DETECTION MONITORING TECHNOLOGIES AIMSFS-05X AIMS FAST SCAN RADAR SYSTEM (AIMSFS-05X) User Manual MSM855 Detailed

DETECTION MONITORING TECHNOLOGIES, LLC (dba DMT, LLC) AIMS FAST SCAN RADAR SYSTEM (AIMSFS-05X) MSM855 Detailed

DETAILED TECHNICAL USER MANUAL FOR: PC/104 plus smartModule855 MSM855/HLV/B/B2 Nordstrasse 11/F CH - 4542 Luterbach Tel.: ++41 (0)32 681 58 00 Fax: ++41 (0)32 681 58 01 Email: support@digitallogic.com Homepage: http://www.digitallogic.com

$DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 2 For internal use only: File: MSM855_Detailed_V1.0A Path: R:\HANDBUCH\MSM\cpu_boards\MSM855\MSM855_Detailed_V1.0A.doc COPYRIGHT  2008 BY DIGITAL-LOGIC AG This publication is protected by copyright and all rights are reserved. No part of this document may be reproduced, transmitted, transcribed or stored in a retrieval system, in any form or by any means, electronic, mechanical, optical, manual, or otherwise, without the prior written permission of DIGITAL-LOGIC AG. The software described herein, together with this document, are furnished under a license agreement and may be used or copied only in accordance with the terms of that agreement. About this Manual and How to Use It This manual is written for the original equipment manufacturer (OEM) who plans to build computer systems based on the single board MICROSPACE-PC. It is for integrators and programmers of systems based on the MICROSPACE-Computer family. This manual provides instructions for installing and configuring the board, and describes the system and setup requirements. This document contains information on hardware requirements, interconnections, and details of how to program the system. Please check the Product CD for further information and manuals. REVISION HISTORY: Document Version Date/Initials: Modification: Remarks, News, Attention: V1.0 02.2008 WAS Initial Version of Detailed Manual adapted from existing V1.4C Sections 1.12, 1.13 added / 2.11.1 & 2.11.2 updated V1.0A 07.2008 DAR Chapter 5.3.6 / 9.71 Attention! 1. All information in this manual, and the product, are subject to change without prior notice. 2. Read this manual prior to installation of the product. 3. Read the security information carefully prior to installation of the product.$

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 3 Table of Contents 1. PREFACE .....................................................................................................................................................6 1.1. Trademarks ..................................................................................................................................... 6 1.2. Disclaimer ....................................................................................................................................... 6 1.3. Environmental Protection Statement ........................................................................................... 6 1.4. Who should use this Product ....................................................................................................... 6 1.5. Recycling Information.................................................................................................................... 7 1.6. Technical Support .......................................................................................................................... 7 1.7. Limited Two Year Warranty........................................................................................................... 7 1.8. Explanation of Symbols................................................................................................................. 8 1.9. Applicable Documents and Standards ........................................................................................ 9 1.10. For Your Safety............................................................................................................................. 10 1.11. RoHS Commitment....................................................................................................................... 10 1.11.1. RoHS Compatible Product Design ........................................................................................ 11 1.11.2. RoHS Compliant Production Process ................................................................................... 11 1.11.3. WEEE Application.................................................................................................................. 11 1.12. Swiss Quality ................................................................................................................................ 12 1.13. The Swiss Association for Quality and Management Systems............................................... 12 2. OVERVIEW .................................................................................................................................................13 2.1. Standard Features........................................................................................................................ 13 2.2. Unique Features ........................................................................................................................... 13 2.3. Standards ...................................................................................................................................... 13 2.4. Block Diagrams ............................................................................................................................ 14 2.4.1. SM855 ................................................................................................................................... 14 2.4.2. MSM855 ................................................................................................................................ 14 2.4.3. MSM855B.............................................................................................................................. 15 2.4.4. MSM855B2 ............................................................................................................................ 15 2.5. Specifications ............................................................................................................................... 16 2.6. Dimensions and Diagrams .......................................................................................................... 19 2.6.1. MSM855/B/B2 (all versions) .................................................................................................. 19 2.6.2. MSM855/B/B2 with SM855.................................................................................................... 20 2.6.3. SM855 ................................................................................................................................... 22 2.6.4. MSM855 LANCON ................................................................................................................ 24 2.6.5. MSM855 USB connector PCB............................................................................................... 26 2.6.6. MSM855 AUDIO/SPDIF connector PCB............................................................................... 27 2.6.7. MSM855-CKCON (USB-, AUDIO- and LAN connector print) ............................................... 28 2.6.8. MSM855-DVICON V1.0......................................................................................................... 29 2.7. MSM855/B/B2 Incompatibilities to a standard PC/AT............................................................... 31 2.7.1. MSM855 / HLV ...................................................................................................................... 31 2.7.2. ISA-Incompatibilitiy with ISA-PCCARD-Controller ................................................................ 31 2.7.3. ISA-Incompatibilitiy with 16bit I/O Transfer with FPGA-Decoder .......................................... 32 2.7.4. ISA-Incompatibilitiy with 16bit Memory Transfer with FPGA-Decoder .................................. 32 2.7.5. Compatibilitiy with DIGITAL-LOGIC Peripheral ISA-Boards ................................................. 32 2.8. MSM855/B/B2/HLV Related Application Notes.......................................................................... 32 2.9. Thermoscan .................................................................................................................................. 33 2.10. High Frequency Radiation (to meet EN55022/EN61000) .......................................................... 35 2.10.1. For Peripheral Cables:........................................................................................................... 35 2.10.2. For Stack-Through Applications: ........................................................................................... 35 2.10.3. Power Supply:........................................................................................................................ 35 2.11. RTC Battery Lifetime.................................................................................................................... 36 2.11.1. Maxell ER3 (MSM855) .......................................................................................................... 36 2.11.2. BR1225 (MSM855B/B2) ........................................................................................................ 37 2.11.3. External Battery Assembly .................................................................................................... 37 3. CHIPSET DESCRIPTION ...............................................................................................................................38 3.1. INTEL Processor Pentium-M....................................................................................................... 38 3.1.1. Introduction ............................................................................................................................ 39 3.1.2. Deep Sleep State................................................................................................................... 39 3.1.3. Low Power Features.............................................................................................................. 39 3.1.4. Deeper Sleep State ............................................................................................................... 39 3.1.5. Enhanced Intel® SpeedStep® Technology............................................................................. 40

