Intel 440GX manual USB Interface, IDE Interface, Non-PIIX4E IDE

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Design Checklist

3.11USB Interface

Contact your local Intel Field Sales representative for the following Application Note: 82371AB PIIX4 Application Note #1: USB Design Guide And Checklist Rev 1.1. This document discusses details of the PIIX4/PIIX4E implementation of the Universal Serial Bus. Included in the discussion are motherboard layout guidelines, options for USB connector implementation, USB clocking guidelines and a design checklist.

The AGP OVRCNT# pin should be pulled up with a 330K ohm resistor to 3.3V on the motherboard to prevent this line from floating when there is no add-in card present.

3.12IDE Interface

Table 3-12. Non-PIIX4E IDE

Pin

Connection

 

 

Pin 28 of IDE connector (CSEL)

470 ohm pull-down.

 

 

Pin 19, 2, 22, 24, 26, 30, 40 of both ATA connectors

Tie to Ground.

 

 

Pin 20, 32, 34of both ATA connectors

Leave as a NC.

 

 

Support Cable Select(CSEL) is a PC97 requirement. The state of the cable select pin determines the master/slave configuration of the hard drive at the end of the cable.

Primary IDE connector uses IRQ14 and the secondary IDE connector uses IRQ15.

Layout - Proper operation of the IDE circuit depends on the total length of the IDE bus. The total signal length from the IDE drivers to the end of the IDE cables should not exceed 18”. Therefore, the PIIX4E should be located at close as possible to the ATA connectors to allow the IDE cable to be as long as possible.

Use ISA reset signal RSTDRV from PIIX4E through a Schmitt trigger for RESET# signals.

IDEACTP# and IDEACTS# each need a 10K ohm (approximate) pull-up resistor to Vcc.

There is no internal pull-up or down on PDD7 or SDD7 of the PIIX4E. The ATA3 specification recommends a 10K ohm pull-down resistor on DD7. Devices shall not have a pull-up resistor on DD7. It is recommended that a host have a 10K ohm pull-down resistor on PDD7 and SDD7 to allow the host to recognize the absence of a device at power-up. This pull- down resistor allows the BIOS to recognize the absence of an IDE slave device. Without this pull-down, some BIOSs may take up to 30 seconds to recognize that there is no slave device, or some BIOSs may hang the system.

If no IDE is implemented with the PIIX4E, the input signals (xDREQ and xIORDY) can be grounded, and the output signals left as no connects. Unused ports can be tri-stated using the General Configuration Register, address offset B0h–B3h, function 0.

