GWIXP465BADT [INTEL]
RISC Microprocessor, 32-Bit, 533MHz, CMOS, PBGA544, PLASTIC, BGA-544;型号: | GWIXP465BADT |
厂家: | INTEL |
描述: | RISC Microprocessor, 32-Bit, 533MHz, CMOS, PBGA544, PLASTIC, BGA-544 时钟 外围集成电路 |
文件: | 总148页 (文件大小:1386K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors
Datasheet
Product Features
For a complete list of product features, see “Product Features” on page 9. This document describes in
full the features of the silicon. Some of these features require enabling software supplied by Intel.
Please refer to the Intel® IXP400 Software Programmer’s Guide for information on which features are
enabled at this time.
These features do not require
These features require enabling
software. For information on which
features are enabled at this time,
see the Intel® IXP400 Software
Programmer’s Guide.
enabling software
Intel XScale® Processor — Up to
667 MHz
PCI v. 2.2 33/66 MHz (Host/Option)
USB 1.1 Device Controller
USB 2.0 Host Controller
DDRI SDRAM Interface
Master/Target Capable Expansion bus
Two UARTs
Internal Bus Performance Monitoring
Unit
16 GPIO
Cryptography Unit (Random Number
Generator and Exponentiation Unit)
Encryption/Authentication (AES/
AES-CCM/3DES/DES/SHA-1/SHA-256/
SHA-384/SHA-512/MD-5)
Two High-Speed, Serial Interfaces
Three Network Processor Engines
Up to three MII Interfaces
Up to three SMII Interfaces
Up to one UTOPIA Level 2 Interface
IEEE-1588 Hardware Assist
Four Internal Timers
Synchronous Serial Protocol (SSP)
Port
I2C Interface
Spread Spectrum clocking for Reduced
EMI
Packaging
— 544-Pin PBGA
— Commercial/Extended Temperature
— Lead-Free Support
Typical Applications
Small-to-Medium Business Router
Industrial Controllers
Modular Router
Access Points (802.11a/b/g)
Network-Attached Storage
Wired/Wireless RFID Readers
VoIP Integrated Access Device (IAD)
Video IP Telephones
Security Gateway/Router
Network Printers
Control Plane
Mini-DSLAM
Document Number: 306261-004US
August 2006
INFORMATION IN THIS DOCUMENT IS PROVIDED IN CONNECTION WITH INTEL® PRODUCTS. NO LICENSE, EXPRESS OR IMPLIED, BY ESTOPPEL OR
OTHERWISE, TO ANY INTELLECTUAL PROPERTY RIGHTS IS GRANTED BY THIS DOCUMENT. EXCEPT AS PROVIDED IN INTEL'S TERMS AND CONDITIONS
OF SALE FOR SUCH PRODUCTS, INTEL ASSUMES NO LIABILITY WHATSOEVER, AND INTEL DISCLAIMS ANY EXPRESS OR IMPLIED WARRANTY, RELATING
TO SALE AND/OR USE OF INTEL PRODUCTS INCLUDING LIABILITY OR WARRANTIES RELATING TO FITNESS FOR A PARTICULAR PURPOSE,
MERCHANTABILITY, OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY RIGHT. Intel products are not intended for
use in medical, life saving, life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
Intel Corporation may have patents or pending patent applications, trademarks, copyrights, or other intellectual property rights that relate to the
presented subject matter. The furnishing of documents and other materials and information does not provide any license, express or implied, by estoppel
or otherwise, to any such patents, trademarks, copyrights, or other intellectual property rights.
Designers must not rely on the absence or characteristics of any features or instructions marked “reserved” or “undefined.” Intel reserves these for
future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.
Intel processor numbers are not a measure of performance. Processor numbers differentiate features within each processor family, not across different
processor families. See http://www.intel.com/products/processor_number for details.
The Intel® IXP45X and Intel® IXP46X Product Line of Network Processors may contain design defects or errors known as errata which may cause the
product to deviate from published specifications. Current characterized errata are available on request.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling
1-800-548-4725 or by visiting Intel's website at http://www.intel.com.
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and Xircom are trademarks or registered trademarks of Intel Corporation or its subsidiaries in the United States and other countries.
*Other names and brands may be claimed as the property of others.
Copyright © 2006, Intel Corporation
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Contents
1.0 Product Features .......................................................................................................9
1.1
1.2
Product Line Features ..........................................................................................9
Model-Specific Features...................................................................................... 12
2.0 About This Document .............................................................................................. 13
3.0 Functional Overview................................................................................................ 14
3.1
Key Functional Units .......................................................................................... 18
3.1.1 Network Processor Engines (NPEs)............................................................ 18
3.1.2 Internal Bus .......................................................................................... 19
3.1.2.1 North AHB ............................................................................... 20
3.1.2.2 South AHB............................................................................... 20
3.1.2.3 Memory Port Interface............................................................... 21
3.1.2.4 APB Bus .................................................................................. 21
3.1.3 MII/SMII Interfaces................................................................................ 21
3.1.4 UTOPIA Level 2...................................................................................... 22
3.1.5 USB 1.1 Device Interface ........................................................................ 22
3.1.6 USB 2.0 Host Interface ........................................................................... 22
3.1.7 PCI Controller........................................................................................ 22
3.1.8 DDRI SDRAM Controller .......................................................................... 23
3.1.9 Expansion Interface................................................................................ 25
3.1.9.1 Expansion Bus Legacy Mode of Operation..................................... 25
3.1.9.2 Expansion Bus Enhanced Mode of Operation................................. 26
3.1.10 High-Speed, Serial Interfaces................................................................... 26
3.1.11 UARTs .................................................................................................. 26
3.1.12 GPIO .................................................................................................... 27
3.1.13 Internal Bus Performance Monitoring Unit (IBPMU) ..................................... 28
3.1.14 Interrupt Controller ................................................................................ 28
3.1.15 Timers.................................................................................................. 28
3.1.16 IEEE 1588 Hardware Assistance ............................................................... 29
3.1.17 Synchronous Serial Port Interface............................................................. 29
3.1.18 I2C Interface......................................................................................... 29
3.1.19 AES/DES/SHA/MD-5 ............................................................................... 30
3.1.20 Cryptography Unit.................................................................................. 30
3.1.21 Queue Manager...................................................................................... 31
Intel XScale® Processor ..................................................................................... 31
3.2.1 Super Pipeline........................................................................................ 32
3.2.2 Branch Target Buffer .............................................................................. 33
3.2.3 Instruction Memory Management Unit....................................................... 33
3.2.4 Data Memory Management Unit ............................................................... 34
3.2.5 Instruction Cache................................................................................... 34
3.2.6 Data Cache ........................................................................................... 34
3.2.7 Mini-Data Cache..................................................................................... 35
3.2.8 Fill Buffer and Pend Buffer....................................................................... 35
3.2.9 Write Buffer........................................................................................... 35
3.2.10 Multiply-Accumulate Coprocessor ............................................................. 36
3.2.11 Performance Monitoring Unit.................................................................... 36
3.2.12 Debug Unit............................................................................................ 36
3.2
4.0 Package Information............................................................................................... 37
4.1
Package Description .......................................................................................... 37
4.1.1 Package Drawings .................................................................................. 37
4.1.2 Package Markings................................................................................... 40
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
4.1.3 Part Numbers.........................................................................................41
Functional Signal Definitions................................................................................42
4.2.1 Pin Description Tables .............................................................................43
Signal-Pin Descriptions.......................................................................................77
Package Thermal Specifications .........................................................................103
4.2
4.3
4.4
5.0 Electrical Specifications .........................................................................................104
5.1
5.2
Absolute Maximum Ratings ...............................................................................104
CCPLL1, VCCPLL2, VCCPLL3, OSC_VCCP, OSC_VCC Pin Requirements.........................105
5.2.1 CCPLL1 Requirement.............................................................................105
V
V
5.2.2 VCCPLL2 Requirement.............................................................................105
5.2.3 VCCPLL3 Requirement.............................................................................106
5.2.4 OSC_VCCP Requirement........................................................................106
5.2.5 OSC_VCC Requirement..........................................................................107
RCOMP Pin Requirements..................................................................................107
DDRI_RCOMP Pin Requirements.........................................................................108
DC Specifications.............................................................................................108
5.5.1 Operating Conditions.............................................................................108
5.5.2 PCI DC Parameters ...............................................................................109
5.5.3 USB 1.1 DC Parameters.........................................................................109
5.5.4 UTOPIA Level 2 DC Parameters...............................................................110
5.5.5 MII/SMII DC Parameters........................................................................110
5.5.6 MDI DC Parameters ..............................................................................110
5.5.7 DDRI SDRAM Bus DC Parameters............................................................111
5.5.8 Expansion Bus DC Parameters................................................................111
5.5.9 High-Speed, Serial Interface 0 DC Parameters..........................................112
5.5.10 High-Speed, Serial Interface 1 DC Parameters..........................................112
5.5.11 UART DC Parameters.............................................................................113
5.5.12 Serial Peripheral Interface DC parameters................................................113
5.5.13 I2C Interface DC Parameters..................................................................113
5.5.14 GPIO DC Parameters.............................................................................114
5.5.15 JTAG DC Parameters.............................................................................114
5.5.16 Reset DC Parameters ............................................................................114
5.5.17 All Remaining I/O DC Parameters............................................................115
AC Specifications .............................................................................................115
5.6.1 Clock Signal Timings .............................................................................115
5.6.1.1 Processors’ Clock Timings.........................................................115
5.6.1.2 PCI Clock Timings ...................................................................116
5.6.1.3 MII/SMII Clock Timings............................................................116
5.6.1.4 UTOPIA Level 2 Clock Timings...................................................117
5.6.1.5 Expansion Bus Clock Timings ....................................................117
5.6.2 Bus Signal Timings................................................................................117
5.6.2.1 PCI........................................................................................117
5.6.2.2 USB 1.1 Interface....................................................................119
5.6.2.3 UTOPIA Level 2 (33 MHz) .........................................................119
5.6.2.4 MII/SMII................................................................................120
5.6.2.5 MDIO.....................................................................................123
5.6.2.6 DDRI SDRAM Bus....................................................................124
5.6.2.7 Expansion Bus ........................................................................126
5.6.2.8 Serial Peripheral Port Interface Timing .......................................140
5.6.2.9 I2C Interface Timing................................................................141
5.6.2.10 High-Speed, Serial Interfaces....................................................143
5.6.2.11 JTAG .....................................................................................144
5.6.3 Reset Timings ......................................................................................145
5.6.3.1 Cold Reset..............................................................................145
5.6.3.2 Hardware Warm Reset .............................................................146
5.6.3.3 Soft Reset..............................................................................146
5.3
5.4
5.5
5.6
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
5.6.3.4 Reset Timings ........................................................................ 147
Power Sequence.............................................................................................. 148
Power Dissipation............................................................................................ 148
5.7
5.8
5.9
Ordering Information....................................................................................... 149
Figures
1
2
3
4
5
6
7
Intel® IXP465 Network Processor Block Diagram.......................................................... 15
Intel® IXP460 Network Processor Block Diagram.......................................................... 16
Intel® IXP455 Network Processor Block Diagram.......................................................... 17
Intel XScale® Technology Block Diagram..................................................................... 32
544-Pin Lead PBGA Package — First of Two Drawings ................................................... 38
544-Pin Lead PBGA Package — Second of Two Drawings ............................................... 39
Package Markings:
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—
Extended and Commercial Temperature, Lead-Free / Compliant with Standard for Restriction
on the Use of Hazardous Substances (RoHS) ............................................................... 40
Package Markings:
8
9
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors —
Commercial and Extended Temperature, Lead-Based.................................................... 41
VCCPLL1 Power Filtering Diagram............................................................................... 105
10 VCCPLL2 Power Filtering Diagram............................................................................... 106
11 VCCPLL3 Power Filtering Diagram............................................................................... 106
12 OSC_VCCP Power Filtering Diagram.......................................................................... 107
13 OSC_VCC Power Filtering Diagram ........................................................................... 107
14 RCOMP Pin External Resistor Requirements ............................................................... 108
15 DDRI_RCOMP Pin External Resistor Requirements ...................................................... 108
16 Typical Connection to an Oscillator ........................................................................... 116
17 PCI Output Timing.................................................................................................. 117
18 PCI Input Timing.................................................................................................... 118
19 UTOPIA Level 2 Input Timings.................................................................................. 119
20 UTOPIA Level 2 Output Timings ............................................................................... 119
21 SMII Output Timings .............................................................................................. 120
22 SMII Input Timings ................................................................................................ 121
23 Source Synchronous SMII Output Timings................................................................. 121
24 Source Synchronous SMII Input Timings ................................................................... 122
25 MII Output Timings ................................................................................................ 122
26 MII Input Timings .................................................................................................. 123
27 MDIO Output Timings ............................................................................................. 123
28 MDIO Input Timings ............................................................................................... 123
29 DDRI SDRAM Write Timings..................................................................................... 124
30 DDRI SDRAM Read Timings (2.0 CAS Latency)........................................................... 125
31 DDRI SDRAM Read Timings (2.5 CAS Latency)........................................................... 125
32 Expansion Bus Synchronous Timing.......................................................................... 126
33 Intel Multiplexed Mode............................................................................................ 127
34 Intel Simplex Mode ................................................................................................ 128
35 Motorola* Multiplexed Mode .................................................................................... 130
36 Motorola* Simplex Mode......................................................................................... 131
37 HPI*–8 Mode Write Accesses................................................................................... 132
38 HPI*-16 Multiplexed Write Mode .............................................................................. 135
39 HPI*-16 Multiplexed Read Mode............................................................................... 136
40 HPI*-16 Non-Multiplexed Read Mode ........................................................................ 137
41 HPI*-16 Non-Multiplexed Write Mode........................................................................ 138
42 I/O Wait Normal Phase Timing................................................................................. 139
43 I/O Wait Extended Phase Timing.............................................................................. 140
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Datasheet
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
44 Serial Peripheral Interface Timing.............................................................................140
45 I2C Interface Timing...............................................................................................141
46 High-Speed, Serial Timings......................................................................................143
47 Boundary-Scan General Timings...............................................................................144
48 Boundary-Scan Reset Timings..................................................................................145
49 Reset Timings........................................................................................................147
50 Power-up Sequence Timing......................................................................................148
Tables
1
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Features.................13
2
3
4
5
6
7
8
9
Related Documents...................................................................................................14
Network Processor Functions......................................................................................18
Supported DDRI Memory Configurations......................................................................24
GPIO Alternate Function Table....................................................................................27
Part Numbers for the Intel® IXP46X Product Line of Network Processors ..........................41
Part Numbers for the Intel® IXP45X Product Line of Network Processors ..........................42
Signal Type Definitions..............................................................................................42
Processors’ Signal Interface Summary Table ................................................................43
10 DDR SDRAM Interface...............................................................................................45
11 PCI Controller ..........................................................................................................46
12 High-Speed, Serial Interface 0 ...................................................................................50
13 High-Speed, Serial Interface 1 ...................................................................................51
14 UTOPIA Level 2/MII_A/ SMII Interface ........................................................................53
15 MII/SMII Interfaces ..................................................................................................59
16 Expansion Bus Interface............................................................................................66
17 UART Interfaces .......................................................................................................69
18 Serial Peripheral Port Interface...................................................................................70
19 I2C Interface ...........................................................................................................70
20 USB Host/Device Interfaces .......................................................................................71
21 Oscillator Interface ...................................................................................................72
22 GPIO Interface.........................................................................................................73
23 JTAG Interface .........................................................................................................73
24 System Interface......................................................................................................74
25 Power Interface........................................................................................................75
26 Processors’ Ball Map Assignments...............................................................................77
27 2.8-Watt Maximum Power Dissipation .......................................................................104
28 3.3-Watt Maximum Power Dissipation .......................................................................104
29 4.0-Watt Maximum Power Dissipation .......................................................................104
30 Operating Conditions ..............................................................................................108
31 PCI DC Parameters.................................................................................................109
32 USB 1.1 DC Parameters...........................................................................................109
33 UTOPIA Level 2 DC Parameters ................................................................................110
34 MII/SMII DC Parameters .........................................................................................110
35 MDI DC Parameters ................................................................................................110
36 DDRI SDRAM Bus DC Parameters .............................................................................111
37 Expansion Bus DC Parameters..................................................................................111
38 High-Speed, Serial Interface 0 DC Parameters............................................................112
39 High-Speed, Serial Interface 1 DC Parameters............................................................112
40 UART DC Parameters ..............................................................................................113
41 Serial Peripheral Interface DC Parameters..................................................................113
42 I2C Interface DC Parameters ...................................................................................113
43 GPIO DC Parameters...............................................................................................114
44 JTAG DC Parameters...............................................................................................114
45 PWRON_RESET _N and RESET_IN_N Parameters........................................................114
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
46 All Remaining I/O DC Parameters (JTAG, PLL_LOCK) .................................................. 115
47 Devices’ Clock Timings............................................................................................ 115
48 Processors’ Clock Timings Spread Spectrum Parameters.............................................. 115
49 PCI Clock Timings .................................................................................................. 116
50 MII/SMII Clock Timings........................................................................................... 116
51 UTOPIA Level 2 Clock Timings.................................................................................. 117
52 Expansion Bus Clock Timings................................................................................... 117
53 PCI Bus Signal Timings ........................................................................................... 118
54 UTOPIA Level 2 Input Timings Values ....................................................................... 119
55 UTOPIA Level 2 Output Timings Values ..................................................................... 120
56 SMII Output Timings Values .................................................................................... 120
57 SMII Input Timings Values ...................................................................................... 121
58 Source Synchronous SMII Output Timings Values....................................................... 121
59 Source Synchronous SMII Input Timings Values......................................................... 122
60 MII Output Timings Values ...................................................................................... 122
61 MII Input Timings Values ........................................................................................ 123
62 MDIO Timings Values.............................................................................................. 124
63 DDRI SDRAM Write Timings Values........................................................................... 124
64 DDRI SDRAM Read Timing Values ............................................................................ 126
65 Expansion Bus Synchronous Operation Timing Values ................................................. 127
66 Intel Multiplexed Mode Values.................................................................................. 128
67 Intel Simplex Mode Values ...................................................................................... 129
68 Motorola* Multiplexed Mode Values .......................................................................... 130
69 Motorola* Simplex Mode Values............................................................................... 132
70 HPI* Timing Symbol Description .............................................................................. 133
71 HPI*–8 Mode Write Accesses Values......................................................................... 133
72 Setup/Hold Timing Values in Asynchronous Mode of Operation..................................... 134
73 HPI*-16 Multiplexed Write Accesses Values ............................................................... 134
74 HPI*-16 Multiplexed Read Accesses Values................................................................ 135
75 HPI-16 Non-Multiplexed Read Accesses Values........................................................... 137
76 HPI-16 Non-Multiplexed Write Accesses Values .......................................................... 138
77 Serial Peripheral Port Interface Timing Values............................................................ 141
78 I2C Interface Timing Values .................................................................................... 141
79 High-Speed, Serial Timing Values............................................................................. 144
80 Boundary-Scan Interface Timings Values................................................................... 145
81 Reset Timings Table Parameters .............................................................................. 147
82 Power Dissipation Values......................................................................................... 149
83 Power Dissipation Test Conditions ............................................................................ 149
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Datasheet
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Revision History
Date
Revision
Description
Table 1, Section 3.1.1, Section 3.1.3: Updated the number of supported
SMII ports from six to three.
Section 3.1.12, Table 5: Clarified GPIO functions
Section 4.1.3: Updated tables to include A2 silicon part numbers.
Section 4.2.1: Added to help explain the tables outlined in Table 9
Table 14 and Table 16: Updated pin types
Table 22 and Table 24: Updated Power on Reset column values. Updated
RESET_IN_N description
Table 52: Updated Expansion Bus clock period
Table 66 to Table 69: Updated Expansion Bus Async. input setup timings
Table 78: Added note 3
August 2006
004
Section 5.9: Clarified ordering information
Removed SS-SMII references since this feature is not supported.
Updated Intel StrataFlash® Synchronous Memory (K3) references to Intel
StrataFlash® Embedded Memory (P30). Added Application Note
references to Table 2
Incorporated specification changes, specification clarifications and
document changes from the Intel® IXP4XX Product Line of Network
Processors Specification Update (306428-004)
Updated Intel® product branding.
Table 1, Table 6, and Table 7: removed Intel® IXP465 667 MHz extended
temperature part offering.
Section 3.2.11: corrected number of PMU 32-bit event counters to 4.
Section 4.1.3: updated part number tables with new A1 stepping values.
Table 12: updated HSS_TXDATA0 and HSS_TXCLK0 description.
Table 13: updated HSS_TXDATA1 description.
Table 16: changed EX_ADDR[24:0] pull-down value to 4.7 KΩ.
Table 25: added 1.5 V information.
August 2005
003
Table 27 and Table 28: clarified table footnote.
Section 5.0, Figure 12, Figure 13, Table 30: corrected supply voltage
names for OSC_VCC, OSC_VCCP, OSC_VSS, and OSC_VSSP.
Table 29: added new table for 4.0 W power.
Table 30 and Table 82: changed 1.4 V to 1.5 V for Intel® IXP465 667 MHz
processor.
Table 50: replaced T
with Frequency Tolerance.
rise-fall
Section 5.6.2.7.3: added new figures for using EX_IOWAIT_N.
Table 63: corrected T3 and T4 values.
Added support for Intel® IXP455 Network Processor including Table 1 on
page 13, Figure 3 on page 17, Table 26 on page 77, and Table 82 on
page 148.
Section 4.0, “Package Information” on page 37: added “Package
Markings” and “Part Numbers” sections.
May 2005
002
001
Table 10 on page 45: enhanced description of DDRI_CB[7:0].
Table 49 on page 115: added T
information.
SLEW RATE
March 2005
Initial release of document.
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
1.0
Product Features
1.1
Product Line Features
This document discusses all features supported on the Intel® IXP45X and Intel®
IXP46X Product Line of Network Processors. 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 Table 1 on page 13.
Some of the features described in this document require software delivered by Intel.
Some features may not be enabled with current software releases.
The features that require software are identified within this document. Please refer to
the Intel® IXP400 Software Programmer’s Guide for information on which features are
enabled at this time.
• Intel XScale® Processor (compliant with Intel® StrongARM* architecture)
— High-performance processor based on Intel XScale® Technology
— Seven/eight-stage Intel® Super-Pipelined RISC Technology
— Memory Management Unit (MMU)
• 32-entry, data memory management unit
• 32-entry, instruction memory management unit (MMU)
• 32-KByte, 32-way, set associative instruction cache
• 32-KByte, 32-way, set associative data cache
• 2-KByte, two-way, set associative mini-data cache
• 128-entry, branch target buffer
• Eight-entry write buffer
• Four-entry fill and pend buffers
— Clock speeds:
• 266 MHz
• 400 MHz
• 533 MHz
• 667 MHz (Not supported on Intel® IXP455 Network Processor)
— Intel® StrongARM* Version 5TE Compliant
— Intel® Media Processing Technology
Multiply-accumulate coprocessor
— Debug unit
Accessible through JTAG port
• PCI interface
— 32-bit interface
— Selectable clock
• 33-MHz clock output produced by GPIO15
• 1- to 66-MHz clock input
— PCI Local Bus Specification, Revision 2.2 compatible
— PCI arbiter supporting up to four external PCI devices (four REQ/GNT pairs)
— Host/option capable
— Master/target capable
— Two DMA channels
• USB 1.1 device controller
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
— Full-speed capable
— Embedded transceiver
— 16 endpoints
• USB 2.0 host controller
— Low-speed and full-speed capable
— Embedded transceiver
— EHCI Compliant
— Separate interface from USB 1.1 device controller
• DDRI-266 SDRAM interface
— Internally multi-ported Memory Controller Unit (Three Internal Ports)
— 32-bit data
— 13-bit address
— 133.32 MHz (which is 4 * OSC_IN input pin)
— Supports 128/256/512/1,024-Mbit technologies
— Unbuffered DDRI SDRAM support only
— Up to eight open pages simultaneously maintained
— Support for 32 Mbyte, minimum; 1 Gbyte, maximum
— User-enabled, single-bit error correction/multi-bit error detection ECC support
(ECC not supported on Intel® IXP455 Network Processor)
• Expansion interface
— Master/Target interface
— 25-bit address
— 32-bit data
— Eight programmable outbound chip selects
— One inbound chip select
— Four request/grant pairs
— Outbound transfers (IXP45X/IXP46X network processors are the master to
external target devices)
— Inbound transfers (IXP45X/IXP46X network processors are a target to external
masters)
— Bus tri-state for sideband transfers (External masters accesses to external
target device)
— Outbound transfer support
• Supports Intel/Motorola* microprocessors
• Multiplexed-style bus cycles
• Simplex-style bus cycles
• Support for Texas Instruments* DSPs using HPI*-8 bus cycles
• Support for Texas Instruments DSPs using HPI-16 bus cycles
• Synchronous flash support
• Flow through ZBT SRAM burst support
• Up to 80-MHz operation at 40 pF load
• Supports even/odd-parity generation and checking in all extended modes and
in some legacy modes (Intel and Motorola style bus cycles)
— Inbound transfer support
• Single transfer or burst transfers
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
• Cryptography Unit
— Exponentiation Unit (EAU)
— Random Number Generator (RNG)
— Secure Hash Algorithm (SHA)
• Two UART Interfaces
— 1,200 Baud to 921 Kbaud
— 16550 compliant
— 64-byte Tx and Rx FIFOs
— CTS and RTS modem-control signals
• Synchronous Serial Port Interface
— Master Mode Only
— Motorola’s Serial Peripheral Interface (SPI)
— National’s Microwire*
— Texas Instruments’ synchronous serial protocol (SSP)
• I2C interface
— Multi-master capable
— Slave capable
— Fast-mode support 400 Kbps
— Slow-mode support 100 Kbps
• Internal bus performance monitoring unit (IBPMU)
— Seven 27-bit event counters
— Monitoring of internal-bus occurrences and duration events
• 16 GPIOs
• Four internal timers
— Watchdog Timer
— General-Purpose Timer
— Two one-shot timers
• Packaging
— 544-pin PBGA
— Commercial temperature (0° to 70° C)
— Extended temperature (-40° to 85° C)
— Lead Free Support
The remaining features described in the product line features list require software in
order for these features to be functional. To determine if the feature is enabled, see the
Intel® IXP400 Software Programmer’s Guide.
• Three network processor engines (NPEs)Note 1
Used to off load typical Layer-2 networking functions such as:
— Ethernet filtering
— ATM SARing
— HDLC
— Layer-2 switching
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— Security acceleration (AES/3DES/SHA/MD-5)
• Configurable Network Interface, configurable in the following manner: Note 1
— Up to three MII/SMII interfaces
— Up to two MII/SMII interfaces + 1 UTOPIA Level 2 interface
• MII/SMII interfaces are: Note 1
— 802.3 MII interfaces that additionally support the SMII interface
— Single MDIO interface to control the MII/SMII interfaces
• UTOPIA Level 2 Interface is: Note 1
— Eight-bit interface
— Up to 33-MHz clock speed
— Five transmit and five receive address lines
• Encryption/Authentication Note 1
— DES
— 3DES
— AES 128-bit and 256-bit
— Single-pass AES-CCM
— SHA-1, SHA-256, SHA-384, SHA-512
— MD-5
• Two high-speed, serial interfaces Note 1
— Six-wire
— Supports speeds up to 8.192 MHz
— Supports connection to T1/E1 framers
— Supports connection to CODEC/SLICs
— Eight HDLC channels
— Clock source provided from an external source or internal HSS clock divider
• IEEE 1588 Hardware Assistance Notes 2, 3
— Time master support
— Time target support
Note:
1. This feature requires Intel supplied software. To determine if this feature is enabled
by a particular software release, see the Intel® IXP400 Software Programmer’s
Guide.
2. Although this feature has direct access from the Intel XScale® Processor, this
feature monitors the activity of the MII interfaces which requires Intel-supplied
software to operate.
3. IEEE 1588 hardware assistance is not available for the Intel® IXP455 Network
Processor.
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
1.2
Model-Specific Features
Table 1.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Features
Feature
Intel® IXP465
Intel® IXP460
Intel® IXP455
Processor Speed (MHz)
GPIO
266 / 400 / 533 / 667
266 / 400 / 533 / 667
266 / 400 / 533
X
X
X
X
UART 0/1
X
X
HSS 0 (NPE-A)†
X
X
HSS 1 (NPE-A)†
X
X
UTOPIA 2/ MII / SMII (NPE A)†
MII / SMII (NPE B)†
MII / SMII (NPE C)†
USB 1.1 Device Controller
USB 2.0 Host Controller
PCI
X
X
X
X
X
X
X
X
X
X
X
X
X
X
32-bit, up to 66-MHz
32-bit, up to 66-MHz
32-bit, up to 66-MHz
32-bit or 16-bit,
up to 80-MHz, Host
Support, Parity
Support
32-bit or 16-bit,
up to 80-MHz, Host
Support, Parity
Support
32-bit or 16-bit,
up to 80-MHz, Host
Support, Parity
Support
Expansion Bus
32-bit, 133-MHz clock
with ECC
32-bit, 133-MHz clock
with ECC
32-bit, 133-MHz clock
without ECC
DDRI-266 SDRAM
AES / AES-CCM/ DES / 3DES †
Cryptography Unit
Multi-Channel HDLC †
SHA / MD-5 †
X
X
X
X
8
X
8
X
IEEE1588 Hardware Assistance
I2C
X
X
X
X
X
X
X
X
SSP
X
X
Commercial Temperature
Extended Temperature
X
X
X††
X††
†
These features require Intel-supplied software in order to be operational. To determine if the feature
is enabled, see the Intel® IXP400 Software Programmer’s Guide.
††
Extended temperature is not available on Intel® IXP465 or Intel® IXP460 at 667 MHz.
2.0
About This Document
This datasheet contains a functional overview of the Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors, as well as mechanical data (package signal
locations and simulated thermal characteristics), targeted electrical specifications, and
some bus functional wave forms for the device.
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—Datasheet
Detailed functional descriptions — other than parametric performance — are published
in the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s
Manual.
Other related documents are shown in Table 2.
Table 2.
