel IXP46X Product Line of Network Processors.
The high-speed clocking required when designing with the processors 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 designers with board layout. In cases where it is too
difficult to follow a design rule, engineering judgment must be used.
5.2
General Layout Guidelines
The layout guidelines recommended in this section are based on experience and
knowledge gained from previous designs. Layer stacking varies, depending on design
complexity, however following standard rules helps minimize potential problems
dealing with signal integrity.
The following are well know documented recommendations that helps route a
functional board:
• Providing enough routing layers to comply with minimum and maximum timing
requirements of the IXP45X/IXP46X network processors and other components.
• Connectors, and mounting holes must be placed in a ways that will not interfere
with basic design guidelines in this document.
• Provide uniform impedance throughout the board, specially for high speed areas
such us clocking, DDR-SDRAM, PCI, device bus, etc.
• Place analog, high-voltage, power supply, low-speed, and high-speed devices in
different sections of the board.
• Decoupling capacitors must be placed next to power pins.
• Series termination resistors must be placed close to the source.
• Analog and digital sections of the board must be physically isolated from each
other. No common ground, power planes, and signal traces are allowed to cross-
isolation zones. Use appropriately sized PCB traces for larger enough to handle
peak current. Keep away from high-speed digital signals.
• Keep stubs as short as possible (preferably, the electrical length of the stub less
than half of the length of the rise time of signal).
• All critical signals should be routed before all other non-critical signals.
• Do not route signals close to the edge of the board, power or ground planes. Route
signal at least 50 to 100 mils away from the edge of the plane.
• Try to match buses to the same trace length and keep them in groups adjacent to
each other, away from other signals.
• Route processor address, data and control signals using a “daisy-chain” topology.
• Minimize number of vias and corners on all high speed signals.
• Do not route under crystals or clock oscillators, clock synthesizers, or magnetic
devices (ferrites, toroids).
• Maintain trace spacing consistent between differential pairs and match trace length.
• Keep differential signals away from long and parallel, high-speed paths, such as
clock signals and data strobe signals.
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• Do not place high-frequency oscillators and switching network devices close to
sensitive analog circuits.
• Arrange the board so that return currents for high-speed traces never must jump
between planes. Restrict traces to remain on either side of whichever ground plane
they start out nearest. This allows the use of naturally grouped horizontal and
vertical routing layers.
If signals change between layers, the reference voltage changes, as shown in
Figure 22. This creates discontinuity in the path of the signal.
Figure 22.
Signal Changing Reference Planes
VIAs
Driver
Receiver
Signal
Signal
GND
PWR
Return Current
ByPass Caps
Trace
Signal
B2269-01
provides a very good return current path. The signal then is routed to the bottom layer,
close to the PWR plane, such that the return currents flows to the ground plane through
bypass caps. Hence the path for the return currents is less inductive than in the
previous case when the signal is routed on the top layer.
5.2.1
General Component Spacing
• Do not place components within 125 mils to the edge of the printed circuit board.
For exact dimensions consult your manufacturing vendor.
• Keep a minimum spacing between via and the solder pad edges > 25mil.
• Position devices that interface with each other close to one another to minimize
trace lengths.
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Figure 23.
Good Design Practice for VIA Hole Placement
25 mils min
25 mils min
25 mils min
B2266-01
surface-mount boards.
Figure 25 shows minimum pad-to-pad clearance for surface-mount passive
components and PGA or BGA components.
Figure 24.
Poor Design Practice for VIA Placement
Flush Via min
Potential Bridge min
B2267-01
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Figure 25.
Pad-to-Pad Clearance of Passive Components to a PGA or BGA
PGA or BGA Package
60 mils min
60 mils min
60 mils min
B2268-01
5.2.2
Clock Signal Considerations
• Provide good return current paths for clock traces.
• Keep clock traces away from the edge of the board and any other high-speed
devices or traces.
• Keep clock traces away from analog signals, including voltage reference signals.
• Clock signals should not cross over a split plane.
• Route clock signals in a single, internal layers and eliminate routing in multiple
layers as much as possible.
• Do not route traces or vias under crystals or clock oscillators devices unless there is
a plane between the trace and the component.
• Do not route parallel signal traces directly above or below clock traces unless there
is a ground or at least a power plane separation between those layers.
• Route clock traces with a minimum number of vias.
• Space clock traces away from other signals three times the trace width on each
side.
• Use guard traces when routing on top or bottom layers whenever possible. Guard
traces must be connected to ground.
• Do not daisy-chain, instead use point-to-point clock distribution. Place a series
termination resistor as close as possible to the source.
• Keep traces short to minimize reflections and signal degradation.
• Maintain control impedance for all clock traces, microstrip or stripline.
— Be aware of propagation delays between a microstrip and stripline.
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— Calculate capacitive loading of all components and properly compensate with a
series or parallel terminations.
• Measure and match trace lengths for devices that interface with each other and
have their clock derived from the same source.
If traces must be long, treat them as transmission lines. Terminate clock traces to
match trace impedance.
• If there is a power plane, instead of a ground plane, make sure that the power
plane has adequate decoupling to ground, especially near clock drivers and
receivers.
5.2.3
SMII Signal Considerations
SMII signals run at 125 MHz, single-ended and require proper trace-routing to achieve
good signal integrity and impedance matching. The following recommendations help
with designs:
• Do not route any of the SMII signals under the IXP45X/IXP46X network processors,
or any other components, unless a ground or power plane isolates the signals.
• Minimize the number of vias to two per trace.
• Keep traces as short as possible and straight, away from other signals.
• Control impedance should maintain to 50 Ω.
• RX signals must have the same length and TX signals must have the same length.
— For the RX group, match the lengths for signals SMII_RX_SYNC,
SMII_RX_DATA, and SMII_RX_CLK.
— For TX group, match lengths for signals SMII_TX_SYNC, SMII_TX_DATA, and
SMII_TX_CLK.
• Avoid sharp corners, using 45° corners instead.
5.2.4
MII Signal Considerations
MII signals run at 25 MHz which makes them less critical that SMII. But these signals
still require certain routing guide lines.
• Minimize the number of vias to two per trace.