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 4 3.2. Graphic-Memory-Control Hub: INTEL 855GME........................................................................ 41 3.2.1. Processor Host Interface ....................................................................................................... 41 3.2.2. Intel 855GME GMCH Host Bus Error Checking.................................................................... 41 3.2.3. Intel 855GME GMCH System Memory Interface .................................................................. 41 3.2.4. Intel 855GME GMCH Internal Graphics ................................................................................ 42 3.2.5. Intel 855GME GMCH Analog Display Port............................................................................ 42 3.2.6. Intel 855GME GMCH Integrated DVO Ports ......................................................................... 42 3.2.7. Hub Interface ......................................................................................................................... 42 3.2.8. Address Decode Policies....................................................................................................... 42 3.3. IO Control Hub Intel-ICH4M / ICH4.............................................................................................. 43 4. BUS SIGNALS ............................................................................................................................................45 4.1. PC104 Bus..................................................................................................................................... 45 4.2. Expansion Bus ............................................................................................................................. 47 4.3. Addressing PCI Devices.............................................................................................................. 48 4.3.1. MSM855/HLV ........................................................................................................................ 48 4.3.2. MSM855B/B2:........................................................................................................................ 49 5. DETAILED SYSTEM DESCRIPTION ................................................................................................................50 5.1. Power Requirements.................................................................................................................... 50 5.1.1. Power Supply Cords.............................................................................................................. 50 5.1.2. Typical Power Consumption.................................................................................................. 51 5.1.3. Minimum Power-Off Time...................................................................................................... 51 5.1.4. ATX–Compatible Power Function ......................................................................................... 51 5.1.5. MSM855-HLV-Input (High Level Voltage Input).................................................................... 52 5.1.6. MSMPS104 (PC104 power supply)....................................................................................... 53 5.2. Boot Time...................................................................................................................................... 54 5.3. Interfaces ...................................................................................................................................... 54 5.3.1. AT Compatible Keyboard and PS/2 Mouse........................................................................... 54 5.3.2. Line Printer Port LPT1 ........................................................................................................... 54 5.3.3. Serial Ports COM1-COM2 ..................................................................................................... 55 5.3.4. Floppy Disk Interface............................................................................................................. 55 5.3.5. Speaker Interface .................................................................................................................. 56 5.3.6. 6 Port USB V2.0 .................................................................................................................... 57 5.3.7. Console Redirection .............................................................................................................. 58 5.4. Controllers .................................................................................................................................... 59 5.4.1. Interrupt Controllers............................................................................................................... 59 5.5. Timers and Counters ................................................................................................................... 59 5.5.1. Programmable Timers ........................................................................................................... 59 5.5.2. Watchdog............................................................................................................................... 59 5.6. BIOS............................................................................................................................................... 60 5.6.1. BIOS History.......................................................................................................................... 60 5.6.2. Core BIOS Download ............................................................................................................ 61 5.6.3. ROM-BIOS Sockets............................................................................................................... 62 5.7. CMOS RAM Map ........................................................................................................................... 62 5.8. EEPROM Saved CMOS Setup ..................................................................................................... 67 5.8.1. EEPROM Memory for Setup ................................................................................................. 67 5.9. Memory & I/O Map ........................................................................................................................ 68 5.9.1. Replacement of the SODIMM-DDRAM ................................................................................. 68 5.9.2. System I/O Map..................................................................................................................... 70 5.10. VGA / LCD ..................................................................................................................................... 71 5.11. LVDS-Display................................................................................................................................ 73 5.12. LAN / Ethernet .............................................................................................................................. 73 5.12.1. LAN Cable Connection .......................................................................................................... 73 5.12.2. Boot from LAN ....................................................................................................................... 74 5.13. AC97 Sound .................................................................................................................................. 75 5.13.1. Audio Cable Connection........................................................................................................ 75 5.13.2. Sound Settings ...................................................................................................................... 75 5.14. SpeedStep Performance Control................................................................................................ 76 5.14.1. Set up Power Management ................................................................................................... 76 6. DESCRIPTION & LOCATION OF THE CONNECTORS........................................................................................78 6.1. Top Side of the MSM855 V1.2/V1.3 ............................................................................................. 79 6.2. Bottom Side of the MSM855 V1.2/V1.3 ....................................................................................... 80

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 5 6.3. Top Side of the MSM855B/B2 V1.1 ............................................................................................. 81 6.4. Top Side of the MSM855B/B2 V1.1 ............................................................................................. 81 7. JUMPER LOCATIONS ON THE BOARD...........................................................................................................91 7.1. The Jumpers on the MSM855...................................................................................................... 92 7.2. The Jumpers on the MSM855/B2 ................................................................................................ 93 8. LED CRITERIA ...........................................................................................................................................94 9. CABLE INTERFACES ...................................................................................................................................95 9.1. The Hard Disk Cable 44pin.......................................................................................................... 95 9.2. The COM 1/2 Serial Cable ............................................................................................................ 96 9.3. VGA Cable..................................................................................................................................... 96 9.4. The Printer Cable (P4).................................................................................................................. 97 9.5. USB Cable ..................................................................................................................................... 97 9.6. The Micro Floppy Cable............................................................................................................... 98 9.7. The LAN Interface Cable (RJ45).................................................................................................. 99 9.7.1. MSM855 LANCON .............................................................................................................. 100 9.7.2. MSM855B/B2 LANCON ...................................................................................................... 100 10. THERMAL SPECIFICATIONS...................................................................................................................101 10.1. Thermal Analysis for Case Integration .................................................................................... 101 10.2. Assembly of the Passive Heat Sink.......................................................................................... 102 10.3. Assembly of the Active Heat Sink ............................................................................................ 103 11. ASSEMBLY VIEWS................................................................................................................................104 11.1. MSM855 V1.2 / V1.3 .................................................................................................................... 104 11.2. MSM855B/B2............................................................................................................................... 106 12. Q&A – QUESTIONS & ANSWERS ..........................................................................................................108 13. PREVIOUS PRODUCT VERSIONS............................................................................................................109 13.1. Mechanical Drawing V0.3/V0.4.................................................................................................. 109 13.2. Assembly Views ......................................................................................................................... 110 13.2.1. MSM855 V0.3 / V0.4 ........................................................................................................... 110 13.2.2. MSM855 V1.0 / V1.1 ........................................................................................................... 112 13.3. Connectors & Jumpers.............................................................................................................. 114 13.3.1. MSM855 V0.3 / V0.4 ........................................................................................................... 114 13.3.2. MSM855 V0.3 / V0.4 – Jumpers only.................................................................................. 116 13.3.3. MSM855 V1.0 / V1.1 ........................................................................................................... 118 13.4. Description of the Connectors for V0.4 ................................................................................... 120 13.5. Description of the Jumpers for V0.4 ........................................................................................ 121 14. INDEX ..................................................................................................................................................122