Related Documents
Document Title
Document #
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual
306262
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Hardware Design
Guidelines
305261
Intel® IXP4XX Product Line of Network Processors Specification Update
Intel® IXP400 Software Programmer’s Guide
306428
252539
Migration Guide for Intel StrataFlash® Synchronous Memory (J3) to Intel StrataFlash®
Embedded Memory (P30) - Application Note 812
306667
306669
Migration Guide for Intel StrataFlash® Synchronous Memory (K3/K18) to Intel StrataFlash®
Embedded Memory (P30) - Application Note 825
Intel XScale® Core Developer’s Manual
273473
—
Intel XScale® Microarchitecture Technical Summary
PCI Local Bus Specification, Revision 2.2
N/A
Universal Serial Bus Specification, Revision 1.1
Universal Serial Bus Specification, Revision 2.0
N/A
N/A
3.0
Functional Overview
The Intel® IXP45X and Intel® IXP46X Product Line of Network Processors are compliant
with the Intel® StrongARM* Version 5TE instruction-set architecture (ISA). The IXP45X/
IXP46X network processors are designed with Intel 0.18-micron semiconductor process
technology. This process technology along with the compactness of the Intel®
StrongARM* RISC ISA, which has the ability to simultaneously process data with up to
three integrated network processing engines (NPEs), and numerous dedicated-function
peripheral interfaces enables the IXP45X/IXP46X network processors to operate over a
wide range of low cost networking applications with industry-leading performance.
As indicated in Figure 1, Figure 2, and Figure 3, the IXP45X/IXP46X network
processors combine many features with the Intel XScale® processor to create a highly
integrated processor applicable to LAN/WAN-based networking applications in addition
to other embedded networking applications.
This section briefly describes the main features of the product. For detailed functional
descriptions, see the Intel® IXP45X and Intel® IXP46X Product Line of Network
Processors Developer’s Manual.
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Figure 1.
Intel® IXP465 Network Processor 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
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Figure 2.
Intel® IXP460 Network Processor Block Diagram
MII/SMII
MII/SMII
NPE B
NPE C
North AHB 133MHz x 32 bits
North AHB
Arbiter
IEEE 1588
I2C
Public Key
Exchange Crypto
Engine
SSP
• AHB-PKE Bridge
• Random Number
Generator (RNG)
• Exponentiation
Queue
Manager
AHB/AHB
Bridge
DDRI Memory
Controller Unit
USB Device
Version 1.1
Acceleration Unit (EAU)
• Secure Hash Algorithm
Unit(SHA)
32 Bit + ECC
UART 0
921 Kbaud
AHB Slave/
APB
Master
Bridge
South AHB 133 MHz x 32 bits
UART 1
921 Kbaud
South AHB
Arbiter
16 GPIO
GPIO
USB-Host
Controller
Version 2.0
Expansion Bus
PCI Controller
Controller
Interrupt
Controller
Intel XScale® Processor
32-Kbyte I-Cache
32-Kbyte D-Cache
2-Kbyte Mini D-Cache
PMU
Timers
16/32 bit + Parity 32 bit at 33/66 MHz
Master on North AHB
Slave Only
Bus Arbiters
Master on South AHB
AHB Slave / APB Master
B4822-02
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Figure 3.
Intel® IXP455 Network Processor 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
I2C
Cryptography
Unit
SSP
AHB/AHB
Bridge
Queue
Manager
DDRI Memory
Controller Unit
USB Device
Version 1.1
Hardware RNG
32 Bit
Exponentiation Unit
with no 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
Max speed = 533 MHz
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
B5024-002
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3.1
Key Functional Units
The following sections briefly describe the functional units and their interaction in the
system. For more detailed information, refer to the Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors Developer’s Manual.
Unless otherwise specified, the functional descriptions apply to all of the IXP45X/
IXP46X network processors. For specific information on supported interfaces, refer to
Table 1 on page 13. For model-specific block diagrams, see Figure 1 on page 15,
Figure 2 on page 16, and Figure 3 on page 17.
3.1.1
Network Processor Engines (NPEs)
The network processor engines (NPEs) are dedicated-function processors containing
hardware coprocessors integrated into the IXP45X/IXP46X network processors. The
NPEs are used to off load processing function required by the Intel XScale® processor.
These NPEs are high-performance, hardware-multi-threaded processors with additional
local-hardware-assist functionality used to off load highly processor-intensive functions
such as MII (MAC), CRC checking/generation, AAL segmentation and re-assembly, AES,
AES-CCM, DES, 3DES, SHA, MD-5, etc.
All instruction code for the NPEs are stored locally and is accessed using a dedicated
instruction memory bus. Likewise, a separate dedicated data memory bus allows
accesses to local code store as well as DDR SDRAM via the AHB bus.
These NPEs support processing of the dedicated peripherals that can include:
• One UTOPIA Level 2 (Universal Test and Operation PHY Interface for ATM) interface
• Two High-Speed Serial (HSS) interfaces
• Up to three Media-Independent Interface (MII), up to three Serial Media
Independent Interfaces (SMII), or some combination of each.
Table 3 specifies the possible combination of interfaces for the NPEs contained on the
IXP45X/IXP46X network processors. These configurations are determined by the
factory programmed fuse settings or by software that configures the part during boot-
up (see the Expansion Bus Configuration Register 1 (EXP_CNFG1) in the Expansion Bus
Chapter of the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Developer’s Manual for more details). The table assumes that all features are
supported on the processor. For details on feature support listed by processor, see
Table 1 on page 13.
Table 3.
Network Processor Functions
AES /
DES /
3DES
MII /
SMII A
MII /
SMII B
MII /
SMII C
SHA, MD-
5
Device
UTOPIA
HSS
HDLC
Configuration 0
Configuration 1
Configuration 2
Configuration 3
Configuration 4
Configuration 5
Configuration 6
Configuration 7
X
X
X
X
X
X
X
X
X
X
X
MII
MII
MII
X
X
X
X
X
X
X
X
8
8
8
8
8
8
8
8
X
X
X
X
X
X
X
X
SMII
SMII
MII
SMII
MII
MII
MII
SMII
SMII
SMII
SMII
MII
MII
SMII
SMII
MII
SMII
SMII
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The NPE is a hardware-multi-threaded processor engine that is used to accelerate
functions that are difficult to achieve high performance in a standard RISC processor.
Each NPE is a 133.32-MHz (which is 4 * OSC_IN input pin) processor core that has self-
contained instruction memory and self-contained data memory that operate in parallel.
Each NPE has 4 K words of instruction memory and 4 K words of data memory.
In addition to having separate instruction/data memory and local-code store, the NPE
supports hardware multi-threading with support for multiple contexts. The support of
hardware multi-threading creates an efficient processor engine with minimal processor
stalls due to the ability of the processor to switch contexts in a single clock cycle, based
on a prioritized/preemptive basis. The prioritized/preemptive nature of the context
switching allows time-critical applications to be implemented in a low-latency fashion —
which is required when processing multi-media applications.
The NPE also connects to several hardware-based coprocessors that are used to
implement functions that are difficult for a processor to implement. These functions
include:
• HSS Serialization/ De-serialization
• DES/3DES/AES
• CRC checking/generation
• SHA-1/256/384/512
• MD-5
• HDLC bit stuffing/de-stuffing
• Learning/filtering content addressable
memory
• Media Access Controller
functionality
• UTOPIA Level 2 Framing
Note:
To determine if the SHA-256/384/512 feature is enabled by a particular software
release, see the Intel® IXP400 Software Programmer’s Guide.
These coprocessors are implemented in hardware, enabling the coprocessors and the
NPE processor core to operate in parallel.
With the addition of the new switching coprocessor (SWCP) and the Ethernet
coprocessors enabled with the Intel® IXP400 Software, functions like a four-port,
Layer-2 switch can be easily implemented using all Intel-based silicon. Also, by using
NPEs to implement switching functions, value added features like VLAN or IP switching
can be easily upgraded using existing silicon. Therefore, speeding up the end
customer’s time to market while keeping product costs the same.
The combined forces of the hardware multi-threading, local-code store, independent
instruction memory, independent data memory, and parallel processing — contained on
the NPE — allows the Intel XScale® processor to be utilized for application purposes.
The multi-processing capability of the peripheral interface functions allows unparalleled
performance to be achieved by the application running on the Intel XScale® processor.
3.1.2
Internal Bus
The internal bus architecture of the IXP45X/IXP46X network processors are designed to
allow parallel processing to occur and to isolate bus utilization, based on particular
traffic patterns. The bus is segmented into four major buses:
• North Advanced, High-Performance Bus
(AHB)
• Memory Port Interface
• South AHB
• Advanced Peripheral Bus
(APB)
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3.1.2.1
North AHB
The North AHB is a 133.32-MHz (which is 4 * OSC_IN input pin), 32-bit bus that can be
mastered by the NPE A, NPE B, or NPE C. The targets of the North AHB can be the DDRI
SDRAM or the AHB/AHB bridge. The AHB/AHB bridge allows the NPEs to access the
peripherals and internal targets on the South AHB.
Data transfers by the NPEs on the North AHB to the South AHB are targeted
predominately to the queue manager. Transfers to the AHB/AHB bridge may be
“posted” — when writing — or “split” — when reading.
When a transaction is “posted,” a master on the North AHB requests a write to a
peripheral on the South AHB. If the AHB/AHB Bridge has a free FIFO location, the write
request will be transferred from the master on the North AHB to the AHB/AHB bridge.
The AHB/AHB bridge will complete the write on the South AHB, when it can obtain
access to the peripheral on the South AHB. The North AHB is released to complete
another transaction.
When a transaction is “split,” a master on the North AHB requests a read of a peripheral
on the South AHB. If the AHB/AHB bridge has a free FIFO location, the read request will
be transferred from the master on the North AHB to the AHB/AHB bridge. The AHB/AHB
bridge will complete the read on the South AHB, when it can obtain access to the
peripheral on the South AHB.
Once the AHB/AHB bridge has obtained the read information from the peripheral on the
South AHB, the AHB/AHB bridge notifies the arbiter, on the North AHB, that the AHB/
AHB bridge has the data for the master that requested the “split” transfer. The master
on the North AHB — that requested the split transfer — will arbitrate for the North AHB
and transfer the read data from the AHB/AHB bridge. The North AHB is released to
complete another transaction while the North AHB master — that requested the “split”
transfer — waits for the data to arrive.
These “posting” and “splitting” transfers allow control of the North AHB to be given to
another master on the North AHB — enabling the North AHB to achieve maximum
efficiency. Transfers to the AHB/AHB bridge are considered to be small and infrequent,
relative to the traffic passed between the NPEs and the DDRI SDRAM on the North AHB.
When multiple masters arbitrate for the North AHB, the masters are awarded access to
the bus in a round-robin fashion. Each transaction can be no longer than an eight-word
burst. This implementation promotes fairness within the system.
3.1.2.2
South AHB
The South AHB is a 133.32-MHz (which is 4 * OSC_IN input pin), 32-bit bus that can be
mastered by the Intel XScale® processor, PCI controller, Expansion Bus Interface, USB
Host Controller, and the AHB/AHB bridge. The targets of the South AHB Bus can be the
DDRI SDRAM, PCI Controller, Queue Manager, Expansion Bus, or the AHB/APB bridge.
As a special case, the Intel XScale® Processor is the only master which can access the
Cryptography Unit (target).
Accesses across the APB/AHB bridge allows interfacing to peripherals attached to the
APB. The Expansion bus and PCI controller can be configured to support split transfers.
Arbitration on the South AHB are round-robin. Each transaction can be no longer than
an eight-word burst. This implementation promotes fairness within the system.
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3.1.2.3
Memory Port Interface
The Memory Port Interface (MPI) is a 128-bit bus that provides the Intel XScale®
processor a dedicated interface to the DDRI SDRAM. The Memory Port Interface
operates at 133.32 MHz (which is 4 * OSC_IN input pin).
The Memory Port Interface stores memory transactions from the Intel XScale®
processor which have not been processed by the Memory Controller. The Memory Port
Interface supports eight processor read transactions up to 32 bytes each. That total
equals the maximum number of outstanding transaction the Processor Bus Controller
can support. (That includes processor DCU [4 - load requests to unique cache lines],
IFU [2 - prefetch], IMM [1 - tablewalk], DMM [1 - tablewalk].)
The Memory Port Interface also supports eight processor-posted write transactions up
to 16 bytes each.
Arbitration on the Memory Port Interface is not required due to no contention with
other masters. Arbitration will exist in the DDRI memory controller between all of the
main internal busses.
3.1.2.4
APB Bus
The APB Bus is a 66.66-MHz (which is 2* OSC_IN input pin), 32-bit bus that can be
mastered by the AHB/APB bridge only. The targets of the APB bus can be:
• USB 1.1 device controller
• UARTs
• The internal bus performance monitoring unit
(IBPMU)
• All NPEs
• GPIO
• Interrupt controller
• Timers
• IEEE 1588 Hardware Assist
• I2C
• Serial Peripheral Port
Interface
The APB interface is also used as an alternate-path interface to the NPEs and is used
for NPE code download and configuration.
No arbitration is required due to a single master implementation.
3.1.3
MII/SMII Interfaces
The IXP45X/IXP46X network processors can be configured to support up to three MII,
up to three SMII industry-standard, or some combination thereof, media-independent
interface (MII) interfaces. These interfaces are integrated into the IXP45X/IXP46X
network processors with separate media-access controllers and in many cases
independent network processing engines. (See Table 3 for allowable combinations.)
The independent NPEs and MACs allow parallel processing of data traffic on the MII
interfaces and off loading of processing required by the Intel XScale® processor. The
IXP45X/IXP46X network processors are compliant with the IEEE 802.3 specification.
In addition to the MII interfaces, the IXP45X/IXP46X network processors include a
single management data interface that is used to configure and control PHY devices
that are connected to the MII interfaces. The IXP45X/IXP46X network processors
provide support for serial media independent interface (SMII).
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3.1.4
UTOPIA Level 2
The integrated UTOPIA Level 2 interface works with a network-processing engine core
for several of the IXP45X/IXP46X network processors. The pins of the UTOPIA Level 2
interface are multiplexed with one of the MII/SMII interfaces. (See Table 3 for details.)
The UTOPIA Level 2 interface supports a single- or a multiple-physical-interface
configuration with cell-level or octet-level handshaking. The network processing engine
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 Level 2 interface, off-loading these processing tasks from the Intel XScale®
processor.
The IXP45X/IXP46X network processors are compliant with the ATM Forum, UTOPIA
Level 2 Specification, Revision 1.0.
3.1.5
USB 1.1 Device Interface
The integrated USB 1.1 device interface supports full-speed operation and 16 endpoints
and includes an integrated transceiver.
There are:
• Six isochronous endpoints (three input and three output)
• One control endpoints
• Three interrupt endpoints
• Six bulk endpoints (three input and three output)
3.1.6
USB 2.0 Host Interface
USB Host functionality is implemented on the IXP45X/IXP46X network processors. The
function being performed is defined by the USB 2.0 Specification, maintained by
usb.org.
Not all features defined by the 2.0 specification are supported for this implementation.
The following is a partial list of supported features:
• Host function
• Low-speed interface
• Full-speed interface
• EHCI register interface
The following is a partial list of features not supported:
• Device function
• OTG function
• High-speed interface
3.1.7
PCI Controller
The IXP45X/IXP46X network processors’ PCI controller is compatible with the PCI Local
Bus Specification, Rev. 2.2. The PCI interface is 32-bit compatible bus and capable of
operating as either a host or an option (i.e. not the Host). This PCI implementation
supports 3.3 V I/O only.
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3.1.8
DDRI SDRAM Controller
The IXP45X/IXP46X network processors integrate a high-performance, multi-ported
Memory Controller Unit (MCU) to provide a direct interface between the IXP45X/IXP46X
network processors and their local memory subsystem. The MCU supports:
• DDRI 266 SDRAM
• 128/256/512-Mbit, 1-Gbit DDRI SDRAM technology support
• Only unbuffered DRAM support (No registered DRAM support)
• Dedicated port for Intel XScale® processor to DDR SDRAM
• Between 32 Mbyte and 1 Gbyte of 32-bit DDR SDRAM for low-cost solutions
• Single-bit error correction, multi-bit detection support (ECC)
• 32-, 40-bit wide Memory Interfaces (non-ECC and ECC support)
The DDRI SDRAM interface provides a direct connection to a high-bandwidth and
reliable memory subsystem. The DDRI SDRAM interface is a 32-bit-wide data path.
An 8-bit Error Correction Code (ECC) across each 32-bit word improves system
reliability. It is important to note that ECC is also referred to as CB in many DIMM
specifications. The pins on IXP45X/IXP46X network processors are called
DDRI_CB[7:0]. ECC is only implemented in the 32-bit mode of operation. However, the
algorithm used to generate the 8-bit ECC is implemented over 64-bit.
Note:
The IXP455 network processor does not support ECC functionality.
The ECC circuitry is designed to operate always on a 64-bit word and when operating in
32-bit mode, the upper 32 bits are driven to zeros internally. To summarize the impact
to the customer, the full 8 bits of ECC must be stored and read from a memory array in
order for the ECC logic to work. An 8-bit-wide memory must be used when
implementing ECC.
The memory controller only corrects single bit ECC errors on read cycles. The ECC is
stored into the DDRI SDRAM array along with the data and is checked when the data is
read. If the code is incorrect, the MCU corrects the data (if possible) before reaching
the initiator of the read. ECC error scrubbing must be done with software. User-defined
fault correction software is responsible for scrubbing the memory array and handling
double-bit errors.
In order to limit double-bit errors from occurring, periodically reading the entire usable
memory array will allow the hardware unit within the memory controller to correct any
single-bit, ECC errors that may have occurred prior to these errors becoming double-bit
ECC errors. Using this method is system-dependent.
It is important to note as well, that when sub-word writes (byte writes or half-word
writes) to a 32-bit memory with ECC enabled, the memory controller will implement
read-modify writes. Implementing read-modify writes is important to understand when
understanding performance implications when writing software.
To understand a read-modify write, understanding that a byte to be written falls within
a 32-bit word which is addressed on a word-aligned boundary. When a byte write is
requested, the memory controller will read the 32-bit word which encompasses the
byte that is to be written. The memory controller will then modify the specified byte,
calculate a new ECC, and then write the entire 32-bit word back into the memory
location it was read from.
The value written back into the memory location will contain the 32-bit word with the
modified byte and the new ECC value.
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The MCU supports two banks of DDR SDRAM. The MCU has support for unbuffered
DDRI 266 only.
Table 4 illustrates the supported DDR SDRAM configurations for the IXP45X/IXP46X
network processors. The 128/256/512-Mbit, 1-Gbit DDRI SDRAM devices comprise four
internal leaves. The MCU controls the leaf selects within 128/256/512-Mbit, 1-Gbit
DDRI SDRAM by toggling DDRI_BA[0] and DDRI_BA[1].
The two DDR SDRAM chip enables (DDRI_CS[1:0]#) support a DDRI SDRAM memory
subsystem consisting of two banks. The base address for the two contiguous banks are
programmed in the DDR SDRAM Base Register (SDBR) and must be aligned to a 32-
Mbyte boundary. The size of each DDR SDRAM bank is programmed with the DDR
SDRAM boundary registers (SBR0 and SBR1).
Table 4.
Supported DDRI Memory Configurations
Address Size
Leaf Select
Total
Memory
Size1
DDRI SDRAM
Technology
DDRI SDRAM
Arrangement
Page
Size2
# Banks
Row
Col
DDRI_BA[1]
DDRI_BA[0]
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
4K
4K
2K
2K
4K
4K
2K
2K
8K
8K
4K
4K
8K
8K
4K
4K
16M x 8
8M x 16
32M x 8
16M x 16
64M x 8
32M x 16
128M x 8
64M x 16
12
10
I_AD[26]
I_AD[25]
I_AD[27]
I_AD[26]
I_AD[28]
I_AD[27]
I_AD[29]
I_AD[28]
I_AD[25]
128 Mbit
12
13
13
13
13
14
14
9
I_AD[24]
I_AD[26]
I_AD[25]
I_AD[27]
I_AD[26]
I_AD[28]
I_AD[27]
10
9
256 Mbit
512 Mbit
1 Gbit
11
10
11
10
256 Mbyte
512 Mbyte
Notes:
1.
2.
Table indicates 32-bit-wide memory subsystem sizes
Table indicates 32-bit-wide memory page sizes
The memory controller is a 32-bit only interface. If a x16 memory chip is used, a
minimum of two memory chips would be required to facilitate the 32-bit interface
required by the IXP45X/IXP46X network processors. If ECC is required, additional
memories would need to be added. For more information on DDRI SDRAM support and
configuration see the Intel® IXP45X and Intel® IXP46X Product Line of Network
Processors Developer’s Manual.
The memory controller internally interfaces to the North AHB, South AHB, and Memory
Port Interface with independent interfaces. This architecture allows DDRI SDRAM
transfers to be interleaved and pipelined to achieve maximum possible efficiency.
The maximum burst size supported to the DDRI SDRAM interface is eight 32-bit words.
This burst size allows the best efficiency/fairness performance between peripheral
accesses from the North AHB, the South AHB, and the MPI.
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The programming priority of the MCU is for the Memory Port Interface to have the
highest priority and two AHB ports will have the next highest priority. For more
information on MCU arbitration support and configuration see the Intel® IXP45X and
Intel® IXP46X Product Line of Network Processors Developer’s Manual.
One item to be aware of is that when ECC is being used, the memory chip chosen to
support the ECC must match that of the technology chosen on the interface. Therefore,
if x8 in a given configuration technology is chosen then the ECC memory chip must be
the same. If a x16 configuration is chosen then a x16 chip must be used for the ECC
chip.
3.1.9
Expansion Interface
The expansion interface allows easy and — in most cases — glue-less connection to
peripheral devices. It also provides input information for device configuration after
reset.
Some of the peripheral device types are SRAM, flash, ATM control interfaces, and DSPs
used for voice applications. (Some voice configurations can be supported by the HSS
interfaces and the Intel XScale® processor, implementing voice-compression
algorithms.)
The expansion interface functions in two modes of operation:
• Legacy (16-bit, data mode)
• Enhanced (32-bit, data mode)
3.1.9.1
Expansion Bus Legacy Mode of Operation
In the legacy mode of operation, the expansion interface is a 16-bit interface that
allows an address range of 512 bytes to 16 Mbytes, using 24 address lines for each of
the eight independent chip selects.
Accesses to the expansion bus interface is completed in five phases. Each of the five
phases can be lengthened or shortened by setting various configuration registers on a
per-chip-select basis. This feature allows the IXP45X/IXP46X network processors to
connect to a wide variety of peripheral devices with varying speeds.
The expansion interface supports Intel or Motorola* microprocessor-style bus cycles.
The bus cycles can be configured to be multiplexed address/data cycles or separate
address/data cycles for each of the eight chip-selects.
Additionally, Chip Selects 4 through 7 can be configured to support Texas Instruments*
HPI-8 or HPI-16 style accesses for DSPs.
The expansion interface is an asynchronous interface to externally connected chips.
However, a clock must be supplied to expansion interface of the IXP45X/IXP46X
network processors for the interface to operate. This clock can be driven from GPIO 15
or an external source. The maximum clock rate that the expansion interface can accept
in legacy mode of operation is 66 MHz. If GPIO 15 is used as the clock source, the
Expansion Bus interface can only be clocked at a maximum of 33.33 MHz. GPIO 15’s
maximum clock rate is 33.33 MHz.
By providing this legacy mode of operation, code developed for previous generations of
this platform becomes easily portable.
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3.1.9.2
Expansion Bus Enhanced Mode of Operation
In the enhanced mode of operation, the expansion interface is a 32-bit interface that
allows an address range of 512 bytes to 32 Mbytes per chip select on IXP45X/IXP46X
network processors, using 25 address lines for each of the eight independent chip
selects.
Additionally, in enhanced mode, the interface supports shared access to the bus with
external masters. This shared access is achieved with four request/grant pins and an
integrated arbiter. Not only can external devices access each other, but they can also
access the IXP45X/IXP46X network processors’ internal registers (including the DDRI
SDRAM interface).
The advantage to this feature is that shared memory access can be achieved by using
the DDRI SDRAM interface attached to IXP45X/IXP46X network processors. This lowers
the system’s overall bill of materials.
Enhanced mode also supports synchronous transfers at speeds of up to 80 MHz with a
40-pF load. In addition to fully synchronous support, the enhanced mode also supports
burst transfers of up to eight-word lengths. The synchronous bus support is compatible
to Zero Bus Turnaround (ZBT) SRAM cycles for inbound/outbound transactions for both
read/write transactions.
Additionally, the outbound read transactions can support the Intel StrataFlash®
Embedded Memory P30 synchronous-burst mode.
Byte-wide parity is an optional configuration of this interface in all modes of operation
except:
• Intel StrataFlash® Embedded Memory P30 synchronous-burst mode
• HPI mode
At the de-assertion of reset, the 25-bit address bus is used to capture configuration
information from the levels that are applied to the pins at this time. External pull-up/
pull-down resistors are used to tie the signals to particular logic levels. (For additional
details, see “Package Information” on page 37.) If a signal is required to be placed into
a pull-up state during this initialization period, the IXP45X/IXP46X network processors
contain internal weak pull-ups. Depending upon the system design, pull-down resistors
may be the only thing required.
3.1.10
High-Speed, Serial Interfaces
The high-speed, serial interfaces (HSS) are six-signal interfaces that support serial
transfer speeds from 512 KHz to 8.192 MHz, for some models of the IXP45X/IXP46X
network processors. (For processor-specific speeds, see Table 3 on page 18.)
Each interface allows direct connection of up to four T1/E1 framers and CODEC/SLICs
to the IXP45X/IXP46X network processors. The high-speed, serial interfaces are
capable of supporting various protocols, based on the implementation of the code
developed for the network processor engine.
For a list of supported protocols, see the Intel® IXP400 Software Programmer’s Guide.
3.1.11
UARTs
The UART interfaces are a 16550-compliant UART with the exception of transmit and
receive buffers. Transmit and receive buffers are 64 bytes-deep versus the 16 bytes
required by the 16550 UART specification.
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The interfaces can be configured to support speeds from 1,200 Baud to 921 Kbaud. The
interfaces support configurations of:
• Five, six, seven, or eight data-bit transfers
• One or two stop bits
• Even, odd, or no parity
The request-to-send (RTS_N) and clear-to-send (CTS_N) modem control signals also
are available with the interface for hardware flow control.
3.1.12
GPIO
16 GPIO pins are supported by the IXP45X/IXP46X network processors. GPIO pins 0
through 15 can be configured to be general-purpose input or general-purpose output.
Additionally, GPIO pins 0 through 12 can be configured to be an interrupt input.
GPIO Pin 1 can also be configured as a clock input for an external USB 2.0 Host Bypass
clock. When spread spectrum clocking (SSC) is used, an external clock should be used
as the source for the USB 2.0 Host clock. Refer to the Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors Developer’s Manual for more information.
GPIO Pin 14 and GPIO 15 can also be configured as a clock output. The output-clock
configuration can be set at various speeds, up to 33.33 MHz, with various duty cycles.
GPIO Pin 14 is configured as an input, upon reset. GPIO Pin 15 is configured as an
output, upon reset. GPIO Pin 15 can be used to clock the expansion interface, after
reset.
Several other GPIO pins can serve as an alternate function, as outlined in Table 5.
Table 5.
GPIO Alternate Function Table
GPIO Pin Number
GPIO function
Alternate Function
External USB v1.1 Device Bypass
Clock
0†
General purpose input/output or interrupt source
External USB v2.0 Host Bypass
Clock
1†
General purpose input/output or interrupt source
2
3
4
5
6
General purpose input/output or interrupt source
General purpose input/output or interrupt source
General purpose input/output or interrupt source
General purpose input/output or interrupt source
General purpose input/output or interrupt source
Reserved
Reserved
Reserved
Reserved
Reserved
Auxiliary IEEE1588 Master
Snapshot
7
General purpose input/output or interrupt source
8
9:12
13
General purpose input/output or interrupt source
General purpose input/output or interrupt source
General purpose input/output
Auxiliary IEEE1588 Slave Snapshot
Reserved
Reserved
14
General purpose input/output or output clock
Output Clock or General purpose input/output
Output clock 14
Output clock 15
15
†
When a spread spectrum clock is used, GPIO Pin 0 and GPIO Pin 1 should be configured as an input clock
for USB. See the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s
Manual for detailed information.
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3.1.13
Internal Bus Performance Monitoring Unit (IBPMU)
The IXP45X/IXP46X network processors contain a performance monitoring unit that
may be used to capture predefined events within the system outside of the Intel
XScale® processor. These features aid in measuring and monitoring various system
parameters that contribute to the overall performance of the processor.
The Performance Monitoring (PMON) facility provided comprises:
• Eight Programmable Event Counters (PECx)
• Previous Master/Slave Register
• Event Selection Multiplexor
The programmable event counters are 27 bits wide. Each counter may be programmed
to observe one event from a defined set of events. An event consists of a set of
parameters which define a start condition and a stop condition.
The monitored events are selected by programming the Event Select Registers (ESR).
3.1.14
Interrupt Controller
The IXP45X/IXP46X network processors implement up to 64 interrupt sources to allow
an extension of the Intel XScale® processor’s FIQ and IRQ interrupt sources. These
sources can originate from some external GPIO pins, internal peripheral interfaces, or
internal logic.
The interrupt controller can configure each interrupt source as an FIQ, IRQ, or disabled.
The interrupt sources tied to Interrupt 0 to 7 can be prioritized. The remaining
interrupts are prioritized in ascending order. For example, Interrupt 8 has a higher
priority than 9, 9 has a higher priority than 10, and 30 has a higher priority that 31.
An additional level of priority can be set for interrupts 32 through 64. This priority
setting gives any interrupt between 32 through 64 priority over interrupts 0 through
31.
3.1.15
Timers
The IXP45X/IXP46X network processors contain four internal timers operating at
66.66 MHz (which is 2* OSC_IN input pin) to allow task scheduling and prevent
software lock-ups. The device has four 32-bit counters:
• Watch-Dog Timer
• Timestamp Timer
• Two general-purpose Timers
The Timestamp Timer and the two general-purpose timers have the optional ability to
use a pre-scaled clock. A programmable pre-scaler can be used to divide the input
clock by a 16-bit value. The input clock can be either the APB clock (66.66 MHz) or a
20-ns version of the APB clock (50 MHz). By default all timers use the APB clock.
The 16-bit pre-scale value ranges from divide by 2 to 65,536 and results in a new clock
enable available for the timers that ranges from 33.33 MHz down to 1,017.26 Hz.
The Timestamp Timer also contains a 32-bit compare register that allows an interrupt
to be created at times other than time 0.
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3.1.16
IEEE 1588 Hardware Assistance
In a distributed control system containing multiple clocks, individual clocks tend to drift
apart. Some kind of correction mechanism is necessary to synchronize the individual
clocks to maintain global time, which is accurate to some clock resolution. The
IEEE 1588 standard for a precision clock synchronization protocol for networked
measurement and control systems can be used for this purpose. The IEEE 1588
standard defines several messages that can be used to exchange timing information.
