Intel KEMX-2030 user manual „ Preventing Electrostatic Discharge

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Safety Instructions

3.Follow the guidelines provided in “Preventing Electrostatic Discharge” on the following page.

4.Disconnect any telephone or telecommunications lines from the computer.

In addition, take note of these safety guidelines when appropriate:

„To help avoid possible damage to system boards, wait five seconds after turning off the computer before removing a component, removing a system board, or disconnecting a peripheral device from the computer.

„When you disconnect a cable, pull on its connector or on its strain-relief loop, not on the cable itself. Some cables have a connector with locking tabs. If you are disconnecting this type of cable, press in on the locking tabs before disconnecting the cable. As you pull connectors apart, keep them evenly aligned to avoid bending any connector pins. Also, before connecting a cable, make sure both connectors are correctly oriented and aligned.

CAUTION

Do not attempt to service the system yourself except as explained in this user’s guide. Follow installation and troubleshooting instructions closely.

„Preventing Electrostatic Discharge

Static electricity can harm system boards. Perform service at an ESD workstation and follow proper ESD procedure to reduce the risk of damage to components. Quanmax strongly encourages you to follow proper ESD procedure, which can include wrist straps and smocks, when servicing equipment.

You can also take the following steps to prevent damage from electrostatic discharge (ESD):

„When unpacking a static-sensitive component from its shipping carton, do not remove the component’s antistatic packing material until you are ready to install the component in a computer. Just before unwrapping the antistatic packaging, be sure you are at an ESD workstation or grounded. This will discharge any static electricity that may have built up in your body.

„When transporting a sensitive component, first place it in an antistatic container

KEMX-2030 User’s Manual

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Contents KEMX-2030 Quanmax Inc. All rights reserved Revision Date Edited by ChangesContent Content Figures Tables Tables „ Before You Begin „ When Working Inside a Computer„ Preventing Electrostatic Discharge Safety Instructions „ Unpacking „ How to Use This Guide„ Regulatory Compliance Statements FCC Compliance Statement for Class a Devices„ Warranty Policy Limited WarrantyReturn Procedure „ Maintaining Your Computer „ TemperatureLimitation of Liability Environmental Factors„ Uninterruptible Power Supply Power Protection„ Altitude „ Surge ProtectorPreface Features ChecklistIntroduction „ OverviewBios „ Product SpecificationsBlock Diagram „ System Block DiagramMechanical Dimensions „ Mechanical DimensionsJumpers Hardware SettingsCN10 „ Jumper Settings and Pin DefinitionsJumper Setting Status FunctionJumper Status Jumper Setting Function Signal Name Pin Signal NameLabel Function DCD, Data carrier detect Pin SignalRXD, Receive data TXD, Transmit dataPin Signal Function Main Board Pin Assignments MIC2-L HDD LED + Signal Name Pin Signal PinDREQ0 GND IDEIOW# IDEIOR# Ideiordy Cbsel USB4 USB5 USB4+ USB5+ GND KEY Pcie slots IRDY# Comments Pitch2.54mm Yimtex 32526SAG1R6T System Installation „ Memory Module Installation„ Expansive Interfaces Align the SO-DIMM Memory Module with the onboard socket Removing a DimmAMI Bios Setup IDE Device Setting Menu Bios Main MenuLBA/ Large Mode Auto „ Main MenuDMA Mode LBA/ Large Mode„ Advanced Menu System InformationCOM4 Mode COM3 ModeParallel Port Mode COM1 AddressUSB Controller Parallel Port IRQUSB Device Legacy Support Audio ControllerCPU Shutdown Temperature CPU Warning TemperatureHardware Health Configuration Trusted ComputingQuick Boot „ Boot MenuBootup Num-Lock On Wait for ‘F1’ If Error EnabledInternal Graphics Mode Select Boots Graphic Adapter Priority„ Chipset Menu Dram FrequencyDvmt Mode Select „ Video Function ConfigurationBoot Display Device DVMT/FIXED Memory„ Power Menu Change User Password Change Supervisor PasswordSecurity Menu Security Menu„ Exit Menu Load Optimal DefaultsSave Changes and Exit Discard Changes and ExitLoad Failsafe Defaults Driver Installation Interrupt Request IRQ Lines System ResourcesMemory Mapping DMA ChannelsPCI Devices PCI Express DevicesHardware Monitor Parameters PS/2 P OSDIO Digital I/O KIT User Guide How to install the test programAppendix B Appendix B CN3 to DIO Program look up table How to run the test programHow to uninstall the test program

KEMX-2030 specifications

The Intel KEMX-2030 is a cutting-edge processor designed to push the boundaries of performance and efficiency in computing applications. This innovative chip integrates advanced technologies that cater to a variety of users, from gamers to data scientists, ensuring that it meets the demands of modern workloads.

At the heart of the KEMX-2030 is Intel's latest microarchitecture, which enhances instruction execution and optimizes power consumption. This microarchitecture employs a combination of high-performance cores and energy-efficient cores, allowing for dynamic scaling based on workload requirements. This enables the KEMX-2030 to deliver exceptional performance while maintaining energy efficiency, a crucial factor in today's environmentally conscious world.

One of the standout features of the KEMX-2030 is its support for Intel's Hyper-Threading technology. This technology allows each core to handle two threads simultaneously, effectively doubling the number of tasks the processor can manage at once. As a result, users can experience improved multitasking and faster processing times, especially in applications that require heavy computations.

The KEMX-2030 also includes built-in artificial intelligence (AI) capabilities that facilitate real-time machine learning applications. With dedicated AI accelerators, the processor can efficiently execute complex algorithms, making it suitable for tasks such as image and speech recognition, natural language processing, and more. This integration of AI and machine learning technologies not only boosts productivity but also opens up new avenues for innovation across industries.

In terms of connectivity, the KEMX-2030 supports the latest standards, including Thunderbolt 4 and USB4. This enables high-speed data transfers and connectivity to a wide array of peripherals. Additionally, the processor is optimized for use in edge computing environments, making it an ideal choice for IoT applications that require quick and reliable data processing at the source.

Thermal management is another critical aspect of the KEMX-2030's design. The processor utilizes advanced thermal throttling techniques to regulate temperature effectively during intensive tasks. This ensures stable performance without the risk of overheating, prolonging the lifespan of the hardware.

In summary, the Intel KEMX-2030 represents a significant advancement in processor technology. With its high-performance capabilities, energy-efficient design, and robust support for AI and connectivity, it is poised to become a preferred choice for a wide range of computing applications, driving innovation and efficiency in various fields.