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 7 1.5. Recycling Information All components within this product fulfill the requirements of the RoHS (Restriction of Hazardous Substances Directive). The product is soldered with a lead free process. 1.6. Technical Support 1. Contact your local DIGITAL-LOGIC Technical Support, in your country. 2. Use the Internet Support Request form at http://support.digitallogic.ch/  embedded products  New Support Request Support requests are only accepted with detailed information about the product (i.e., BIOS-, Board-version)! 1.7. Limited Two Year Warranty DIGITAL-LOGIC AG guarantees the hardware and software products it manufactures and produces to be free from defects in materials and workmanship for two years following the date of shipment from DIGITAL-LOGIC AG, Switzerland. This warranty is limited to the original purchaser of the product and is not transferable. During the two year warranty period, DIGITAL-LOGIC AG will repair or replace, at its discretion, any defective product or part at no additional charge, provided that the product is returned, shipping prepaid, to DIGITAL-LOGIC AG. All replaced parts and products become property of DIGITAL-LOGIC AG. Before returning any product for repair, direct customers of DIGITAL-LOGIC AG, Switzerland are required to register a RMA (Return Material Authorization) number in the Support Center at http://support.digitallogic.ch/ All other customers must contact their local distributors for returning defective materials. This limited warranty does not extend to any product which has been damaged as a result of accident, misuse, abuse (such as use of incorrect input voltages, wrong cabling, wrong polarity, improper or insufficient ventilation, failure to follow the operating instructions that are provided by DIGITAL-LOGIC AG or other contingencies beyond the control of DIGITAL-LOGIC AG), wrong connection, wrong information or as a result of service or modification by anyone other than DIGITAL-LOGIC AG. Nor if the user has insufficient knowledge of these technologies or has not consulted the product manuals or the technical support of DIGITAL-LOGIC AG and therefore the product has been damaged. Empty batteries (external and onboard), as well as all other battery failures, are not covered by this manufacturer’s limited warranty. Except, as directly set forth above, no other warranties are expressed or implied, including, but not limited to, any implied warranty of merchantability and fitness for a particular purpose, and DIGITAL-LOGIC AG expressly disclaims all warranties not stated herein. Under no circumstances will DIGITAL-LOGIC AG be liable to the purchaser or any user for any damage, including any incidental or consequential damage, expenses, lost profits, lost savings, or other damages arising out of the use or inability to use the product.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 8 1.8. Explanation of Symbols CE Conformity This symbol indicates that the product described in this manual is in compliance with all applied CE standards. Caution, Electric Shock! This symbol and title warn of hazards due to electrical shocks (> 60V) when touching products or parts of them. Failure to observe the precautions indicated and/or prescribed by the law may endanger your life/health and/or result in damage to your equipment. Caution, Electric Shock! This symbol and title warn of hazards due to electrical shocks (> 32V) when touching products or parts of them. Failure to observe the precautions indicated and/or prescribed by the law may endanger your life/health and/or result in damage to your equipment Warning, ESD Sensitive Device! This symbol and title inform that electronic boards and their components are sensitive to Electro Static Discharge (ESD). In order to ensure product integrity at all times, care must always be taken while handling and examining this product. Attention! This symbol and title emphasize points which, if not fully understood and taken into consideration by the reader, may endanger your health and/or result in damage to your equipment. Note... This symbol and title emphasize aspects the user should read through carefully for his, or her, own advantage. Warning, Heat Sensitive Device! This symbol indicates a heat sensitive component. Safety Instructions This symbol shows safety instructions for the operator to follow. This symbol warns of general hazards from mechanical, electrical, and/or chemical failure. This may endanger your life/health and/or result in damage to your equipment.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 9 1.9. Applicable Documents and Standards The following publications are used in conjunction with this manual. When any of the referenced specifications are superseded by an approved revision, that revision shall apply. All documents may be obtained from their respective organizations.  Advanced Configuration and Power Interface Specification Revision 2.0c, August 25, 2003 Copyright © 1996-2003 Compaq Computer Corporation, Intel Corporation, Microsoft Corporation, Phoenix Technologies Ltd., Toshiba Corporation. All rights reserved. http://www.acpi.info/  ANSI/TIA/EIA-644-A-2001: Electrical Characteristics of Low Voltage Differential Signaling (LVDS) Interface Circuits, January 1, 2001. http://www.ansi.org/  ANSI INCITS 361-2002: AT Attachment with Packet Interface - 6 (ATA/ATAPI-6), November 1, 2002. http://www.ansi.org/  ANSI INCITS 376-2003: American National Standard for Information Technology – Serial Attached SCSI (SAS), October 30, 2003. http://www.ansi.org/  Audio Codec ’97 Revision 2.3 Revision 1.0, April 2002 Copyright © 2002 Intel Corporation. All rights reserved. http://www.intel.com/labs/media/audio/  Display Data Channel Command Interface (DDC/CI) Standard (formerly DDC2Bi) Version 1, August 14, 1998 Copyright © 1998 Video Electronics Standards Association. All rights reserved. http://www.vesa.org/summary/sumddcci.htm  ExpressCard Standard Release 1.0, December 2003 Copyright © 2003 PCMCIA. All rights reserved. http://www.expresscard.org/  IEEE 802.3-2002, IEEE Standard for Information technology, Telecommunications and information exchange between systems–Local and metropolitan area networks–Specific requirements – Part 3: Carrier Sense Multiple Access with Collision Detection (CSMA/CD) Access Method and Physical Layer Specifications. http://www.ieee.org  IEEE 802.3ae (Amendment to IEEE 802.3-2002), Part 3: Carrier Sense Multiple Access with Collision Detection (CSMA/CD) Access Method and Physical Layer Specifications, Amendment: Media Access Control (MAC) Parameters, Physical Layers, and Management Parameters for 10 GB/s Operation. http://www.ieee.org  Intel Low Pin Count (LPC) Interface Specification Revision 1.1, August 2002 Copyright © 2002 Intel Corporation. All rights reserved. http://developer.intel.com/design/chipsets/industry/lpc.htm  PCI Express Base Specification Revision 1.1, March 28, 2005, Copyright © 2002-2005 PCI Special Interest Group. All rights reserved. http://www.pcisig.com/  PCI Express Card Electromechanical Specification Revision 1.1, March 28, 2005, Copyright © 2002-2005 PCI Special Interest Group. All rights reserved. http://www.pcisig.com/  PCI Local Bus Specification Revision 2.3, March 29, 2002 Copyright © 1992, 1993, 1995, 1998, 2002 PCI Special Interest Group. All rights reserved. http://www.pcisig.com/  PCI-104 Specification, Version V1.0, November 2003. All rights reserved. http://www.pc104.org  PICMG® Policies and Procedures for Specification Development, Revision 2.0, September 14, 2004, PCI Industrial Computer Manufacturers Group (PICMG®), 401 Edgewater Place, Suite 500, Wakefield, MA 01880, USA, Tel: 781.224.1100, Fax: 781.224.1239. http://www.picmg.org/  Serial ATA: High Speed Serialized AT Attachment Revision 1.0a January 7, 2003 Copyright © 2000-2003, APT Technologies, Inc, Dell Computer Corporation, Intel Corporation, Maxtor Corporation, Seagate Technology LLC. All rights reserved. http://www.sata-io.org/