• Keep traces as short as possible and straight, away from other signals.
• Control impedance should maintain to 50 Ω.
• Each group either RX or TX must be length match.
• Avoid sharp corners, using 45° corners instead.
5.2.5
USB Considerations
recommended schematic interface.
The following are recommendations for routing differential pair signal required to by
the USB interface:
• Traces can be routed in tightly couple structure with 5mil trace width and 10-mil air
gap, or maintain air gap equal 2X trace width. It is recommended these be hand-
routed.
• Match trace length for each differential pair.
• Avoid sharp corners, using 45° corners instead.
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• Wherever possible, use a perfect symmetry within a differential pair.
• Minimize the number vias.
• Avoid routing other signals close by or in parallel to the differential pair,
maintaining no less than 50 mil to any other signal.
• Maintain control impedance for each differential pair to 90 Ω +/- 15 Ω.
• Use high value ferrite beads (100 MHz/60 Ω – 100 MHz/240 Ω).
5.2.6
Cross-Talk
Cross-talk is caused by capacitance and inductance coupling between signals. It is
composed of both backward and forward cross-talk components.
Backward cross-talk creates an induced signal on the network that propagates in the
opposite direction of the aggressor signal. Forward cross-talk creates a signal that
propagates in the same direction as the aggressor signal.
Circuit board analysis software should be used to analyze your board layout for cross-
talk problems.
• To effectively route signals on the PCB, signals are grouped (address, data, etc.).
— The space between groups can be 3 w (where w is the width of the traces).
— Space within a group can be just 1 w.
— Space between clock signals or clock to any other signal should be 3 w. The
coupled noise between adjacent traces decreases by the square of the distance
between the adjacent traces.
5.2.7
EMI-Design Considerations
It is strongly recommended that good electromagnetic interference (EMI) design
practices be followed when designing with the IXP45X/IXP46X network processors.
®
• Information on spread-spectrum clocking is available in Intel IXP4XX Product Line
of Network Processors and IXC1100 Control Plane Processor: Spread-Spectrum
Clocking to Reduce EMI Application Note.
• Place high-current devices as closely as possible to the power sources.
• Proper termination of signals can reduce reflections, which may emit a high-
frequency component that may contribute to more EMI than the original signal
itself.
• Ferrite beads may be used to add high frequency loss to a circuit without
introducing power loss at DC and low frequencies. They are effective when used to
absorb high-frequency oscillations from switching transients or parasitic
resonances within a circuit.
• Keep rise and fall times as slow as possible. Signals with fast rise and fall times
contain many high-frequency harmonics which may radiate significantly.
• A solid ground is essential at the I/O connector to chassis and ground plane.
• Keep the power plane shorter than the ground plane by at least 5x the spacing
between the power and ground planes.
• Stitch together all ground planes around the edge to the board every 100 to
200 mil. This helps reduce EMI radiating out of the board from inner layers.
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General Layout and Routing Guide—Intel IXP45X and Intel IXP46X Product Line of Network
Processors
5.2.8
5.2.9
Trace Impedance
All signal layers require controlled impedance of 50 Ω ±10 % microstrip or stripline
(unless otherwise specified) where appropriate. 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.
Power and Ground Plane
Power and ground planes should have sufficient de-coupling capacitors to ensure
sustainable current needed for high-speed switching devices. (See Section 3.15.1, “De-
• It is highly recommended to use sufficient internal power and ground planes.
• Due to the complexity of the IXP45X/IXP46X network processors, there are a
number of power supplies required. It is appropriate to use power islands in the
power plane under the processor, as it would be too expensive to have a power
plane for each power source.
• Power islands must be large enough to include the required power supply
decoupling capacitance, and the necessary connection to the voltage source and
destination.
• Islands can be separated by a minimum of 20-mil air gap.
• Use at least one via per power or ground pin, wherever possible use more vias,
depending on current drawn.
• Use at least one de-coupling capacitor per power pin and place it as close as
possible to the pin.
• Minimize the number of traces routed across the air gaps between power islands.
— Each crossing introduces signal degradation due to the impedance
discontinuity.
— For traces that must cross air gaps, route them on the side of the board next to
a ground plane to reduce or eliminate signal degradation caused by crossing
the gap.
— When this is not possible, then route the trace to cross the gap at a right angle
(90°).
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PCI Interface Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
6.0
PCI Interface Design Considerations
®
®
The Intel IXP45X and Intel IXP46X Product Line of Network Processors has a single,
32-bit PCI device module that runs at 33/66 MHz. This chapter describes some basic
guidelines to help design hardware that interfaces with PCI devices.
The PCI module is compatible with the PCI Local Bus Specification, Rev. 2.2. For a
complete functional description and physical requirements, see PCI Local Bus
Specification, Rev. 2.2.
6.1
6.2
Electrical Interface
The electrical definition is restricted to 3.3 V signaling environment. The device is not
5 V tolerant. All devices interfacing with the PCI module need to operate at 3.3 V.
Topology
Interfacing devices need to be connected in a daisy-chain topology. When more than
one device is in the bus, connecting stubs need to be kept as short as possible.
There is a limitation to the number of devices connected to the internal arbiter. If more
than four devices are required to be connected, an external arbiter is required.
The system time budget must be satisfied for 66 MHz and 33 MHz cycles. It is expected
that if the timing budget for 66 MHz clock cycles is satisfied, then the 33 MHz cycles
also work. The following equation and timing parameters need to be met when routing
a board that either interfaces to a single PCI device or up to four devices as shown in
TCYC ≥ TVAL +TPROP + TSKEW + TSU
where:
TVAL = Valid Output Delay
TPROP = Bus Propagation Delay (maximum time for complete flight)
TSKEW = Total Clock Skew
TSU = Input Setup Time
@33 MHz
@66 MHz
TCYC = 30 nSec
CYC = 15 nSec
TVAL = 11 nSec
TVAL = 6 nSec
TPROP = 10 nSec
TPROP = 5 nSec
TSKEW = 2 nSec
TSKEW = 1 nSec
TSU = 7 nSec
TSU = 3 nSec
T
calculation must:
• Include an additional trace length segment from the PCI connector to the input
device within the expansion PCI card.