The IXP45X/IXP46X network processors implement the IEEE 1588 hardware-assist
logic on three of the MII interfaces. Using the hardware assist logic along with software
running on the Intel XScale® processor, a full source or sink capable IEEE-1588
compliant network node can be implemented.
Note:
The IXP455 network processor does not support IEEE 1588 hardware-assist.
3.1.17
Synchronous Serial Port Interface
The IXP45X/IXP46X network processors have a dedicated Synchronous Serial Port
(SSP) interface. The SSP interface is a full-duplex synchronous serial interface. It can
connect to a variety of external analog-to-digital (A/D) converters, audio and telecom
CODECs, and many other devices which use serial protocols for transferring data.
It supports National’s Microwire*, Texas Instruments’* synchronous serial protocol
(SSP), and Motorola's* serial peripheral interface (SPI*) protocol.
The SSP operates in master mode (the attached peripheral functions as a slave), and
supports serial bit rates from 7.2 Kbps to 1.8432 Mbps using the on-chip, 3.6864-MHz
clock, and bit rates from 65.10 Kbps to 16.67 Mbps using a maximum off-chip, 33.33
MHz clock. Serial data formats may range from 4 to 16 bits in length. Two on-chip
register blocks function as independent FIFOs for data, one for each direction. The
FIFOs are 16 entries deep x 16 bits wide. Each 32-bit word from the system fills one
entry in a FIFO using the lower half 16-bits of a 32-bit word.
3.1.18
I2C Interface
The I2C Bus Interface Unit allows the IXP45X/IXP46X network processors to serve as a
master and slave device residing on the I2C bus. The I2C bus is a two-pin serial bus.
SDA is the data pin for input and output functions and SCL is the clock pin for reference
and control of the I2C bus.
The I2C bus allows the IXP45X/IXP46X network processors to interface to other I2C
peripherals and micro-controllers for system management functions. The serial bus
requires a minimum of hardware for an economical system to relay status and
reliability information on the IXP45X/IXP46X network processors subsystem to an
external device.
The I2C Bus Interface Unit is a peripheral device that resides on the IXP45X/IXP46X
network processors’ APB. Data is transmitted to and received from the I2C bus via a
buffered interface. Control and status information is relayed through a set of memory-
mapped registers. Refer to the I2C Bus Specification for complete details on I2C bus
operation.
The I2C supports:
• Multi-master capabilities
• Slave capabilities
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The I2C unit supports both fast-mode operation — at 400 Kbps — and standard mode
— at 100 Kbps. Fast mode logic levels, formats, capacitive loading and protocols
function the same in both modes. The I2C unit does not support I2C 10-bit addressing
or CBUS.
3.1.19
Encryption/Decryption/Authentication - AES/DES/SHA/MD-5
The IXP45X/IXP46X network processors implement on-chip hardware acceleration for
underlying security and authentication algorithms.
The encryption/decryption algorithms supported are AES, single pass AES-CCM, DES,
and triple DES. These algorithms are commonly found when implementing IPSEC, VPN,
WEP, WEP2, WPA, and WPA2.
The authentication algorithms supported are MD-5, SHA-1, SHA-256, SHA-384, and
SHA-512. Inclusion of SHA-384 and SHA-512 allows 256-bit key authentication to pair
up with 256-bit AES support.
Note:
To determine if the SHA-256/384/512 feature is enabled by a particular software
release, see the Intel® IXP400 Software Programmer’s Guide.
3.1.20
Cryptography Unit
The Cryptography Unit implements three major functions:
• Exponentiation Unit (EAU)
• Random Number Generator (RNG)
• Secure Hash Algorithm (SHA function for the RNG)
The EAU supports various large number arithmetic operations. These operations include
modular exponentiation, modular reduction, multiply, add and subtract. These
operations are controlled through a set of memory mapped registers. Parameters for
and results of the operations are written in little-endian ordering into a RAM (contained
within the EAU) which the EAU state machine accesses and also uses for temporary
registers. The arithmetic operations supported by the EAU are used by software
executing in the host processor to build larger cryptographic functions such as signing
and verification procedures. Since the EAU executes only one operation at a time, the
host processor must serialize the required operations to the EAU.
The EAU begins operating after the host processor has moved data into the EAU RAM
and loads the EAU’s command register with an appropriate command. After executing
the command, the EAU appropriately sets its status bits and waits idle until it receives
another command from the host processor.
The RNG unit provides a digital, random-number generation capability. It uses a LFSR
(Linear Feedback Shift Register) to generate a sequence of pseudo-random bits. These
sequences are shifted into a FIFO of 32-bit words, which may be read sequentially from
the random number register. A new word is generated every 32 clocks and the RNG will
buffer 16 of these words at a time.
The output of the RNG should be passed through the SHA engine for added
randomness. The host processor (Intel XScale® processor) is responsible for
implementing this SHA-based, random-number generation. The LFSR also allows one
entropy source. The entropy source is fed in from a PN sequence generator which has a
period of 2^42 - 1. The coefficients for the PN sequence is chosen such that it produces
the maximal sequence length. The coefficients are not mentioned for security reasons.
The coefficients for the 128-stage LSFR are similarly not mentioned here for security
reasons.
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3.1.21
Queue Manager
The Queue Manager provides a means for maintaining coherency for data handling
between various processors cores contained on the IXP45X/IXP46X network processors
(NPE to NPE, NPE to Intel XScale® processor, etc.). It maintains the queues as circular
buffers in an embedded 8-Kbyte SRAM. The Queue Manager also implements the status
flags and pointers required for each queue.
The Queue Manager manages 64 independent queues. Each queue is configurable for
buffer and entry size. Additionally status flags are maintained for each queue.
The Queue Manager interfaces include an Advanced High-performance Bus (AHB)
interface to the NPEs and Intel XScale® processor (or any other AHB bus master), a
Flag Bus interface, an event bus (to the NPE condition select logic), and two interrupts
to the Intel XScale® processor.
The AHB interface is used for configuration of the Queue Manager and provides access
to queues, queue status, and SRAM. Individual queue status for queues 0-31 is
communicated to the NPEs via the flag bus. Combined queue status for queues 32-63
are communicated to the NPEs via the event bus. The two interrupts, one for queues 0-
31 and one for queues 32-63, provide status interrupts to the Intel XScale® processor.
3.2
Intel XScale® Processor
The Intel XScale technology is compliant with the Intel® StrongARM* Version 5TE
instruction-set architecture (ISA). The Intel XScale® processor, shown in Figure 4, is
designed with Intel, 0.18-micron production semiconductor process technology. This
process technology — with the compactness of the Intel® StrongARM* RISC ISA —
enables the Intel XScale® processor to operate over a wide speed and power range,
producing industry-leading mW/MIPS performance.
Intel XScale® processor features include:
• Seven/eight-stage super-pipeline promotes high-speed, efficient performance
• 128-entry branch target buffer keeps pipeline filled with statistically correct branch
choices
• 32-entry instruction memory-management unit for logical-to-physical address
translation, access permissions, and Instruction-Cache (I-cache) attributes
• 32-entry data-memory management unit for logical-to-physical address
translation, access permissions, Data-Cache (D-Cache) attributes
• 32-Kbyte instruction cache can hold entire programs, preventing processor stalls
caused by multi-cycle memory accesses
• 32-Kbyte data cache reduces processor stalls caused by multi-cycle memory
accesses
• 2-Kbyte mini-data cache for frequently changing data streams avoids “thrashing”
of the D-cache
• Four-entry, fill-and-pend buffers to promote processor efficiency by allowing “hit-
under-miss” operation with data caches
• Eight-entry write buffer allows the processor to continue execution while data is
written to memory
• Multiple-accumulate coprocessor that can do two simultaneous, 16-bit, SIMD
multiplies with 40-bit accumulation for efficient, high-quality media and signal
processing
• Performance monitoring unit (PMU) furnishing two 32-bit event counters and one
32-bit cycle counter for analysis of hit rates, etc.
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This PMU is for the Intel XScale® processor only. An additional PMU is supplied for
monitoring of internal bus performance.
• JTAG debug unit that uses hardware break points and 256-entry trace history
buffer (for flow-change messages) to debug programs
Figure 4.
Intel XScale® Technology Block Diagram
Branch Target Cache
FIQ
Interrupt
Request
IRQ
M
M
U
Instruction Cache
32 Kb
Instruction
South
AHB
Bus
Execution
Core
Data Cache
32 Kb
Data
Address
M
M
U
Coprocessor Interface
Mini-Data Cache
2 Kb
Data
Multiply
Accumulate
System
Management
Debug/
PMU
JTAG
A9568-01
3.2.1
Super Pipeline
The super pipeline is composed of integer, multiply-accumulate (MAC), and memory
pipes.
The integer pipe has seven stages:
• Branch Target Buffer (BTB)/Fetch 1
• Fetch 2
• Decode
• Register File/Shift
• ALU Execute
• State Execute
• Integer Writeback
The memory pipe has eight stages:
• The first five stages of the Integer pipe (BTB/Fetch 1 through ALU Execute)
. . . then finishes with the following memory stages
• Data Cache 1
• Data Cache 2
• Data Cache Writeback
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The MAC pipe has six to nine stages:
• The first four stages of the Integer pipe (BTB/Fetch 1 through Register File/ Shift)
. . . then finishes with the following MAC stages
• MAC 1
• MAC 2
• MAC 3
• MAC 4
• Data Cache Writeback
The MAC pipe supports a data-dependent early terminate where stages MAC 2, MAC 3,
and/or MAC 4 are bypassed.
Deep pipes promote high instruction execution rates only when a means exists to
successfully predict the outcome of branch instructions. The branch target buffer
provides such a means.
3.2.2
Branch Target Buffer
Each entry of the 128-entry Branch Target Buffer (BTB) contains the address of a
branch instruction, the target address associated with the branch instruction, and a
previous history of the branch being taken or not taken. The history is recorded as one
of four states:
• Strongly
taken
• Weakly taken
• Weakly not
taken
• Strongly not taken
The BTB can be enabled or disabled via Coprocessor 15, Register 1.
When the address of the branch instruction hits in the BTB and its history is strongly or
weakly taken, the instruction at the branch target address is fetched. When its history
is strongly or weakly not-taken, the next sequential instruction is fetched. In either
case the history is updated.
Data associated with a branch instruction enters the BTB the first time the branch is
taken. This data enters the BTB in a slot with a history of strongly not-taken
(overwriting previous data when present).
Successfully predicted branches avoid any branch-latency penalties in the super
pipeline. Unsuccessfully predicted branches result in a four-to-five-cycle, branch-
latency penalty in the super pipeline.
3.2.3
Instruction Memory Management Unit
For instruction pre-fetches, the Instruction Memory Management Unit (IMMU) controls
logical-to-physical address translation, memory access permissions, memory-domain
identifications, and attributes (governing operation of the instruction cache).
The IMMU contains a 32-entry, fully associative instruction-translation, look-aside
buffer (ITLB) that has a round-robin replacement policy. ITLB entries zero through 30
can be locked.
When an instruction pre-fetch misses in the ITLB, the IMMU invokes an automatic
table-walk mechanism that fetches an associated descriptor from memory and loads it
into the ITLB. The descriptor contains information for logical-to-physical address
translation, memory-access permissions, memory-domain identifications, and
attributes governing operation of the I-cache. The IMMU then continues the instruction
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pre-fetch by using the address translation just entered into the ITLB. When an
instruction pre-fetch hits in the ITLB, the IMMU continues the pre-fetch using the
address translation already resident in the ITLB.
Access permissions for each of up to 16 memory domains can be programmed. When
an instruction pre-fetch is attempted to an area of memory in violation of access
permissions, the attempt is aborted and a pre-fetch abort is sent to the Intel XScale®
processor for exception processing. The IMMU and DMMU can be enabled or disabled
together.
3.2.4
Data Memory Management Unit
For data fetches, the Data Memory Management Unit (DMMU) controls logical-to-
physical address translation, memory-access permissions, memory-domain
identifications, and attributes (governing operation of the data cache or mini-data
cache and write buffer). The DMMU contains a 32-entry, fully associative data-
translation, look-aside buffer (DTLB) that has a round-robin replacement policy. DTLB
entries 0 through 30 can be locked.
When a data fetch misses in the DTLB, the DMMU invokes an automatic table-walk
mechanism that fetches an associated descriptor from memory and loads it into the
DTLB. The descriptor contains information for logical-to-physical address translation,
memory-access permissions, memory-domain identifications, and attributes (governing
operation of the D-cache or mini-data cache and write buffer).
The DMMU continues the data fetch by using the address translation just entered into
the DTLB. When a data fetch hits in the DTLB, the DMMU continues the fetch using the
address translation already resident in the DTLB.
Access permissions for each of up to 16 memory domains can be programmed. When a
data fetch is attempted to an area of memory in violation of access permissions, the
attempt is aborted and a data abort is sent to the Intel XScale® processor for exception
processing.
The IMMU and DMMU can be enabled or disabled together.
3.2.5
Instruction Cache
The Instruction Cache (I-Cache) can contain high-use, multiple-code segments or
entire programs, allowing the Intel XScale® processor access to instructions at core
frequencies. This prevents processor stalls caused by multi-cycle accesses to external
memory.
The 32-Kbyte I-cache is 32-set/32-way associative, where each set contains 32 ways
and each way contains a tag address, a cache line of instructions (eight 32-bit words
and one parity bit per word), and a line-valid bit. For each of the 32 sets, 0 through
28 ways can be locked. Unlocked ways are replaceable via a round-robin policy.
The I-cache can be enabled or disabled. Attribute bits within the descriptors —
contained in the ITLB of the IMMU — provide some control over an enabled I-cache.
When a needed line (eight 32-bit words) is not present in the I-cache, the line is
fetched (critical word first) from memory via a two-level, deep-fetch queue. The fetch
queue allows the next instruction to be accessed from the I-cache, but only when its
data operands do not depend on the execution results of the instruction being fetched
via the queue.
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3.2.6
Data Cache
The Data Cache (D-Cache) can contain high-use data such as lookup tables and filter
coefficients, allowing the Intel XScale® processor access to data at core frequencies.
This prevents processor stalls caused by multi-cycle accesses to external memory.
The 32-Kbyte D-cache is 32-set/32-way associative, where each set contains 32 ways
and each way contains a tag address, a cache line (32 bytes with one parity bit per
byte) of data, two dirty bits (one for each of two eight-byte groupings in a line), and
one valid bit. For each of the 32 sets, zero through 28 ways can be locked, unlocked,
or used as local SRAM. Unlocked ways are replaceable via a round-robin policy.
The D-cache (together with the mini-data cache) can be enabled or disabled. Attribute
bits within the descriptors, contained in the DTLB of the DMMU, provide significant
control over an enabled D-cache. These bits specify cache operating modes such as
read and write allocate, write-back, write-through, and D-cache versus mini-data cache
targeting.
The D-cache (and mini-data cache) work with the load buffer and pend buffer to
provide “hit-under-miss” capability that allows the Intel XScale® processor to access
other data in the cache after a “miss” is encountered. The D-cache (and mini-data
cache) works in conjunction with the write buffer for data that is to be stored to
memory.
3.2.7
Mini-Data Cache
The mini-data cache can contain frequently changing data streams such as MPEG
video, allowing the Intel XScale® processor access to data streams at core frequencies.
This prevents processor stalls caused by multi-cycle accesses to external memory. The
mini-data cache relieves the D-cache of data “thrashing” caused by frequently
changing data streams.
The 2-Kbyte, mini-data cache is 32-set/two-way associative, where each set contains
two ways and each way contains a tag address, a cache line (32 bytes with one parity
bit per byte) of data, two dirty bits (one for each of two eight-byte groupings in a line),
and a valid bit. The mini-data cache uses a round-robin replacement policy, and cannot
be locked.
The mini-data cache (together with the D-cache) can be enabled or disabled. Attribute
bits contained within a coprocessor register specify operating modes write and/or read
allocate, write-back, and write-through.
The mini-data cache (and D-cache) work with the load buffer and pend buffer to
provide “hit-under-miss” capability that allows the Intel XScale® processor to access
other data in the cache after a “miss” is encountered. The mini-data cache (and D-
cache) works in conjunction with the write buffer for data that is to be stored to
memory.
3.2.8
Fill Buffer and Pend Buffer
The four-entry fill buffer (FB) works with the Intel XScale® processor to hold non-
cacheable loads until the bus controller can act on them. The FB and the four-entry
pend buffer (PB) work with the D-cache and mini-data cache to provide “hit-under-
miss” capability, allowing the Intel XScale® processor to seek other data in the caches
while “miss” data is being fetched from memory.
The FB can contain up to four unique “miss” addresses (logical), allowing four “misses”
before the processor is stalled. The PB holds up to four addresses (logical) for
additional “misses” to those addresses that are already in the FB. A coprocessor
register can specify draining of the fill and pend (write) buffers.
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3.2.9
Write Buffer
The write buffer (WB) holds data for storage to memory until the bus controller can act
on it. The WB is eight entries deep, where each entry holds 16 bytes. The WB is
constantly enabled and accepts data from the processor, D-cache, or mini-data cache.
Coprocessor 15, Register 1 specifies whether WB coalescing is enabled or disabled.
When coalescing is disabled, stores to memory occur in program order — regardless of
the attribute bits within the descriptors located in the DTLB.
When coalescing is enabled, the attribute bits within the descriptors located in the
DTLB are examined to determine when coalescing is enabled for the destination region
of memory. When coalescing is enabled in both CP15, R1 and the DTLB, data entering
the WB can coalesce with any of the eight entries (16 bytes) and be stored to the
destination memory region, but possibly out of program order.
Stores to a memory region specified to be non-cacheable and non-bufferable by the
attribute bits within the descriptors located in the DTLB causes the processor to stall
until the store completes. A coprocessor register can specify draining of the write
buffer.
3.2.10
Multiply-Accumulate Coprocessor
For efficient processing of high-quality, media-and-signal-processing algorithms, the
Multiply-Accumulate Coprocessor (CP0) provides 40-bit accumulation of 16 x 16, dual-
16 x 16 (SIMD), and 32 x 32 signed multiplies. Special MAR and MRA instructions are
implemented to move the 40-bit accumulator to two Intel XScale® processor general
registers (MAR) and move two Intel XScale® processor general registers to the 40-bit
accumulator (MRA). The 40-bit accumulator can be stored or loaded to or from D-
cache, mini-data cache, or memory using two STC or LDC instructions.
The 16 x 16 signed multiply-accumulates (MIAxy) multiply either the high/high, low/
low, high/low, or low/high 16 bits of a 32-bit Intel XScale® processor general register
(multiplier) and another 32-bit Intel XScale® processor general register (multiplicand)
to produce a full, 32-bit product that is sign-extended to 40 bits and added to the 40-
bit accumulator.
Dual-signed, 16 x 16 (SIMD) multiply-accumulates (MIAPH) multiply the high/high and
low/low 16-bits of a packed 32-bit, Intel XScale® processor general register (multiplier)
and another packed 32-bit, Intel XScale® processor general register (multiplicand) to
produce two 16-bits products that are both sign-extended to 40 bits and added to the
40-bit accumulator.
The 32 x 32 signed multiply-accumulates (MIA) multiply a 32-bit, Intel XScale®
processor general register (multiplier) and another 32-bit, Intel XScale® processor
general register (multiplicand) to produce a 64-bit product where the 40 LSBs are
added to the 40-bit accumulator. The 16 x 32 versions of the 32 x 32 multiply-
accumulate instructions complete in a single cycle.
3.2.11
Performance Monitoring Unit
The performance monitoring unit (PMU) contains four 32-bit, event counters and one
32-bit, clock counter. The event counters can be programmed to monitor I-cache hit
rate, data caches hit rate, ITLB hit rate, DTLB hit rate, pipeline stalls, BTB prediction hit
rate, and instruction execution count.
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3.2.12
Debug Unit
The debug unit is accessed through the JTAG port. The industry-standard, IEEE 1149.1
JTAG port consists of a test access port (TAP) controller, boundary-scan register,
instruction and data registers, and dedicated signals TDI, TDO, TCK, TMS, and TRST#.
The debug unit — when used with debugger application code running on a host system
outside of the Intel XScale® processor — allows a program, running on the Intel
XScale® processor, to be debugged. It allows the debugger application code or a debug
exception to stop program execution and redirect execution to a debug-handling
routine.
Debug exceptions are instruction breakpoint, data breakpoint, software breakpoint,
external debug breakpoint, exception vector trap, and trace buffer full breakpoint. Once
execution has stopped, the debugger application code can examine or modify the Intel
XScale® processor’s state, coprocessor state, or memory. The debugger application
code can then restart program execution.
The debug unit has two hardware-instruction, break point registers; two hardware,
data-breakpoint registers; and a hardware, data-breakpoint control register. The
second data-breakpoint register can be alternatively used as a mask register for the
first data-breakpoint register.
A 256-entry trace buffer provides the ability to capture control flow messages or
addresses. A JTAG instruction (LDIC) can be used to download a debug handler via the
JTAG port to the mini-instruction cache (the I-cache has a 2-Kbyte, mini-instruction
cache, like the mini-data cache, that is used only to hold a debug handler).
4.0
Package Information
This section contains information on the following topics:
• “Package Description” which includes “Package Drawings”, “Package Markings”,
and “Part Numbers”
• “Functional Signal Definitions” on page 43
• “Signal-Pin Descriptions” on page 77
• “Package Thermal Specifications” on page 102
4.1
Package Description
The IXP45X/IXP46X network processors are built using a 544-ball, plastic ball grid
array (PBGA) package with a drop-in heat spreader (H).
For all extended temperature products and the 667-MHz speed option of the
commercial temperature product, a 10-mm-high, thermal-adhesive-based heat sink
will be required. The heat sink does not force the addition of any surface area to the
board design.
4.1.1
Package Drawings
The package is shown in Figure 5 and Figure 6.
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Figure 5.
544-Pin Lead PBGA Package — First of Two Drawings
1.27
0.61
1.17
0.75
B3846-01
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Figure 6.
544-Pin Lead PBGA Package — Second of Two Drawings
B3847-01
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
4.1.2
Package Markings
Figure 7.
Package Markings:
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—
Extended and Commercial Temperature, Lead-Free / Compliant with Standard
for Restriction on the Use of Hazardous Substances (RoHS)
Drop-In Heat Spreader
(24-mm Diameter)
1
Part Number
EWIXP465AET
FPO#
Finish Site Traceability Code
Lead-Free Designator (e1)
e1
C
M
'04
i
Intel Copyright
Assembly Site Traceability Code
ATPO#
Assembly Year (Y) and
Work Week (WW) and
Country of Origin
YWW KOREA
Pin # 1
B4916-001
Notes:
1.
Part Number field — For the different part numbers of Intel® IXP45X and Intel® IXP46X Product Line of Network
Processors, see Section 4.1.3.
2.
3.
Package ball counts — Intel® IXP45X and Intel® IXP46X Product Line of Network Processors have a ball count of 544.
Drawing is not to scale. Marking content is an example.
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Figure 8.
Package Markings:
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors —
Commercial and Extended Temperature, Lead-Based
Drop-In Heat Spreader
(24-mm Diameter)
1
Part Number
GWIXP465AET
FPO#
Finish Site Traceability Code
Intel Copyright
C
INTEL M
'04
i
Assembly Site Traceability Code
ATPO#
Assembly Year (Y) and
Work Week (WW) and
Country of Origin
YWW KOREA
Pin # 1
B4923-001
Notes:
1.
Part Number field — For the different part numbers of Intel® IXP45X and Intel® IXP46X Product Line of Network
Processors, see Section 4.1.3.
2.
3.
Package ball counts — Intel® IXP45X and Intel® IXP46X Product Line of Network Processors have a ball count of 544.
Drawing is not to scale. Marking content is an example.
4.1.3
Part Numbers
The tables in this section list the part numbers for the IXP46X product line of network
processors (Table 6) and the IXP45X product line of network processors (Table 7).
Table 6.
Part Numbers for the Intel® IXP46X Product Line of Network Processors
(Sheet 1 of 2)
Speed
(MHz)
Temperature
Offering
Lead
Free
Device
Stepping
Part #
Intel® IXP465
Intel® IXP465
Intel® IXP465
Intel® IXP465
Intel® IXP465
Intel® IXP465
Intel® IXP465
Intel® IXP460
A2
A2
A2
A2
A2
A2
A2
A2
667
533
533
667
533
266
533
533
Commercial
Commercial
Extended
Yes
Yes
Yes
EWIXP465BAE
EWIXP465BAD
EWIXP465BADT
GWIXP465BAE
GWIXP465BAD
GWIXP465BAB
GWIXP465BADT
EWIXP460BAD
Commercial
Commercial
Commercial
Extended
Commercial
Yes
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 6.
Part Numbers for the Intel® IXP46X Product Line of Network Processors
(Sheet 2 of 2)
Speed
(MHz)
Temperature
Offering
Lead
Free
Device
Stepping
Part #
Intel® IXP460
Intel® IXP460
Intel® IXP460
A2
A2
A2
533
266
533
Commercial
Commercial
Extended
GWIXP460BAD
GWIXP460BAB
GWIXP460BADT
Table 7.
Part Numbers for the Intel® IXP45X Product Line of Network Processors
Speed
(MHz)
Lead
Free
Temperature
Offering
Device
Stepping
Part #
Intel® IXP455
Intel® IXP455
Intel® IXP455
Intel® IXP455
Intel® IXP455
Intel® IXP455
A2
A2
A2
A2
A2
A2
533
400
266
533
400
266
Yes
Yes
Yes
Commercial
Commercial
Commercial
Commercial
Commercial
Commercial
EWIXP455BAD
EWIXP455BAC
EWIXP455BAB
GWIXP455BAD
GWIXP455BAC
GWIXP455BAB
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4.2
Functional Signal Definitions
The signal definition tables list pull-up and pull-down resistor recommendations when
the particular enabled interface is not being used in the application. These external
resistor requirements are only needed if the particular model of IXP45X/IXP46X
network processors has the particular interface enabled and the interface is not
required in the application.
Warning:
None of the IXP45X/IXP46X network processors’ I/O pins are 5-V tolerant.
Disabled features within the IXP45X/IXP46X network processors do not require
external resistors, as the processor will have internal pull-up or pull-down resistors
enabled as part of the disabled interface. To determine which interfaces are not enabled
within the IXP45X/IXP46X network processors, see Table 1 on page 13.
Table 8 presents the legend for interpreting the Type field in the other tables in this
section of the document.
Table 8.
Signal Type Definitions
Symbol
Description
I
O
Input pin only
Output pin only
I/O
OD
PWR
GND
1
Pin can be either an input or output
Open Drain pin
Power pin
Ground pin
Driven to Vcc
0
Driven to Vss
X
Driven to unknown state
Input is disabled
ID
H
Pulled up to Vcc
L
Pulled to Vss
PD
Z
Pull-up Disabled
Output Disabled
VO
VB
A valid output level is driven, allowed states - 1, 0, H
Valid level on the signal, allowed states - 1, 0, H, Z
Need to drive a valid input level, allowed states - 1, 0, H,
Z
VI
VOD
PE
Valid Open Drain output, allowed states are 0 or Z
Pull-up Enabled, equivalent to H
Output Only/Tristatable
TRI
ePU
N/C
-
External 10K ohm Pull-Up is required on the board
No Connect
Pin must be connected as described
4.2.1
Pin Description Tables
This section identifies all the signal pins by symbol name, type and description. Names
should follow the following convention, all capital letters with a trailing “_N” indicate a
signal is asserted when driven to a logic low (digital 0). The description includes the full
name of the pin along with a functional description. This section does not specify the
number of power and ground pins required, but does include the number of different
types of power pins required.
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A signal called active high specifies that the interface is active when driven to a logic 1
and inactive when driven to a logic 0.
A signal called active low specifies that the interface is active when driven to a logic 0
and inactive when driven to a logic 1.
The following information attempts to explain how to interpret the tables. There are
five vertical columns:
• Power On Reset Active - This is when the Power on Reset signal is driven to logic 0.
When this happens the part will behave as described in this column irrelevant of the
settings on other signals.
• Reset Active - When Power on Reset is driven to a logic 1 and Reset is driven to a
logic 0, the part will exhibit this behavior.
• Normal After Reset Until Software Enables - This is sometimes called safe mode.
The intent of this is to allow the interface to be brought out of reset to a state,
which will not cause any protocol violations or any damage to the parts prior to
being enabled via software. This state will occur when both Power on Reset and
Reset are driven to a logic 1.
• Possible Configurations after Software Enables - This state describes the way that
the part is capable of behaving with appropriate software written. This state will
occur when both Power on Reset and Reset are driven to a logic 1.
Table 9.
Processors’ Signal Interface Summary Table
Reference
Table 10, “DDR SDRAM Interface” on page 45
Table 11, “PCI Controller” on page 46
Table 12, “High-Speed, Serial Interface 0” on page 50
Table 13, “High-Speed, Serial Interface 1” on page 51
Table 14, “UTOPIA Level 2/MII_A/ SMII Interface” on page 53
Table 15, “MII/SMII Interfaces” on page 59
Table 16, “Expansion Bus Interface” on page 66
Table 17, “UART Interfaces” on page 69
Table 18, “Serial Peripheral Port Interface” on page 70
Table 19, “I2C Interface” on page 70
Table 20, “USB Host/Device Interfaces” on page 71
Table 21, “Oscillator Interface” on page 72
Table 22, “GPIO Interface” on page 73
Table 23, “JTAG Interface” on page 73
Table 24, “System Interface” on page 74
Table 25, “Power Interface” on page 75
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Package Information
Table 10. DDR SDRAM Interface (Sheet 1 of 2)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
DDR SDRAM Clock Out — Provide the positive differential clocks to the external SDRAM
memory subsystem.
DDRI_CK[2:0]
Z
Z
0
1
VO
VO
O
O
DDR SDRAM Clock Out — Provide the negative differential clocks to the external SDRAM
memory subsystem.
DDRI_CK_N[2:0]
VO
VO
DDRI_CS_N[1:0]
DDRI_RAS_N
Z
Z
Z
Z
VO
VO
VO
VO
O
O
Chip Select — Must be asserted for all transactions to the DDR SDRAM device. One per bank.
Row Address Strobe — Indicates that the current address on DDRI_MA[13:0] is the row.
Column Address Strobe — Indicates that the current address on DDRI_MA[13:0] is the
column.
DDRI_CAS_N
DDRI_WE_N
Z
Z
Z
Z
VO
VO
VO
VO
O
O
Write Strobe — Defines whether or not the current operation by the DDR SDRAM is to be a
read or a write.
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.
DDRI_DM[4:0]
DDRI_BA[1:0]
Z
Z
Z
Z
VO
VO
VO
VO
O
O
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.
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]
Z
Z
Z
VO
VB
VO
VB
O
VB
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].