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 10  Smart Battery Data Specification Revision 1.1, December 11, 1998. www.sbs-forum.org  System Management Bus (SMBus) Specification Version 2.0, August 3, 2000 Copyright © 1994, 1995, 1998, 2000 Duracell, Inc., Energizer Power Systems, Inc., Fujitsu, Ltd., Intel Corporation, Linear Technology Inc., Maxim Integrated Products, Mitsubishi Electric Semiconductor Company, Power-Smart, Inc., Toshiba Battery Co. Ltd., Unitrode Corporation, USAR Systems, Inc. All rights reserved. http://www.smbus.org/  Universal Serial Bus Specification Revision 2.0, April 27, 2000 Copyright © 2000 Compaq Computer Corporation, Hewlett-Packard Company, Intel Corporation, Lucent Technologies Inc., Microsoft Corporation, NEC Corporation, Koninklijke Philips Electronics N.V. All rights reserved. http://www.usb.org/ 1.10. For Your Safety Your new DIGITAL-LOGIC product was developed and tested carefully to provide all features necessary to ensure its compliance with electrical safety requirements. It was also designed for a long, fault-free life. However, this life expectancy can be drastically reduced by improper treatment during unpacking and installation. Therefore, in the interest of your own safety and for the correct operation of your new DIGITAL-LOGIC product, please comply with the following guidelines. Attention! All work on this device must only be carried out by sufficiently skilled personnel. Caution, Electric Shock! Before installing your new DIGITAL-LOGIC product, always ensure that your mains power is switched off. This applies also to the installation of piggybacks or peripherals. Serious electrical shock hazards can exist during all installation, repair and maintenance operations with this product. Therefore, always unplug the power cable and any other cables which provide external voltage before performing work. Warning, ESD Sensitive Device! Electronic boards and their components are sensitive to static electricity. In order to ensure product integrity at all times, be careful during all handling and examinations of this product. 1.11. RoHS Commitment DIGITAL-LOGIC AG is committed to develop and produce environmentally friendly products according to the Restriction of Hazardous Substances (RoHS) Directive (2002/95/EC) and the Waste Electrical and Electronic Equipment (WEEE) Directive (2002/96/EC) established by the European Union. The RoHS directive was adopted in February 2003 by the European Union and came into effect on July 1, 2006. It is not a law but a directive, which restricts the use of six hazardous materials in the manufacturing of various types of electronic and electrical equipment. It is closely linked with the Waste Electrical and Electronic Equipment Directive (WEEE) 2002/96/EC, which has set targets for collection, recycling and recovery of electrical goods and is part of a legislative initiative to solve the problem of huge amounts of toxic e-waste. Each European Union member state is adopting its own enforcement and implementation policies using the directive as a guide. Therefore, there could be as many different versions of the law as there are states in the EU. Additionally, non-EU countries like China, Japan, or states in the U.S. such as California may have their own regulations for green products, which are similar, but not identical, to the RoHS directive.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 11 RoHS is often referred to as the "lead-free" directive but it restricts the use of the following substances:  Lead  Mercury  Cadmium  Chromium VI  PBB and PBDE The maximum allowable concentration of any of the above mentioned substances is 0.1% (except for Cadmium, which is limited to 0.01%) by weight of homogeneous material. This means that the limits do not apply to the weight of the finished product, or even to a component but to any single substance that could (theoretically) be separated mechanically. 1.11.1. RoHS Compatible Product Design All DIGITAL-LOGIC standard products comply with RoHS legislation. Since July 1, 2006, there has been a strict adherence to the use of RoHS compliant electronic and mechanical components during the design-in phase of all DIGITAL-LOGIC standard products. 1.11.2. RoHS Compliant Production Process DIGITAL-LOGIC selects external suppliers that are capable of producing RoHS compliant devices. These capabilities are verified by: 1. A confirmation from the supplier indicating that their production processes and resulting devices are RoHS compliant. 2. If there is any doubt of the RoHS compliancy, the concentration of the previously mentioned substances in a produced device will be measured. These measurements are carried out by an accredited laboratory. 1.11.3. WEEE Application The WEEE directive is closely related to the RoHS directive and applies to the following devices:  Large and small household appliances  IT equipment  Telecommunications equipment (although infrastructure equipment is exempt in some countries)  Consumer equipment  Lighting equipment – including light bulbs  Electronic and electrical tools  Toys, leisure and sports equipment  Automatic dispensers It does not apply to fixed industrial plants and tools. The compliance is the responsibility of the company that brings the product to market, as defined in the directive. Components and sub-assemblies are not subject to product compliance. In other words, since DIGITAL-LOGIC does not deliver ready-made products to end users the WEEE directive is not applicable for DIGITAL-LOGIC. Users are nevertheless encouraged to properly recycle all electronic products that have reached the end of their life cycle.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 12 1.12. Swiss Quality  100% Made in Switzerland  DIGITAL-LOGIC is a member of "Swiss-Label"  This product was not manufactured by employees earning piecework wages  This product was manufactured in humane work conditions  All employees who worked on this product are paid customary Swiss market wages and are insured  ISO 9000:2001 (quality management system) 1.13. The Swiss Association for Quality and Management Systems The Swiss Association for Quality and Management Systems (SQS) provides certification and assessment services for all types of industries and services. SQS certificates are accepted worldwide thanks to accreditation by the Swiss Accreditation Service (SAS), active membership in the International Certification Network, IQNet, and co-operation contracts/agreements with accredited partners. www.sqs.ch The SQS Certificate ISO 9001:2000 has been issued to DIGITAL-LOGIC AG, the entire company, in the field of development, manufacturing and sales of embedded computer boards, embedded computer modules and computer systems. The certification is valid for three years at which time an audit is performed for recertification.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 13 2. OVERVIEW 2.1. Standard Features The MICROSPACE PC/104 is a miniaturized modular device incorporating the major elements of a PC/AT compatible computer. It includes standard PC/AT compatible elements, such as:  Powerful PENTIUM -M from 600MHz up to 2GHz  BIOS ROM  DDRAM 128-1024MByte SODIMM 200pin  1024/2048kByte second level cache  Timers  DMA  Real-time clock with CMOS-RAM and 10 year battery buffer  LPT1 parallel port  COM1-, COM2- RS2332 serial port 16C550 comp.  Speaker interface  AT-keyboard interface or PS/2-keyboard interface  Floppy disk interface  AT-IDE hard disk interface  VGA video interface  6 channel sound interface AC97-V2.3  100/10-Base-T LAN (second LAN interface on the MSM855B2 with an Intel 82551ER)  PC/104 embedded BUS (8bit on the MSM855; 8/16bit on the MSM855B/B2)  PS/2 mouse interface  Power management functions AMP and ACPI  6 channel USB V1.1 & V2.0 2.2. Unique Features The MICROSPACE MSM855 includes all standard PC/AT functions plus unique DIGITAL-LOGIC AG enhancements, such as:  Single 5Volt supply  Watchdog  Power-fail detection  EEPROM for setup and configuration  IrDA  Optional: Compact Card holder type 1  UL approved parts  Console redirection 2.3. Standards This MICROSPACE product meets all standards for personal computer architecture. Standard How to contact the organization Remarks PC/104BUS www.pc104.org USB www.usb.org PCI www.pcisig.com SMB www.smbus.org WfM www.intel.com/labs/manage/wfm Wired for management baseline AC97 www.developer.intel.com/ial/scalableplatforms/audio LPC www.developer.intel.com/design/chipsets/industry/lpc.htm ATA/ATAPI-6 www.t13.org ACPI www.acpi.info Power management