• Assume the segment to be 1.5 inch.
• Use trace propagation delay of 150 to 190 ps/in as specified by the PCI standard.
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—PCI Interface Design
Considerations
Figure 26.
PCI Address/Data Topology
Intel® IXP46X
Product Line
PCI Slot
PCI Slot
PCI Slot
PCI Slot
Network Processor
A
B
B
B
B5196 -01
Table 25.
PCI Address/Data Routing Guidelines
Parameter
Routing Guidelines
Signal Group
Topology
PCI Address/Data
Daisy Chain
Ground
Reference Plane
Characteristic Trace Impedance
Nominal Trace Width
55 Ω ±10%
5 mils
Nominal Trace Separation
Spacing to Other Groups
Limit the number of VIAS to 10 per Signal
10 mils
20 mils
10
6.3
Clock Distribution
In order to meet timing and avoid clock overloading, it is recommended to use point-
Clock skew between interfacing devices is very critical and must be met. The maximum
skew must be measured between any two components. If designing a motherboard,
the skew must be measured to the expansion card device and not to the PCI connector.
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PCI Interface Design Considerations—Intel IXP45X and Intel IXP46X Product Line of
Network Processors
Figure 27.
PCI Clock Topology
PCI Devices
A
A
B
B
Rs
Rs
Clock
Driver
33/66 MHz
Intel® IXP46X
Product Line
Network
A
B
Rs
Processor
B4114-02
Table 26.
PCI Clock Routing Guidelines
Parameter
Routing Guidelines
Signal Group
Topology
PCI Clock
Point-to-Point
Ground
Reference Plane
Characteristic Trace Impedance
Nominal Trace Width
Nominal Trace Separation
Spacing to Other Groups
Trace length A
55 Ω ±10%
5 mils
10 mils
20 mils
Maximum 300 mils
There is no limit as long as the trace
length is maintained for each clock and
that maximum clock skew is not violated.
Trace length B
Resistor Rs
22 Ω ±10%
Maximum VIAS
6
6.3.1
Trace Length Limits
Maximum trace lengths can be calculated for specific speeds at which the bus is
intended to run. Typically, PCI boards with devices that can support up to 66 MHz are
designed to function at up to 66 MHz, even if the design is originally intended to run at
33 MHz. This way, if design requirements change to 66 MHz, then timing is met at the
higher frequency. In this case, the only additional requirement is to change the clock
speed and the expansion bus initial strapping at the EX_ADDR[4] signal. If you are
designing your board for 66 MHz and intend it to operate at 33 MHz, ensure that timing
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Intel IXP45X and Intel IXP46X Product Line of Network Processors—PCI Interface Design
Considerations
The limitations of the maximum trace length can be calculated with the equations
This is a straight-forward calculation, but very critical to meet timing. It is
recommended to keep the trace lengths as short as possible and not to exceed TPROP
.
Note:
For acceptable signal integrity at up to 66 MHz, it is very important to design the PCB
board with controller impedance in the range of 55 Ω ±10%.
6.3.2
Routing Guidelines
It is recommended to route signals with respect to an adjacent ground plane. If routing
signals over power planes, ensure that the signals are referenced to a single power
plane voltage level and not multiple levels. For example, you can route signals over a
3.3 V plane or a 5 V plane, but do not route the same signal over both planes. If signals
are routed over split planes, you must connect the splitting planes with 0.01 µF, high-
speed capacitors near the signal crossing the split. The capacitors should be placed no
more than 0.25 inches from the point at which the signals cross the split.
This manual does not repeat all the guidelines that are already stated in the PCI Local
Bus Specification, Rev. 2.2, instead you should refer to the specification when
designing either a motherboard or an expansion card.
6.3.3
Signal Loading
Shared PCI signals must be limited to one load on each of the PCI slots. Any violation of
expansion board or add-on device trace length or loading limits compromises system-
signal integrity.
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DDR-SDRAM—Intel IXP45X and Intel IXP46X Product Line of Network Processors
7.0
DDR-SDRAM
7.1
Introduction
®
This document is intended to be used as a guide for routing DDR, based on the Intel
IXDP465 Development Platform. It contains routing guidelines and simulation results
for using x16 Thin Small Outline Package (TSOP) memory devices soldered onto the
processor module.
®
®
Processors support two banks of 32-bit wide non-Error Correcting Code (non-ECC) or
40-bit wide (ECC) DDR-266 memory with the ability for single-bit error correction or
multi-bit error detection (ECC). The IXP45X/IXP46X network processors support un-
groups used for the DDR interface.
In this document, the term IXP45X/IXP46X product line refers to both the IXP46X
network processors (with DDR ECC) and IXP45X network processors (without DDR
ECC).
Table 27.
DDR Signal Groups
No of Single
Ended Signals
Group
Signal Name
Description
DDRI_CK[2:0]
DDRI_CK_N[2:0]
DDRI_CB[7:0]
DDRI_DQ[31:0]
DDRI_DQS[4:0]
DDRI_DM[4:0]
DDRI_CKE[1:0]
DDRI_CS_N[1:0]
DDRI_MA[13:0]
DDRI_BA[1:0]
DDRI_RAS_N
DDR-SDRAM Differential Clocks
DDR-SDRAM Inverted Differential Clocks
ECC Data
0
Clocks
0
8
Data Bus
32
5
Data
Data Strobes
Data Mask
5
Clock Enable - one per bank
Chip Select - one per bank
Address Bus
2
Control
2
14
2
Bank Select
Command
Row Address Select
Column Address Select
Write Enable
1
DDRI_CAS_N
1
DDRI_WE_N
1
Total
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Figure 28.