DDRI_CB[7:0]
Z
Z
VB
VB
VB
VB
VB
VB
I/O
I/O
When ECC is disabled and not being used in a system design, these signals are not required for
any connection.
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.
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.
DDRI_CKE[1:0]
Z
b’00
VO
VO
O
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
45
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 10. DDR SDRAM Interface (Sheet 2 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
RECEIVE ENABLE OUT must be connected to DDRI_RCVENIN_N signal of the IXP45X/IXP46X
network processors and the propagation delay of the trace length must be matched to the
clock trace plus the average DQ Traces.
DDRI_RCVENOUT_N
DDRI_RCVENIN_N
DDRI_RCOMP
Z
Z
1
VO
VO
O
I
RECEIVE ENABLE IN provides delay information for enabling the input receivers and must be
connected to the DDRI_RCVENOUT_N signal of the IXP45X/IXP46X network processors.
VI
VI
VI
Tied off
to a
resistor
Tied off
to a
resistor
Tied off to Tied off to
a resistor
20 Ohm 1% tolerance Resistor connected to ground used for process/temperature
adjustments.
O
a resistor
DDR SDRAM Voltage Reference — is used to supply the reference voltage to the differential
inputs of the memory controller pins.
DDRI_VREF
VCCM/2 VCCM/2
VCCM/2
VCCM/2
I
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
Table 11.
PCI Controller (Sheet 1 of 4)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
After
Power
on
Name
Reset†
Type†
Description
Reset†
Enables
PCI Address/Data bus used to transfer address and bidirectional data to and from multiple PCI
devices.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_AD[31:0]
Z
Z
Z
VB
VB
I/O
PCI Command/Byte Enables is used as a command word during PCI address cycles and as byte
enables for data cycles.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_CBE_N[3:0]
Z
VB
VB
I/O
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
46
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 11.
PCI Controller (Sheet 2 of 4)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
PCI Parity used to check parity across the 32 bits of PCI_AD and the four bits of PCI_CBE_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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_PAR
Z
Z
Z
VB
VB
I/O
PCI Cycle Frame used to signify the beginning and duration of a transaction. The signal will be
inactive prior to or during the final data phase of a given transaction.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_FRAME_N
Z
VB
VB
I/O
PCI Target Ready informs that the target of the PCI bus is ready to complete the current data phase
of a given transaction.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_TRDY_N
PCI_IRDY_N
PCI_STOP_N
Z
Z
Z
Z
Z
Z
VB
VB
VB
VB
VB
VB
I/O
I/O
I/O
PCI Initiator Ready informs the PCI bus that the initiator is ready to complete the transaction.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI Stop indicates that the current target is requesting the current initiator to stop the current
transaction.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
47
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 11.
PCI Controller (Sheet 3 of 4)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
PCI Parity Error asserted when a PCI parity error is detected — between the PCI_PAR and
associated information on the PCI_AD bus and PCI_CBE_N — during all PCI transactions, except for
Special Cycles. The agent receiving data will drive this signal.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_PERR_N
PCI_SERR_N
Z
Z
Z
VB
VB
I/O
PCI System Error asserted when a parity error occurs on special cycles or any other error that will
cause the PCI bus not to function properly. This signal can function as an input or an open drain
output.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
Z
VB
VB
I/OD
PCI Device Select:
•
When used as an output, PCI_DEVSEL_N indicates that device has decoded that address as the
target of the requested transaction.
•
When used as an input, PCI_DEVSEL_N indicates if any device on the PCI bus exists with the
given address.
PCI_DEVSEL_N
Z
Z
VB
VB
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI Initialization Device Select is a chip select during configuration reads and writes.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_IDSEL
Z
Z
Z
Z
VI
VI
VI
VI
I
I
PCI arbitration request: Used by the internal PCI arbiter to allow an agent to request the PCI bus.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_REQ_N[3:1]
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
48
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 11.
PCI Controller (Sheet 4 of 4)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
PCI arbitration request:
•
When configured as an input (PCI arbiter enabled), the internal PCI arbiter will allow an agent
to request the PCI bus.
•
When configured as an output (PCI arbiter disabled), the pin will be used to request access to
the PCI bus from an external arbiter.
PCI_REQ_N[0]
PCI_GNT_N[3:1]
PCI_GNT_N[0]
Z
Z
Z
Z
Z
Z
VI
VI / VO
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI arbitration grant: Generated by the internal PCI arbiter to allow an agent to claim control of the
PCI bus.
VO
VO
VO
O
PCI arbitration grant:
•
When configured as an output (PCI arbiter enabled), the internal PCI arbiter to allow an agent
to claim control of the PCI bus.
•
When configured as an input (PCI arbiter disabled), the pin will be used to claim access of the
PCI bus from an external arbiter.
VI / VO
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI interrupt: Used to request an interrupt.
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. When this interface is disabled via the PCI soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
PCI_INTA_N
PCI_CLKIN
Z
Z
Z
Z
VOD
VI
O/D
PCI Clock: Clock provides timing for all transactions on PCI. All PCI signals — except INTA#, INTB#,
INTC#, and INTD# — are sampled on the rising edge of CLK and timing parameters are defined
with respect to this edge. The PCI clock rate can operate at up to 66 MHz.
VI
VI
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
49
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 12. High-Speed, Serial Interface 0 (Sheet 1 of 2)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
The High-Speed Serial (HSS) transmit frame signal can be configured as an input or an output to
allow an external source become synchronized with the transmitted data. Often known as a Frame
Sync signal. Configured as an input upon reset.
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. When this interface is disabled via the HSS soft
fuse (refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
HSS_TXFRAME0
Z
Z
VB
VB
I/O
Transmit data out. Open Drain output.
When this interface/signal is enabled and either used or unused in a system design, it should be
pulled high with a 10-KΩ resistor to V . When this interface is disabled via the HSS soft fuse
CCP
HSS_TXDATA0
HSS_TXCLK0
Z
Z
Z
Z
VOD
VB
VOD
VB
OD
I/O
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
The High-Speed Serial (HSS) transmit clock signal can be configured as an input or an output. The
clock can be a frequency ranging from 512 KHz to 8.192 MHz. Used to clock out the transmitted
data. Configured as an input upon reset. Frame sync and data can be selected to be generated on
the rising or falling edge of the 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.
The High-Speed Serial (HSS) receive frame signal can be configured as an input or an output to
allow an external source to become synchronized with the received data. Often known as a Frame
Sync signal. Configured as an input upon reset.
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. When this interface is disabled via the HSS soft
fuse (refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
HSS_RXFRAME0
Z
Z
VB
VB
I/O
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
50
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 12. High-Speed, Serial Interface 0 (Sheet 2 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Receive data input. Can be sampled on the rising or falling edge of the receive 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. When this interface is disabled via the HSS soft
fuse (refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
HSS_RXDATA0
HSS_RXCLK0
Z
Z
VI
Z
VI
VI
I
The High-Speed Serial (HSS) receive clock signal can be configured as an input or an output. The
clock can be from 512 KHz to 8.192 MHz. Used to sample the received data. Configured as an
input upon reset.
VB
VB
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
Table 13.
High-Speed, Serial Interface 1 (Sheet 1 of 2)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
The High-Speed Serial (HSS) transmit frame signal can be configured as an input or an output to
allow an external source to be synchronized with the transmitted data. Often known as a Frame
Sync signal. Configured as an input upon reset.
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. When this interface is disabled via the HSS soft
fuse (refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
HSS_TXFRAME1
HSS_TXDATA1
Z
Z
Z
Z
VB
VB
I/O
Transmit data out. Open Drain output.
When this interface/signal is enabled and either used or unused in a system design, it should be
pulled high with a 10-KΩ resistor to V . When this interface is disabled via the HSS soft fuse
CCP
VOD
VOD
OD
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/
signal is not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
51
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 13. High-Speed, Serial Interface 1 (Sheet 2 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
The High-Speed Serial (HSS) transmit clock signal can be configured as an input or an output. The
clock can be a frequency ranging from 512 KHz to 8.192 MHz. Used to clock out the transmitted
data. Configured as an input upon reset. Frame sync and Data can be selected to be generated on
the rising or falling edge of the 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.
HSS_TXCLK1
Z
Z
Z
VB
VB
I/O
The High-Speed Serial (HSS) receive frame signal can be configured as an input or an output to
allow an external source to be synchronized with the received data. Often known as a Frame Sync
signal. Configured as an input upon reset.
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. When this interface is disabled via the HSS soft
fuse (refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
HSS_RXFRAME1
Z
VB
VB
I/O
Receive data input. Can be sampled on the rising or falling edge of the receive 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. When this interface is disabled via the HSS soft
fuse (refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product
Line of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
HSS_RXDATA1
HSS_RXCLK1
Z
Z
VI
Z
VI
VI
I
The High-Speed Serial (HSS) receive clock signal can be configured as an input or an output. The
clock can be from 512 KHz to 8.192 MHz. Used to sample the received data. Configured as an
input upon reset.
VB
VB
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
52
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 1 of 7)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
UTOPIA Mode of Operation:
UTOPIA Transmit clock input. Also known as UTP_TX_CLK. This signal is used to synchronize all
UTOPIA transmit outputs to the rising edge of the UTP_OP_CLK.
MII Mode of Operation:
Externally supplied transmit clock.
UTP_OP_CLK /
ETHA_TXCLK
Z
VI
VI
VI
I
•
•
25 MHz for 100 Mbps operation
2.5 MHz for 10 Mbps operation
SMII Mode of Operation:
Not Used.
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.
Used to inform the selected PHY that data is being transmitted to the PHY. Placing the PHY’s
address on the UTP_OP_ADDR — and bringing UTP_OP_FCO to logic 1, during the current clock —
followed by the UTP_OP_FCO going to a logic 0, on the next clock cycle, selects which PHY is
active in MPHY mode.
In SPHY configurations, UTP_OP_FCO is used to inform the PHY that the processor is ready to
send data.
UTP_OP_FCO
UTP_OP_SOC
Z
Z
Z
Z
Z
Z
VO
VO
TRI
TRI
This signal must be tied to Vcc with an external 10-KΩ resistor.
Start of Cell. Also known as TX_SOC.
Active high signal is asserted when UTP_OP_DATA contains the first valid byte of a transmitted
cell.
This signal must be tied to Vss with an external 10-KΩ resistor.
UTOPIA Mode of Operation:
UTOPIA output data. Also known as UTP_TX_DATA. Used to send data from the processor to an
ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
UTP_OP_DATA[3:0] /
ETHA_TXDATA[3:0]
Z
Z
Z
VO
TRI
Transmit data bus to PHY, asserted synchronously with respect to ETHA_TXCLK. This MAC
interface does not contain hardware hashing capabilities local to the interface. In this mode of
operation the pins represented by this interface are ETHA_TXDATA3:0].
SMII mode of operation:
Not used.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
August 2006
53
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 2 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
UTOPIA Mode of Operation:
UTOPIA output data. Also known as UTP_TX_DATA. Used to send data from the processor to an
ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
UTP_OP_DATA[4] /
ETHA_TXEN
Indicates that the PHY is being presented with nibbles on the MII interface. Asserted
synchronously, with respect to ETHA_TXCLK, at the first nibble of the preamble, and remains
asserted until all the nibbles of a frame are presented. This MAC does not contains hardware
hashing capabilities local to the interface.
SMII mode of operation:
Not used.
Z
Z
Z
Z
Z
Z
Z
VO
TRI
TRI
TRI
UTOPIA Mode of Operation:
UTP_OP_DATA[6:5]
Z
Z
VO
VO
UTOPIA output data. Also known as UTP_TX_DATA. Used to send data from the processor to an
ATM UTOPIA Level 2-compliant PHY.
UTOPIA Mode of Operation:
UTOPIA output data. Also known as UTP_TX_DATA. Used to send data from the processor to an
ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
Not used.
SMII mode of operation:
UTP_OP_DATA[7] /
SMII_TXDATA[4]
Output data for SMII interface number four. The data on this signal is transmitted synchronously
with respect to the rising edge of SMII_CLK when operating as an SMII interface and
synchronously with respect to the rising edge of SMII_TXCLK when operating as a Source
Synchronous SMII interface
Transmit PHY address bus. Used by the processor when operating in MPHY mode to poll and select
a single PHY at any given time.
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
UTP_OP_ADDR[4:0]
Z
Z
Z
VO
I/O
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
August 2006
54
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 3 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
UTOPIA Output data flow control input: Also known as the TXFULL/CLAV signal.
Used to inform the processor of the ability of each polled PHY to receive a complete cell. For cell-
level flow control in an MPHY environment, TxClav is an active high tri-stateable signal from the
MPHY to ATM layer. The UTP_OP_FCI, which is connected to multiple MPHY devices, will see logic
high generated by the PHY, one clock after the given PHY address is asserted — when a full cell
can be received by the PHY. The UTP_OP_FCI will see a logic low generated by the PHY one clock
cycle, after the PHY address is asserted — if a full cell cannot be received by the PHY.
UTP_OP_FCI
Z
VI
VI
VI
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
UTOPIA Mode of Operation:
UTOPIA Receive clock input. Also known as UTP_RX_CLK.
This signal is used to synchronize all UTOPIA-received inputs to the rising edge of the
UTP_IP_CLK.
MII Mode of Operation:
Externally supplied receive clock.
UTP_IP_CLK /
ETHA_RXCLK
Z
VI
VI
VI
I
•
•
25 MHz for 100 Mbps operation
2.5 MHz for 10 Mbps operation
This MAC interface does not contain hardware hashing capabilities local to the interface.
SMII Mode of Operation:
Not used.
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
August 2006
55
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 4 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
UTOPIA Input Data flow control input signal. Also known as RXEMPTY/CLAV.
Used to inform the processor of the ability of each polled PHY to send a complete cell. For cell-
level flow control in an MPHY environment, RxClav is an active high tri-stateable signal from the
MPHY to ATM layer. The UTP_IP_FCI, which is connected to multiple MPHY devices, will see logic
high generated by the PHY, one clock after the given PHY address is asserted, when a full cell can
be received by the PHY. The UTP_IP_FCI will see a logic low generated by the PHY, one clock cycle
after the PHY address is asserted if a full cell cannot be received by the PHY.
UTP_IP_FCI
Z
VI
VI
VI
I
In SPHY mode, this signal is used to indicate to the processor that the PHY has an octet or cell
available to be transferred to the processor.
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
Start of Cell. RX_SOC
Active-high signal that is asserted when UTP_IP_DATA contains the first valid byte of a
transmitted cell.
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
UTP_IP_SOC
Z
VI
VI
VI
I
UTOPIA Mode of Operation:
UTOPIA input data. Also known as RX_DATA.
Used by to the processor to receive data from an ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
Receive data bus from the PHY, asserted synchronously with respect to ETHA_RXCLK.
SMII mode of operation:
Not used.
UTP_IP_DATA[3:0] /
ETHA_RXDATA[3:0]
Z
VI
VI
VI
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
August 2006
56
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 5 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
UTOPIA Mode of Operation:
UTOPIA input data. Also known as RX_DATA.
Used by to the processor to receive data from an ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
Receive data valid, used to inform the MII interface that the Ethernet PHY is sending data.
This MAC does not contains hardware hashing capabilities local to the interface.
SMII mode of operation:
UTP_IP_DATA[4] /
ETHA_RXDV
Z
VI
VI
VI
I
Not used.
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
UTOPIA Mode of Operation:
UTOPIA input data. Also known as RX_DATA.
Used by the processor to receive data from an ATM UTOPIA Level 2-compliant PHY.
•
When NPE A is configured in UTOPIA mode of operation and the signal is not being used, it
should be pulled high through a 10-KΩ resistor.
MII Mode of Operation:
Asserted by the PHY when a collision is detected by the PHY.
•
When NPE A is configured in MII mode of operation and the signal is not being used, it should
UTP_IP_DATA[5] /
ETHA_COL
Z
VI
VI
VI
I
be pulled low through a 10-KΩ resistor.
SMII Mode of Operation:
Not used.
•
When NPE A is configured in SMII mode of operation, this signal must be pulled high through
a 10-KΩ resistor.
When this interface is disabled via the UTOPIA and/ or the NPE-A Ethernet soft fuse (refer to the
Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of Network
Processors Developer’s Manual) and is not being used in a system design, this interface/signal is
not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
August 2006
57
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 6 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
UTOPIA Mode of Operation:
UTOPIA input data. Also known as RX_DATA.
Used by to the processor to receive data from an ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
Asserted by the PHY when the transmit medium or receive medium are active. De-asserted when
both the transmit and receive medium are idle. Remains asserted throughout the duration of
collision condition. PHY asserts CRS asynchronously and de-asserts synchronously with respect to
ETHA_RXCLK.
SMII mode of operation:
Not used.
UTP_IP_DATA[6] /
ETHA_CRS
Z
VI
VI
VI
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
UTOPIA Mode of Operation:
UTOPIA input data. Also known as RX_DATA.
Used by to the processor to receive data from an ATM UTOPIA Level 2-compliant PHY.
MII Mode of Operation:
Not Used.
SMII mode of operation:
UTP_IP_DATA[7] /
SMII_RXDATA[4]
Input data for SMII interface number four. The data on this signal is received synchronously with
respect to the rising edge of SMII_CLK when operating as an SMII interface and synchronously
with respect to the rising edge of SMII_RXCLK when operating as a Source Synchronous SMII
interface.
Z
VI
VI
VI
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. When this interface is disabled via the UTOPIA
and/or the NPE-A Ethernet soft fuse (refer to Expansion Bus Controller chapter of the Intel®
IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual) and is not
being used in a system design, this interface/signal is not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
August 2006
58
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 14. UTOPIA Level 2/MII_A/ SMII Interface (Sheet 7 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Receive PHY address bus.
UTP_IP_ADDR[4:0]
UTP_IP_FCO
Z
Z
Z
Z
VO
I/O
Used by the processor when operating in MPHY mode to poll and select a single PHY at any one
given time.
UTOPIA Input Data Flow Control Output signal: Also known as the RX_ENB_N.
In SPHY configurations, UTP_IP_FCO is used to inform the PHY that the processor is ready to
accept data.
In MPHY configurations, UTP_IP_FCO is used to select which PHY will drive the UTP_RX_DATA and
UTP_RX_SOC signals. The PHY is selected by placing the PHY’s address on the UTP_IP_ADDR and
bringing UTP_OP_FCO to logic 1 during the current clock, followed by the UTP_OP_FCO going to a
logic 0 on the next clock cycle.
Z
Z
VO
TRI
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
For information on selecting the desired interface, see the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual.
Table 15.
MII/SMII Interfaces (Sheet 1 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
MII Mode of Operation:
Externally supplied transmit clock.
•
•
25 MHz for 100 Mbps operation
2.5 MHz for 10 Mbps operation
ETHB_TXCLK /
SMII_CLK
This MAC interface does not contain hardware hashing capabilities local to the interface.
SMII Mode of Operation:
Z
VI
VI
VI
I
125-MHz input clock used as the reference clock when operating in SMII or Source Synchronous
SMII mode of operation.
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
59
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 15. MII/SMII Interfaces (Sheet 2 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
MII Mode of Operation:
Transmit data bus to PHY, asserted synchronously with respect to ETHB_TXCLK. This MAC
interface does not contain hardware hashing capabilities local to the interface.
SMII Mode of Operation:
ETHB_TXDATA[3:0] /
SMII_TXDATA[0] /
SMII_TXDATA[1] /
SMII_TXDATA[2] /
SMII_TXDATA[3]
Each SMII_TXDATA line is an interface to a separate physical port.
ETHB_TXDATA[3] is multiplexed with SMII_TXDATA[3],
ETHB_TXDATA[2] is multiplexed with SMII_TXDATA[2],
ETHB_TXDATA[1] is multiplexed with SMII_TXDATA[1],
ETHB_TXDATA[0] is multiplexed with SMII_TXDATA[0]
Z
0
VO
VO
O
The data on these signal are transmitted synchronously with respect to the rising edge of
SMII_CLK when operating as an SMII interface and synchronously with respect to the rising edge
of SMII_TXCLK when operating as a Source Synchronous SMII interface
MII Mode of Operation:
Indicates that the PHY is being presented with nibbles on the MII interface. Asserted
synchronously, with respect to ETHB_TXCLK, at the first nibble of the preamble and remains
asserted until all the nibbles of a frame are presented. This MAC interface does not contain
hardware hashing capabilities local to the interface.
ETHB_TXEN /
SMII_TXCLK
Z
0
VO
VO
O
SMII Mode of Operation:
125-MHz clock that is used to send data to a physical interface when operating in a Source
Synchronous SMII mode of operation.
MII Mode of Operation:
Externally supplied receive clock.
•
•
25 MHz for 100 Mbps operation
2.5 MHz for 10 Mbps operation
ETHB_RXCLK /
SMII_RXCLK
This MAC interface does not contain hardware hashing capabilities local to the interface.
SMII Mode of Operation:
Z
VI
VO
VO
I
125-MHz clock that is used to sample data being received from a physical interface when
operating in a Source Synchronous SMII mode of operation.
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.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
60
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 15. MII/SMII Interfaces (Sheet 3 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
MII Mode of Operation:
Receive data bus from PHY, data sampled synchronously with respect to ETHB_RXCLK. This MAC
interface does not contain hardware hashing capabilities local to the interface.
SMII Mode of Operation:
Each SMII_RXDATA line is a separate physical port
ETHB_RXDATA[3] is multiplexed with SMII_RXDATA[3],
ETHB_RXDATA[2] is multiplexed with SMII_RXDATA[2],
ETHB_RXDATA[1] is multiplexed with SMII_RXDATA[1],
ETHB_RXDATA[0] is multiplexed with SMII_RXDATA[0]
The data on these signal are received synchronously with respect to the rising edge of SMII_CLK
when operating as an SMII interface and synchronously with respect to the rising edge of
SMII_RXCLK when operating as a Source Synchronous SMII interface
ETHB_RXDATA[3:0] /
SMII_RXDATA[0] /
SMII_RXDATA[1] /
SMII_RXDATA[2] /
SMII_RXDATA[3]
Z
VI
VI
VI
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. When this interface is disabled via the NPE-B
Ethernet 0 and/or the NPE Ethernet 1-3 soft fuse (refer to Expansion Bus Controller chapter of
the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual)
and is not being used in a system design, this interface/signal is not required for any connection.
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.
MII Mode of Operation:
Receive data valid, used to inform the MII interface that the Ethernet PHY is sending data. This
MAC interface does not contain hardware hashing capabilities local to the interface.
SMII Mode of Operation:
In Source Synchronous mode of operation, this signal is an input from a synchronous pulse
created once every 10 SMII_RXCLK reference clocks to signal the start of the next 10 bits of data
to be received. SMII_RXCLK Reference clock operates at 125MHz.
ETHB_RXDV /
SMII_RXSYNC
Z
VI
VI
VI
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. When this interface is disabled via the NPE-B
Ethernet 0 and/or the NPE Ethernet 1-3 soft fuse (refer to Expansion Bus Controller chapter of
the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual)
and is not being used in a system design, this interface/signal is not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
61
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 15. MII/SMII Interfaces (Sheet 4 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
MII Mode of Operation:
Asserted by the PHY when a collision is detected by the PHY. This MAC interface does not contain
hardware hashing capabilities local to the interface.
•
When NPE B is configured in MII mode of operation and the signal is not being used, it
should be pulled low through a 10-KΩ resistor.
SMII Mode of Operation:
Not used.
ETHB_COL
Z
VI
VI
VI
I
•
When NPE B is configured in SMII mode of operation, this signal must be pulled high with a
10-KΩ resistor.
When this interface is disabled via the NPE-B Ethernet 0 and/or the NPE Ethernet 1-3 soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line
of Network Processors Developer’s Manual) and is not being used in a system design, this
interface/signal is not required for any connection.
MII Mode of Operation:
Asserted by the PHY when the transmit medium or receive medium is active. De-asserted when
both the transmit and receive medium are idle. Remains asserted throughout the duration of a
collision condition. PHY asserts CRS asynchronously and de-asserts synchronously, with respect
to ETHB_RXCLK. This MAC interface does not contain hardware hashing capabilities local to the
interface.
SMII Mode of Operation:
In SMII Mode of Operation, this signal is an output that creates a synchronous pulse once every
10 SMII_CLK reference clocks to signal the start of the next 10 bits of data to be transmitted/
received. SMII_CLK Reference clock operates at 125MHz.
In Source Synchronous mode of operation, a synchronous pulse output created once every 10
SMII_TXCLK clocks to signal the start of the next 10 bits of data to be transmitted. SMII_TXCLK
operates at 125MHz.
ETHB_CRS/
SMII_SYNC/
SMII_TXSYNC
Z
Z
Z
VI / VO
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. When this interface is disabled via the NPE-B
Ethernet 0 and/or the NPE Ethernet 1-3 soft fuse (refer to Expansion Bus Controller chapter of
the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual)
and is not being used in a system design, this interface/signal is not required for any connection.
In MII mode of operation, this signal is a valid input. In SMII mode of operation this signal is a
valid output.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
62
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 15. MII/SMII Interfaces (Sheet 5 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Management data output. Provides the write data to both PHY devices connected to each MII
interface. An external pull-up resistor of 1.5K ohm 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
ETH_MDC
Z
Z
Z
Z
Z
VB
I/O
I/O
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Management data clock. Management data interface clock is used to clock the MDIO signal as an
output and sample the MDIO as an input. The ETH_MDC is an input on power up and can be
configured to be an output through an Intel API as documented in the Intel® IXP400 Software
Programmer’s Guide.
VI
VI
VI / VO
Externally supplied transmit clock.
•
•
25 MHz for 100 Mbps operation
2.5 MHz for 10 Mbps operation
This MAC contains hardware hashing capabilities local to the interface.
This signal should be pulled high through a 10-KΩ resistor when being utilized in SMII mode of
operation.
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_TXCLK
Z
Z
VI
VI
I
MII Mode of Operation:
Transmit data bus to PHY, asserted synchronously with respect to ETHC_TXCLK. This MAC
contains hardware hashing capabilities local to the interface.
ETHC_TXDATA[3:1]
0
VO
VO
O
SMII Mode of Operation:
Not used in SMII mode of operation.
MII Mode of Operation:
Transmit data bus to PHY, asserted synchronously with respect to ETHC_TXCLK. This MAC
contains hardware hashing capabilities local to the interface.
SMII Mode of Operation:
The data on this signal is transmitted synchronously with respect to the rising edge of SMII_CLK
when operating as an SMII interface and synchronously with respect to the rising edge of
SMII_TXCLK when operating as a Source Synchronous SMII interface
ETHC_TXDATA[0] /
SMII_TXDATA[5]
Z
Z
0
0
VO
VO
VO
VO
O
O
Indicates that the PHY is being presented with nibbles on the MII interface. Asserted
synchronously, with respect to ETHC_TXCLK, at the first nibble of the preamble, and remains
asserted until all the nibbles of a frame are presented. This MAC contains hardware hashing
capabilities local to the interface.
ETHC_TXEN
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 15. MII/SMII Interfaces (Sheet 6 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Externally supplied receive clock.
•
•
25 MHz for 100 Mbps operation
2.5 MHz for 10 Mbps operation
ETHC_RXCLK
Z
Z
VI
VI
VI
VI
I
I
This MAC contains hardware hashing capabilities local to the interface.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system or when in
SMII mode of operation.
Receive data bus from PHY, data sampled synchronously, with respect to ETHC_RXCLK. This MAC
contains hardware hashing capabilities local to the interface.
•
ETHC_RXDATA[3:1]
VI
VI
Not used when operating in SMII mode of operation.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system or when in
SMII mode of operation.
MII Mode of Operation:
Receive data bus from PHY, data sampled synchronously, with respect to ETHC_RXCLK. This MAC
contains hardware hashing capabilities local to the interface
ETHC_RXDATA[0] /
SMII_RXDATA[5]
SMII Mode of Operation:
Z
Z
VI
VI
VI
VI
VI
VI
I
I
The data on this signal is received synchronously with respect to the rising edge of SMII_CLK
when operating as an SMII interface and synchronously with respect to the rising edge of
SMII_RXCLK when operating as a Source Synchronous SMII interface
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Receive data valid, used to inform the MII interface that the Ethernet PHY is sending data.
This MAC contains hardware hashing capabilities local to the interface.
ETHC_RXDV
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 15. MII/SMII Interfaces (Sheet 7 of 7)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
MII Mode of Operation:
Asserted by the PHY when a collision is detected by the PHY. This MAC contains hardware hashing
capabilities local to the interface.
•
When NPE C is configured in MII mode of operation and the signal is not being used, it
should be pulled low through a 10-KΩ resistor.
SMII Mode of Operation:
Not used.
ETHC_COL
Z
VI
VI
VI
I
•
When NPE C is configured in SMII mode of operation, this signal must be pulled high through
a 10-KΩ resistor.
When this interface is disabled via the NPE-C Ethernet soft fuse (refer to the Expansion Bus
Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Developer’s Manual) and is not being used a system design, this interface/signal is not required
for any connection.
Asserted by the PHY when the transmit medium or receive medium are active. De-asserted when
both the transmit and receive medium are idle. Remains asserted throughout the duration of
collision condition. PHY asserts CRS asynchronously and de-asserts synchronously with respect
to ETHC_RXCLK.
ETHC_CRS
Z
VI
VI
VI
I
This MAC contains hardware hashing capabilities local to the interface.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system or when in
SMII mode of operation.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
†
††
For a legend of the Type codes, see Table 8 on page 43.
Please refer to Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s Manual for information on how to select the interface desired
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 16.
Expansion Bus Interface (Sheet 1 of 3)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
Input clock signal used to sample all expansion interface inputs and clock all expansion interface
outputs.
EX_CLK
EX_ALE
Z
H
VI
H
VI
VI
I
Expansion bus Address-latch enable used for multiplexed address/data bus accesses, as an Advance
pin for Intel synchronous modes of operation/ZBT SRAM mode of operation, and LD_N for ZBT
SRAM. EX_ALE is always used by outbound transfers.
VO
VB
VO / Z
TRI
Expansion bus address used as an output for data accesses over the expansion bus when executing
outbound transactions and used as an input for data accesses over the expansion bus when
executing inbound transactions. Also, used as an input during reset to capture device configuration.
These signals have a weak pull-up resistor attached internally. Based on the desired configuration,
various address signals must be tied low in order for the device to operate in the desired mode. A
4.7 KΩ pull-down resistor is required to override these pull-up resistors. These pull-ups are disabled
when PLL_LOCK is asserted and the IXP45X/IXP46X network processors drive the signal based upon
grant. EX_ADDR is driven by IXP45X/IXP46X network processors except when grant is asserted to
an external master or during reset.