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 14 2.4. Block Diagrams 2.4.1. SM855 2.4.2. MSM855

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 15 2.4.3. MSM855B On the MSM855B/B2 there is a PCI to ISA bridge (not an LPC to ISA bridge). 2.4.4. MSM855B2 There is a second LAN chip (Intel 82551ER) assembled on the MSM855B2.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 16 2.5. Specifications CPU CPU Intel® Pentium®-M or Intel® Celeron-M Compatibility 8086-PentiumM 1st Level Cache 16k data and 16k code 2nd Level Cache 1024/2048kByte Socket SmartBus855 320pin Clock MSM855-16 1600MHz (600MHz up to 2GHz available) FSB 400MHz Power management Yes, APM2.1 and ACPI 1.2 FPU Integrated Chipset Northbridge I from Intel Southbridge ICH4 from Intel LAN Integrated (comp. to 82C559 Intel) On the MSM855B2 is an additional Intel 82551ER. Audio AC97 – V2.3 5.1-Sound Firewire IEEE1394 Not on board Video Intel Extreme Graphics 2 DirectX-9 compatible, 64MByte Video-DDRAM Memory Main Memory 1x SODIMM200 socket SDRAM, 64bit, up to 1024Mbyte stacked Flash-BIOS 1024kByte Flash Setup EEPROM 2kByte for CMOS-backup in battery-free applications Flash-Video BIOS Serial-Flash Video RAM 16MByte to 64MByte DDRAM Video Controller Intel Extreme Graphics 2 is integrated in the Intel 855GME chipset Memory 64MB Channel 1 CRT VGA up to 2048 x 1600 pixels Channel 2 LVDS ,DVI, TV-Out  = with the MSM855-DVICON Bootup-Resolution 640x480 / 800x600 / 1024x768 2D-Graphics Integrated accelerator 3D-Graphics Integrated accelerator Direct-X, Version 9 PnP Integrated External Interfaces Video interfaces CRT1, DVO USB V1.1/2.0 6 channels LPT1 IEEE1293 Printer COM1 RS232 COM2 RS232 Keyboard PS/2 Mouse PS/2 Floppy 26pin FCC Interface for TEAC Mini-floppy Hard disk 1 channel, 44pin RM2.0mm ATAIDE-cable Speaker 0.1Watt Speaker ISA-Bus PC/104 PCI-Bus PC/104plus LAN 10/100 Base-TX (from the SM855) LAN 2 10/100 Base-TX (only available on the MSM855B2 with Intel's 82551ER)

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 17 Power Supply MSM855/B/B2 Input voltage Nominal 5V Tolerance +/- 3% Input inrush current Typically 5Amp, inrush current 15Amp for power-up of 10ms Protection Not integrated, EMI filter must be added externally Specification None 3.3Volt power output Not available Power Supply MSM855-HLV Input voltage 5-32V (typically 24V) and 5V (tolerance +/- 3%) Input inrush current Protection Not integrated, EMI filter must be added externally Specification MIL-Norm VG 96916-5 3.3Volt power output Not available Power Consumption At 5V (with 256MByte) MSM855-16 typically 2.0Amp (10W) at 600MHz typically 5.0Amp (25W) at 1600MHz Standby Typically 0.5Amp Power-off Typically 40mA Physical Characteristics PC/104plus Dimensions Length: 91mm Depth: 99mm Height: 25mm Weight 170gr Operating Environment Relative Humidity 5-90% non condensing IEC68-2-30 at -20° to +50°C, operating Vibration, operating IEC68-2-6 10-50Hz, 0.075mm and 55-500Hz, 1.0G Vibration, non-operating IEC68-2-6 10-50Hz, 0.15mm and 55-500Hz, 2.0G Shock, operating IEC68-2-27 10G, 11ms ½ sine Shock, non-operating IEC68-2-27 50G, 11ms, ½ sine Altitude IEC68-2-13 4571meter operating Temperature, operating IEC68-2-1,2,14 MSM855, standard -20°C to +60°C Extended Temperature (option) MIL-810-501/502 see separate table below Temperature, storage IEC68-2-1,2,14 -65°C to +125°C   The back-up battery is limited on -40°C to +80°C operating and storage temperatures Operating Temperature MIL-810-501 MIL-810-502 Extended Temperature Range MSM855-16 (600MHz) -40°C to +70°C Security e1 Not planned UL Not planned ETS 301 Not planned CE/SEV Yes Safety AR385-16

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 18 EMI / EMC Tests Provided all signals are externally filtered and assembled into a closed metallic housing! EMC Emission EN61000-6-2:2001 Conducted Disturbance EN55022 Class B Radiated Disturbance EN55022 Class B EMC Immunity EN61000-6-2 ESD Electrostatic Discharge EN61000-4-2 Voltage = 4kV contact / 8kV air, Criteria A RF Radiated Field EN61000-4-3 Level = 10V/m, Criteria A EFT Electrical Fast Transient (Burst) EN61000-4-4 Grade 2: DC-Power lines = 1000V (5/50ns) Grade 2: AC-Power lines = 2000V (5/50ns) Grade 2: Signal lines = 500V (5/50ns) Criteria B Surge EN61000-4-5 Grade 2: DC-Power lines = 1kV, (1.2/50us) Grade 2: AC-Power lines = 2kV, (1.2/50us) Criteria B Conducted Disturbances EN61000-4-6 Voltage = 10V coupled by case, Criteria A All information is subject to change without notice.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 19 2.6. Dimensions and Diagrams 2.6.1. MSM855/B/B2 (all versions)