Processor-DDR Interface
DDRI_DQ[31:0]
DATA[31:0]
ADDRESS[13:0]
DQ[31:0]
A[13:0]
DDRI_MA[13:0]
DDRI_CK[2:0]
DDRI_CK_N[2:0]
CK[2:0]
CK#[2:0]
CLOCK[2:0], CLOCK#[2:0]
CLOCK ENABLE[1:0]
CHIP SELECT#[1:0]
BANK SELECT[1:0]
DDRI_CKE[1:0]
DDRI_CS_N[1:0]
DDRI_BA[1:0]
CKE[1:0]
CS#[1:0]
BA[1:0]
DDRI_CB[7:0]
DDRI_DM[4:0]
ECC DATA[7:0]
DQ[7:0]
DM[4:0]
DATA MASK[4:0]
DDRI_DQS[4:0]
DATA STROBE[4:0]
WRITE#, RAS#, CAS#
DQS[4:0]
WE#
RAS#
CAS#
DDRI_WE_N
DDRI_RAS_N
DDRI_CAS_N
B3986-001
for one or two banks. Notice that depending on the number of devices used, loading of
the driving signals is affected. The most critical signal affected by the loading is the
DDRI_CK (clock output). This signal has a very strict timing requirement defined in the
JEDEC standard, therefore signal integrity of this signal is a must. The following table
shows how to assign the number of devices per clock line for the various configuration.
It also suggest to use a DDR SSTL zero delay clock driver when more than two devices
meant to let designers know that for that particular configuration, a clock driver is
required. One recommended clock driver can be the Pericom PI6CV855 or a similar
device. The Pericom device is highly used in DIMM memory modules that required to
deliver clocks to many devices in a single module.
The best approach is to minimize the number of devices used to get the target total
memory size required by design.
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DDR-SDRAM—Intel IXP45X and Intel IXP46X Product Line of Network Processors
Besides assigning clock signals (DDRI_CK and DDRI_CK_N) to the memory devices,
there are two more requirements, one implemented in hardware (termination) and the
other implemented in software (configuration), these requirements are explained as
follow:
• It is recommended to properly terminate the clock output signals by the Thevenin
that required deviation from the recommended topology, which include series
termination and trace impedance.
• It is required to tune the drive strength of the clock driver to properly drive clocks
out to loads of one or two memory devices, terminated with Thevenins termination
scheme. Follow the recommendations described in Section 7.1.6, “Resistive
Note that when simulating, the IBIS model representation of signals DDRI_CK[2:0] and
DDRI_CK_N[2:0] has been created for the new Rcomp settings described in Section
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Table 28.
Supported Memory Configurations
DDR
Device
Density
Number of
DDRDevices
(non-ECC)
Devices
per
Clock
Number of
DDRDevices
(ECC)
Devices
per
Clock
Device
Width
Number
of Banks
Total
Memory Size
128 Mbit
128 Mbit
128 Mbit
128 Mbit
256 Mbit
256 Mbit
256 Mbit
256 Mbit
512 Mbit
512 Mbit
512 Mbit
512 Mbit
1 Gbit
x8
x8
4
8
2
4
4
8
2
4
4
8
2
4
4
8
2
4
2,2
Driver
1,1
5
10
3
2,2,1
Driver
1,1,1
2,2,2
2,2,1
Driver
1,1,1
2,2,2
2,2,1
Driver
1,1,1
2,2,2
2,2,1
Driver
1,1,1
2,2,2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
1
2
64 Mbyte
128 Mbyte
32 Mbyte
64 Mbyte
128 Mbyte
256 Mbyte
64 Mbyte
128 Mbyte
256 Mbyte
512 Mbyte
128 Mbyte
256 Mbyte
512 Mbyte
1 Gbyte
x16
x16
x8
2,2
6
2,2
5
x8
Driver
1,1
10
3
x16
x16
x8
2,2
6
2,2
5
x8
Driver
1,1
10
3
x16
x16
x8
2,2
6
2,2
5
1 Gbit
x8
Driver
1,1
10
3
1 Gbit
x16
x16
256 Mbyte
512 Mbyte
1 Gbit
2,2
6
Figure 29 shows the DDR memory interface of the IXP45X/IXP46X network processors
using x16 devices with Error Correcting Code (ECC). Bank 0 is represented by DDR
devices 1, 3, and 5. Bank 1 is represented by DDR devices 2, 4, and 6. Unused data
inputs on the ECC devices (5 and 6) are pulled to ground through 10-KΩ resistors.
The VTT signal termination used for all signals, except clocks, is a series 60.4-Ω resistor
to a 1.25-V DC power supply designed for DDR memory termination. The appropriate
value for termination resistance should be verified through simulation for the specific
application was the TPS54672 from Texas Instruments*.
The DDRI_RCVENOUT_N signal must be connected to the DDRI_RCVENIN_N signal
with a trace which is propagation delay length matched to the average delay of the
clock (DDRI_CK[2:0]) plus data (DDRI_DQ[31:0]). A series terminating resistor (R )
s
should be used to control overshoot and undershoot, as shown in Figure 49 on
A resistance value in the 25- to 50-Ω range should be used as it adds minimal
propagation delay to the signal without adversely varying from the CLK plus DQ
propagation delay average. The appropriate value for termination resistance should be
verified through simulation for the specific topology.
The DDRI_RCOMP signal must be terminated through a 20-Ω, 1%, 0.1-W resistor
(R
) to ground. This allows the DDR controller to make temperature and process
comp
adjustments.
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DDR-SDRAM—Intel IXP45X and Intel IXP46X Product Line of Network Processors
Figure 29.
