Intel TE430VX manual Battery Marking, Overload Protection

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Motherboard Description

1.15.4.6Battery Marking

There is insufficient space on this board product to provide the required replacement and disposal instructions for the battery. The following marking must be placed permanently and legibly on the host system as near as possible to the battery:

CAUTION

Danger of explosion if battery is incorrectly replaced

Replace with only the same or equivalent type recommended by the manufacturer. Dispose of used batteries according to the manufacturer’s instructions.

1.15.4.7Overload Protection:

Unless the power supply is provided with inherent overcurrent protection, use caution to avoid overloading the power supply output. This can be accomplished by assuring that the calculated total current load of all the modules within the system is less than the output current rating of the power supply. Failure to accomplish this could result in overheating in the power supply, which could result in a fire or could cause damage to insulation separating hazardous AC line circuitry from low-voltage user accessible circuitry. If the load drawn by a particular module cannot be determined by the markings and instructions supplied with the module, contact the module supplier’s technical support organization.

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Contents TE430VX Date RevisionRevision History Table of Contents Motherboard Resources TE430VX Motherboard Technical Product SpecificationContents Motherboard Bios and Setup UtilityError Messages and Beep Codes Page Overview Motherboard DescriptionTigereye board diagram Motherboard Description Motherboard Manufacturing OptionsForm Factor System Memory Microprocessor UpgradeMicroprocessor Memory1 82430VX System Controller TVX ChipsetSdram Second Level CachePCI ISA/IDE Xcelerator PIIX3 2 82430VX Data Path TDXKeyboard and mouse interface Real time clock, Cmos RAM and batteryUltra I/O Interface Controller SMC FDC37C93FR Floppy controllerParallel port Graphics Subsystem S3 Trio64V+IrDA infra-red support Consumer IR SupportGraphics Drivers and Utilities Resolutions supportedGraphics Resolutions Audio Subsystem Creative Labs Vibra 16CAudio Drivers Vibra 16C resource mapMotherboard Connector Locations Motherboard ConnectorsPower Connector J7M2 CD-ROM Connector J2F2Wave Table Connector J2F3 Telephony Connector J2F1Motherboard Description Signal Name Floppy Drive Connector J10H1IDE Connectors J9H1, J9H2 IDE Connectors J9H1, J9H2 Front Panel I/O Connectors J9E2ISA Connectors- J1A1, J1A2, J1B1 Pin PCI Connectors J2C1, J2D1, J2E1, J2E2ISA Connectors Signal Name PinPCI Connectors J2C1, J2D1, J2E1, J2E2 Power Supply ConnectorsSpeaker Front panel ConnectorsHD LED ResetSleep or Power LED Infra-Red IrDA connectorBack Panel Connectors Remote ON/OFF and Soft Power SupportO Connections Add-in Board Expansion ConnectorsJumper Jumper SettingsConfiguration FunctionCmos Setup Access J9C1-B, Pins 1,2,3 CPU Configuration J9C1-C, DClear Cmos J9C1-A, Pins 4,5,6 Password clear J9C1-A, Pins 1,2,3Environmental Bios Recovery J7A1Motherboard Environmental Specifications ReliabilityRegulatory Compliance Power Consumption15.2.3 EN 50 082-1 ICES-003, Issue15.2 EMI Cispr 22, 2nd Edition 15.2.2 EN 55 022Assure Host System Compatibility Installation RequirementsFollow Installation Instructions Canadian ComplianceInstallation Precautions Assure Host System & Accessory CertificationsOverload Protection Battery MarkingPage O Map Memory MapI/O Map Memory MapAddress hex Size DMA Channels PCI Configuration Space MapPCI Configuration Space Map Soft-Off ControlInterrupts InterruptsSystem Address Bios Flash Memory OrganizationIntroduction Flash Memory OrganizationPrimary Cable Bios UpgradesRecommendations for Configuring an Atapi Device PCI IDE SupportISA Plug and Play PCI Auto-configurationMotherboard Bios and Setup Utility Language Support Advanced Power ManagementBoot Options Flash Logo Area Setup Enable JumperBios Setup Program Overview of the Setup Menu ScreensFloppy Options Main Bios Setup ScreenSystem Date System TimeSecondary Master Boot OptionsVideo Mode Primary SlaveFloppy B Type Floppy AccessIDE Device Configuration Subscreen Floppy a TypeFirst, Second, Third, Fourth Boot Device IDE Translation ModeMultiple Sector Setting Boot Options SubscreenTypematic Rate Programming Setup PromptTypematic Rate Delay Num LockPlug and Play Configuration Peripheral ConfigurationAdvanced Chipset Configuration Power Management ConfigurationParallel Port Address Serial Port 2 IR ModeParallel Port Mode Advanced Chipset Configuration SubscreenIDE Drive Power Down Latency Timer PCI ClocksPower Management Configuration Subscreen Advanced Power ManagementISA Shared Memory Base Address Plug and Play Configuration SubscreenBoot with PnP OS ISA Shared Memory SizeSecurity Screen Administrative and User Access ModesAdministrative and User Password Functions Password SetSet Administrative Password Security Screen Options User Password isAdministrative Password is Set User PasswordDiscard Changes Load Setup DefaultsPage Beeps Error Message Bios Beep CodesPCI Configuration Error Messages Explanation Bios Error MessagesError Message ISA NMI Message Explanation Bios Error MessagesError Messages and Beep Codes ISA NMI Messages

TE430VX specifications

The Intel TE430VX was a landmark product in the realm of computing during the early 1990s. This microprocessor, part of Intel's line of Pentium processors, was primarily aimed at the burgeoning market for personal and business computing.

One of the main features of the Intel TE430VX was its 32-bit architecture, which allowed for a significant increase in processing power compared to its predecessors. The 32-bit data bus enabled the handling of larger amounts of data simultaneously, enhancing overall system performance. The TE430VX was capable of executing instructions at clock speeds ranging from 60 MHz to 66 MHz, which was quite impressive for its time. This processing power made it suitable not only for everyday computing tasks but also for more demanding applications such as graphic design and gaming.

The TE430VX also incorporated advanced technologies such as pipelining, which allowed it to execute multiple instructions in a single clock cycle. This feature contributed to improved performance and responsiveness, making the user experience smoother. The microprocessor supported a variety of RAM types, including EDO (Extended Data Out) RAM, which further enhanced its performance by reducing memory access times.

Another characteristic that set the TE430VX apart was its compatibility with a wide range of operating systems, including DOS, Windows, and various UNIX variants. This flexibility ensured that users could run their preferred software without compatibility issues, making it a versatile choice for home and business environments alike.

The integration of a built-in memory controller also simplified motherboard design, reducing the overall cost of systems utilizing the TE430VX. This chip also supported advanced graphics options, allowing users to experience better multimedia performance through dedicated graphics cards.

Power consumption was another consideration in the design of the TE430VX. It was engineered to operate efficiently while maintaining good performance, an important factor for long-term sustainability in computing environments.

In summary, the Intel TE430VX was a significant advancement in microprocessor technology during the early 1990s. Its 32-bit architecture, pipelining capabilities, compatibility with multiple operating systems, and efficient power consumption contributed to its reputation as a reliable choice for both personal and professional use, solidifying Intel's position as a leader in the computing landscape.