EX_ADDR[24:0]
H
H
VB
I/O
Very Important Note: See Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Developer’s Manual for additional details on address strapping.
Expansion bus write enable signal is used as an Intel-mode write strobe / Motorola-mode data
strobe (EXP_MOT_DS_N) / TI*-mode data strobe (TI_HDS1_N) / ZBT SRAM mode read/
write_n(ZBT_RD_WR_N) for outbound transactions. This signal is an output for outbound
transactions.
Expansion bus write enable signal is used as a write enable signal to the IXP45X/IXP46X network
processors for inbound transaction support. This signal is an input for inbound transactions.
EX_WR_N
EX_RD_N
H
H
H
H
VB
VB
VB
VB
I/O
I/O
EX_WR_N is driven by IXP45X/IXP46X network processors unless grant is asserted to an external
master
Expansion bus read enable signal is used as an Intel-mode read strobe / Motorola-mode read-not-
write (EXPB_MOT_RNW) / TI mode read-not-write (TI_HR_W_N) / ZBT SRAM mode output enable
(ZBT_OE_N) for outbound transactions. This signal is an output for outbound transactions.
Expansion bus read enable signal is used as a read enable signal to the IXP45X/IXP46X network
processors for inbound transaction support. This signal is an input for inbound transactions.
EX_RD_N is driven by IXP45X/IXP46X network processors unless grant is asserted to an external
master.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 16.
Expansion Bus Interface (Sheet 2 of 3)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Used to drive chip selects for outbound transactions for the expansion bus.
•
Chip selects 0 through 7 can be configured to support Intel/Intel Synchronous/Motorola/ZBT
SRAM bus cycles.
•
•
Chip selects 4 through 7 can be configured to support TI HPI bus cycles.
These signal are also sampled by the arbiter to determine when to arbitrate. Driving the signals
from an external interface has no effect on the operation of anything but the arbiter.
EX_CS_N[7:0]
H
H
VB
VB
I/O
•
External board pull-ups are required on EX_CS_N to ensure this signal remains deasserted
(especially in a multi-master environment). Additionally, the system designer is responsible for
ensuring that all the tri-stated signals do not become indeterminate. If they become
indeterminate, excessive power consumption will occur in the PAD input buffers.
EX_DATA[31:0]
EX_BE_N[3:0]
H
H
H
H
VB
VB
VB
VB
I/O
I/O
Expansion bus, bidirectional data
Expansion bus Byte enables. EX_BE_N is used to select the particular bytes that will be written or
read when executing outbound transfers.
When executing inbound transfers, EX_BE_N will be used to select sub-word writes. Only 32 bit
reads of the expansion bus is supported when operating on inbound transfers.
EX_BE_N is driven by the IXP45X/IXP46X network processors unless grant is asserted to an
external master.
Data ready/acknowledge from expansion bus devices. Expansion bus access is halted when an
external device sets EX_IOWAIT_N to logic 0 and resume from the halted location once the external
device sets EX_IOWAIT_N to logic 1. This signal affects accesses that use EX_CS_N[7:0] when the
chip select is configured in Intel and Motorola modes of operation.
During idle cycles, the board is responsible for ensuring that EX_IOWAIT_N is pulled-up.
Additionally, EX_IOWAIT_N must always be pulled high during Micron ZBT, Intel Synchronous Mode,
and HPI cycles
EX_IOWAIT_N
Z
VI
VI
VI
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
HPI interface ready signals. Can be configured to be active high or active low. These signals are
used to halt accesses using Chip Selects 7 through 4 when the chip selects are configured to
operate in HPI mode. There is one RDY signal per chip select. This signal only affects accesses that
use EX_CS_N[7:4].
EX_RDY_N[3:0]
EX_PARITY[3:0]
Z
H
VI
H
VI
VI
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
VB
VB
I/O
Byte wide parity protection on the EX_DATA[31:0]
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
67
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 16.
Expansion Bus Interface (Sheet 3 of 3)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Signals used by external masters to gain access to the bus. An external master asserts this signal to
the internal arbiter to request access to use the expansion bus signals.
EX_REQ_N[3:1]
EX_REQ_GNT_N
Z
Z
H
VI/H*
VI/H*
I
I
* When configured in external arbiter mode of operation, an internal pull-up will be enabled, thus
the pins will be driven to VCC
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
When the IXP45X/IXP46X network processors are functioning as the Expansion bus arbiter, this
signal will serve as the request input from an external master. If there is an external arbiter used for
expansion bus accesses, this signal will serve as the expansion bus grant input from the external
arbiter.
VI
VI
VI
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Signals used by the arbiter to inform external masters that the master is now granted access to use
the bus. In response to an EX_REQ_N being asserted by an external master, the arbiter will output
the corresponding EX_GNT_N signal to inform the external master that the expansion bus is clear
for that master to utilize.
EX_GNT_N[3:1]
EX_GNT_REQ_N
Z
Z
b’111
1
VO
VO
VO
VO
O
O
When the IXP45X/IXP46X network processors are functioning as the Expansion bus arbiter, this
signal will serve as the grant output for an external master asserting the corresponding request. If
there is an external arbiter used for expansion bus accesses, this signal will serve as the expansion
bus request output signal to the external arbiter.
The expansion bus chip select input is used to determine when an external master is attempting to
access the IXP45X/IXP46X network processors’ expansion bus interface and internal memory map
of the processors.
EX_SLAVE_CS_N
EX_BURST
Z
Z
VI
VI
VI
VI
VI
VI
I
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
For inbound transfers, this signal is used to signify that a burst operation is being requested to
occur.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Expansion bus IXP45X/IXP46X network processors wait. EX_WAIT_N is driven by the processors
when EX_SLAVE_CS_N is asserted. After the de-assertion of EX_SLAVE_CS_N, the IXP45X/IXP46X
network processors will stop driving this signal. A pull-up in the PAD IO is enabled all the time to
prevent this bus from floating or transitioning to VSS. This signal is used to hold off an external
master when the expansion interface cannot be accessed immediately. Most commonly seen when a
read access of the interface is occurring and the data has not been returned from the internal
peripheral unit to the expansion interface.
EX_WAIT_N
H
H
H
VO/H
O
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 17.
UART Interfaces
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
UART serial data input to UART Pins.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
RXDATA0
TXDATA0
Z
Z
VI
VI
VI
I
UART serial data output. The TXD signal is set to the MARKING (logic 1) state upon a reset
operation.
V0
VO
VO
O
UART CLEAR-TO-SEND input to UART Pins.
When logic 0, this pin indicates that the modem or data set connected to the UART interface of the
processor is ready to exchange data. The signal is a modem status input whose condition can be
tested by the processor.
CTS0_N
RTS0_N
H
Z
VI/H
V0
VI/H
VI/H
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
UART REQUEST-TO-SEND output:
When logic 0, this informs the modem or the data set connected to the UART interface of the
processor that the UART is ready to exchange data. A reset sets the request to send signal to logic 1.
VO
VO
O
LOOP-mode operation holds this signal in its inactive state (logic 1)
UART serial data input.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
RXDATA1
TXDATA1
Z
Z
VI
VI
VI
I
UART serial data output. The TXD signal is set to the MARKING (logic 1) state upon a Reset
operation.
VO
VO
VO
O
UART CLEAR-TO-SEND input to UART pins.
When logic 0, this pin indicates that the modem or data set connected to the UART interface of the
processor is ready to exchange data. The signal is a modem status input whose condition can be
tested by the processor.
CTS1_N
RTS1_N
H
Z
VI/H
V0
VI/H
VO
VI/H
VO
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
UART REQUEST-TO-SEND output:
When logic 0, this informs the modem or the data set connected to the UART interface of the
processor that the UART is ready to exchange data. A reset sets the request to send signal to logic 1.
O
LOOP-mode operation holds this signal in its inactive state (logic 1).
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 18.
Serial Peripheral Port Interface
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
SSP_SCLK is the serial bit clock used to control the timing of a transfer. SSP_SCLK can be generated
internally (Master mode) as defined by a control register bit internal to the IXP45X/IXP46X network
processors.
SSP_SCLK
SSP_SFRM
Z
Z
0
1
VO
VO
O
O
SSP_SFRM is the serial frame indicator that indicates the beginning and the end of a serialized data
word. The SSP_SFRM can be generated internally (Master mode) or taken from an external source
(Slave mode) as defined by a control register bit internal to the IXP45X/IXP46X network processors.
This signal may be active low or active high depending upon the mode of operation.
Please refer to the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Developer’s
Manual for additional details.
VO
VO
SSP_TXD is the Transmit data (serial data out) serialized data line. Sample length is a function of the
selected serial data sample size.
SSP_TXD
SSP_RXD
Z
Z
0
VO
VI
VO
VI
O
I
SSP_RXD is the Receive data (serial data in) serialized data line. Sample length is a function of the
selected serial data sample size.
VI
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
SSP_EXTCLK is an external clock which can be selected to replace the internal 3.6864 MHz clock. The
SSP_EXTCLK input is selected by setting various internal registers to appropriate values.
SSP_EXTCLK
Z
VI
VI
VI
I
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
Table 19.
I2C Interface
Possible
Configur
ations
After
Softwar
e
Enables
Normal
After
Power
Reset
Name
on
Reset†
Type†
Description
Until
Software
Enables
Reset†
I/O/
OD
The receive and transmit data/address line used to communicate between various master and slave I2C
interfaces. A pull up resistor is required on this interface. Please refer to the I2C specification.
I2C_SDA
I2C_SCL
Z
Z
Z
Z
VOD
VOD
VOD
VOD
The master and slave clock line used to communicate between various master and slave I2C interfaces. A
pull up resistor is required on this interface.
Please refer to the I2C specification.
I/O/
OD
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 20.
USB Host/Device Interfaces (Sheet 1 of 2)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
Positive signal of the differential USB receiver/driver for the USB device interface.
Note: This pin requires an 18Ω external series resistor. This resistor is located after the pin, but before
the pull-down resistor.
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. When this interface is disabled via the USB Device soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/signal
is not required for any connection.
USB_DPOS
USB_DNEG
USB_HPOS
USB_HNEG
Z
Z
Z
Z
Z
VB
VB
I/O
Negative signal of the differential USB receiver/driver for the USB device interface.
Note: This pin requires an 18Ω external series resistor. This resistor is located after the pin, but before
the pull-down resistor.
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. When this interface is disabled via the USB Device soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/signal
is not required for any connection.
Z
Z
Z
VB
VB
VB
VB
VB
VB
I/O
I/O
I/O
Positive signal of the differential USB receiver/driver for the USB host interface.
Note: This pin requires an 20Ω external series resistor. This resistor is located after the pin, but before
the pull-down resistor.
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. When this interface is disabled via the USB Device soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/signal
is not required for any connection.
Negative signal of the differential USB receiver/driver for the USB host interface.
Note: This pin requires an 20Ω external series resistor. This resistor is located after the pin, but before
the pull-down resistor.
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. When this interface is disabled via the USB Device soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/signal
is not required for any connection.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
††
Please refer to the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Hardware Design Guidelines for additional board design details.
August 2006
71
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 20.
USB Host/Device Interfaces (Sheet 2 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
USB_HPEN
USB_HPWR
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Z
Z
Z
Z
VO
VO
O
I
Enable to the external VBUS power source
External VBUS power is in over current condition
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. When this interface is disabled via the USB Device soft fuse
(refer to Expansion Bus Controller chapter of the Intel® IXP45X and Intel® IXP46X Product Line of
Network Processors Developer’s Manual) and is not being used in a system design, this interface/signal
is not required for any connection.
VI
VI
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
Please refer to the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Hardware Design Guidelines for additional board design details.
†
††
Table 21.
Oscillator Interface
Normal
Possible
Configur
ations
After
Reset
Until
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
OSC_IN
n/a
n/a
VI
VI
VI
I
33.33-MHz, sinusoidal input signal. Can be driven by an oscillator.
OSC_OUT
VO
VO
VO
O
33.33-MHz, sinusoidal output signal. Left disconnected when being driven by an oscillator.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 22.
GPIO Interface
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Enables
General purpose Input/Output pins. May be configured as an input or an output. As an input, each signal
may be configured a processor interrupt. Default after reset is to be configured as inputs. Some GPIO may
serve as an optional alternate function.
Refer to Section 3.1.12, “GPIO” on page 27, for additional details on alternate function mapping.
Should be pulled high using a 10-KΩ resistor when not being utilized in the system.
GPIO[12:0]
GPIO[13]
GPIO[14]
Z
Z
Z
Z
Z
Z
VI
VB
I/O
I/O
I/O
General purpose input/output pins. May be configured as an input or an output. Default after reset is to be
configured as inputs. Some GPIO may serve as an optional alternate function.
Refer to Section 3.1.12, “GPIO” on page 27, for additional details on alternate function mapping.
VI
VI
VB
VB
Should be pulled high using a 10-KΩ resistor when not being utilized in the system.
Can be configured the same as GPIO Pin 13 or as a clock output. Configuration as an output clock can be
set at various speeds of up to 33 MHz with various duty cycles. Configured as an input, upon reset. Some
GPIO may serve as an optional alternate function.
Refer to Section 3.1.12, “GPIO” on page 27, for additional details on alternate function mapping.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system.
Can be configured the same as GPIO Pin 13 or as a clock output. Configuration as an output clock can be
set at various speeds of up to 33 MHz with various duty cycles. Configured as an output, upon reset. Can
be used to clock the expansion interface, after reset. Some GPIO may serve as an optional alternate
function.
clkout /
VO
GPIO[15]
0
VO
VB
I/O
Refer to Section 3.1.12, “GPIO” on page 27, for additional details on alternate function mapping.
Should be pulled high through a 10-KΩ resistor when not being utilized in the system. The interface should
be set to an input in the not used configuration.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
Table 23.
JTAG Interface (Sheet 1 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
After
Power
on
Name
Reset†
Type†
Description
Reset†
Software Software
Enables
Enables
JTG_TMS
JTG_TDI
H
H
VI / H
VI /H
VI/H
VI/H
VI/H
VI/H
I
I
Test mode select for the IEEE 1149.1 JTAG interface.
Input data for the IEEE 1149.1 JTAG interface.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
73
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 23.
JTAG Interface (Sheet 2 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
JTG_TDO
Z
H
Z
VO/Z
VO / Z
VO / Z
TRI
Output data for the IEEE 1149.1 JTAG interface.
Used to reset the IEEE 1149.1 JTAG interface.
Important:
JTG_TRST_N
JTG_TCK
VI/H
VI
VI
I
The JTG_TRST_N signal must be asserted (driven low) during power-up, otherwise the TAP controller
will not be initialized properly and the processor may be locked.
When the JTAG interface is not being used, the signal must be pulled low using a 10-KΩ resistor.
VI
VI
VI
I
Used as the clock for the IEEE 1149.1 JTAG interface.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
Table 24.
System Interface (Sheet 1 of 2)
Normal
After
Reset
Until
Software Software
Enables
Possible
Configur
ations
After
Power
on
Name
Reset†
Type†
Description
Reset†
Enables
Used for test purposes only.
Must be pulled high using a 10-KΩ resistor for normal operation.
BYPASS_CLK
Z
VI
VI
VI
I
I
Used for test purposes only.
Must be pulled high using a 10-KΩ resistor for normal operation.
SCANTESTMODE_N
VI/H
VI/H
VI / H
VI / H
VI / H
VI / H
Used as a reset input to the device when PWRON_RESET_N is in an inactive state and once
power up conditions are met. Power up conditions include the following:
RESET_IN_N
VI/H
VI/H
I
—
—
Power supplies reaching a safe stable condition and
The PLL achieving a locked state
Signal used at power up to reset all internal logic to a known state after the PLL has achieved a
locked state. The PWRON_RESET_N signal is a 3.3-V signal.
PWRON_RESET_N
HIGHZ_N
VI/H
VI/H
V I/ H
VI / H
VI / H
VI / H
I
I
Used for test purposes only.
Must be pulled high using a 10-KΩ resistor for normal operation.
VI / H
VI / H
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
74
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 24. System Interface (Sheet 2 of 2)
Normal
After
Reset
Until
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software Software
Enables
Enables
Signal used to inform external reset logic that the internal PLL has achieved a locked state.
PLL_LOCK will also be de-asserted during a watchdog timeout.
PLL_LOCK
0
VO
VO
VO
O
O
Signal used to control PCI and SMII drive strength characteristics. Drive strength is varied on
PCI and SMII signals depending upon temperature.
Pin requires a 34-Ω +/- 1% tolerance resistor to ground. (Refer to Figure 14 on page 107.)
Tied off
to a
resistor
Tied off
to a
resistor
Tied off to Tied off to
a resistor
RCOMP_REF
a resistor
SPARE1
SPARE2
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
No Connection is to be made to this signal
No Connection is to be made to this signal
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
Table 25.
Power Interface (Sheet 1 of 2)
Normal
After
Reset
Until
Software
Enables
Possible
Configur
ations
After
Software
Enables
Power
on
Name
Reset†
Type†
Description
Reset†
1.3-V power supply input pins used for the internal logic. If operating at 667 MHz, this supply voltage
needs to be increased to VCC = 1.5 V.
V
N/A
N/A
N/A
N/A
I
CC
V
V
V
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
I
I
I
3.3-V power supply input pins used for the peripheral (I/O) logic.
CCP
CCM
SS
2.5-V power supply input pins used for the DDR memory interface
Ground power supply input pins used for both the 3.3-V, 2.5-V, and the 1.3-V power supplies.
3.3-V power supply input pins used for the peripheral (I/O) logic of the analog oscillator circuitry.
Require special power filtering circuitry. Refer to Figure 12 on page 106.
OSC_VCCP
OSC_VSSP
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
I
I
Ground input pins used for the peripheral (I/O) logic of the analog oscillator circuitry. Used in
conjunction with the OSC_VCCP pins.
Requires special power filtering circuitry. Refer to Figure 12 on page 106.
1.3-V power supply input pins used for the internal logic of the analog oscillator circuitry. Requires
special power filtering circuitry. If operating at 667 MHz, this supply voltage needs to be increased to
VCC = 1.5 V. Refer to Figure 13 on page 106.
OSC_VCC
N/A
N/A
N/A
N/A
I
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
75
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Package Information
Table 25.
Power Interface (Sheet 2 of 2)
Normal
After
Reset
Until
Software
Enables
Possible
Configur
ations
Power
on
Name
Reset†
Type†
Description
After
Reset†
Software
Enables
Ground power supply input pins used for the internal logic of the analog oscillator circuitry. Used in
conjunction with the OSC_VCC pins.
Requires special power filtering circuitry. Refer to Figure 13 on page 106.
OSC_VSS
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
I
I
I
I
1.3-V power supply input pins used for the internal logic of the analog phase lock-loop circuitry.
Requires special power filtering circuitry. If operating at 667 MHz, this supply voltage needs to be
increased to VCC = 1.5 V. Refer to Figure 9 on page 104.
V
V
V
CCPLL1
CCPLL2
CCPLL3
1.3-V power supply input pins used for the internal logic of the analog phase lock-loop circuitry.
Requires special power filtering circuitry. If operating at 667 MHz, this supply voltage needs to be
increased to VCC = 1.5 V. Refer to Figure 10 on page 105.
1.3-V power supply input pins used for the internal logic of the analog phase lock-loop circuitry.
Requires special power filtering circuitry. If operating at 667 MHz, this supply voltage needs to be
increased to VCC = 1.5 V. Refer to Figure 11 on page 105.
Note: This table discusses all features supported on the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors. For details on feature support listed by processor,
see Table 1 on page 13.
For a legend of the Type codes, see Table 8 on page 43.
†
August 2006
76
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors Datasheet
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
4.3
Signal-Pin Descriptions
When designing with a multifunction processor, sometimes a board design may be built
to allow a group of products to be produced from a single board design. When this
occurs, some features of a given processor may not be used. The Intel® IXP45X and
Intel® IXP46X Product Line of Network Processors Hardware Design Guidelines gives
the system designer a guide to determine how the signals must be conditioned and
how the part behaves under given configurations.
Table 26.
Processors’ Ball Map Assignments (Sheet 1 of 26)
Signal Name
Pin Configurations
VSS
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
A1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
A2
VSS
A3
DDRI_CB[0]
DDRI_CK_N[1]
DDRI_DM[3]
DDRI_DQ[30]
DDRI_DQ[26]
DDRI_DQ[25]
DDRI_DQ[22]
DDRI_DQ[18]
DDRI_MA[4]
VSS
A4
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
A5
A6
A7
A8
A9
A10
A11
A12
A13
A14
A15
A16
A17
A18
A19
A20
A21
A22
A23
A24
A25
A26
DDRI_MA[0]
DDRI_MA[8]
DDRI_BA[1]
VCCM
DDRI_CS_N[1]
DDRI_CAS_N
DDRI_DM[1]
DDRI_DQ[13]
DDRI_DQ[11]
DDRI_DM[0]
DDRI_DQ[6]
VCCM
VSS
VSS
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
77
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 2 of 26)
Signal Name
Pin Configurations
VSS
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
B1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
B2
VSS
B3
DDRI_CB[2]
DDRI_CB[1]
DDRI_CK[1]
DDRI_DQS[3]
DDRI_DQ[31]
DDRI_DQ[24]
DDRI_DQ[21]
DDRI_DQ[23]
DDRI_DQ[17]
DDRI_MA[5]
DDRI_MA[7]
DDRI_MA[9]
DDRI_MA[11]
DDRI_CS_N[0]
DDRI_RAS_N
DDRI_VREF
DDRI_DQS[1]
DDRI_DQ[14]
DDRI_DQS[0]
DDRI_DQ[5]
DDRI_DQ[7]
VCCP
B4
B5
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
B6
B7
B8
B9
B10
B11
B12
B13
B14
B15
B16
B17
B18
B19
B20
B21
B22
B23
B24
B25
B26
USB_HPEN
VSS
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
78
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 3 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_AD[30]
PCI_GNT_N[0]
DDRI_CB[3]
DDRI_CB[5]
DDRI_CB[7]
DDRI_DQS[4]
DDRI_DQ[28]
DDRI_DQ[27]
DDRI_DM[2]
VCCM
C1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
C2
C3
C4
C5
C6
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
C7
C8
C9
C10
C11
C12
C13
C14
C15
C16
C17
C18
C19
C20
C21
C22
C23
C24
C25
C26
DDRI_DQ[16]
VSS
DDRI_MA[1]
VCCM
DDRI_BA[0]
DDRI_CKE[0]
DDRI_CK[0]
DDRI_RCVENOUT_N
DDRI_DQ[15]
DDRI_DQ[10]
DDRI_DQ[4]
DDRI_DQ[3]
DDRI_DQ[2]
VSS
EX_CS_N[2]
EX_CS_N[5]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
79
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 4 of 26)
Signal Name
Pin Configurations
VCCP
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
D1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
D2
PCI_REQ_N[1]
PCI_GNT_N[1]
VSS
D3
D4
D5
DDRI_CB[4]
DDRI_CB[6]
DDRI_DM[4]
DDRI_DQ[29]
VSS
D6
D7
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
D8
D9
D10
D11
D12
D13
D14
D15
D16
D17
D18
D19
D20
D21
D22
D23
D24
D25
D26
DDRI_DQS[2]
DDRI_DQ[19]
DDRI_MA[3]
DDRI_MA[6]
DDRI_MA[10]
DDRI_MA[13]
DDRI_CKE[1]
DDRI_CK_N[0]
DDRI_DQ[12]
DDRI_DQ[9]
DDRI_DQ[8]
VCCM
DDRI_DQ[1]
DDRI_DQ[0]
EX_CS_N[1]
EX_CS_N[4]
VCCP
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
80
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 5 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_AD[26]
PCI_AD[28]
PCI_REQ_N[0]
PCI_GNT_N[2]
VSS
E1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
E2
E3
E4
E5
E6
VSS
E7
VCCM
E8
VCCM
E9
VCCM
E10
E11
E12
E13
E14
E15
E16
E17
E18
E19
E20
E21
E22
E23
E24
E25
E26
VSS
DDRI_DQ[20]
VCCM
DDRI_MA[2]
VSS
DDRI_MA[12]
DDRI_WE_N
DDRI_RCVENIN_N
VSS
VSS
VCCM
VSS
VSS
USB_HPWR
EX_CS_N[3]
EX_GNT_N[1]
EX_REQ_N[2]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
81
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 6 of 26)
Signal Name
Pin Configurations
PCI_AD[21]
PCI_CBE_N[3]
VCCP
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
F1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
F2
F3
F4
PCI_AD[31]
PCI_GNT_N[3]
VSS
F5
F6
F7
DDRI_CK[2]
VSS
F8
F9
VCCM
F10
F11
F12
F13
F14
F15
F16
F17
F18
F19
F20
F21
F22
F23
F24
F25
F26
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VSS
VSS
VSS
VSS
SPARE1
VSS
EX_CS_N[0]
EX_GNT_REQ_N
EX_REQ_N[1]
VSS
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
82
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 7 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_AD[18]
PCI_AD[20]
PCI_AD[22]
PCI_AD[25]
PCI_REQ_N[3]
PCI_INTA_N
RCOMP_REF
DDRI_CK_N[2]
VCC
G1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
G2
G3
G4
G5
G6
G7
G8
G9
G10
G11
G12
G13
G14
G15
G16
G17
G18
G19
G20
G21
G22
G23
G24
G25
G26
VCC
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
VCC
DDRI_RCOMP
USB_DPOS
USB_HPOS
EX_SLAVE_CS_N
EX_REQ_GNT_N
EX_ADDR[22]
EX_ADDR[18]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
83
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 8 of 26)
Signal Name
Pin Configurations
VCCP
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
H1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
H2
PCI_AD[17]
VSS
H3
H4
PCI_AD[24]
PCI_AD[29]
PCI_REQ_N[2]
PCI_SERR_N
H5
H6
H7
H8
H9
H10
H11
H12
H13
H14
H15
H16
H17
H18
H19
H20
H21
H22
H23
H24
H25
H26
USB_DNEG
USB_HNEG
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_CS_N[7]
EX_GNT_N[3]
EX_ADDR[23]
EX_ADDR[21]
EX_ADDR[17]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
84
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 9 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_CLKIN
PCI_FRAME_N
PCI_AD[16]
PCI_AD[19]
PCI_AD[23]
PCI_AD[27]
VCC
J1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
J2
J3
J4
J5
J6
J7
J8
J9
J10
J11
J12
J13
J14
J15
J16
J17
J18
J19
J20
J21
J22
J23
J24
J25
J26
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_CS_N[6]
VSS
EX_ADDR[24]
EX_ADDR[20]
EX_ADDR[5]
VCCP
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
85
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 10 of 26)
Signal Name
Pin Configurations
VSS
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
K1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
K2
PCI_DEVSEL_N
PCI_CBE_N[2]
PCI_STOP_N
VSS
K3
K4
K5
K6
PCI_IDSEL
VCC
K7
K8
K9
K10
K11
K12
K13
K14
K15
K16
K17
K18
K19
K20
K21
K22
K23
K24
K25
K26
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_GNT_N[2]
EX_REQ_N[3]
EX_ADDR[19]
EX_ADDR[4]
EX_RD_N
EX_CLK
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
86
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 11 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_AD[11]
PCI_CBE_N[1]
PCI_PERR_N
PCI_PAR
L1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
L2
L3
L4
L5
PCI_IRDY_N
VCC
L6
L7
L8
L9
L10
L11
L12
L13
L14
L15
L16
L17
L18
L19
L20
L21
L22
L23
L24
L25
L26
VSS
VSS
VSS
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCCP
EX_ALE
EX_BE_N[0]
EX_BE_N[2]
EX_BE_N[3]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
87
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 12 of 26)
Signal Name
Pin Configurations
PCI_CBE_N[0]
PCI_AD[12]
PCI_AD[14]
PCI_AD[13]
PCI_AD[15]
VCC
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
M1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
M2
M3
M4
M5
M6
M7
M8
M9
M10
M11
M12
M13
M14
M15
M16
M17
M18
M19
M20
M21
M22
M23
M24
M25
M26
VSS
VSS
VSS
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_WR_N
EX_BE_N[1]
VSS
EX_IOWAIT_N
EX_RDY_N[0]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
88
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 13 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_AD[6]
PCI_AD[4]
VCCP
N1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
N2
N3
N4
PCI_AD[10]
PCI_AD[9]
VCC
N5
N6
N7
N8
N9
N10
N11
N12
N13
N14
N15
N16
N17
N18
N19
N20
N21
N22
N23
N24
N25
N26
VSS
VSS
VSS
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_ADDR[3]
EX_ADDR[2]
EX_RDY_N[1]
EX_RDY_N[2]
EX_RDY_N[3]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
89
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 14 of 26)
Signal Name
Pin Configurations
VSS
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
P1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
P2
PCI_TRDY_N
PCI_AD[2]
PCI_AD[8]
PCI_AD[0]
VCC
P3
P4
P5
P6
P7
P8
P9
P10
P11
P12
P13
P14
P15
P16
P17
P18
P19
P20
P21
P22
P23
P24
P25
P26
VSS
VSS
VSS
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_DATA[23]
EX_PARITY[1]
EX_PARITY[2]
EX_BURST
EX_WAIT_N
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
90
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 15 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
PCI_AD[7]
PCI_AD[5]
PCI_AD[3]
PCI_AD[1]
HSS_TXFRAME0
VCC
R1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
R2
R3
R4
R5
R6
X
R7
R8
R9
R10
R11
R12
R13
R14
R15
R16
R17
R18
R19
R20
R21
R22
R23
R24
R25
R26
VSS
VSS
VSS
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
EX_DATA[21]
EX_DATA[22]
EX_DATA[15]
VCCP
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
91
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 16 of 26)
Signal Name
Pin Configurations
HSS_TXDATA0
HSS_TXCLK0
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
T1
X
X
X
X
X
X
X
X
X
X
X
X
T2
T3
HSS_RXFRAME0
HSS_RXDATA0
HSS_RXCLK0
T4
T5
T6
ETHC_TXEN
X
T7
T8
T9
T10
T11
T12
T13
T14
T15
T16
T17
T18
T19
T20
T21
T22
T23
T24
T25
T26
VSS
VSS
VSS
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_DATA[17]
EX_DATA[11]
VSS
EX_DATA[13]
EX_DATA[14]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
92
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 17 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
HSS_TXFRAME1
HSS_TXDATA1
VCCP
U1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
U2
U3
X
U4
HSS_TXCLK1
VSS
U5
X
X
X
U6
ETHC_RXDV
VCC
U7
U8
U9
U10
U11
U12
U13
U14
U15
U16
U17
U18
U19
U20
U21
U22
U23
U24
U25
U26
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_DATA[28]
EX_DATA[30]
EX_DATA[16]
EX_DATA[18]
EX_DATA[12]
EX_DATA[20]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
93
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 18 of 26)
Signal Name
Pin Configurations
HSS_RXFRAME1
HSS_RXDATA1
HSS_RXCLK1
ETHC_TXDATA[1]
ETHC_RXDATA[3]
VCC
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
V1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
V2
V3
V4
X
X
X
X
V5
V6
V7
VCC
V8
V9
V10
V11
V12
V13
V14
V15
V16
V17
V18
V19
V20
V21
V22
V23
V24
V25
V26
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_DATA[25]
VSS
EX_DATA[6]
EX_DATA[8]
EX_DATA[10]
EX_DATA[19]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
94
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 19 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
VCCP
W1
W2
W3
W4
W5
W6
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
ETHC_TXDATA[3]
VSS
ETHC_RXDATA[2]
ETHC_CRS
ETHB_COL
W7
ETHB_TXDATA[0]
SMII_TXDATA[0]
W8
W9
W10
W11
W12
W13
W14
W15
W16
W17
W18
W19
W20
W21
W22
W23
W24
W25
W26
EX_ADDR[12]
EX_ADDR[6]
EX_DATA[2]
VCCP
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EX_DATA[29]
EX_DATA[31]
EX_DATA[9]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
95
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 20 of 26)
Signal Name
Pin Configurations
ETHC_TXDATA[2]
SMII_TXDATA[5]
ETHC_RXDATA[1]
ETHC_COL
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
Y1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
Y2
Y3
Y4
Y5
ETHC_TXDATA[0]
ETHB_TXEN
SMII_TXCLK
Y6
Y7
Y8
ETHB_TXDATA[1]
SMII_TXDATA[1]
VCCP
X
X
X
Config. 1 only Config. 1 only
X
X
X
X
ETHB_RXDATA[3]
SMII_RXDATA[3]
Config. 1 only Config. 1 only
Y9
VCC
VCC
X
X
X
X
X
X
Y10
Y11
Y12
Y13
Y14
Y15
Y16
Y17
Y18
Y19
Y20
Y21
Y22
Y23
Y24
Y25
Y26
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
EX_ADDR[13]
EX_ADDR[11]
EX_ADDR[10]
EX_ADDR[7]
EX_DATA[1]
EX_DATA[4]
EX_DATA[5]
EX_DATA[7]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
96
August 2006
Document Number: 306261-004US
Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Ball
Processors’ Ball Map Assignments (Sheet 21 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Pin Configurations
ETHC_TXCLK
SMII_RXDATA[5]
VSS
AA1
X
X
X
X
X
X
X
X
X
X
X
AA2
AA3
ETHC_RXDATA[0]
AA4
ETHB_TXDATA[3]
SMII_TXDATA[3]
X
X
Config. 1 only Config. 1 only
AA5
AA6
AA7
VSS
X
X
SPARE2
ETHB_RXDV
SMII_RXSYNC
X
X
X
X
X
X
AA8
ETHB_RXDATA[1]
SMII_RXDATA[1]
Config. 1 only Config. 1 only
AA9
UTP_OP_DATA[4]
UTP_IP_DATA[3]
ETHA_TXEN
ETHA_RXDATA[3]
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
AA10
AA11
AA12
AA13
AA14
AA15
AA16
AA17
AA18
AA19
AA20
AA21
AA22
AA23
AA24
AA25
AA26
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VCC
VCC
VCC
VCC
VCC
GPIO[7]
GPIO[1]
SSP_RXD
EX_ADDR[14]
VSS
EX_ADDR[0]
EX_PARITY[3]
EX_DATA[26]
EX_DATA[27]
VSS
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
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Datasheet
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 22 of 26)
Signal Name
Pin Configurations
ETHC_RXCLK
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
AB1
AB2
X
X
X
X
X
X
X
X
ETH_MDIO
AB3
ETHB_TXDATA[2]
SMII_TXDATA[2]
X
Config. 1 only Config. 1 only
AB4
AB5
AB6
VSS
VSS
VSS
X
X
X
X
X
X
X
X
X
X
X
AB7
ETHB_RXDATA[2]
SMII_RXDATA[2]
X
Config. 1 only Config. 1 only
AB8
UTP_OP_DATA[5]
VSS
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
AB9
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
AB10
AB11
AB12
AB13
AB14
AB15
AB16
AB17
AB18
AB19
AB20
AB21
AB22
AB23
AB24
AB25
AB26
UTP_OP_FCI
VCCPLL2
VCCPLL3
VCC
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
PLL_LOCK
VCCP
RXDATA0
GPIO[12]
GPIO[8]
VCCP
I2C_SDA
VSS
VCCP
EX_ADDR[1]
EX_PARITY[0]
EX_DATA[24]
EX_DATA[3]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 23 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
Ball
Pin Configurations
ETH_MDC
SMII_SYNC
VCCP
AC1
AC2
AC3
AC4
AC5
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
ETHB_CRS
SMII_TXSYNC
VSS
VCCP
AC6
UTP_OP_DATA[7]
UTP_OP_DATA[3]
UTP_IP_DATA[5]
SMII_TXDATA[4]
ETHA_TXDATA[3]
ETHA_COL
UTP_OP_FCO
VCCP
AC7
AC8
AC9
AC10
AC11
AC12
AC13
AC14
AC15
AC16
AC17
AC18
AC19
AC20
AC21
AC22
AC23
AC24
AC25
AC26
X
X
UTP_IP_FCI
VCCPLL1
UTP_IP_ADDR[4]
RESET_IN_N
JTG_TMS
X
X
X
X
X
X
X
X
X
X
X
X
X
JTG_TCK
CTS0_N
GPIO[14]
GPIO[9]
GPIO[4]
SSP_TXD
EX_ADDR[15]
VSS
EX_ADDR[9]
EX_DATA[0]
VCCP
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
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Datasheet
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 24 of 26)
Signal Name
Pin Configurations
SMII_CLK
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
AD1
ETHB_TXCLK
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
AD2
ETHB_RXCLK
ETHB_RXDATA[0]
UTP_IP_DATA[7]
SMII_RXCLK
SMII_RXDATA[0]
SMII_RXDATA[4]
VCCP
AD3
AD4
AD5
X
X
AD6
UTP_IP_DATA[6]
ETHA_CRS
VSS
AD7
AD8
UTP_OP_SOC
UTP_OP_ADDR[3]
UTP_IP_SOC
OSC_VCCP
OSC_VSS
AD9
AD10
AD11
AD12
AD13
AD14
AD15
AD16
AD17
AD18
AD19
AD20
AD21
AD22
AD23
AD24
AD25
AD26
X
X
X
OSC_VCC
UTP_IP_ADDR[0]
VSS
X
X
X
X
X
X
X
X
X
X
X
X
JTG_TDI
TXDATA1
TXDATA0
VSS
GPIO[13]
GPIO[5]
GPIO[0]
SSP_SFRM
I2C_SCL
EX_ADDR[16]
EX_ADDR[8]
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 26.