Processor-DDR Interface: x16 Devices with ECC
DDRI_RCVENOUT_N
VTT Signal Termination
Rs
DDRI_RCVENIN_N
DDRI_RCOMP
DDRI_DQ[15:0]
Rcomp
DDRI_DQS[1:0]
DDR 1
DDR 3
DDR 5
DDR 2
DDR 4
DDR 6
DDRI_DM[1:0]
GND
DDRI_CK[0]
DDRI_CK_N[0]
DDRI_DQ[31:16]
DDRI_DQS[3:2]
DDRI_DM[3:2]
DDRI_CK[2]
DDRI_CK_N[2]
Intel® IXP46X
Product Line
of Network
Processors
DDRI_CB[7:0]
DDRI_DQS[4]
DDRI_DM[4]
DDRI_CK[1]
DDRI_CK_N[1]
DDRI_CS_N[0]
DDRI_CKE[0]
DDRI_WE, DDRI_RAS
DDRI_CAS
DDRI_MA[13:0]
DDRI_CS_N[1]
DDRI_CKE[1]
B3987-001
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7.1.1
Selecting VTT Power Supply
Selecting the minimum power requirement for VTT supply is a simple calculation that
varies depending on the resistive value of RVTT terminating resistors. Since all RVTT has
the same value, the power calculation becomes a simple, current times voltage times
terminating network, for which the following equation can be solved for the unknown:
Vout = 0 or 2.5V
VTT=1.25V
RVTT= 60 Ω (we can assume this value)
P = (V x I) x N= (Vout (- or +) VTT) x (VTT/RVTT) x N
P = (2.5V-1.25V) x (1.25V/60 Ω) x 73
P = 1.9 Watt. Allow a 25% overhead. P = 1.9W + 1.9W x 0.25 = 2.38 Watt
It is very important to allow some overhead for the VTT power supply, just like any
other power distribution allow some overhead in case the value of RVTT or simply for
inrush current. The following figure shows the diagram of the current paths for the
above equation.
Figure 30.
VTT Terminating Circuitry
VTT
RVTT
Vout
IXP46X
DDR SDRAM
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7.1.2
Signal-Timing Analysis
Figure 31.
DDR Command and Control Setup and Hold
T1
T2
T3
T4
T5
T6
DDR_M_CLK
Control/Command Valid
B3988-001
Table 29.
DDR Command and Control Setup and Hold Values
Symbol
Parameter
Min
Max
Units
Notes
Output of IXP45X/IXP46X network processors valid for
Command and Control signals prior to the transition of
DDR_M_CLK
T
T
1.5
ns
1
2
Output hold time of IXP45X/IXP46X network processors for
Command and Control signals after the transition of
DDR_M_CLK
1.5
ns
Required Command and Control input setup time at DDR
memory device
T
T
0.9
0.9
ns
ns
3
4
Required Command and Control input hold time at DDR
memory device
Allowable setup time difference between IXP45X/IXP46X
network processors Command and Control output and setup
time required by DDR memory device
T
T
0.6
0.6
ns
ns
5
6
Allowable hold time difference between IXP45X/IXP46X
network processors Command and Control output and hold
time required by DDR memory device
Notes:
1.
DDR_M_CLK represents the combined clock signal for DDRI_CK and DDRI_CK_N.
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Figure 32.
DDR Data to DQS Read Timing Parameters
T1
T4
T7
T3
T2
DQS
Data
D0
T6
D1
T8
T5
B3989-001
Table 30.
DDR Data to DQS Read Timing Parameters
Symbol
Parameter
Min
Max
Units
Notes
IXP45X/IXP46X network processors delay for data group
valid after any edge of DQS
T
0.75
ns
1
IXP45X/IXP46X network processors guaranteed time
before data group begins to transition invalid prior to DQS
T
T
T
1.0
ns
ns
ns
2
3
4
Data valid window for IXP45X/IXP46X network processors
2.0
DQ-DQS skew, DQS to last data group signal going valid
from DDR memory device
0.5
DQ-DQS hold, DQS to first data group signal going non-
valid from DDR memory device
T
T
T
3.0
2.5
ns
ns
ns
5
6
7
Data valid window from DDR memory device
Allowable data group to DQS difference for data going
0.25
0.25
valid (T - T )
1
4
Allowable data group to DQS difference for data going
invalid (T - T - T )
T
ns
8
5
3
1
Notes:
1.
Data group signals consist of DDRI_DM[4:0], DDRI_DQ[31:0], and DDRI_CB[7:0].
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Figure 33.
DDR-Data-to-DQS-Write Timing Parameters
T1
T2
T3
T4
T5
T6
DQS
Data
Data Valid
B3990-001
Table 31.
DDR Data to DQS Write Timing Parameters
Symbol
Parameter
Min
Max
Units
Notes
IXP45X/IXP46X network processors output valid for data
group signals prior to the transition of DQS
T
T
T
T
1.0
1.0
0.5
0.5
ns
1
2
3
4
IXP45X/IXP46X network processors output hold time for
data group signals after the transition of DQS
ns
ns
ns
Required data group input setup time at DDR memory
device
Required data group input hold time at DDR memory
device
Allowable setup time difference between IXP45X/IXP46X
network processors data group output and setup time
required by DDR memory device
T
T
0.5
0.5
ns
ns
5
6
Allowable hold time difference between IXP45X/IXP46X
network processors data group output and hold time
required by DDR memory device
Notes:
1.
Data group signals consist of DDRI_DM[4:0], DDRI_DQ[31:0], and DDRI_CB[7:0]
Figure 34.
DDR-Clock-to-DQS-Write Timing Parameters
T3 T4
T1
T2
T5
T6
DDR_M_CLK
DQS
B3991-001
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Table 32.
DDR-Clock-to-DQS-Write Timing Parameters
Symbol
Parameter
Min
Max
Units
Notes
IXP45X/IXP46X network processors output valid for
DDRI_DQS prior to the transition of DDR_M_CLK
T
T
T
T
1.4
ns
1
2
3
4
IXP45X/IXP46X network processors output hold time for
DDRI_DQS after the transition of DDR_M_CLK
1.0
ns
ns
ns
Required write command to DQS latching transition at
DDR memory device (early transition)
1.875
1.875
Required write command to DQS latching transition at
DDR memory device (late transition)
Allowable difference between IXP45X/IXP46X network
processors DDR_M_CLK output and first DQS transition
(early transition)
T
T
0.475
0.875
ns
ns
5
6
Allowable difference between IXP45X/IXP46X network
processors DDR_M_CLK output and first DQS transition
(late transition)
Notes:
1.
DDR_M_CLK represents the combined clock signal for DDR_CK and DDR_CK_N.
7.1.3
Printed Circuit Board Layer Stackup
The layer stackup used for the IXDP465 platform x16 Processor Module is shown in
signal layers and four plane layers.
• Layers 5 and 8 are used as digital ground planes
• Layers 2 and 11 are used as split planes for the different voltage references (3.3 V
and 2.5 V).
Details on the voltage reference layout are available in the CAD database or Gerber
files database for the IXDP465 platform x16 Processor Module.