Intel®440GX AGPset Design Guide

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Contents Intel 440GX AGPset Design GuideIntel440GX AGPset Design Guide Contents Dimm Solution With FET Switches System Bus Clock Layout 6.36.4 6.5PIIX4E Power And Ground Pins ISA and X-Bus SignalsThermals / Cooling Solutions 20.1 82371EB PIIX4EIntelPentiumII Processor LAI Issue FET Switches4 DIMM/FET DesignVoltage Regulator Control Silicon Intel440GX AGPset Platform Reference DesignExample ATX Placement for a UP Pentium II processor Example NLX Placement for a UP Intel Pentium II processorSolution Space for Single Processor Design Based on Results Solution Space for Single Processor Designs With Single-EndTables Intel Pentium II Processor and Intel 440GX AGPsetIntel Pentium II Processor and Intel 440GX AGPset 100 MHz Motherboard Model MAB12,11,90#, MAB14,13,10, 4 DIMMsRevision History Date Revision DescriptionIntel440GX AGPset Design Guide Introduction Page Introduction About This Design GuideReferences Intel Pentium II Processor / Intel 440GX AGPset Overview Intel Pentium II ProcessorIntel 440GX AGPset VCRSystem Bus Interface Dram InterfaceAccelerated Graphics Port Interface Wired for Management Initiative PCI-to-ISA/IDE Xcelerator PIIX4EPCI Interface System ClockingRemote Service Boot InstrumentationPower Management Design RecommendationsVoltage Definitions Remote Wake-UpGeneral Design Recommendations Introduction Motherboard Design Page Major Signal Sections 82443GX Top View BGA Quadrant AssignmentATX Form Factor Board Description NLX Form FactorFour Layer Board Stack-up Routing Guidelines 1 GTL+ Description 2 GTL+ Layout RecommendationsSingle Processor Design Single Processor Network Topology and ConditionsSingle Processor Recommended Trace Lengths Recommended Trace Lengths for Single Processor DesignTrace Minimum Length Maximum Length Dual Processor Systems Single Processor Systems-Single-End Termination SETDual Processor Network Topology and Conditions Dual Processor Recommended Trace LengthsSET Trace Length Requirements SET Trace Length RequirementsAdditional Guidelines Minimizing CrosstalkPractical Considerations Design Methodology Performance Requirements 12. GTL+ Design ProcessTopology Definition Pre-Layout Simulation Sensitivity AnalysisSimulation Methodology Recommended 100 MHz System Flight Time SpecsPlacement & Layout Post-Layout SimulationCrosstalk and the Multi-Bit Adjustment Factor ValidationFlight Time Measurement Signal Quality Measurement Edge Guideline @ Processor Edge Spec @ Processor CoreTiming Analysis Term Description10. Recommended 100 MHz System Timing Parameters 11. Recommended 100 MHz System Flight Time SpecsTiming Term Intel Pentium II Processor Intel 440GX AGPset Timing Term ValueAGP Connector Up Option Layout Guidelines ConnectorAGP Layout and Routing Guidelines 12. Data and Associated Strobe14. Control Signal Line Length Recommendations On-board AGP Compliant Device Down Option Layout Guidelines13. Source Synchronous Motherboard Recommendations WidthSpace Trace Line Length Line Length Matching16. Control Signal Line Length Recommendations Compliant 82443GX Graphics Data Routing Device15. Source Synchronous Motherboard Recommendations 82443GX Memory Subsystem Layout and Routing Guidelines 1 100 MHz 82443GX Memory Array ConsiderationsTo 82443GX MDs & MECCs To DIMM10 DQs To DIMM32 DQs Matching the Reference Planes Adding Additional Decoupling CapacitorRegister Register Data Control ClockMemory Layout & Routing Guidelines Trace Width vs. Trace Spacing18. FET Switch DQ Route Example Switch 16212 Dimm Module82443GX 0.6 0.4 0.6 0.4 Dimm Module 82443GX Dimm Module24. Motherboard Model-DQMB1,5, 4 DIMMs 19. Motherboard Model SRASB#, 4 DIMMs 20. Motherboard Model SCASA#, 4 DIMMs21. Motherboard Model SCASB#, 4 DIMMs 22. Motherboard Model WEA#, 4 DIMMs 23. Motherboard Model WEB#, 4 DIMMs24. Motherboard Model MAA140, 4 DIMMs 3 4 Dimm Routing Guidelines no FET PCI Bus Routing Guidelines25. Motherboard Model MAB12,11,90#, MAB14,13,10, 4 DIMMs VCC3Decoupling Guidelines Intel 440GX AGPset Platform Host Bridge Controller 492 BGAIntel 440GX AGPset Clock Layout Recommendations Clock Routing SpacingSystem Bus Clock Layout 014 018 ClockPCI Clock Layout Sdram Clock LayoutNet Trace Length Min Max Cap 440GX Ckbf DlkoAGP Clock Layout Net Trace Length Min Max Card TraceDesign Checklist Page Overview Pull-up and Pull-down Resistor ValuesIntel Pentium II Processor Checklist Slot Connectivity Sheet 1Processor Pin Pin Connection Slot Connectivity Sheet 2 GND & Power Pin Definition Slot Connectivity Sheet 3Vtt VCC3 Reserved NC Vcc Intel Pentium II Processor Signals Intel Pentium II Processor ClocksDesign Checklist Uni-Processor UP Slot 1 Checklist Dual-Processor DP Slot 1 ChecklistSlot 1 Decoupling Capacitors Voltage Regulator Module, VRMIntel 440GX AGPset Clocks 1 CK100 100 MHz Clock SynthesizerProcessor Frequency Select SEL100/66#Ckbf Sdram 1 to 18 Clock Buffer Gcke and Dclkwr Connection82443GX Host Bridge 1 82443GX InterfaceGX Connectivity Sheet 1 GX Connectivity Sheet 2 2 82443GX GTL+ Bus Interface 3 82443GX PCI InterfaceGX Connectivity Sheet 3 VTTA, VttbSignal Description Register Pulled to ‘0’ Pulled to ‘1’ 4 82443GX AGP InterfaceStrapping Options 82443GX Pins/Connection Dimm Pins Pin Function Intel 440GX AGPset Memory InterfaceSdram Connections Sdram ConnectivityDimm Solution With FET Switches Registered SdramSignal Names Connection 82371EB PIIX4EPIIX4E Connections PIIX4E Connectivity Sheet 1PIIX4E Connectivity Sheet 2 PIIX4E Connectivity Sheet 3 PIIX4E Connectivity Sheet 4 Signal Resistor IDE Routing GuidelinesCabling MotherboardReset# PDD150 PDA20Pin32,34 IDEPCI Bus Signals PIIX4E Power And Ground PinsPIIX4E PWR & GND ISA Signals ISA and X-Bus Signals10. Non-PIIX4E PCI Signals 11. Non-PIIX4E ISA SignalsUSB Interface IDE Interface12. Non-PIIX4E IDE Flash Design Dual-Footprint Flash DesignFlash Design Considerations PLCC32 to TSOP40 PLCC32 to PSOP44 PDIP32 to TDIP40XD70 13. Flash Vpp Recommendations Write ProtectionSystem and Test Signals Power Management SignalsVCC3 Power Button Implementation Miscellaneous 17 82093AA Ioapic 18.1 Max1617 Temperature Sensor Manageability Devices18.2 LM79 Microprocessor System Hardware Monitor 18.3 82558B LOM Checklist Pin Number Pin Name Resistor Value CommentRequired in both a and B stepping designs Software/BIOS USB and Multi-processor BiosWake On LAN WOL Header Thermals / Cooling Solutions MechanicalsDesign Considerations Electricals Layout Checklist Applications and Add-in HardwareRouting and Board Fabrication Design ConsiderationDebug Recommendations Page Slot 1 Test Tools Debug/Simulation ToolsLogic Analyzer Interface LAI In-Target Probe ITPDebug Features Intel Pentium II Processor LAI IssueBus Functional Model BFM 4 I/O Buffer Models150 330 ohm Kohm430 ohm 150 ohmDebug Logic Recommendations A20M# 150 330 ohmPICD0# 150 ohm PICD1# Debug Procedures Debug LayoutDebug Considerations Design ConsiderationsDebug Recommendations Third Party Vendors Page Slot 1 Connector ProcessorsGTL+ Bus Slot 1 Terminator Cards Supplier Contact PhoneVoltage Regulator Modules Voltage Regulator Control SiliconVoltage Regulator Modules Voltage Regulator Control Silicon VendorsPower Management Components FET Switches4 DIMM/FET DesignIntel 440GX AGPset Clock DriversOther Processor Components Reference Design Schematics Page Intel 440GX AGPset Platform Reference Design 82443GX Component System bus and Dram Interfaces VRM Power Connectors Front Panel Jumpers