Processors’ Ball Map Assignments (Sheet 25 of 26)
Signal Name
Processor Number
Intel® IXP465 Intel® IXP460 Intel® IXP455
X
Ball
Pin Configurations
VSS
AE1
AE2
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
UTP_OP_DATA[6]
ETHA_TXDATA[2]
ETHA_TXDATA[1]
ETHA_RXDV
ETHA_RXDATA[1]
VCCP
AE3
UTP_OP_DATA[2]
AE4
UTP_OP_DATA[1]
UTP_IP_DATA[4]
UTP_IP_DATA[1]
AE5
AE6
AE7
X
AE8
UTP_OP_ADDR[4]
UTP_OP_ADDR[1]
UTP_IP_FCO
OSC_VSSP
AE9
AE10
AE11
AE12
AE13
AE14
AE15
AE16
AE17
AE18
AE19
AE20
AE21
AE22
AE23
AE24
AE25
AE26
X
X
OSC_VSSP
UTP_IP_ADDR[3]
UTP_IP_ADDR[1]
VCCP
X
X
X
X
X
X
X
X
X
X
X
X
SCANTESTMODE_N
JTG_TDO
RXDATA1
RTS1_N
RTS0_N
GPIO[15]
GPIO[6]
GPIO[2]
SSP_SCLK
SSP_EXTCLK
VSS
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
August 2006
Document Number: 306261-004US
Datasheet
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 26.
Processors’ Ball Map Assignments (Sheet 26 of 26)
Signal Name
Pin Configurations
VSS
Processor Number
Ball
Intel® IXP465 Intel® IXP460 Intel® IXP455
AF1
AF2
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
VSS
AF3
UTP_OP_DATA[0]
ETHA_TXDATA[0]
ETHA_RXDATA[2]
VSS
AF4
UTP_IP_DATA[2]
AF5
X
AF6
UTP_IP_DATA[0]
UTP_OP_CLK
ETHA_RXDATA[0]
ETHA_TXCLK
UTP_OP_ADDR[2]
UTP_OP_ADDR[0]
ETHA_RXCLK
OSC_IN
AF7
AF8
AF9
AF10
AF11
AF12
AF13
AF14
AF15
AF16
AF17
AF18
AF19
AF20
AF21
AF22
AF23
AF24
AF25
AF26
UTP_IP_CLK
X
X
X
VCCP
OSC_OUT
UTP_IP_ADDR[2]
BYPASS_CLK
PWRON_RESET_N
HIGHZ_N
X
X
X
X
X
X
X
X
X
X
X
X
JTG_TRST_N
VCCP
CTS1_N
VSS
GPIO[11]
GPIO[10]
GPIO[3]
VSS
VSS
Note: Interfaces not being utilized at a system level may require external pull-up or pull-down resistors. For specific details and
requirements, see Section 4.2, “Functional Signal Definitions” on page 43.
Note: Pin Configuration is set by the Expansion bus configuration when Reset is deasserted.
Note: Blank field indicates no physical ball on package.
4.4
Package Thermal Specifications
The thermal parameters defined in Table 27, Table 28, and Table 29 are based on
simulated results of packages assembled on standard multi-layer, 2s2p, 1.0-oz copper
layer boards in a natural convection environment. The maximum case temperature is
based on the maximum junction temperature and defined by the relationship:
Tcase max = Tjmax - (ΨJT x Power)
Where ΨJT is the junction-to-package top thermal characterization parameter. If the
case temperature exceeds the specified Tcase max, thermal enhancements such as heat
sinks or forced air will be required. In the tables below, ΘJA is the package junction-to-
air thermal resistance.
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Table 27.
Table 28.
Table 29.
2.8-Watt Maximum Power Dissipation
Estimated Power
Package Type
(TPD)
Θ
Ψ
T
Max. †
JA
JT
case
35mm HSBGA
2.8W
12.5°C/W
1.4 °C/W
116°C
† This is the maximum allowable case temperature and not normal operating condition.
3.3-Watt Maximum Power Dissipation
Estimated Power
Package Type
Θ
Ψ
T
Max. †
JA
JT
case
(TPD)
35mm HSBGA
3.3W
12.5°C/W
1.4 °C/W
115°C
† This is the maximum allowable case temperature and not normal operating condition.
4.0-Watt Maximum Power Dissipation
Estimated Power
Package Type
Θ
Ψ
T
Max. †
JA
JT
case
(TPD)
35mm HSBGA
4.0W
12.5°C/W
1.4 °C/W
114°C
† This is the maximum allowable case temperature and not normal operating condition.
5.0
Electrical Specifications
5.1
Absolute Maximum Ratings
Parameter
Maximum Rating
Ambient Air Temperature (Extended)
Ambient Air Temperature (Commercial)
Supply Voltage (Intel XScale® processor)
Supply Voltage I/O
-40º C to 85º C
0º C to 70º C
-0.3 V to 2.1 V
-0.3 V to 3.6 V
-0.3V to 2.75V
-0.3 V to 2.1 V
-0.3 V to 3.6 V
-0.3 V to 2.1 V
-0.3 V to 2.1 V
-0.3 V to 2.1 V
-0.3 V to 3.6V
Supply Voltage DDR
Supply Voltage Oscillator (OSC_VCC)
Supply Voltage Oscillator (OSC_VCCP)
Supply Voltage PLL (V
Supply Voltage PLL (V
Supply Voltage PLL (V
)
)
)
CCPLL1
CCPLL2
CCPLL3
Voltage On Any I/O Ball
Storage Temperature
-55o C to 125o
C
Warning:
Stressing the device beyond the absolute maximum ratings may cause permanent
damage. These are stress ratings only. Operation beyond the operating conditions is
not recommended and extended exposure beyond the operating conditions may affect
device reliability.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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5.2
V
, V
, V
, OSC_VCCP, OSC_VCC Pin
CCPLL1
CCPLL2
CCPLL3
Requirements
To reduce voltage-supply noise on the analog sections of the IXP45X/IXP46X network
processors, the phase-lock loop circuits (VCCPLL1, VCCPLL2, VCCPLL3) and oscillator circuit
(OSC_VCC, OSC_VCCP) require isolated voltage supplies.
The filter circuits for each supply are shown in the following sections.
5.2.1
VCCPLL1 Requirement
A parallel combination of a 10-nF capacitor (for bypass) and a 200-nF capacitor (for a
first-order filter with a cut-off frequency below 30 MHz) must be connected to the
VCCPLL1 pin of the IXP45X/IXP46X network processors.
The ground of both capacitors should be connected to the nearest VSS supply pin. Both
capacitors should be located less than 0.5 inch away from the VCCPLL1 pin and the
associated VSS pin. In order to achieve the 200-nF capacitance, a parallel combination
of two 100-nF capacitors may be used as long as the capacitors are placed directly
beside each other.
Figure 9.
V
CCPLL1 Power Filtering Diagram
V c c
V C C P L L 1
1 0 0 n F
In te l®
IX P 4 5 X /IX P 4 6 X
N e tw o rk
1 0 n F
1 0 0 n F
V S S
P ro c e s s o rs
V S S
5.2.2
VCCPLL2 Requirement
A parallel combination of a 10-nF capacitor (for bypass) and a 200-nF capacitor (for a
first-order filter with a cut-off frequency below 30 MHz) must be connected to the
VCCPLL2 pin of the IXP45X/IXP46X network processors.
The ground of both capacitors should be connected to the nearest VSS supply pin. Both
capacitors should be located less than 0.5 inch away from the VCCPLL2 pin and the
associated VSS pin. In order to achieve the 200-nF capacitance, a parallel combination
of two 100-nF capacitors may be used as long as the capacitors are placed directly
beside each other.
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Figure 10.
V
CCPLL2 Power Filtering Diagram
V c c
In te l®
IX P 4 5 X /IX P 4 6 X
N e tw o rk
V C C P L L 2
1 0 0 n F
1 0 n F
1 0 0 n F
P ro c e s s o rs
V S S
V S S
5.2.3
VCCPLL3 Requirement
A parallel combination of a 10-nF capacitor (for bypass) and a 200-nF capacitor (for a
first-order filter with a cut-off frequency below 30 MHz) must be connected to the
V
CCPLL3 pin of the IXP45X/IXP46X network processors.
The ground of both capacitors should be connected to the nearest VSS supply pin. Both
capacitors should be located less than 0.5 inch away from the VCCPLL3 pin and the
associated VSS pin. In order to achieve the 200-nF capacitance, a parallel combination
of two 100-nF capacitors may be used as long as the capacitors are placed directly
beside each other.
Figure 11.
VCCPLL3 Power Filtering Diagram
V c c
V C C P L L 3
1 0 0 n F
In te l®
IX P 4 5 X /IX P 4 6 X
1 0 n F
1 0 0 n F
N e tw o rk
P ro c e s s o rs
V S S
V S S
5.2.4
OSC_VCCP Requirement
A single, 170-nF capacitor must be connected between the OSC_VCCP pin and
OSC_VSSP pin of the IXP45X/IXP46X network processors. This capacitor value provides
both bypass and filtering.
When 170 nF is an inconvenient size, capacitor values between 150 nF to 200 nF can
be used with little adverse effects, assuming that the effective series resistance of the
200-nF capacitor is under 50 mΩ.
In order to achieve a 200-nF capacitance, a parallel combination of two 100-nF
capacitors may be used as long as the capacitors are placed directly beside each other.
OSC_VSSP is made up with two pins, AE11 and AE12. Ensure that both pins are
connected as shown in Figure 12.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Figure 12.
OSC_VCCP Power Filtering Diagram
V c c p
O S C _ V C C P
In te l®
IX P 4 5 X /IX P 4 6 X
N e tw o r k
1 7 0 n F
O S C _ V S S P
P ro c e s s o rs
O S C _ V S S P
V
S S
5.2.5
OSC_VCC Requirement
A parallel combination of a 10-nF capacitor (for bypass) and a 200-nF capacitor (for a
first-order filter with a cut-off frequency below 33 MHz) must be connected to both of
the OSC_VCC pins of the IXP45X/IXP46X network processors.
The grounds of both capacitors should be connected to the OSC_VSS supply pin. Both
capacitors should be located less than 0.5 inch away from the OSC_VCC pin and the
associated OSC_VSS pin.
In order to achieve a 200-nF capacitance, a parallel combination of two 100-nF
capacitors may be used as long as the capacitors are placed directly beside each other.
Figure 13.
OSC_VCC Power Filtering Diagram
V c c
O S C _ V C C
In te l®
IX P 4 5 X /IX P 4 6 X
1 0 n F
1 0 0 n F
1 0 0 n F
N e tw o rk
P ro c e s s o rs
O S C _ V S S
V S S
5.3
RCOMP Pin Requirements
Figure 14 shows the requirements for the RCOMP pin.
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Figure 14.
RCOMP Pin External Resistor Requirements
RCOMP
Intel®
IXP45X/IXP46X
Network
34 Ω,
+ 1%
Processors
VSS
VSS
B5030-01
5.4
DDRI_RCOMP Pin Requirements
Figure 15 shows the requirements for the DDRI_RCOMP pin.
Figure 15.
DDRI_RCOMP Pin External Resistor Requirements
DDR1_RCOMP
Intel®
IXP45X/IXP46X
Network
20 Ω,
+ 1%
Processors
VSS
VSS
B5031-01
5.5
DC Specifications
5.5.1
Operating Conditions
Table 30.
Operating Conditions (Sheet 1 of 2)
Symbol
Parameter
Min.
Typ.
Max.
Units
Voltage supplied to the I/O, with the exception of the
DDRI SDRAM Interface.
V
3.135
3.3
3.465
V
V
CCP
Voltage supplied to the internal logic.
For 266, 400, and 533 MHz
For 667 MHz
1.235
1.425
1.3
1.5
1.365
1.575
V
CC
V
V
V
Voltage supplied to the DDRI SDRAM Interface.
2.300
2.5
2.700
CCM
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Table 30.
Operating Conditions (Sheet 2 of 2)
Symbol
Parameter
Min.
Typ.
Max.
Units
Voltage supplied to the internal oscillator logic.
For 266, 400, and 533 MHz
For 667 MHz
1.235
1.425
1.3
1.5
1.365
1.575
OSC_VCC
V
V
V
OSC_VCCP
Voltage supplied to the oscillator I/O.
3.135
3.3
3.465
Voltage supplied to the analog phase-lock loop.
For 266, 400, and 533 MHz
For 667 MHz
1.235
1.425
1.3
1.5
1.365
1.575
V
V
V
CCPLL1
CCPLL2
CCPLL3
Voltage supplied to the analog phase-lock loop.
For 266, 400, and 533 MHz
For 667 MHz
1.235
1.425
1.3
1.5
1.365
1.575
V
V
Voltage supplied to the analog phase-lock loop.
For 266, 400, and 533 MHz
For 667 MHz
1.235
1.425
1.3
1.5
1.365
1.575
5.5.2
PCI DC Parameters
Table 31.
PCI DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
0.5 V
V
V
3, 4
3
IH
CCP
V
0.3 V
IL
CCP
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= -500 µA
= 1500 µA
0.9 V
V
3
OH
OUT
OUT
CCP
V
I
0.1 V
10
V
3
OL
CCP
0 < V < V
-10
µA
pF
1, 3
2, 3
IL
IN
CCP
C
5
5
IN
I/O or output pin
capacitance
C
pF
2,3
OUT
C
IDSEL-pin capacitance
Pin inductance
5
pF
2,3
2,3
IDSEL
L
20
nH
PIN
Notes:
1.
2.
3.
4.
Input leakage currents include hi-Z output leakage for all bidirectional buffers with tri-state outputs.
These values are typical values seen by the manufacturing process and are not tested.
For additional information, see the PCI Local Bus Specification, Revision 2.2.
Please consult the Intel® IXP4XX Product Line of Network Processors Specification Update for the VIH
specification.
5.5.3
USB 1.1 DC Parameters
Table 32.
USB 1.1 DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
1
IH
V
0.8
IL
I
=
OUT
V
Output-high voltage
Output-low voltage
2.8
-10
V
V
OH
-6.1 * V mA
OH
IOUT =
6.1 * V mA
V
I
0.3
10
OL
OH
Input-leakage current
Input-pin capacitance
0 < V < V
µA
pF
IL
IN
CCP
C
5
2
IN
Notes:
1.
2.
Please consult the product specification update for the VIH specification.
These values are typical values seen by the manufacturing process and are not tested.
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5.5.4
UTOPIA Level 2 DC Parameters
Table 33.
UTOPIA Level 2 DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
Output-high voltage
Output-low voltage
2.0
V
V
V
V
IH
V
0.8
0.5
IL
V
I
I
= -8 mA
= 8 mA
2.4
-8
OH
OUT
V
OL
OUT
Output current at high
voltage
I
V
V
> 2.4 V
< 0.5 V
mA
mA
OH
OH
OL
Output current at low
voltage
I
8
OL
I
Input-leakage current
Input-pin capacitance
0 < V < V
CCP
-10
10
µA
pF
1
2
IL
IN
C
5
5
IN
I/O or output pin
capacitance
C
pF
2
OUT
Notes:
1.
2.
Input leakage currents include hi-Z output leakage for all bidirectional buffers with tri-state outputs.
These values are typical values seen by the manufacturing process and are not tested.
5.5.5
MII/SMII DC Parameters
Table 34.
MII/SMII DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
0.4
IL
OHMII
V
Output-high voltage
Output-low voltage
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
I
I
= - 6 mA
= 6 mA
2.4
2.4
-10
V
OUT
OUT
OUT
OUT
V
V
OLMII
V
= -10 mA
= 10mA
V
OHSMII
V
0.4
10
V
OLSMII
I
0 < V < V
CCP
µA
pF
IL
IN
C
5
1
IN
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
5.5.6
MDI DC Parameters
Table 35.
MDI DC Parameters (Sheet 1 of 2)
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
Output-high voltage
Output-low voltage
2.0
V
V
V
V
IH
V
0.8
0.4
IL
V
I
I
= - 6 mA
= 6 mA
2.4
OH
OUT
V
OL
OUT
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
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Table 35.
MDI DC Parameters (Sheet 2 of 2)
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
I
Input-leakage current 0 < V < V
IN
-10
10
µA
pF
pF
IL
CCP
C
Input-pin capacitance
Input-pin capacitance
5
5
1
1
IN
INMDIO
C
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
5.5.7
DDRI SDRAM Bus DC Parameters
Table 36.
DDRI SDRAM Bus DC Parameters
Symbol
Parameter
Conditions
Min.
0.49*V
Typ.
Max.
0.51*V
CCM
Units
Notes
V
I/O Reference voltage
V
DDRI_VREF
CCM
V
+
DDRI_VREF
0.15
V
Input-high voltage
Input-low voltage
V
+0.3
CCM
V
V
1
2
IH
V
-
DDRI_VREF
0.15
V
-0.3
1.95
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
I/O-pin capacitance
I
I
= -15mA
= 15mA
V
V
OH
OUT
OUT
V
0.35
10
OL
IL
I
0 < V < V
-10
µA
pF
IN
CCM
C
5
1
IO
Notes:
1.
2.
These values are typical values seen by the manufacturing process and are not tested.
Only 2.5V DDRI SDRAM is supported
5.5.8
Expansion Bus DC Parameters
Table 37.
Expansion Bus DC Parameters (Sheet 1 of 2)
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
Output-high voltage
Output-low voltage
Output-high voltage
Output-low voltage
2.0
V
V
V
V
V
V
IH
V
0.8
0.4
0.4
IL
OHDRV0
V
I
I
I
I
= -8 mA
= 8 mA
2.4
2.4
1, 2
1, 2
1, 3
1, 3
OUT
OUT
OUT
OUT
V
OLDRV0
OHDRV1
V
= -14 mA
= 14mA
V
OLDRV1
Notes:
1.
2.
These values are typical values seen by the manufacturing process and are not tested.
The values represented with this voltage parameter would typically be used in a system in which the
expansion bus interfaces a single load of 6pF placed less than 2 inches away from the IXP45X/IXP46X
network processors. This drive strength setting should be used to avoid ringing when minimal loading
is attached. Please use IBIS models and simulation tools to guarantee the design.
The values represented with this voltage parameter would typically be used in a system in which the
expansion bus interfaces four loads of 6pF each. All components are placed no further than 4 inches
away from the IXP45X/IXP46X network processors. This drive strength setting should be used to
avoid ringing when medium loading is attached. Please use IBIS models and simulation tools to
guarantee the design.
3.
4.
The values represented with this voltage parameter would typically be used in a system in which the
expansion bus interfaces eight loads of 6pF and all components are placed less than 6 inches from the
IXP45X/IXP46X network processors. Another use case of this drive strength would typically be four
loads of 6pF operating at 80MHz. This drive strength setting should be used to avoid ringing when
maximum loading or frequency is utilized. Please use IBIS models and simulation tools to guarantee
the design.
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Table 37.
Expansion Bus DC Parameters (Sheet 2 of 2)
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= -20 mA
= 20 mA
2.4
V
V
1, 4
1, 4
OHDRV2
OUT
V
0.4
10
OLDRV2
OUT
I
0 < V < V
CCP
-10
µA
pF
IL
IN
C
5
2
IN
Notes:
1.
2.
These values are typical values seen by the manufacturing process and are not tested.
The values represented with this voltage parameter would typically be used in a system in which the
expansion bus interfaces a single load of 6pF placed less than 2 inches away from the IXP45X/IXP46X
network processors. This drive strength setting should be used to avoid ringing when minimal loading
is attached. Please use IBIS models and simulation tools to guarantee the design.
The values represented with this voltage parameter would typically be used in a system in which the
expansion bus interfaces four loads of 6pF each. All components are placed no further than 4 inches
away from the IXP45X/IXP46X network processors. This drive strength setting should be used to
avoid ringing when medium loading is attached. Please use IBIS models and simulation tools to
guarantee the design.
The values represented with this voltage parameter would typically be used in a system in which the
expansion bus interfaces eight loads of 6pF and all components are placed less than 6 inches from the
IXP45X/IXP46X network processors. Another use case of this drive strength would typically be four
loads of 6pF operating at 80MHz. This drive strength setting should be used to avoid ringing when
maximum loading or frequency is utilized. Please use IBIS models and simulation tools to guarantee
the design.
3.
4.
5.5.9
High-Speed, Serial Interface 0 DC Parameters
Table 38.
High-Speed, Serial Interface 0 DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= - 6mA
= 6mA
2.4
-10
V
OH
OUT
V
I
0.4
10
V
OL
OUT
0 < V < V
µA
pF
IL
IN
CCP
C
5
1
Notes
1
IN
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
5.5.10
High-Speed, Serial Interface 1 DC Parameters
Table 39.
High-Speed, Serial Interface 1 DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= -6mA
= 6mA
2.4
-10
V
OH
OUT
V
I
0.4
10
V
OL
IL
OUT
0 < V < V
µA
pF
IN
CCP
C
5
IN
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
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5.5.11
UART DC Parameters
Table 40.
UART DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= - 4mA
= 4mA
2.4
-10
V
OH
OUT
V
I
0.4
10
V
OL
IL
OUT
0 < V < V
µA
pF
IN
CCP
C
5
1
IN
Notes:
1.
2.
These values are typical values seen by the manufacturing process and are not tested.
This interface has been designed assuming a single load which can be between 5pF to 25pF.
5.5.12
Serial Peripheral Interface DC parameters
Table 41.
Serial Peripheral Interface DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= - 6mA
= 6mA
2.4
-10
V
OH
OUT
OUT
V
I
0.4
10
V
OL
0 < V < V
µA
pF
IL
IN
CCP
C
5
1
IN
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
5.5.13
I2C Interface DC Parameters
Table 42.
I2C Interface DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
n/a
0.4
10
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= n/a
n/a
-10
n/a
5
V
2
1
OH
OUT
OUT
V
I
= 4mA
V
OL
IL
0 < V < V
µA
pF
IN
CCP
C
IN
Notes:
1.
2.
These values are typical values seen by the manufacturing process and are not tested.
Voltage output high for this interface is not applicable due to it being an open drain I/O.
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5.5.14
GPIO DC Parameters
Table 43.
GPIO DC Parameters
Note
s
Symbol
Parameter
Conditions
Min.
Typ.
Max. Units
V
Input-high voltage
2.0
V
IH
V
Input-low voltage
0.8
0.4
V
V
IL
Output-high voltage for GPIO 0 to
GPIO 13
V
I
OUT = -16 mA
2.4
OH
Output-low voltage for GPIO 0 to
GPIO 13
V
I
= 16 mA
= -4 mA
= 4 mA
V
V
V
OL
OUT
Output-high voltage for GPIO 14 and
GPIO 15
V
I
2.4
-10
OH
OUT
Output-low voltage for GPIO 14 and
GPIO 15
V
I
I
0.4
10
OL
OUT
Input-leakage current
Input-pin capacitance
0 < V < V
µA
pF
IL
IN
CCP
C
5
1
IN
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
5.5.15
JTAG DC Parameters
Table 44.
JTAG DC Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= -4 mA
= 4 mA
2.4
-10
V
OH
OUT
OUT
V
I
0.4
10
V
OL
IL
0 < V < V
µA
pF
IN
CCP
C
5
1
IN
Notes:
1.
These values are typical values seen by the manufacturing process and are not tested.
5.5.16
Reset DC Parameters
Table 45.
PWRON_RESET _N and RESET_IN_N Parameters
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
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5.5.17
All Remaining I/O DC Parameters
Table 46.
All Remaining I/O DC Parameters (JTAG, PLL_LOCK)
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
Notes
V
Input-high voltage
Input-low voltage
2.0
V
V
IH
V
0.8
IL
V
Output-high voltage
Output-low voltage
Input-leakage current
Input-pin capacitance
I
I
= - 4mA
= 4mA
2.4
-10
V
OH
OUT
OUT
V
I
0.4
10
V
OL
IL
0 < V < V
µA
pF
IN
CCP
C
5
1
IN
Notes:
1.
2.
These values are typical values seen by the manufacturing process and are not tested.
These parameters are only applicable to signal other than power and ground signals.