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Figure 35.
Printed Circuit Board Layer Stackup
7.1.4
Printed Circuit Board Controlled Impedance
Controlled impedance for each layer of the IXDP465 platform x16 Processor Module is
necessary to provide proper matching from driver to receiver(s) for improved signal
integrity and higher reliability in the signal analysis results obtained through
controlled for clock routing (60-Ω, single-ended’ 120-Ω, differential) as well as all other
DDR signals (50 Ω, single-ended). Layers 3 and 10 are also impedance controlled for
50-Ω, single-ended traces.
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7.1.5
Timing Relationships
The routing guidelines presented in the following subsections define the recommended
routing topologies, trace width, spacing geometries, and typical routed lengths for each
signal group. These parameters are recommended to achieve optimal signal integrity
and timing.
All signal groups are length matched to the DDR clocks. The clocks on the processor
module are length matched to within ±10 mils of each other. Once this overall clock
length for any given DDR differential clock is determined, the command and control
signals can be routed to within the timing specified. A simple summary of the timing
Control/Command Group to Clock Summary:
• The maximum allowable difference from any command/control signal to the clock is
±0.6 ns.
Data Group to Strobe Summary:
• The more restrictive data group to strobe timing occurs for read operations
• The maximum allowable difference from any data group signal to the strobe is
±0.25 ns.
Strobe to Clock Summary:
• The maximum allowable difference from any data strobe signal to the clock is -
0.475 ns to +0.875 ns
These are absolute maximum ratings for length mismatch based in ideal printed board
conditions (exact signal propagation delays, ideal signal integrity with no reflections or
settling, zero rise/fall times, etc.) In order to compensate for these non-ideal
conditions, more restrictive length matching conditions should be used based on signal
integrity analysis and simulation to provide a buffer zone and avoid possible variations
in silicon or printed circuit board manufacture.
Table 33.
Timing Relationships
Absolute Minimum
Length
Absolute Maximum
Length
Signal Group
Control to Clock
Command to Clock
Data to Strobe
Clock – 600 ps
Clock – 600 ps
Strobe – 250 ps
Clock – 475 ps
Clock + 600 ps
Clock + 600 ps
Strobe + 250 ps
Clock + 875 ps
Strobe to Clock
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In addition to any trace length differentials which must be considered between signal
groups, differences in the package length between signals should be considered when
determining the total propagation delay of the signals. When using the IBIS model for
signal analysis, package characteristics are included in the simulation results.
7.1.6
Resistive Compensation Register (Rcomp)
Critical signals such as the differential clock drivers used for driving clock out to
memory devices is very critical. The JEDEC standard has a very critical requirement for
the crossing of the differential clock signals which required proper termination and
drive strength of the signals. Therefore, in order to comply with this requirement, two
recommendations have been made.
termination and impedance matching is strictly follow.
• Configuration of the Rcomp circuit.
The steps to follow and the order in which they need to occur to configure Rcomp are
®
®
described in section “DDRI SDRAM Initialization” of the Intel IXP45X and Intel
IXP46X Product Line of Network Processors Developer’s Manual. Here is a recap of the
two registers that are required to be overwritten with the new value:
• Override default value of register DDR_RCOMP_CSR3 with 0x0000 1000Hex
• Override default value of register DDR_DRIVE3 with 0x0002 08F0Hex
Note that this configuration only affects the SDRAM differential clock driver for all three
outputs DDRI_CK[2:0] and DDRI_CK_N[2:0].
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Refer to the Intel IXP45X and Intel IXP46X Product Line of Network Processors
Developer’s Manual for the complete sequence of steps to follow to configure the
SDRAM DDRI memory module.
Note that when simulating, the IBIS model representation of signals DDRI_CK[2:0] and
DDRI_CK_N[2:0] has been created for the new Rcomp settings described in this
section.
7.1.7
Routing Guidelines
Clock Group
7.1.7.1
The clock signal group includes the differential clock pairs DDRI_CK[2:0] and
DDRI_CK_N[2:0].
Here are some tips on how to route the differential clock pairs:
• Ensure that DDR clocks are routed on a single internal layers, except for pin
escapes.
• A ground plane must be adjacent to the layer where the signals are routed.
• Minimize the number of vias used, but ensure that the same number of vias are
used in the positive and negative trace.
• It is recommended that pin escape vias be located directly adjacent to the ball pads
on all clocks.
• Traces must be routed for differential mode impedance of 120 Ω.
• Surface layer routing should be minimized (top or bottom layers).
• It is recommended to perform pre- and post-layout simulation.
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Table 34.
Clock Signal Group Routing Guidelines
Parameter
Definition
Signal Group Members
Topology
DDRI_CK[2:0] and DDRI_CK_N[2:0]
Differential Pair Point to Point (1 Driver, 2 Receivers)
Single Ended Trace Impedance (Z )
o
60 Ωs
Differential Mode Impedance (Z
)
120 Ωs
diff
Nominal Trace Width
Internal (Strip Line) 3.5 mils, External (Micro Strip) 5 mils
Nominal Pair Spacing (edge to edge)
Minimum Pair to Pair Spacing
Internal (Strip Line) 10.5 mils, External (Micro Strip) 10 mils
Any layer 20mils
20.0 mils
Minimum Spacing to Other DDR Signals
Minimum Spacing to non-DDR Signals
25.0 mils
4 per trace
8 per differential pair
Maximum Via Count
DDRI_CK to DDRI_CK_N Length Matching
Match total length to +/- 10 mils between clocks
Notes:
1.
Nominal trace width is determined by board physical characteristics and stack-up. This value should
be verified with the PWB manufacturer to achieve the desired Zo.
2.
Nominal pair to pair spacing is determined by board physical characteristics and stack-up. This value
should be verified with the PWB manufacturer to achieve the desired Zdiff.
7.1.7.2
Data, Command, and Control Groups
The data, command, and control signal groups include all signals other than the clock
group signals. The groups should be routed on internal layers, except for pin escapes.
It is recommended that pin escape vias be located directly adjacent to the ball pads on
all signals. Surface layer routing should be minimized. The following table provides
routing guidelines for signals within these groups.