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 20 2.6.2. MSM855/B/B2 with SM855

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 21

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 22 2.6.3. SM855

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 23

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 24 2.6.4. MSM855 LANCON

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 25 2.6.4.1. Mechanical Drawing

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 26 2.6.5. MSM855 USB connector PCB

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 27 2.6.6. MSM855 AUDIO/SPDIF connector PCB

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 28 2.6.7. MSM855-CKCON (USB-, AUDIO- and LAN connector print) 2.6.7.1. Mechanical Drawing

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 29 2.6.8. MSM855-DVICON V1.0

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 30 2.6.8.1. MSM855-DVICON mechanical drawing

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 31 2.7. MSM855/B/B2 Incompatibilities to a standard PC/AT 2.7.1. MSM855 / HLV On the Intel855GME Design and in the PC-03 specification, no ISA-Bus is available. For the BIOS and the SuperIO functions, the LPC-Bus is integrated. The LPC-Bus is a serialized ISA-Bus with some limitations. Onboard is an LPC to ISA-Bridge integrated to generate a standard ISA-Bus. In using the combination of the LPC-Bus and the LPC-Bridge there are some incompatibilities. The LPC support the following bus cycles: This means that all non-Busmaster I/Os and MEM Cycles are only 8bit wide and never 16bit wide. 16bit data transfer is available in the BusMaster modus only. 2.7.2. ISA-Incompatibilitiy with ISA-PCCARD-Controller Experience shows that ATA-Drives controlled in an ISA-PCMCIA Controller do not work. Solution: Use a PCCARD-Controller on the PCI-Bus.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 32 2.7.3. ISA-Incompatibilitiy with 16bit I/O Transfer with FPGA-Decoder Our experience shows that 16bit I/O-transfers decoded with an FPGA do not always work correct. Each case must be tested.. Solution: Use two 8bit transfers instead one 16bit transfer. For time critical transfers we recommend using the PCI-Bus. 2.7.4. ISA-Incompatibilitiy with 16bit Memory Transfer with FPGA-Decoder Experience shows that 16bit Memory-transfers decoded with an FPGA do not always work correctly. Each case must be tested. Expect problems on odd addresses. Solution: Use two 8bit transfers instead of one 16bit transfer. For time critical transfers we recommend using the PCI-Bus. 2.7.5. Compatibilitiy with DIGITAL-LOGIC Peripheral ISA-Boards Funktion Product Transfer Result Remarks Serial MSMX104 8bit I/O Works fine - CAN-Bus MSMCAN104 8bit I/O Works fine - Ethernet MSME104 16bit I/O Works fine Int. Autoaddressincrement Video MSMV104 16bit MEM Works fine - PCMCIA MSMJ104 8/16bit I/O & MEM Doesn’t work with ATA-Cards Flash- and SRAM-Cards with 16bit MEM are ok Sound Card MSMM104 16bit I/O DMA Works fine 2.8. MSM855/B/B2/HLV Related Application Notes Application Notes are available at http://www.digitallogic.com  support, or on any DIGITAL-LOGIC Application CD from. # Description 80 High frequency Radiation (to meet EN55022)

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 33 2.9. Thermoscan Equipment: Product Part Number Serial Number Version MSM855 803010 46201010507 1.1 SM855-11P 1.1GHz 805161 45216110026 0.8 SM855-P378 1.4GHz 805164 45316410032 0.8 SODIMM DDR 1GB 870672 - - Software Windows XP SP2 running desk top MSM855-11P Top view t [min] fCPU [MHz] I [A] TSensor[°C] TCPU[°C] THS[°C] P [W] 60 1100 3.65 65 69 63 18.6 MSM855-11P Bottom view: t [min] fCPU [MHz] I [A] TSensor[°C] TCPU[°C] TKK[°C] P [W] 60 1100 3.68 67 72 65 18.8

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 34 MSM855-738 Top view: t [min] fCPU [MHz] I [A] TSensor[°C] TCPU[°C] THS[°C] P [W] 60 1400 3.58 42 47 32 18.3 MSM855-738 Bottom view: t [min] fCPU [MHz] I [A] TSensor[°C] TCPU[°C] THS[°C] P [W] 60 1400 3.65 53 59 44 18.6

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 35 2.10. High Frequency Radiation (to meet EN55022/EN61000) Since the PC/104 CPU modules are very highly integrated embedded computers, peripheral lines are not protected against radiation from the high frequency spectrum. To meet a typical EN55022 requirement, all peripherals that go outside of the computer case must be externally filtered. Typical signals that must be filtered: Keyboard: KBCLK, KBDATA, VCC Mouse: MSCLK, MSDATA, VCC COM1/2/3/4: All serial signals must be filtered LPT: All parallel signals must be filtered CRT: Red, blue, green, hsynch and vsynch must be filtered Typical signals that must not be filtered, since they are used internally: IDE: Connected to the hard disk Floppy: Connected to the floppy LCD: Connected to the internal LCD 2.10.1. For Peripheral Cables: Use a filtered version for all DSUB connectors. Select the filter specifications carefully. Place the filtered DSUB connector directly on the front side and be sure that the shielding makes good contact with the case. 9pin DSUB connector from AMPHENOL: FCC17E09P 820pF 25pin DSUB connector from AMPHENOL: FCC17B25P 820pF 2.10.2. For Stack-Through Applications: On each peripheral signal line that goes outside the computer case, place a serial inductivity followed by a grounded capacitor of 100pF to 1000pF. In this case, no filtered connectors are needed. Place the filter directly under or behind the onboard connector. Serial Inductivity: TDK HF50ACB321611-T 100Mhz, 500mA, 1206 Case Ground capacitor: Ceramic Capacitor with 1000pF 2.10.3. Power Supply: Use a current-compensated dual inductor on the 5V supply. For more information, please see Section 5.1.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 36 2.11. RTC Battery Lifetime An AT compatible date/time clock is located within the chipset. The device also contains a CMOS static RAM compatible with that in standard ATs. System configuration data is normally stored in the clock chip's CMOS RAM in a manner consistent with the convention used in other AT compatible computers. There are two ways to connect an external 3.6V lithium battery. 1. The most commonly used connection: MSM855 The LAN-adaptor includes the LAN-transformer and the lithium battery. We recommend connecting the battery to J29 , the universal LAN-Adaptor-Connector. The LAN-adaptor and the LAN-cable are included. MSM855B/B2 There is an onboard battery socket for a BR1225. 2. Alternative connection: Keyboard connector J8 (pin8 = battery 3.6V input, pin7 = GND). If the the battery is connected to J8, the J29 must not be used to connect the RTC-battery. The battery-backed clock may be set during the boot process by using DIGITAL-LOGIC's setup. 2.11.1. Maxell ER3 (MSM855) Battery Specifications Lowest Temp. -40°C Nominal Temp. +20°C Highest Temp. +85°C Manufacturer pbq Type ER10280 Capacity versus Temp. 8uA 850mAh 910mAh 850mAh Voltage versus Temp. 8uA 3.5V 3.6V Ca. 3.6V Nominal Values 3.6V / 450mAh / -40°C...~+85°C Information is taken from the datasheet of the pbq ER10280 Product Temperature °C Battery Voltage V VCC (+5V) switched ON µA VCC (+5V) switched off µA MSM855 +25°C 3.6 0.1 8 -40°C 3.5 0.1 8 Battery Current +85°C 3.6 0.1 8 +25°C >10 years >5 years -40°C >10 years >4 years Battery Lifetime +85°C >10 years ~3 years