5.6
AC Specifications
Clock Signal Timings
5.6.1
5.6.1.1
Processors’ Clock Timings
Devices’ Clock Timings
Table 47.
Symbol
Parameter
Min.
Nom.
Max.
Units
Notes
V
Input-high voltage
2.0
V
V
IH
V
Input-low voltage
0.8
33.33
50
IL
Clock frequency for IXP45X/IXP46X
network processors oscillator.
T
33.33
-50
33.33
MHz
ppm
pF
1, 2
FREQUENCY
U
Clock tolerance over -40º C to 85º C.
FREQUENCY
Pin capacitance of IXP45X/IXP46X
network processors inputs.
C
5
IN
T
Duty cycle
35
50
65
%
DC
Notes:
1.
2.
This value is oscillator input. Leave the oscillator output pin as a no-connect.
Where the IXP45X/IXP46X network processors are configured with an input reference-clock, the slew
rate should never be faster than 2.5 V/nS to ensure proper PLL operation. To properly guarantee PLL
operation at the slower slew rate, the Vih and Vil levels need to be met at the 33.33MHz frequency.
Table 48.
Processors’ Clock Timings Spread Spectrum Parameters
Spread-Spectrum
Min
Max
Notes
Conditions
Characterized and guaranteed by design, but not
tested. Do not over-clock the PLL input. The A.C.
timings will not be guaranteed if the device exceeds
33.33 MHz.
Frequency deviation from
33.33 MHz as a percentage
-2.0%
+0.0%
50 KHz
Characterized and guaranteed by design, but not
tested
Modulation Frequency
Notes:
1.
It is important to note that when using spread spectrum clocking, other clocks in the system will
change frequency over a specific range. This change in other clocks can present some system level
limitations. Please refer to the application note titled Spread Spectrum Clocking to Reduce EMI
Application Note, when designing a product that utilizes spread spectrum clocking.
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Figure 16.
Typical Connection to an Oscillator
Intel® IX P 45X / IX P 46X
N etw ork P rocessors
O S C _IN
O scillator
O S C _O U T
5.6.1.2
PCI Clock Timings
PCI Clock Timings
Table 49.
33 MHZ
66 MHZ
Symbol
Parameter
Units
Notes
Min.
Max.
Min.
Max.
T
Clock period for PCI Clock
PCI Clock high time
PCI Clock low time
30
11
11
15
6
ns
ns
ns
PERIODPCICLK
T
CLKHIGH
T
6
CLKLOW
Slew Rate requirements for
PCI Clock
T
1
4
1.5
4
V/ns
SLEW RATE
5.6.1.3
MII/SMII Clock Timings
MII/SMII Clock Timings
Table 50.
Symbol
Parameter
Min.
Nom.
Max.
Units
Notes
Clock period for SMII_CLK reference
clock when operating in SMII or
Source Synchronous mode of
operation
T
8
8
ns
period100Mbit
Clock period for SMII_TXCLK and
SMII_RXCLK clock when operating
in Source Synchronous SMII mode
of operation
T
T
8
8
ns
period100Mbit
period100Mbit
Clock period for Tx and Rx Ethernet
clocks
40
400
40
400
ns
ns
Clock period for Tx and Rx Ethernet
clocks
T
period10Mbit
Duty cycle for Tx and Rx Ethernet
clocks
T
35
50
65
%
duty
Frequency
Tolerance
Frequency tolerance requirement
for Tx and Rx Ethernet clocks
+/- 50
+/- 100
ppm
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5.6.1.4
UTOPIA Level 2 Clock Timings
UTOPIA Level 2 Clock Timings
Table 51.
Symbol
Parameter
Min.
Nom.
Max.
Units
Notes
Clock period for Tx and Rx UTOPIA Level 2
clocks
T
30.303
ns
period
Duty cycle for Tx and Rx UTOPIA Level 2
clocks
T
40
50
60
2
%
ns
duty
Rise and fall time requirements for Tx and
Rx UTOPIA Level 2 clocks
T
rise/fall
5.6.1.5
Expansion Bus Clock Timings
Expansion Bus Clock Timings
Table 52.
Symbol
Parameter
Min.
Nom.
Max.
Units
Notes
T
Clock period for expansion bus clock
Duty cycle for expansion bus clock
12.5
40
ns
%
period
T
50
60
2
duty
Rise and fall time requirements for
expansion bus clock
T
ns
rise/fall
5.6.2
Bus Signal Timings
The AC timing waveforms are shown in the following sections.
5.6.2.1
PCI
Figure 17.
PCI Output Timing
V
V
hi
CLK
low
T
clk2out(b)
Output
Delay
A9572-01
Note:
V
= 0.6 V and V
= 0.2 V
LOW CC.
HI
CC
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Figure 18.
PCI Input Timing
CLK
T
setup(b)
T
hold
Inputs
Valid
Input
A9573-01
Table 53.
PCI Bus Signal Timings
33 MHz
66 MHz
Symbol
Parameter
Units
ns
Notes
Min.
Max.
Min.
Max.
Clock to output for all bused
signals. This is the PCI_AD[31:0],
PCI_CBE_N [3:0], PCI_PAR,
PCI_FRAME_N, PCI_IRDY_N,
PCI_TRDY_N, PCI_STOP_N,
PCI_DEVSEL_N, PCI_PERR_N,
PCI_SERR_N
1, 2, 5,
7, 8
T
2
11
1
6
clk2outb
Clock to output for all point-to-
point signals. This is the
PCI_GNT_N and PCI_REQ_N(0)
only.
1, 2, 5,
7, 8
T
2
7
12
1
3
6
ns
clk2out
Input setup time for all bused
signals. This is the PCI_AD[31:0],
PCI_CBE_N [3:0], PCI_PAR,
PCI_FRAME_N, PCI_IRDY_N,
PCI_TRDY_N, PCI_STOP_N,
PCI_DEVSEL_N, PCI_PERR_N,
PCI_SERR_N
4, 6, 7,
8
T
ns
setupb
Input setup time for all point-to-
point signals. This is the
PCI_REQ_N and PCI_GNT_N(0)
only.
3, 4, 7,
8
T
10, 12
0
5
0
ns
setup
T
Input hold time from clock.
ns
ns
4, 7, 8
hold
5, 6, 7,
8
T
Reset active-to-output float delay
40
40
rst-off
Notes:
1.
2.
3.
See the timing measurement conditions.
Parts compliant to the 3.3 V signaling environment.
REQ# and GNT# are point-to-point signals and have different output valid delay and input setup
times than do bused signals. GNT# has a setup of 10 ns for 33 MHz and 5 ns for 66 MHz; REQ# has
a setup of 12 ns for 33 MHz and 5 ns for 66 MHz.
4.
5.
6.
RST# is asserted and de-asserted asynchronously with respect to CLK.
All PCI outputs must be asynchronously driven to a tri-state value when RST# is active.
Setup time applies only when the device is not driving the pin. Devices cannot drive and receive
signals at the same time.
7.
8.
Timing was tested with a 70-pF capacitor to ground.
For additional information, see the PCI Local Bus Specification, Revision 2.2.
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5.6.2.2
USB 1.1 Interface
For timing parameters, see the USB 1.1 specification. The USB 1.1 interface for the
IXP45X/IXP46X network processors supports both a device or function controller only
and a host only controller. The IXP45X/IXP46X network processors USB 1.1 device
interface cannot be line-powered.
To assure proper operation with the IXP45X/IXP46X network processors USB
interfaces, please consult the Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Hardware Design Guidelines and the Intel® IXP4XX Product Line of Network Processors
Specification Update.
5.6.2.3
UTOPIA Level 2 (33 MHz)
UTOPIA Level 2 Input Timings
Figure 19.
Clock
Signals
Tsetup
Thold
A9578-01
Table 54.
UTOPIA Level 2 Input Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
Input setup prior to rising edge of clock. Inputs
included in this timing are UTP_IP_DATA[7:0],
UTP_IP_SOC, AND UTP_IP_FCI, and
UTP_OP_FCI.
T
8
ns
ns
setup
Input hold time after the rising edge of the
clock. Inputs included in this timing are
UTP_IP_DATA[7:0], UTP_IP_SOC, and
UTP_IP_FCI, and UTP_OP_FCI.
T
1
hold
Figure 20.
UTOPIA Level 2 Output Timings
Clock
Signals
Tclk2out
Tholdout
A9579-01
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Table 55.
UTOPIA Level 2 Output Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
Rising edge of clock to signal output. Outputs
included in this timing are UTP_OP_SOC,
UTP_OP_FCO, UTP_IP_FCO,
T
17
ns
1
clk2out
UTP_OP_DATA[7:0], UTP_IP_ADDR[4:0] and
UTP_OP_ADDR[4:0].
Signal output hold time after the rising edge of
the clock. Outputs included in this timing are
UTP_OP_SOC, UTP_OP_FCO, UTP_IP_FCO,
UTP_OP_DATA[7:0], UTP_IP_ADDR[4:0] and
UTP_OP_ADDR[4:0].
T
1
ns
1
holdout
Notes:
1.
Timing was designed for a system load between 5pF and 25pF
5.6.2.4
MII/SMII
Figure 21.
SMII Output Timings
T2
T1
SMII_CLK
SMII_OUTPUTS
Table 56.
SMII Output Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
Clock to output delay for SMII_TXD[4:0] and
SMII_SYNC with respect to rising edge of
SMII_CLK
T
T
1.5
5
ns
1
1
1
SMII_TXD[4:0] and SMII_SYNC hold time after
SMII_CLK.
1.5
ns
2
Notes:
1.
Timing was designed for a system load between 5pF and 15pF
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Figure 22.
SMII Input Timings
T3
T4
SMII_CLK
SMII_INPUTS
Table 57.
SMII Input Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
SMII_RXD setup time prior to rising edge of
SMII_CLK
T
T
1.5
ns
3
4
SMII_RXD hold time after the rising edge of
SMII_CLK
1
ns
Figure 23.
Source Synchronous SMII Output Timings
T2
T1
SMII_TXCLK
SMII_OUTPUTS
Table 58.
Source Synchronous SMII Output Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
Clock to output delay for SMII_TXD[4:0] and
SMII_TXSYNC with respect to rising edge of
SMII_TXCLK
T
T
1.5
1.5
5
ns
1
1
SMII_TXD[4:0] and SMII_TXSYNC hold time after
SMII_TXCLK.
ns
1
2
Notes:
1.
Timing was designed for a system load between 5pF and 15pF
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Figure 24.
Source Synchronous SMII Input Timings
T3
T4
SMII_RXCLK
SMII_INPUTS
Table 59.
Source Synchronous SMII Input Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
SMII_RXD and SMII_RXSYNC setup time prior to
rising edge of SMII_RXCLK
T
T
1.5
1
ns
1
3
4
SMII_RXD and SMII_RXSYNC hold time after the
rising edge of SMII_CLK
ns
1
Notes:
1.
Timing was designed for a system load between 5pF and 15pF
Figure 25.
MII Output Timings
T
T
2
1
eth_tx_clk
eth_tx_data[7:0]
eth_tx_en
eth_crs
A9580-01
Table 60.
MII Output Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
Clock to output delay for ETH_TXDATA and
ETH_TXEN.
T
T
12.5
ns
1, 2
2
1
2
ETH_TXDATA and ETH_TXEN hold time after
ETH_TXCLK.
1.5
ns
Notes:
1.
2.
These values satisfy t the MII specification requirement of 0 ns to 25 ns clock to output delay.
Timing was designed for a system load between 5 pF and 15 pF.
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Figure 26.
MII Input Timings
T
T
4
3
eth_rx_clk
eth_rx_data[7:0]
eth_rx_dv
eth_crs
A9581-01
Table 61.
MII Input Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
ETH_RXDATA and ETH_RXDV setup time prior to
rising edge of ETH_RXCLK
T
T
5.5
ns
1
3
4
ETH_RXDATA and ETH_RXDV hold time after the
rising edge of ETH_RXCLK
0
ns
1, 2
Notes:
1.
These values satisfying the 10-ns setup and hold time requirements necessary for the MII
specification.
2.
The T4 input hold timing parameter is not 100% tested and is guaranteed by design.
5.6.2.5
MDIO
Figure 27.
MDIO Output Timings
ETH_MDC
ETH_MDIO
T
T
1
2
A9582-02
Note: Processor is sourcing MDIO.
Figure 28.
MDIO Input Timings
T
5
ETH_MDC
ETH_MDIO
T
T
4
3
A9583-02
Note: PHY is sourcing MDIO.
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Table 62.
MDIO Timings Values
Symbol
Parameter
Min.
Max.
Units
Notes
ETH_MDIO, clock to output timing with respect to
rising edge of ETH_MDC clock
ETH_MDC/2
+ 15 ns
T1
T2
T3
ns
ETH_MDIO output hold timing after the rising
edge of ETH_MDC clock
10
3
ns
ns
ETH_MDIO input setup prior to rising edge of
ETH_MDC clock
ETH_MDIO hold time after the rising edge of
ETH_MDC clock
T4
T5
1
ns
ns
ETH_MDC clock period
125
500
1
Note:
1.
Timing was designed for a system load between 5pF and 20pF
5.6.2.6
DDRI SDRAM Bus
Figure 29.
DDRI SDRAM Write Timings
T1 T2
T3
T4
DDRI_M_CLK
ADDR/CTRL
ADDR/CMDVALID
T5 T6
DDRI_DQS
DATAVALID
DDRI_DQ, _CB, _DM
Table 63.
DDRI SDRAM Write Timings Values (Sheet 1 of 2)
Symbol
Parameter
Min.
Max.
Units
Notes
Output valid for DDRI_DQS prior to each edge of
DDRI_M_CLK.
T
1.4
ns
1
1
2
DDRI_DQS output hold time after each edge of
the DDRI_M_CLK.
T
1.0
ns
ns
1
1
Output valid for ADDR/CTRL prior to the rising
edge of DDRI_M_CLK. Address and control
signals consist of DDRI_RAS_N, DDRI_CAS_N,
DDRI_CS_N, DDRI_WE_N, DDRI_BA, DDRI_MA,
and DDRI_CKE.
T
2.5
3
Notes:
1.
DDRI_M_CLK is representative of all DDRI_CK and DDRI_CK_N signals. The rising edge of
DDRI_M_CLK represents the crossover point of the respective DDRI_CK and DDRI_CK_N signals.
The skew between the separate DDR clocks have been compensated in the timings which have been
described. The period to period clock jitter on each DDRI_M_CLK pair is spec’ed at +/-100ps.
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Table 63.
DDRI SDRAM Write Timings Values (Sheet 2 of 2)
Symbol
Parameter
Min.
Max.
Units
Notes
ADDR/CTRL output hold time after the rising
edge of the DDRI_M_CLK. Address and control
signals consist of DDRI_RAS_N, DDRI_CAS_N,
DDRI_CS_N, DDRI_WE_N, DDRI_BA, DDRI_MA,
and DDRI_CKE.
T
2.3
ns
1
4
Output valid for DDRI_DQ, DDRI_CB, and
DDRI_DM prior to each edge of DDRI_DQS.
T
T
1.0
1.0
ns
ns
5
6
DDRI_DQ, DDRI_CB, and DDRI_DM output hold
time after each edge of the DDRI_DQS.
Notes:
1.
DDRI_M_CLK is representative of all DDRI_CK and DDRI_CK_N signals. The rising edge of
DDRI_M_CLK represents the crossover point of the respective DDRI_CK and DDRI_CK_N signals.
The skew between the separate DDR clocks have been compensated in the timings which have been
described. The period to period clock jitter on each DDRI_M_CLK pair is spec’ed at +/-100ps.
Figure 30.
DDRI SDRAM Read Timings (2.0 CAS Latency)
T1
T2
T3
T4
DDRI_M_CLK
DDRI_DQS
T5
DDRI_RCVENOUT_N
DDRI_RCVENIN_N
T6
RD CMD
D0
D1
D2
D3
D4
D5
D6
D7
DDRI_DQ, _CB, _DM
Figure 31.
DDRI SDRAM Read Timings (2.5 CAS Latency)
T1
T2
T3
T4
DDRI_M_CLK
DDRI_DQS
T5
DDRI_RCVENOUT_N
DDRI_RCVENIN_N
T6
RD CMD
D0
D1
D2
D3
D4
D5
D6
D7
DDRI_DQ, _CB, _DM
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Table 64.
DDRI SDRAM Read Timing Values
Symbol
Parameter
Min.
Max.
Units
Notes
DDRI_RCVENOUT_N minimum output valid time
after DDRI_M_CLK
T
T
T
T
0.9
ns
1
1
2
3
4
DDRI_RCVENOUT_N maximum output valid
time after DDRI_M_CLK
2.7
ns
ns
ns
1
DDRI_RCVENIN_N input valid time before
DDRI_DQS
3.6
DDRI_RCVENIN_N hold time from DDRI_DQS
valid
-0.1
Maximum delay for Data valid after any edge of
DDRI_DQS. Both of these signal are inputs from
the memory during read operations.
T
0.75
1.0
ns
5
Maximum guaranteed time before data begins
to transition to the next valid data prior to any
DDRI_DQS clock edge. Both of these signal are
inputs from the memory during read operations.
This time in conjunction with timing parameter
T
ns
6
T
specify the window for which the DDRI data
5
signals can operate with the memory controller
on the IXP45X/IXP46X network processors.
Notes:
1.
It is recommended that IBIS models be used to verify signal integrity on individual designs
5.6.2.7
Expansion Bus
5.6.2.7.1
Expansion Bus Synchronous Operation
Expansion Bus Synchronous Timing
Figure 32.
T1
EX_CLK
T2
EX_DATA, _BE_N, PARITY -
output_signals
EX_ control signals -
output_signals
T3 T4
EX_DATA, _BE_N, PARITY -
input_signals
EX_ control signals -
input_signals
T5 T6
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Table 65.
Expansion Bus Synchronous Operation Timing Values
Low Drive
Med Drive
Hi Drive
Symbol
Parameter
Units Notes
Min. Max.
Min.
Max. Min. Max.
Valid rising edge of EX_CLK to valid signal on the
output.
1, 2, 3,
T
T
T
T
T
T
10
8.5
6.5
ns
4
1
2
3
4
5
6
1, 2, 3,
Valid signal hold time after the rising edge of EX_CLK
1
1
1
ns
4
Valid data signal on an input prior to the rising edge of
EX_CLK
1, 2, 3,
2
2
2
ns
4
Required hold time of a data input after the rising edge
of EX_CLK
1, 2, 3,
0.5
3.5
0.5
0.5
3.5
0.5
0.5
3.5
0.5
ns
4
Valid control/arbiter signal on an input prior to the
rising edge of EX_CLK
1, 2, 3,
ns
4
Required hold time of a control/arbiter input after the
rising edge of EX_CLK
1, 2, 3,
ns
4
Notes:
1.
Timing was designed for a system load between 5pF and 60pF for low drive setting at typically no more than a 33MHz
clock
2.
3.
4.
5.
6.
Timing was designed for a system load between 5pF and 50pF for medium drive setting at typically no more than a
66MHz clock
Timing was designed for a system load between 5pF and 40pF for high drive setting at typically no more than a 80MHz
clock
Drive settings do not apply to EX_CS_N signals and are expected to be point to point. The timing on this signal was
designed for a system load between 5pF and 10pF
EX_control_signals output signals consist of EX_ALE, EX_ADDR, EX_CS_N, EX_GNT_REQ_N, EX_GNT_N, EX_RD_N,
EX_WR_N, EX_WAIT_N
EX_control_signals input signals consist of EX_ADDR, EX_CS_N, EX_SLAVE_CS_N, EX_REQ_GNT_N, EX_REQ_N,
EX_BURST, EX_RD_N, EX_WR_N
5.6.2.7.2
Expansion Bus Asynchronous Operation
Intel Multiplexed Mode
Figure 33.
T1
T2
T3
T4
T5
2-5 Cycles
1-4 Cycles
1-16 Cycles
1-4 Cycles
1-16 Cycles
ALE Extended
EX_CLK
T
recov
T
T
EX_CS_N
EX_ADDR
EX_ALE
alepulse
ale2valcs
Valid Address
T
dhold2afterwr
T
wrpulse
EX_WR_N
T
dval2valwrt
T
ale2addrhold
Multiplexed Address/Data
EX_DATA
EX_RD_N
EX_DATA
Output Data
Address
T
rdsetup
T
rdhold
Address
Input Data
A9585-01
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Table 66.
Intel Multiplexed Mode Values
Symbol
Parameter
Min. Max. Units Notes
Talepulse
Pulse width of ALE (ADDR is valid at the rising edge of ALE)
1
1
4
1
Cycles 1, 7
Cycles 1, 2, 7
Cycles 3, 7
Cycles 4, 7
Cycles 5, 7
Cycles 7
ns
Tale2addrhold Valid address hold time after from falling edge of ALE
Tdval2valwrt
Twrpulse
Write data valid prior to WR_N falling edge
Pulse width of the WR_N
1
4
1
16
4
Tdholdafterwr Valid data after the rising edge of WR_N
1
Tale2valcs
Trdsetup
Trdhold
Valid chip select after the falling edge of ALE
Data valid required before the rising edge of RD_N
Data hold required after the rising edge of RD_N
1
4
14.7
2
ns
Time needed between successive accesses on expansion
interface.
Trecov
1
16
Cycles 6
Notes:
1.
2.
3.
4.
5.
6.
The EX_ALE signal is extended form T to 4T nnsec based on the programming of the T1 timing
parameter. The parameter Tale2addrhold is fixed at T.
Setting the address phase parameter (T1) will adjust the duration that the address appears to the
external device.
Setting the data setup phase parameter (T2) will adjust the duration that the data appears prior to a
data strobe (read or write) to an external device.
Setting the data strobe phase parameter (T3) will adjust the duration that the data strobe appears
(read or write) to an external device. Data will be available during this time as well.
Setting the data hold strobe phase parameter (T4) will adjust the duration that the chip selects,
address, and data (during a write) will be held.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on the
expansion interface.
T is the period of the clock measured in ns.
Clock to output delay for all signals will be a maximum of 15 ns for devices requiring operation in
synchronous mode.
Timing was designed for a system load between 5pF and 60pF for high drive setting
7.
8.
9.
Figure 34.
Intel Simplex Mode
T1
T2
T3
T4
T5
1-4 Cycles
1-4 Cycles
1-16 Cycles
1-4 Cycles
1-16 Cycles
EX_CLK
T
recov
EX_CS_N
EX_ADDR
EX_WR_N
Valid Address
T
wrpulse
T
dval2valwrt
T
T
addr2valcs
dhold2afterwr
T
Output Data
EX_DATA
EX_RD_N
EX_DATA
T
rdsetup
rdhold
Input Data
A9586-01
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Table 67.
Intel Simplex Mode Values
Symbol
Parameter
Min. Max. Units
Notes
T
Valid address to valid chip select
1
1
1
1
4
4
Cycles
Cycles
Cycles
Cycles
1, 2, 7
3, 7
addr2valcs
T
Write data valid prior to EXPB_IO_WRITE_N falling edge
Pulse width of the EXP_IO_WRITE_N
dval2valwrt
T
16
4
4, 7
wrpulse
dholdafterwr
T
Valid data after the rising edge of EXPB_IO_WRITE_N
5, 7
Data valid required before the rising edge of
EXP_IO_READ_N
T
14.7
ns
ns
rdsetup
Data hold required after the rising edge of
EXP_IO_READ_N
T
2
1
rdhold
Time required between successive accesses on the
expansion interface.
T
16
Cycles
6
recov
Notes:
1.
2.
EX_ALE is not valid in simplex mode of operation.
Setting the address phase parameter (T1) will adjust the duration that the address appears to the
external device.
3.
4.
5.
6.
Setting the data setup phase parameter (T2) will adjust the duration that the data appears prior to a
data strobe (read or write) to an external device.
Setting the data strobe phase parameter (T3) will adjust the duration that the data strobe appears
(read or write) to an external device. Data will be available during this time as well.
Setting the data hold strobe phase parameter (T4) will adjust the duration that the chip selects,
address, and data (during a write) will be held.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the expansion interface.
7.
8.
T is the period of the clock measured in ns.
Clock to output delay for all signals will be a maximum of 15 ns for devices requiring operation in
synchronous mode.
9.
Timing was designed for a system load between 5pF and 60pF for high drive setting
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Figure 35.
Motorola* Multiplexed Mode
T1
T2
T3
T4
T5
2-5 Cycles
ALE Extended
1-4 Cycles
1-16 Cycles
1-4 Cycles
1-16 Cycles
EX_CLK
T
recov
EX_CS_N
T
T
alepulse
ale2valcs
EX_ADDR
EX_ALE
Valid Address
T
dhold2afterds
EX_RD_N
(exp_mot_rnw)
T
dspulse
EX_WR_N
(exp_mot_ds_n)
T
dval2valds
T
ale2addrhold
Multiplexed Address/Data
EX_DATA
Output Data
Address
EX_RD_N
(exp_mot_rnw)
T
rdsetup
EX_WR_N
(exp_mot_ds_n)
T
rdhold
Address
Input Data
EX_DATA
A9587-01
Table 68.
Motorola* Multiplexed Mode Values (Sheet 1 of 2)
Symbol
Parameter
Min. Max. Units
Notes
T
Pulse width of ALE (ADDR is valid at the rising edge of ALE)
Valid address hold time after from falling edge of ALE
Write data valid prior to EXP_MOT_DS_N falling edge
Pulse width of the EXP_MOT_DS_N
1
1
1
1
1
4
1
Cycles
Cycles
Cycles
Cycles
Cycles
1, 7
alepulse
T
1, 2, 7
3, 7
ale2addrhold
T
4
dval2valds
T
16
4
4, 7
dspulse
dholdafterds
T
Valid data after the rising edge of EXP_MOT_DS_N
5, 7
Notes:
1.
The EX_ALE signal is extended form T to 4T nnsec, based on the programming of the T1 timing
parameter. The parameter Tale2addrhold is fixed at T.
2.
3.
4.
5.
6.
Setting the address phase parameter (T1) will adjust the duration that the address appears to the
external device.
Setting the data setup phase parameter (T2) will adjust the duration that the data appears prior to a
data strobe (read or write) to an external device.
Setting the data strobe phase parameter (T3) will adjust the duration that the data strobe appears
(read or write) to an external device. Data will be available during this time as well.
Setting the data hold strobe phase parameter (T4) will adjust the duration that the chip selects,
address, and data (during a write) will be held.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the expansion interface.
T is the period of the clock measured in ns.
Clock to output delay for all signals will be a maximum of 15 ns for devices requiring operation in
synchronous mode.
Timing was designed for a system load between 5pF and 60pF for high drive setting
7.
8.
9.
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Table 68.
Motorola* Multiplexed Mode Values (Sheet 2 of 2)
Symbol
Parameter
Min. Max. Units
Notes
T
Valid chip select after the falling edge of ALE
1
14.7
2
4
Cycles
ns
7
ale2valcs
Data valid required before the rising edge of
EXP_MOT_DS_N
T
rdsetup
T
Data hold required after the rising edge of EXP_MOT_DS_N
ns
rdhold
Time needed between successive accesses on expansion
interface.
T
1
16
Cycles
6
recov
Notes:
1.
The EX_ALE signal is extended form T to 4T nnsec, based on the programming of the T1 timing
parameter. The parameter Tale2addrhold is fixed at T.
2.
3.
4.
5.
6.
Setting the address phase parameter (T1) will adjust the duration that the address appears to the
external device.
Setting the data setup phase parameter (T2) will adjust the duration that the data appears prior to a
data strobe (read or write) to an external device.
Setting the data strobe phase parameter (T3) will adjust the duration that the data strobe appears
(read or write) to an external device. Data will be available during this time as well.
Setting the data hold strobe phase parameter (T4) will adjust the duration that the chip selects,
address, and data (during a write) will be held.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the expansion interface.
T is the period of the clock measured in ns.
Clock to output delay for all signals will be a maximum of 15 ns for devices requiring operation in
synchronous mode.
Timing was designed for a system load between 5pF and 60pF for high drive setting
7.
8.
9.
Figure 36.
Motorola* Simplex Mode
T1
T2
T3
T4
T5
1-4 Cycles
1-4 Cycles
1-16 Cycles
1-4 Cycles
1-16 Cycles
EX_CLK
T
recov
EX_CS_N
T
ad2valcs
EX_ADDR
Valid Address
T
dhold2afterds
EX_RD_N
(exp_mot_rnw)
T
dspulse
EX_WR_N
(exp_mot_ds_n)
T
dval2valds
Output Data
EX_DATA
EX_RD_N
(exp_mot_rnw)
T
rdsetup
EX_WR_N
(exp_mot_ds_n)
T
rdhold
Input Data
EX_DATA
A9588-01
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Table 69.
Motorola* Simplex Mode Values
Symbol
Parameter
Min. Max. Units
Notes
T
Valid address to valid chip select
1
1
1
1
4
4
Cycles
Cycles
Cycles
Cycles
1, 2, 7
3, 7
ad2valcs
T
Write data valid prior to EXP_MOT_DS_N falling edge
Pulse width of the EXP_MOT_DS_N
dval2valds
T
16
4
4, 7
dspulse
dholdafterds
T
Valid data after the rising edge of EXP_MOT_DS_N
5, 7
Data valid required before the rising edge of
EXP_MOT_DS_N
T
14.7
ns
ns
rdsetup
T
Data hold required after the rising edge of EXP_MOT_DS_N
2
1
rdhold
Time required between successive accesses on the
expansion interface.
T
16
Cycles
6
recov
Notes:
1.
2.
EX_ALE is not valid in simplex mode of operation.
Setting the address phase parameter (T1) will adjust the duration that the address appears to the
external device.
3.
4.
5.
6.
Setting the data setup phase parameter (T2) will adjust the duration that the data appears prior to a
data strobe (read or write) to an external device.
Setting the data strobe phase parameter (T3) will adjust the duration that the data strobe appears
(read or write) to an external device. Data will be available during this time as well.
Setting the data hold strobe phase parameter (T4) will adjust the duration that the chip selects,
address, and data (during a write) will be held.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the expansion interface.
T is the period of the clock measured in ns.
7.
8.
Clock to output delay for all signals will be a maximum of 15 ns for devices requiring operation in
synchronous mode.
Timing was designed for a system load between 5pF and 60pF for high drive setting
9.
Figure 37.
HPI*–8 Mode Write Accesses
T1
T2
T3
T4 T5 T1 T2
T3
T4
T5
EX_CLK
EX_CS_N
(hcs_n)
Trecov
Tadd_setup
Valid
EX_ADDR[2:1]
(hcntl)
Valid
EX_RD_N
(hr_w_n)
EX_ADDR[0]
(hbil)
Thds1_pulse
Tcs2hds1val
EX_WR_N
(hds1_n)
EX_RDY_N
(hrdy)
Tdata_hold
Tdata_setup
Data
EX_DATA
(hdin)
Data
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Table 70.