Table 35.
Data, Command, and Control Group Routing Guidelines
Parameter
Definition
DDRI_CB[7:0], DDRI_DQ[31:0], DDRI_DQS[4:0], DDRI_DM[4:0],
DDRI_CKE[1:0], DDRI_CS_N[1:0], DDRI_MA[13:0],
DDRI_BA[1:0], DDRI_RAS_N, DDRI_CAS_N, DDRI_WE_N
Signal Group Members
Topology
Single-Ended, Point-to-Point (1 Driver, 6 Receivers max)
Single Ended Trace Impedance (Z )
o
50 Ω
Nominal Trace Width
Layers 3, 4, 6, 7, 9, and 10: 5.7 mils
Minimum Spacing to DDR Clock Signals
Minimum Spacing to other DDR Signals
Minimum Spacing to non-DDR Signals
Maximum Via Count
20.0 mils
10.0 mils
25.0 mils
6 per signal
Length Matching
Notes:
1.
Nominal trace width is determined by board physical characteristics and stack-up. This value should
be verified with the PWB manufacturer to achieve the desired Zo.
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7.2
Simulation Results
This section contains the simulation results for each of the DDR signal groups. Each of
the signal groups may have different overall topologies based on the number of banks
and ECC usage.
Each signal group simulated below uses a two-bank, 32-bit data bus with ECC based on
16-bit DDR devices.
7.2.1
Clock Group
The clock signal group includes the differential clock pairs DDRI_CK[2:0] and
DDRI_CK_N[2:0]. The following simulation was constructed for the 2 bank x16 device
configuration where each clock would have two receivers.
Figure 37 on page 91. These lengths were chosen as realistic goals given the IXP45X/
IXP46X network processors to DDR device body to body separation of no more than
500 mils.
Table 36.
Clock Group Topology Transmission Line Characteristics
Transmission Line
TL1 (T = 175 ps/in)
Length
~100 mils
~1300 mils
~50 mils
pd
TL2 (T = 175 ps/in)
pd
TL3 (T = 175 ps/in)
pd
TL4, TL5 (T = 175 ps/in)
pd
~300 mils
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Figure 38.
DDR Clock Simulation Results: Two-Bank x16 Devices
meets the DDR device input voltage requirements. The crossing point for the clock
input must occur between V
=1.05 V and V
=1.45 V and have a minimum
ix(min)
ix(max)
peak to peak swing of 700 mV. The receiver input waveform must also not exceed a
maximum voltage of V =2.8 V or the minimum voltage of V =-0.3 V.
in(max)
in(min)
Waveform results for device DDR_DEVICE2 is not shown as it is identical to that of
device DDR_DEVICE1 due to symmetry. When final routing data is available, simulation
results for all receivers are analyzed as variations in routing may result in differences.
These differences should be minimal.
7.2.2
Data Group
The data signal group includes the signals DDRI_CB[7:0], DDRI_DQ[31:0],
DDRI_DQS[4:0], and DDRI_DM[4:0]. The following simulations were constructed for
the 2 bank x16 device configuration where each signal would have two receivers where
only one is active for a read or write.
IXP45X/IXP46X network processors to DDR device body to body separation of no more
than 500 mils.
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Table 37.
Data Group Topology Transmission Line Characteristics
Transmission Line
TL1 (T = 175 ps/in)
Length
~600 mils
~50 mils
pd
TL2 (T = 175 ps/in)
pd
TL3 (T = 175 ps/in)
~1,100 mils
~50 mils
pd
TL4 (T = 175 ps/in)
pd
TL5, TL6 (T = 175 ps/in)
~300 mils
~800 mils
pd
TL7, TL8 (T = 175 ps/in)
pd
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Figure 40.
DDR Data Write Simulation Results: Two-Bank x16 Devices
the DDR device input voltage requirements. V
of V – 0.310 or 940 mV and
il(max)
ref
V
of V + 0.310 or 1.56 V are easily achieved at the receiver (DDR_DEVICE1).
ih(min)
ref
The receiver waveform must also not exceed a maximum voltage of V
= 2.8 V or
in(max)
the minimum voltage of V
=-0.3 V.
in(min)
Waveform results for DDR_DEVICE2 are not shown as it is identical to that of device
DDR_DEVICE1 due to symmetry. When final routing data is available, simulation results
for all receivers are analyzed as variations in routing may result in differences. These
differences should be minimal.
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Figure 41.
DDR Data Read Simulation Results: Two-Bank x16 Devices
(Reduced Drive Strength)
reduced drive strength and shows that the voltage waveform meets the DDR device
input voltage requirements. V
of V – 0.150 or 1.10 V and V
of V
+
il(max)
ref
ih(min)
ref
0.150 or 1.40 V are easily achieved at the receiver (IXP45X/IXP46X network
processors). The receiver waveform must also not exceed a maximum voltage of
=2.8 V or the minimum voltage of V =-0.3 V.
V
in(max)
in(min)
Waveform results for DDR_DEVICE2 are not shown as it is not relevant when reading
from DDR_DEVICE1. Due to the symmetry of the topology, waveform results when
reading from DDR_DEVICE2 would be identical to those when reading from
DDR_DEVICE1. When final routing data is available, simulation results for all receivers
are analyzed as variations in routing may result in differences. These differences should
be minimal.
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Figure 42.
DDR Data Read Simulation Results: Two-Bank x16 Devices (Full Drive
Strength)
drive strength and show that the voltage waveform meets the DDR device input voltage
requirements. V
of V – 0.150 or 1.10 V and V
of V + 0.150 or 1.40 V
il(max)
ref
ih(min) ref
are easily achieved at the receiver (IXP45X/IXP46X network processors). However, the
receiver waveform must also not exceed a maximum voltage of V = 2.8 V or the
in(max)
minimum voltage of V
= -0.3 V and the waveforms at the IXP45X/IXP46X
in(min)
network processors are close to these limits. A larger series resistor could be used to
attenuate the signal, but the results of doing so might have an adverse effect on write
operations.
