Intel US15W user manual Uart Connector, H8 Programming Jumpers, Jtag

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Reference Board Summary

Table 14. H8 Programming Jumpers

#

Jumper

Reference

Default Stuffing Option

Programming Stuffing Option

 

 

Designator

 

 

 

 

 

 

 

 

Remote H8

 

1-2 – normal operation

1-x – link the Host Unit to On Board H8

1

Programming

J8D4

Remove Power Supply from the

(Default)

 

(BB_PROG)

 

system.

 

 

 

 

 

 

 

 

 

Remote H8

J8E1

 

 

2

Programming

1-X (Open)

1-2 (Short) – to program H8

J8E4

 

(JTAG)

 

 

 

 

 

 

 

 

 

 

 

4.10UART Connector

UART functionality is added to the Intel® SCH SKU. Use connector J9G6 for UART connectivity.

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User’s Manual

38

Document Number: 320264

Image 38
Contents User’s Manual July Document # RevisionUser’s Manual Document Number Contents Power Up Figures TablesInitial release Revision HistoryDocument Revision Description Release for public postingIntroduction About the Development KitTerminology Term DefinitionTechnical Support Additional Technical SupportIntel Literature Centers Product LiteratureRelated Documents Related DocumentsCrown Beach Board Block Diagram Crown Beach BoardGetting Started Crown Beach Board Top ViewFeature Crown Beach Board Comments Implementation Major FeaturesCrown Beach Feature Set Summary OverviewSDIO/MMC SMC/KBC Processor SupportProcessor Voltage Regulators System Memory Subsystem DescriptionsIntel SCH Chipset DisplaySoft Audio/Soft Modem Manufacturer Size Resolution Back Aspect Part#PCI Express* Slots Crown Beach Supported Lvds DisplaysLPC Slot USB ConnectorsPata Storage System Management Controller SMC/Keyboard Controller KBC12 SD/SDIO/MMC EFI Firmware Hub FWHTrusted Platform Module TPM Header ClocksBoard Size Power Supply SolutionIn-Target Probe ITP and Debug Support Board TechnologyPower Measurement Resistor Power ManagementPower Measurement Support EquationSch Component Voltage Supply Rail Ref Des Resistor Crown Beach Voltage RailsAgilent 34401A 6½ digit Lvdsbcklt DDR2VRLvdsddc LvdsvdlKeyboard Vcore +V12SCPU+V12S Reference Board Summary Crown Beach Board FeaturesConnectors Back Panel Connectors Ref Des DescriptionConfiguration Settings Configuration Jumpers/SwitchesConfiguration Jumper/Switches Settings BbprogPSON# Manual VID Support for CPU Bsel Jumper SettingsBsel Jumper Settings ProcessorPower On and Reset Push Buttons Crown Beach Manual VIDFunction Reference Designator LEDsCrown Beach LEDs PCI Express* Slot 1 Board Rework to Enable Functionality PCI Express* X1 Slots and Mini Card ConnectorsMini Card a connector J7H1 is enabled by default Rework Impacted components CommentsH8S Jtag Programming Headers Mini Card B connector J2G1 is disabled by defaultMini Card B Board Rework to Enable Functionality 1 H8 In-System ProgrammingReference Board Summary Jtag Uart ConnectorH8 Programming Jumpers Quick Start Required PeripheralsGraphics Assembly Lvds Panel Samsung 15 inch 381.00 mm PanelCrown Beach Board Lvds Cable Connected to the Crown Beach Board Power Up Powering Up the Board EFI Firmware Updates Appendix a Daughter and Plug-In Cards Mott Canyon 4 Interposer CardJumper Settings Mott Canyon 4 Interposer CardMott Canyon 4 Interposer Card Configuration Jumper/Switches Description Default Setting Optional Setting ReferenceFirmware Configuration Appendix B Intel MVP-6 VID Codes Voltage Identification DefinitionVID6 VID5 VID4 VID3 VID2 VID1 VID0 VCC 5625 Appendix C External Features External Feature Location Front of ChassisExternal Feature Location Rear of Chassis Rear Chassis View with Board Installed

US15W specifications

The Intel US15W is an embedded chipset designed to meet the demands of ultra-low power computing environments. Released in 2008, this chipset was aimed at small form-factor devices such as netbooks, thin clients, and embedded systems. With its unique blend of features, the US15W has played a crucial role in the evolution of low-power computing technologies.

One of the standout characteristics of the US15W chipset is its integration of a single-chip design, which significantly reduces the overall footprint of the system. This is particularly advantageous for manufacturers looking to create compact devices without compromising on performance. The chipset integrates the Intel Atom processor, which is known for its efficient power consumption and solid performance for lightweight applications. The combination provides a balance between energy efficiency and processing capability, making it suitable for various applications ranging from internet browsing to multimedia playback.

Another major feature of the Intel US15W is its support for Intel's Graphics Media Accelerator 500, which enhances visual performance by providing hardware acceleration for graphics rendering. This capability enables smoother video playback and improved graphical user interfaces, which are essential for user-centric devices.

The US15W chipset also supports various connectivity options, including USB 2.0 and Serial ATA (SATA) interfaces. This flexibility allows for ease in peripheral connectivity and storage solutions, accommodating the needs of embedded applications and consumer electronics alike. Moreover, the chipset supports Intel's Enhanced SpeedStep technology, a power management feature that adjusts processor voltage and frequency based on workload, helping to extend battery life in portable devices.

In terms of memory support, the Intel US15W can handle up to 2GB of DDR2 RAM, which is adequate for many embedded computing tasks. The chipset is designed to facilitate efficient thermal management, which is crucial in maintaining long-lasting performance in compact and thermally constrained environments.

Overall, the Intel US15W chipset exemplifies the shift towards energy-efficient, compact computing solutions. Its innovative integration of features, support for modern graphics, and robust connectivity options make it a significant player in the embedded chipset market. As technology continues to evolve, the US15W remains a testament to Intel's commitment to providing high-performance solutions that meet the demands of modern computing without sacrificing power efficiency.