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 37 2.11.2. BR1225 (MSM855B/B2) Battery Specifications Lowest Temp. -30°C Nominal Temp. +20°C Highest Temp. +80°C Manufacturer Various Type BR1225 Capacity versus Temp. 7uA 35mAh 48mAh 50mAh Voltage versus Temp. 7uA 2.6V 3V 3V Nominal Values 3V / 48mAh / -30°C...~+80°C Information taken from the datasheet of Panasonic BR1225 Product Temperature °C Battery Voltage V VCC (+5V) switched ON µA VCC (+5V) switched off µA MSM855B/B2 +25°C 3 0.1 7 -40°C 2.6 0.1 7 Battery Current +85°C 3 0.1 7 +25°C >5 years ~280 days -40°C >5 years ~210 days Battery Lifetime +85°C >5 years ~300 days 2.11.3. External Battery Assembly If the customer wants to connect an external battery (check for the appropriate connector in Chapter 6), some precautions must be taken:  Do not use a rechargeable battery – the battery is prohibited from charging.  The RTC device defines a voltage level of 2.0-3.6V, so use an external battery within this range (inclusive of the diode which is already assembled onboard).

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 38 3. CHIPSET DESCRIPTION 3.1. INTEL Processor Pentium-M The Intel® Pentium® M processor is a high-performance, low-power mobile processor with several micro-architectural enhancements over existing Intel mobile processors. The following is a list of some of the key features on this processor:  Supports Intel® Architecture with Dynamic Execution  High-performance, low-power core  On-die, primary 32kByte instruction cache and 32kByte write-back data cache  On-die, 1/2MByte 2nd level cache with Advanced Transfer Cache Architecture  Advanced Branch Prediction and Data Prefetch Logic  Streaming SIMD Extensions 2 (SSE2)  400/533MHz, source-synchronous processor system bus  Advanced Power Management features including Enhanced Intel® SpeedStep® technology  Micro-FCPGA and Micro-FCBGA packaging technologies The Intel Pentium M processor is manufactured on Intel’s advanced 0.13/0.09 micron process technology with copper interconnect. The processor maintains support for MMX™ technology and Internet Streaming SIMD instructions and full compatibility with IA-32 software. The high-performance core features architectural innovations like Micro-op Fusion and Advanced Stack Management that reduce the number of micro-ops handled by the processor. This results in more efficient scheduling and better performance at lower power. The on-die 32kB Level 1 instruction and data caches and the 1MB Level 2 cache with Advanced Transfer Cache Architecture enable significant performance improvement over existing mobile processors. The processor also features a very advanced branch prediction architecture that significantly reduces the number of mispredicted branches. The processor’s Data Prefetch Logic speculatively fetches data to the L2 cache before an L1 cache requests occurs, resulting in reduced bus cycle penalties and improved performance. The Streaming SIMD Extensions 2 (SSE2) enable break-through levels of performance in multimedia applications including 3-D graphics, video decoding/encoding, and speech recognition. The new packed double-precision floating-point instructions enhance performance for applications that require greater range and precision, including scientific and engineering applications and advanced 3-D geometry techniques, such as ray tracing. The Intel Pentium M processor’s 400MHz processor system bus utilizes a split-transaction, deferred reply protocol. The 400MHz processor system bus uses Source-Synchronous Transfer (SST) of address and data to improve performance by transferring data four times per bus clock (4X data transfer rate, as in AGP 4X). Along with the 4X data bus, the address bus can deliver addresses two times per bus clock and is referred to as a “double-clocked” or 2X address bus. Working together, the 4X data bus and 2X address bus provide a data bus bandwidth of up to 3.2GBytes/second. The processor system bus uses Advanced Gunning Transceiver Logic (AGTL+) signal technology, a variant of GTL+ signalling technology with low power enhancements. Note: The term AGTL+ has been used for Assisted Gunning Transceiver Logic technology on other Intel products.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 39 3.1.1. Introduction The processor features Enhanced Intel SpeedStep technology, which enables real-time dynamic switching between multiple voltage and frequency points instead of two points supported on previous versions of Intel SpeedStep technology. This results in optimal performance without compromising low power. The processor features the Auto Halt, Stop-Grant, Deep Sleep, and Deeper Sleep low-power states. The Intel Pentium M processor utilizes socket-able Micro Flip-Chip Pin Grid Array (Micro-FCPGA) and surface mount Micro Flip-Chip Ball Grid Array (Micro-FCBGA) package technology. The Micro-FCPGA package plugs into a 479-hole, surface-mount, Zero Insertion Force (ZIF) socket, which is referred to as the mPGA479M socket. This document includes specifications for the Intel Pentium M processor at Highest Frequency Mode (HFM) core frequencies of 1.30, 1.40, 1.50, and 1.60GHz, the Low Voltage Intel Pentium M processor at HFM core frequency of 1.10GHz and the Ultra Low Voltage Intel Pentium M processor at HFM core frequency of 900MHz. 3.1.2. Deep Sleep State Deep Sleep state is a very low power state the processor can enter while maintaining context. Deep Sleep state is entered by asserting the DPSLP# pin while in the Sleep state. BCLK may be stopped during the Deep Sleep state for additional platform level power savings. BCLK stop/restart timings on Intel 855PM and Intel 855GME chipset-based platforms are as follows: Intel® Pentium® M Processor Datasheet 14 3.1.3. Low Power Features  Deep Sleep entry - DPSLP# and CPU_STP# are asserted simultaneously. The platform clock chip will stop/tristate BCLK within 2 BCLKs +/- a few nanoseconds.  Deep Sleep exit - DPSLP# and CPU_STP# are deasserted simultaneously. The platform clock chip will drive BCLK to differential DC levels within 2-3 ns and starts toggling BCLK 2-6 BCLK periods later. To re-enter the Sleep state, the DPSLP# pin must be deasserted. BCLK can be re-started after DPSLP# deassertion as described above. A period of 30 microseconds (to allow for PLL stabilization) must occur before the processor can be considered to be in the Sleep state. Once in the Sleep state, the SLP# pin must be deasserted to re-enter the Stop-Grant state. While in Deep Sleep state, the processor is incapable of responding to snoop transactions or latching interrupt signals. No transitions of signals are allowed on the system bus while the processor is in Deep Sleep state. Any transition on an input signal before the processor has returned to Stop-Grant state will result in unpredictable behavior. 