440GX specifications

The Intel 440GX chipset was launched in 1997 as part of Intel's series of chipsets known as the 440 family, and it served as a critical component for various Pentium II and Pentium III-based motherboard architectures. Specifically designed for the second generation of Intel’s processors, the 440GX delivered enhanced performance and supported a range of important technologies that defined PC architectures of its time.

One of the main features of the Intel 440GX was its support for a 100 MHz front-side bus (FSB), which significantly improved data transfer rates between the CPU and the memory subsystem. This advancement allowed the 440GX to accommodate both the original Pentium II processors as well as the later Pentium III chips, providing compatibility and flexibility for system builders and consumers alike.

The 440GX chipset included an integrated AGP (Accelerated Graphics Port) controller, which supported AGP 2x speeds. This enabled high-performance graphics cards to be utilized effectively, delivering many enhanced graphics capabilities for gaming and multimedia applications. The AGP interface was crucial at the time as it offered a dedicated pathway for graphics data, increasing bandwidth compared to traditional PCI slots.

In terms of memory support, the 440GX could address up to 512 MB of SDRAM, allowing systems built with this chipset to run comfortably with sufficient memory for the era’s demanding applications. The memory controller was capable of supporting both single and double-sided DIMMs, which provided versatility in memory configuration for system builders.

Another notable feature of the Intel 440GX was its support for multi-processor configurations through its Dual Processors support feature. This allowed enterprise and workstation computers to leverage the performance advantages of multiple CPUs, making the chipset suitable for business and professional environments where multitasking and high-performance computing were essential.

On the connectivity front, the chipset supported up to six PCI slots, enhancing peripheral device integration and expansion capabilities. It also included integrated IDE controllers, facilitating connections for hard drives and CD-ROM devices.

Overall, the Intel 440GX chipset represented a balanced combination of performance, flexibility, and technology advancements for its time. Its introduction helped establish a foundation for subsequent advancements in PC technology and set the stage for more powerful computing systems in the years to come.
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