Waveform results for DDR_DEVICE2 are not shown as it is not relevant when reading
from DDR_DEVICE1. Due to the symmetry of the topology, waveform results when
reading from DDR_DEVICE2 would be identical to those when reading from
DDR_DEVICE1. When final routing data is available, simulation results for all receivers
are analyzed as variations in routing may result in differences. These differences should
be minimal.
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7.2.3
Control Group
The control signal group includes the signals DDRI_CS[1:0] and DDRI_CKE[1:0]. The
following simulations were constructed for the 2 bank x16 device configuration where
each signal would have three receivers.
IXP45X/IXP46X network processors to DDR body to body separation of no more than
500 mils.
Table 38.
Control Group Topology Transmission Line Characteristics
Transmission Line
TL1 (T = 175 ps/in)
Length
~ 600 mils
~ 50 mils
pd
TL2 (T = 175 ps/in)
pd
TL3 (T = 175 ps/in)
~ 1,100 mils
~ 50 mils
pd
TL4 (T = 175 ps/in)
pd
TL5, TL6, TL7 (T = 175 ps/in)
~ 800 mils
~ 300 mils
pd
TL8, TL9, TL10 (T = 175 ps/in)
pd
Figure 43.
DDR Control (CS0) Topology: Two-Bank x16 Devices
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Figure 44.
DDR RAS Simulation Results: Two-Bank x16 Devices
waveform meets the DDR device input voltage requirements. V
of V – 0.310 or
il(max)
ref
940 mV and V
of V + 0.310 or 1.56 V are easily achieved at the receiver
ih(min)
ref
(DDR_DEVICE1). The receiver waveform must also not exceed a maximum voltage of
= 2.8 V or the minimum voltage of V = -0.3 V.
V
in(max)
in(min)
Waveform results for DDR_DEVICE2 and DDR_DEVICE3 are not shown as it is identical
to that of DDR_DEVICE1 due to symmetry. When final routing data is available,
simulation results for all receivers are analyzed as variations in routing may result in
differences. These differences should be minimal.
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7.2.4
Command Group
The command signal group includes the signals DDRI_MA[13:0], DDRI_BA[1:0],
DDRI_RAS, DDRI_CAS and DDRI_WE. The following simulations were constructed for
the 2 bank x16 device configuration where each signal would have six receivers.
the IXP45X/IXP46X network processors to DDR body to body separation of no more
than 500 mils.
Table 39.
Command Group Topology Transmission Line Characteristics
Transmission Line
TL1 (T = 175 ps/in)
Length
~ 600 mils
~ 50 mils
pd
TL2 (T = 175 ps/in)
pd
TL3 (T = 175 ps/in)
~ 1,100 mils
~ 50 mils
pd
TL4 (T = 175 ps/in)
pd
TL5, TL8, TL11 (T = 175 ps/in)
~ 800 mils
~ 300 mils
pd
TL6, TL7, TL9, TL10, TL12, TL13 (T = 175 ps/in)
pd
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Figure 46.
DDR Address Simulation Results: Two-Bank x16 Devices
waveform meets the DDR device input voltage requirements. V of V – 0.310 or
il(max)
ref
940 mV and V
of V + 0.310 or 1.56 V are easily achieved at the receiver
ih(min)
ref
(DDR_DEVICE1). The receiver waveform must also not exceed a maximum voltage of
= 2.8 V or the minimum voltage of V = -0.3 V.
V
in(max)
in(min)
Waveform results for devices DDR_DEVICE2 through DDR_DEVICE6 are not shown as
they are identical to that of device DDR_DEVICE1 due to symmetry. When final routing
data is available, simulation results for all receivers are analyzed as variations in
routing may result in differences. These differences should be minimal.
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Figure 48.
DDR RAS Simulation Results: Two-Bank x16 Devices
the DDR device input voltage requirements. V of V – 0.310 or 940 mV and
il(max)
ref
V
of V + 0.310 or 1.56 V are easily achieved at the receiver (DDR_DEVICE1).
ih(min)
ref
The receiver waveform must also not exceed a maximum voltage of V
= 2.8 V or
in(max)
the minimum voltage of V
= -0.3 V.
in(min)
Waveform results for devices DDR_DEVICE2 through DDR_DEVICE6 are not shown as
they are identical to that of device DDR_DEVICE1 due to symmetry. When final routing
data is available, simulation results for all receivers are analyzed as variations in
routing may result in differences. These differences should be minimal.
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7.2.5
RCVENIN and RCVENOUT
The Receive Enable In (RCVENIN) and Receive Enable Out (RCVENOUT) should be
connected and routed to match the length of the clock signal plus the average data
signal trace. This length matching is important to insure the signal propagation delay of
RCVENIN/RCVENOUT is the same as that for the clock plus average DQ length.
simulation topologies.
Table 40.
Figure 49.
Control Group Topology Transmission Line Characteristics
Transmission Line
TL1 (T = 175 ps/in)
Length
~1,700 mils
~1,700 mils
pd
TL2 (T = 175 ps/in)
pd
DDR RCVENIN/RCVENOUT Topology
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Figure 50.
DDR RCVENIN/RCVENOUT Simulation Results (Rseries = 0 Ω)
series resistor, the voltage waveform meets the DDR device input voltage
requirements. V
of V – 0.150 or 1.10 V and V
of V + 0.150 or 1.40 V
il(max)
ref
ih(min) ref
are easily achieved at the receiver (RCVENIN). However, the receiver waveform must
also not exceed a maximum voltage of V = 2.8 V or the minimum voltage of
in(max)
V
= -0.3 V and the waveforms at the IXP45X/IXP46X network processors are
in(min)
outside of these limits. A different series resistor should be chosen. The results of using
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Figure 51.
DDR RCVENIN/RCVENOUT Simulation Results (Rseries = 60 Ω)
waveform meets the DDR device input voltage requirements. V
of V – 0.150 or
il(max)
ref
1.10 V and V
of V + 0.150 or 1.40 V are easily achieved at the receiver
ih(min)
ref
(RCVENIN). The receiver waveform must also not exceed a maximum voltage of
V
= 2.8 V or the minimum voltage of V
= -0.3 V.
in(max)
in(min)
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