HPI* Timing Symbol Description
State
Description
Min
Max
Unit
Notes
1, 5, 6
T1
T2
T3
T4
T5
Address Timing
Setup/Chip Select Timing
Strobe Timing
3
3
2
3
2
4
4
Cycles
Cycles
Cycles
Cycles
Cycles
2, 6
16
4
3, 5, 6
Hold Timing
6
6
Recovery Phase
17
Table 71.
HPI*–8 Mode Write Accesses Values
Symbol
Parameter
Min.
Max.
Units
Notes
Valid time that address is asserted on the line. The
address is asserted at the same time as chip select.
T
11
45
Cycles 1, 5, 6
add_setup
Delay from chip select being active and the HDS1 data
strobe being active.
T
3
4
4
4
2
4
5
Cycles 5, 6
Cycles 2, 4, 5
Cycles 3, 5, 6
Cycles 3, 6
Cycles 4, 6
cs2hds1val
hds1_pulse
data_setup
T
T
Pulse width of the HDS1 data strobe
Data valid prior to the rising edge of the HDS1 data
strobe.
5
T
Data valid after the rising edge of the HDS1 data strobe.
36
17
data_hold
Time required between successive accesses on the
expansion interface.
T
recov
Notes:
1.
The address phase parameter (T1) must be set to a minimum value of 2. This value allows three T
clocks for the address phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
address phase for at least one clock pulse after the HRDY is de-active.
2.
3.
The data setup phase parameter (T2) must be set to a minimum value of 2. This value allows three
T clocks for setup phase.
The data strobe phase parameter (T3) must be set to a minimum value of 1. This value allows two T
clocks for the data phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
data setup phase for at least one clock pulse after the HRDY is de-active
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the Expansion Bus interface.
4.
5.
HRDY can be asserted by the DSP at any point in the access. The interface will not leave states T1
or T3 until HRDY is de-active
6.
7.
One cycle is the period of the Expansion Bus clock.
Timing was designed for a system load between 5 pF and 60 pF for high drive setting.
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Table 72.
Setup/Hold Timing Values in Asynchronous Mode of Operation
Parameter
Min.
Max.
Units
Notes
Output Valid after rising edge of EX_CLK
Output Hold after rising edge of EX_CLK
Input Setup prior to rising edge of EX_CLK
Input Hold required after rising edge of EX_CLK
Notes:
10
ns
ns
ns
ns
1
0
1
1
1
3.5
0.5
1.
The Setup and Hold Timing values are for all modes.
Table 73.
HPI*-16 Multiplexed Write Accesses Values
Symbol
Parameter
Min. Max.
Units
Notes
Valid time that address is asserted on the line. The address
is asserted at the same time as chip select.
T
11
3
45
4
Cycles 1, 5, 6
Cycles 5, 6
add_setup
Delay from chip select being active and the HDS1 data
strobe being active.
T
cs2hds1val
T
T
Pulse width of the HDS1 data strobe
4
4
4
5
5
Cycles 2, 4, 5
Cycles 3, 5, 6
Cycles 3, 6
hds1_pulse
Data valid prior to the rising edge of the HDS1 data strobe.
Data valid after the rising edge of the HDS1 data strobe.
data_setup
T
36
data_hold
Time required between successive accesses on the
expansion interface.
T
2
17
Cycles 4, 6
recov
Notes:
1.
The address phase parameter (T1) must be set to a minimum value of 2. This value allows three T
clocks for the address phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
address phase for at least one clock pulse after the HRDY is de-active.
The data setup phase parameter (T2) must be set to a minimum value of 2. This value allows three T
clocks for setup phase.
The data strobe phase parameter (T3) must be set to a minimum value of 1. This value allows two T
clocks for the data phase. This setting is required to ensure that in the event of an HRDY, the IXP45X/
IXP46X network processors have had sufficient time to recognize the HRDY and hold the data setup
phase for at least one clock pulse after the HRDY is de-active
2.
3.
4.
5.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the Expansion Bus interface.
HRDY can be asserted by the DSP at any point in the access. The interface will not leave states T1 or
T3 until HRDY is de-active
One cycle is the period of the Expansion Bus clock.
6.
7.
Timing was designed for a system load between 5pF and 60pF for high drive setting
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Figure 38.
HPI*-16 Multiplexed Write Mode
T1
T2
T5
T1 T2
T4
T3
T3
T4
EX_CLK
EX_CS_N
(hcs_n)
Trecov
Tadd_setup
Valid
EX_ADDR[2:1]
(hcntl)
Valid
EX_RD_N
(hr_w_n)
Tcs2hds1val
Thds1_pulse
Tdata_setup
EX_WR_N
(hds1_n)
EX_RDY_N
(hrdy)
Tdata_hold
Data
EX_DATA
(hdin)
Data
Table 74.
HPI*-16 Multiplexed Read Accesses Values
Symbol
Parameter
Min. Max.
Units Notes
Valid time that address is asserted on the line. The address
is asserted at the same time as chip select.
T
11
45
Cycles 1, 5, 6
add_setup
Delay from chip select being active and the HDS1 data
strobe being active.
T
3
4
4
4
5
5
Cycles 5, 6
cs2hds1val
hds1_pulse
data_setup
T
T
Pulse width of the HDS1 data strobe
Cycles 2, 4, 5
Cycles 3, 5, 6
Data is valid from the time from of the falling edge of
HDS1_N to when the data is read.
Time required between successive accesses on the
expansion interface.
T
2
17
cycles 4, 6
recov
Notes:
1.
The address phase parameter (T1) must be set to a minimum value of 2. This value allows three T
clocks for the address phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
address phase for at least one clock pulse after the HRDY is de-active.
The data setup phase parameter (T2) must be set to a minimum value of 2. This value allows three
T clocks for setup phase.
The data strobe phase parameter (T3) must be set to a minimum value of 1. This value allows two T
clocks for the data phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
data setup phase for at least one clock pulse after the HRDY is de-active
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the Expansion Bus interface.
2.
3.
4.
5.
HRDY can be asserted by the DSP at any point in the access. The interface will not leave states T1 or
T3 until HRDY is de-active
One cycle is the period of the Expansion Bus clock.
Timing was designed for a system load between 5pF and 60pF for high drive setting
6.
7.
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Figure 39.
HPI*-16 Multiplexed Read Mode
T1 T2
T3
T4
T5 T1 T2 T3 T4 T5
EX_CLK
EX_CS_N
(hcs_n)
Trecov
Tadd_setup
Valid
EX_ADDR[2:1]
(hcntl)
Valid
EX_RD_N
(hr_w_n)
Tcs2hds1val
Thds1_pulse
EX_WR_N
(hds1_n)
EX_RDY_N
(hrdy)
Tdata_setup
Valid Data
EX_DATA
(hdout)
Data
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Table 75.
HPI-16 Non-Multiplexed Read Accesses Values
Min
.
Symbol
Parameter
Max.
Units
Notes
Valid time that address is asserted on the line. The address is
asserted at the same time as chip select.
T
11
45
Cycles 1, 5, 6
add_setup
Delay from chip select being active and the HDS1 data strobe
being active.
T
3
4
4
4
5
5
Cycles 5, 6
cs2hds1val
hds1_pulse
data_setup
T
T
Pulse width of the HDS1 data strobe
Cycles 2, 4, 5
Cycles 3, 5, 6
Data is valid from the time from of the falling edge of
HDS1_N to when the data is read.
Time required between successive accesses on the expansion
interface.
T
2
17
Cycles 4, 6
recov
Notes:
1.
The address phase parameter (T1) must be set to a minimum value of 2. This value allows three T
clocks for the address phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
address phase for at least one clock pulse after the HRDY is de-active.
The data setup phase parameter (T2) must be set to a minimum value of 2. This value allows three T
clocks for setup phase.
The data strobe phase parameter (T3) must be set to a minimum value of 1. This value allows two T
clocks for the data phase. This setting is required to ensure that in the event of an HRDY, the IXP45X/
IXP46X network processors have had sufficient time to recognize the HRDY and hold the data setup
phase for at least one clock pulse after the HRDY is de-active
2.
3.
4.
5.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the Expansion Bus interface.
HRDY can be asserted by the DSP at any point in the access. The interface will not leave states T1 or
T3 until HRDY is de-active
6.
7.
One cycle is the period of the Expansion Bus clock.
Timing was designed for a system load between 5pF and 60pF for high drive setting
Figure 40.
HPI*-16 Non-Multiplexed Read Mode
T1
T2
T3
T4
T5 T1
T2
T3
EX_CLK
EX_CS_N
(hcs_n)
Trecov
Tadd_setup
EX_ADDR[23:0]
(ha)
Valid
Valid
EX_RD_N
(hr_w_n)
Thds1_pulse
Tcs2hds1val
EX_WR_N
(hds1_n)
EX_RDY_N
(hrdy)
Tdata_setup
EX_DATA
(hdout)
Valid Data
Valid Data
B-01
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Table 76.
HPI-16 Non-Multiplexed Write Accesses Values
Symbol
Parameter
Min. Max.
Units
Notes
Valid time that address is asserted on the line. The address
is asserted at the same time as chip select.
T
11
3
45
4
Cycles 1, 5, 6
Cycles 5, 6
add_setup
Delay from chip select being active and the HDS1 data
strobe being active.
T
cs2hds1val
T
T
Pulse width of the HDS1 data strobe
4
4
4
5
5
Cycles 2, 4, 5
Cycles 3, 5, 6
Cycles 3, 6
hds1_pulse
Data valid prior to the rising edge of the HDS1 data strobe.
Data valid after the rising edge of the HDS1 data strobe.
data_setup
T
36
data_hold
Time required between successive accesses on the
expansion interface.
T
2
17
Cycles 4, 6
recov
Notes:
1.
The address phase parameter (T1) must be set to a minimum value of 2. This value allows three T
clocks for the address phase. This setting is required to ensure that in the event of an HRDY, the
IXP45X/IXP46X network processors have had sufficient time to recognize the HRDY and hold the
address phase for at least one clock pulse after the HRDY is de-active.
2.
3.
The data setup phase parameter (T2) must be set to a minimum value of 2. This value allows three T
clocks for setup phase.
The data strobe phase parameter (T3) must be set to a minimum value of 1. This value allows two T
clocks for the data phase. This setting is required to ensure that in the event of an HRDY, the IXP45X/
IXP46X network processors have had sufficient time to recognize the HRDY and hold the data setup
phase for at least one clock pulse after the HRDY is de-active
4.
5.
Setting the recovery phase parameter (T5) will adjust the duration between successive accesses on
the Expansion Bus interface.
HRDY can be asserted by the DSP at any point in the access. The interface will not leave states T1 or
T3 until HRDY is de-active
6.
7.
One cycle is the period of the Expansion Bus clock.
Timing was designed for a system load between 5 pF and 60 pF for high drive setting
Figure 41.
HPI*-16 Non-Multiplexed Write Mode
T1 T2
T5
T1 T2
T3
T4
T3
T4
EX_CLK
EX_CS_N
(hcs_n)
Trecov
Tadd_setup
Valid
EX_ADDR[23:0]
(ha)
Valid
EX_RD_N
(hr_w_n)
Thds1_pulse
Tcs2hds1val
EX_WR_N
(hds1_n)
EX_RDY_N
(hrdy)
Tdata_hold
Tdata_setup
EX_DATA
(hdin)
Data
Data
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5.6.2.7.3
Using I/O Wait
The EX_IOWAIT_N signal is available to be shared by devices attached to chip selects 0
through 7, when configured in Intel or Motorola modes of operation. The main purpose
of this signal is to properly communicate with slower devices requiring more time to
respond during data access. During idle cycles, the board is responsible for ensuring
that EX_IOWAIT_N is pulled-up. The Expansion bus controller will always ignore
EX_IOWAIT_N for synchronous Intel mode writes.
For details, see the Intel® IXP45X and Intel® IXP46X Product Line of Network
Processors Developer’s Manual, in the Expansion Bus Controller chapter’s “Using I/O
Wait” section.
Figure 42.
I/O Wait Normal Phase Timing
T1=0 h T2=0 h
T3=2h or 1h or 0h
3 Cycles
T4=0 h T5=0 h
1 Cycle
1 Cycle
1 Cycle
1 Cycle
EX_CLK
2 Cycles
EX_CS_N[0]
EX_ADDR[23:0]
Valid Address
EX_IOWAIT_N
EX_RD_N
Valid Data
EX_DATA[15:0]
B5242-01
Note: Notice that the access is an Intel-style simplex read access. The data strobe phase is set to a value to last
three clock cycles. The data is returned from the peripheral device prior to the three clocks and the
peripheral device de-asserts EX_IOWAIT_N. The data strobe phase terminates after two clocks even though
the strobe phase was configured to pulse for three clocks.
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Figure 43.
I/O Wait Extended Phase Timing
T1=3 h T2=3 h
4 Cycles 4 Cycles
T3=F h
T4=3 h
4 Cycles
T5=F h
16 Cycles
16 Cycles
....
....
EX_CLK
2 Cycles
EX_CS_N[0]
EX_ADDR[23:0]
Valid Address
EX_IOWAIT_N
EX_RD_N
Valid Data
EX_DATA[15:0]
B5243-01
5.6.2.8
Serial Peripheral Port Interface Timing
Figure 44.
Serial Peripheral Interface Timing
TOV
SSPEXTCLK
SSPSCLK
TIS
TDOH
TIH
SSPINPUTS
TDOV
SSPOUTPUTS
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Table 77.
Serial Peripheral Port Interface Timing Values
Symbol
Parameter
Min.
Max.
Units Notes
Minimum and maximum clock periods which can
be produced by the SSP_SCLK when the clock is
being generated from the internal 3.7033MHz
clock.
T
T
.0072
1.8432
MHz
PER_INTCLK
Minimum and maximum clock period which can be
produced by the SSP_SCLK when the clock is being
generated from the externally supplied maximum
clock rate of 33 MHz clock (SSP_EXTCLK).
.06445
16.5
MHz
PER_EXTCLK
Input Setup time for data prior to the valid edge of
SSP_SCLK. These signals include SSP_SRXD.
TIS
TIH
15
0
ns
ns
Input hold time for data after the to the valid edge
of SSP_SCLK. These signals include SSP_SRXD.
SSP_SCLK clock to output valid delay from output
signals. These signals include SSP_STXD and
SSP_SFRM.
TDOV
1
6
ns
Output data hold valid from valid edge of
SSP_SCLK. These signals include SSP_STXD and
SSP_SFRM.
TDOH
TOV
1
2
ns
ns
Output Valid Delay from SSP_EXTCLK to SSP_SCLK
in external clock mode
15
1.
2.
Timing was designed for a system load between 5pF and 40pF
Clock jitter on the SSPSCLK is designed to be an average of the specified clock frequency. The
SSPSCLK jitter specification is unspecified.
5.6.2.9
I2C Interface Timing
I2C Interface Timing
Figure 45.
I2C_SDA
TBUF
TSF
TLOW
THDSTA
TSP
TSR
I2C_SCL
THDDAT
TSUSTO
TSUSTA
THDSTA
THIIGH
Stop
Stop
Start
Repeated
Start
TSUDAT
Table 78.
I2C Interface Timing Values (Sheet 1 of 2)
Symbol
Parameter
SCL Clock Frequency
Min.
Max.
Min.
Max.
Units
Notes
FSCL
TBUF
0
100
0
400
KHz
Bus Free Time Between STOP and START
Condition
4.7
1.3
μs
THDSTA
TLOW
Hold Time (repeated) START Condition
SCL Clock Low Time
4
4.7
4
0.6
1.3
0.6
0.6
0
μs
μs
μs
μs
μs
ns
2
1
1
THIGH
SCL Clock High Time
TSUSTA
THDDAT
TSUDAT
Setup Time for a Repeated START Condition
Data Hold Time
4.7
0
3.45
0.9
Data Setup Time
250
100
Notes:
1.
2.
3.
Not tested
After this period, the first clock pulse is generated
Cb = capacitance of one bus line in pF.
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Table 78.
I2C Interface Timing Values (Sheet 2 of 2)
Symbol
Parameter
SCL and SDA Rise Time
Min.
Max.
Min.
Max.
Units
Notes
TSR
1000
300
20+0.1Cb
20+0.1Cb
0.6
300
300
ns
ns
μs
3
3
TSF
SCL and SDA Fall Time
TSUSTO
Setup Time for STOP Condition
4
Notes:
1.
2.
3.
Not tested
After this period, the first clock pulse is generated
Cb = capacitance of one bus line in pF.
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5.6.2.10
High-Speed, Serial Interfaces
Figure 46.
High-Speed, Serial Timings
T2
T4
T9
T1
T3
As Inputs:
hss_txclk/
hss_rxclk1
hss_(tx or rx)frame
(Positive edge)
hss_(tx or rx)frame
(Negative edge)
hss_ rxdata
(Positive edge)
Valid Data
hss_ rxdata
(Negative edge)
Valid Data
T5
T6
T7
T8
As Outputs:
hss_(tx or rx)frame
(Positive edge)
hss_(tx or rx)frame
(Negative edge)
hss_ txdata
(Positive edge)
Valid Data
hss_ txdata
(Negative edge)
Valid Data
A9594-01
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Table 79.
High-Speed, Serial Timing Values
Symbol
Parameter
Min.
Max.
Units Notes
Setup time of HSS_TXFRAME, HSS_RXFRAME, and
HSS_RXDATA prior to the rising edge of clock
T1
T2
T3
T4
T5
T6
T7
5
ns
ns
ns
ns
ns
ns
ns
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
1, 4
Hold time of HSS_TXFRAME, HSS_RXFRAME, and
HSS_RXDATA after the rising edge of clock
0
5
0
Setup time of HSS_TXFRAME, HSS_RXFRAME, and
HSS_RXDATA prior to the falling edge of clock
Hold time of HSS_TXFRAME, HSS_RXFRAME, and
HSS_RXDATA after the falling edge of clock
Rising edge of clock to output delay for HSS_TXFRAME,
HSS_RXFRAME, and HSS_TXDATA
15
15
Falling edge of clock to output delay for HSS_TXFRAME,
HSS_RXFRAME, and HSS_TXDATA
1, 3, 4
1, 3, 4
Output Hold Delay after rising edge of final clock for
HSS_TXFRAME, HSS_RXFRAME, and HSS_TXDATA
0
0
Output Hold Delay after falling edge of final clock for
HSS_TXFRAME, HSS_RXFRAME, and HSS_TXDATA
T8
T9
ns
ns
1, 3, 4
5
HSS_TXCLK period and HSS_RXCLK period
1/8.192 MHz 1/512 KHz
Notes:
1.
HSS_TXCLK and HSS_RXCLK may be coming from external independent sources or being driven by the
IXP45X/IXP46X network processors. The signals are shown to be synchronous for illustrative purposes and
are not required to be synchronous.
2.
3.
Applicable when the HSS_RXFRAME and HSS_TXFRAME signals are being driven by an external source as
inputs into the IXP45X/IXP46X network processors. Always applicable to HSS_RXDATA.
The HSS_RXFRAME and HSS_TXFRAME can be configured to accept data on the rising or falling edge of the
given reference clock. HSS_RXFRAME and HSS_RXDATA signals are synchronous to HSS_RXCLK and
HSS_TXFRAME and HSS_TXDATA signals are synchronous to the HSS_TXCLK.
4.
5.
Applicable when the HSS_RXFRAME and HSS_TXFRAME signals are being driven by the IXP45X/IXP46X
network processors to an external source. Always applicable to HSS_TXDATA.
The HSS_TXCLK can be configured to be driven by an external source or be driven by the IXP45X/IXP46X
network processors. The slowest clock speed that can be accepted or driven is 512 KHz. The maximum
clock speed that can be accepted or driven is 8.192 MHz. The clock duty cycle accepted will be 50/50 +
20%.
6.
Timing was designed for a system load between 5 pF and 30 pF for high drive setting
5.6.2.11
JTAG
Figure 47.
Boundary-Scan General Timings
T
T
bsch
bsel
JTG_TCK
JTG_TMS, JTG_TDI
T
bsis
T
bsih
JTG_TDO
T
bsoh
T
bsod
B0416-01
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Figure 48.
Boundary-Scan Reset Timings
JTG_TRST_N
JTG_TMS
T
bsr
T
T
bsrs bsrh
A9597-01
Table 80.
Boundary-Scan Interface Timings Values
Symbol
Parameter
JTG_TCK low time
Conditions
Min.
Typ.
Max.
Units Notes
T
50
50
ns
ns
2
2
bscl
T
JTG_TCK high time
bsch
JTG_TDI, JTG_TMS setup time to
rising edge of JTG_TCK
T
10
10
ns
ns
ns
bsis
bsih
bsoh
bsod
JTG_TDI, JTG_TMS hold time from
rising edge of JTG_TCK
T
JTG_TDO hold time after falling
edge of JTG_TCK
T
T
1.5
1
1
JTG_TDO clock to output from
falling edge of JTG_TCK
40
ns
ns
ns
T
JTG_TRST_N reset period
30
10
bsr
JTG_TMS setup time to rising edge
of JTG_TRST_N
T
bsrs
JTG_TMS hold time from rising
edge of JTG_TRST_N
T
10
ns
bsrh
Notes:
1.
2.
Tests completed with a 40-pF load to ground on JTAG_TDO.
JTG_TCK may be stopped indefinitely in either the low or high phase.
5.6.3
Reset Timings
The IXP45X/IXP46X network processors can be reset in any of the following three
modes:
• Cold Reset
• Warm Reset
• Soft Reset.
Normally, a Cold Reset is executed each time power is initially applied to the board, a
Warm Reset is executed when it is only intended to reset the IXP45X/IXP46X network
processors, and a Soft Reset is executed by the watchdog timer.
5.6.3.1
Cold Reset
A Cold Reset condition is when the network processor is initially powered-up and has
successfully come out of the Reset. During this state all internal modules and registers
are set to the initial default state. To successfully come out of reset, two things must
occur:
• Proper power sequence as described in Section 5.7
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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• Followed by proper resetting of PWRON_RST_N and RESET_IN_N signals as
described in Section 5.6.3.4, “Reset Timings” on page 146
The following procedural sequence must be followed to achieve a successful cold reset:
1. VCC and VCC33 power supplies must reach steady state
2. Hold PWRON_RST_N and RESET_IN_N asserted for 2000nSec
3. De-assert PWRON_RST_N (signal goes high with the help of a pull-up resistor)
4. Continue to hold RESET_IN_N asserted for at least 10nSec more after releasing
PWRON_RST_N
5. De-assert RESET_IN_N (signal goes high with the help of a pull-up resistor)
6. The network processor asserts PLL_LOCK indicating that the processor has
successfully come out of Reset
5.6.3.2
Hardware Warm Reset
A Hardware Warm Reset can only be asserted when PWRON_RST_N is de-asserted and
the network processor is in a normal operating mode. A Hardware Warm Reset is
initiated by the assertion of RESET_IN_N. During this state, all internal registers and
modules are set to their initial default state except for the PLL internal modules. Since
the PLL modules are not reset, the Reset sequence is executed much faster by the
processor.
The following procedural sequence must be followed to achieve a successful Warm
Reset:
1. The system must have previously completed a Cold Reset successfully.
2. PWRON_RST_N must be de-asserted (held high for the entire process).
3. Hold RESET_IN_N asserted for 500nSec.
4. De-assert RESET_IN_N (signal goes high with the help of a pull-up resistor)
5. The network processor asserts PLL_LOCK indicating that the processor has
successfully come out of reset.
5.6.3.3
Soft Reset
A Soft Reset condition is accomplished by the usage of the hardware Watch-Dog Timer
module, and software to manage and perform counter updates. For a complete
description of Watch-Dog Timer functionality, refer to Watchdog Timer Operation sub-
section in the Operating System Timer Chapter of the Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors Developer’s Manual.
The Soft Reset is similar to what is described in Section 5.6.3.2. The main difference is
that there is no hardware requirement; everything is done within the network
processor and software support. That is why it is also referred to as a Soft Warm Reset.
Since Hardware Warm Reset and Soft Reset are very similar, there must be a way to
determine which reset was last executed after recovering. This is done by reading the
Timer Status Register bit 4 (Warm Reset). If this bit was last set to 1, it will indicate
that a Soft Reset was executed, and if the bit was last reset to 0, then it will indicate
that the processor has just come out of either a Hardware Warm Reset or a Cold Reset.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
5.6.3.4
Reset Timings
Reset Timings
Figure 49.
VCCP
VCCM
VCC
PLL_LOCK
PWRON_RESET_N
RESET_IN_N
CFG Settings To Be Captured
CFG Settings To Be Captured
EX_ADDR[24:0]
IXP46X Drives Outputs
EX_ADDR[24:0]-Pull Up/Down
TEX_ADDR_HOLD
TRELEASE_RST_N
TPLL_LOCK
TRELEASE_PWRON_RST_N
TEX_ADDR_SETUP
Table 81.
Reset Timings Table Parameters
Symbol
Parameter
Min.
Typ.
Max.
Units
Note
Minimum time required to hold the PWON_RST_N at logic 0
state after stable power has been applied to the IXP45X/
IXP46X network processors.
T
T
2000
ns
1
RELEASE_PWRON_RST_N
RELEASE_RESET_IN_N
Minimum time required to hold the RESET_IN_N at logic 0
state after PWRON_RST_N has been released to a logic 1
state. The RESET_IN_N signal must be held low when the
PWRON_RST_N signal is held low.
10
ns
Maximum time for PLL_LOCK signal to drive to logic 1 after
RESET_IN_N is driven to logic 1 state. The boot sequence
does not occur until this period is complete.
T
T
T
10
20
µs
ns
ns
PLL_LOCK
Minimum time for the EX_ADDR signals to drive the inputs
prior to RESET_IN_N being driven to logic 1 state. This is
used for sampling configuration information.
50
0
2
2
EX_ADDR_SETUP
EX_ADDR_HOLD
Minimum/maximum time for the EX_ADDR signals to drive
the inputs prior to PLL_LOCK being driven to logic 1 state.
This is used for sampling configuration information.
Minimum time required to drive RESET_IN_N signal to logic
0 in order to cause a Warm Reset in the IXP45X/IXP46X
network processors. During this period, the power supply
must not be disturbed and PWRON_RST_N signal must
remain at logic high during the entire process.
T
500
ns
WARM_RESET
Notes:
1.
2.
T
is the time required for the internal oscillator to reach stability.
RELEASE_PWRON_RST_N
The expansion bus address is captured as a derivative of the RESET_IN_N signal going high. When a programmable-logic
device is used to drive the EX_ADDR signals instead of pull-downs, the signals must be active until PLL_LOCK is active.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Datasheet—Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
5.7
Power Sequence
The 3.3-V I/O voltage (VCCP) and the 2.5-V I/O voltage (VCCM) must be powered up at
least 1 µs before the processor voltage (VCC). The IXP45X/IXP46X network processors
voltage (VCC) must never become stable prior to the 3.3-V I/O voltage (VCCP) or the
2.5-V I/O voltage (VCCM).
Sequencing between VCCP and VCCM can occur in any order with respect to one another.
TIO_PHASE can be:
• VCCP prior to VCCM
• VCCM prior to VCCP
• VCCP simultaneously to VCCM
The VCCOSC, VCCPLL1, VCCPLL2, and VCCPLL3 voltages follow the VCC power-up pattern.
The VCCOSCP follows the VCCP power-up pattern.
The value for TPOWER_UP must be at least 1 µs after the later of VCCP and VCCM reaching
stable power. The TPOWER_UP timing parameter is measured between the later of the I/
O power rails (VCCP at 3.3 V or VCCM at 2.5 V) and VCC at 1.3 V.
Figure 50.
Power-up Sequence Timing
VCCP
VCC
VCCM
TIO_PHASE TPOWER_UP
4
3
2
1
TIME
5.8
Power Dissipation
The Intel® IXP45X and Intel® IXP46X Product Line of Network Processors were tested
assuming a typical worst case networking application under a tester environment. The
following power assessments in Table 82 assume this typical worst case networking
application using the interface activity factors listed in Table 83. The actual power may
vary if interface activity factors are different from Table 83. If applications do not
require use of certain peripherals or if interfaces operate at lower activity factors, then
the power required by the part may be significantly less than the numbers stated in
Table 82.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
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Intel® IXP45X and Intel® IXP46X Product Line of Network Processors—Datasheet
Table 82.
Power Dissipation Values
Power Per
Rail
(mW)†
Maximum Power
Dissipation
(Watts)
I
CC_TOTAL
(mA)
Part Type
Power Rail
3.3 V
2.5 V
1.3 V
3.3 V
2.5 V
1.3 V
3.3 V
2.5 V
1.3 V
3.3 V
2.5 V
1.5 V
88
255
1335
88
305
669
Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors—
266 MHz
2.8
3.0
3.2
4.0
1822
305
Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors —
400 MHz
255
1485
88
669
2027
305
Intel® IXP45X and Intel® IXP46X
Product Line of Network Processors —
533 MHz
255
1630
88
669
2225
305
Intel® IXP46X Product Line — 667 MHz
255
1920
669
3024
Notes:
1.
2.
3.
I
I
I
for 3.3V includes total current for V
and V
CCP OSC_VCCP
CC_TOTAL
CC_TOTAL
CC_TOTAL
for 2.5V includes total current for V
CCM
for 1.3V includes total current for V , V
, V
, V
and V
CCPLL2, CCPLL3
CC
OSC_VCCP
CCPLL1
† Power in mW is calculated using Maximum Vcc specification for each power rail.
Activity factor is directly proportional to the overall power consumption where each
application will have a different activity factor and different power conclusion. Table 83
illustrates the activity factor of each interface on the tester during the typical worst
case networking application.
Table 83.
Power Dissipation Test Conditions
DDR
(data/addr)
PCI
(addr/cntl)
EXP
(data/cntl)
Ethernet
(data)
UTOPIA
(data)
Interface
Activity
Factor
15% / 6%
16% / 10%
5% / 3.7%
20%
17%
Notes:
1.
2.
3.
4.
All output clocks toggling at their specified rate.
Tester did not include termination resistors on any interface for power analysis.
Tester measures power at 85 degrees C Ambient.
Intel XScale® Processor tested running DSP software.
5.9
Ordering Information
For ordering information, please contact your local Intel sales representative.
Please refer to the following tables for the part number list:
• Table 6 on page 41 for Intel® IXP46X Product Line of Network Processors.
• Table 7 on page 42 for Intel® IXP45X Product Line of Network Processors.
Intel® IXP45X and Intel® IXP46X Product Line of Network Processors
Datasheet
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Document Number: 306261-004US
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