3.1.4. Deeper Sleep State The Deeper Sleep state is the lowest power state the processor can enter. This state is functionally identical to the Deep Sleep state but at a lower core voltage. The control signals to the voltage regulator to initiate a transition to the Deeper Sleep state are provided on the platform. Please refer to the platform design guides for details.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 40 3.1.5. Enhanced Intel® SpeedStep® Technology (only available with Pentium-M CPUs, not with Celeron-M CPUs) The Intel Pentium M processor features Enhanced Intel SpeedStep® technology. Unlike previous implementations of Intel SpeedStep, this technology enables the processor to switch between multiple frequency and voltage points instead of two. This enables superior performance with optimal power savings. Switching between states is software controlled unlike previous implementations where the GHI# pin was used to toggle between the two states. The key features of Enhanced Intel SpeedStep technology are:  Multiple voltage/frequency operating points provide optimal performance at the lowest power.  Voltage/Frequency selection is software controlled by writing to processor MSR’s (Model Specific Registers) thus eliminating chipset dependency. o If the target frequency is higher than the current frequency, Vcc is ramped up by placing a new value on the VID pins and the PLL then locks to the new frequency. o If the target frequency is lower than the current frequency, the PLL locks to the new frequency and the Vcc is changed through the VID pin mechanism. o Software transitions are accepted at any time. If a previous transition is in progress, the new transition is deferred until its completion.  The processor controls voltage ramp rates internally to ensure glitch free transitions.  Low transition latency and large number of transitions possible per second. o Processor core (including L2 cache) is unavailable for up to 10 µs during the frequency transition o The bus protocol (BNR# mechanism) is used to block snooping Low Power Features:  No bus master arbiter disable required prior to transition and no processor cache flush necessary.  Improved Intel Thermal Monitor mode. o When the on-die thermal sensor indicates that the die temperature is too high, the processor can automatically perform a transition to a lower frequency/voltage specified in a software programmable MSR. o The processor waits for a fixed time period. If the die temperature is down to acceptable levels, an up transition to the previous frequency/voltage point occurs. o An interrupt is generated for the up and down Intel Thermal Monitor transitions enabling better system level thermal management. Enhancements:  Dynamic PSB Power Down  BPRI# control for address and control input buffers  Dynamic On Die Termination disabling  Low VCCP (I/O termination voltage) switching power at all times monitoring requirements in the Deeper Sleep state.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 41 3.2. Graphic-Memory-Control Hub: INTEL 855GME 3.2.1. Processor Host Interface The GMCH is optimized for the Intel Pentium M processor. Key features of the Intel Pentium M processor system bus (PSB) are:  Source synchronous double-pumped address.  Source synchronous quad-pumped data.  System bus interrupt delivery.  Low voltage swing (Vtt = 1.05 V).  Dynamic Power Down (DPWR#) support.  GMCH supports a 64-B cache line size.  Support for a 400MHz system bus frequency. Dual processor is not supported.  Integrates AGTL+ termination resistors on all of the AGTL+ signals.  Supports 64bit host bus addressing allowing the CPU to access the entire 4GB of the GMCH memory address space.  A 12-deep, In-Order queue to support up to twelve outstanding pipelined address requests on the host bus.  Drives DPWR# signal to the processor, which can then disable its sense amplifiers.  Supports only one outstanding defer cycle at a time to any particular I/O interface.  Host initiated I/O cycles are positively decoded to the GMCH configuration space and subtractively decoded to the Hub Interface  Host initiated memory cycles are positively decoded to DDR SDRAM.  Memory accesses initiated from the Hub Interface to DDR SDRAM will be snooped on the system bus. 3.2.2. Intel 855GME GMCH Host Bus Error Checking The Intel 855GME GMCH does not generate, nor check, parity on Data, Address/Request, and Response signals on the PSB. 3.2.3. Intel 855GME GMCH System Memory Interface The GMCH System Memory Controller directly supports the following:  One channel of PC1600/2100 SO-DIMM DDR SDRAM memory.  DDR SDRAM devices with densities of 128, 256 and 512MB technology.  Maximum System Memory with two, double-sided SO-DIMMs (four rows populated) supporting up to 1GB system memory, and high density supporting up to 2GB system memory.  Variable page sizes of 2, 4, 8 and 16kB. Page size is individually selectable for every row and a maximum of 16 pages may be opened simultaneously The GMCH System Memory interface supports a thermal throttling scheme to selectively throttle reads and/or writes. Throttling can be triggered either by the on-die thermal sensor, or by preset write bandwidth limits. Read throttle can also be triggered by an external input pin. The memory controller logic supports aggressive Dynamic Row Power Down features to help reduce power and supports Address and Control line Tri-stating when DDR SDRAM is in an active power-down or in self-refresh state. The GMCH System Memory architecture is optimized to maintain open pages (up to 16kB page size) across multiple rows. As a result, up to 16 pages across four rows is supported. To complement this, the GMCH will tend to keep pages open within rows, or will only close a single bank on a page miss. The GMCH supports only four bank memory technologies.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 42 3.2.4. Intel 855GME GMCH Internal Graphics The GMCH IGD provides a highly integrated graphics accelerator delivering high performance 2D, 3D, and video capabilities. With its interfaces to UMA using a DVMT configuration, an analog display, a LVDS port, and two digital display ports (e.g., flat panel), the GMCH can provide a complete graphics solution. The GMCH also provides 2D hardware acceleration for block transfers of data (BLTs). The BLT engine provides the ability to copy a source block of data to a destination and perform raster operations (e.g., ROP1, ROP2, and ROP3) on the data using a pattern, and/or another destination. Performing these common tasks in hardware reduces CPU load, and thus improves performance. High bandwidth access to data is provided through the System Memory interface. The GMCH uses Tiling architecture to increase System Memory efficiency and thus maximize effective rendering bandwidth. The Intel 855GME GMCH also improves 3D performance and quality with 3D Zone Rendering technology. The GMCH has four display ports, one analog and three digital. These provide support for a progressive scan analog monitor, a dedicated dual channel LVDS LCD panel, and two DVO devices. Each port can transmit data according to one or more protocols. The DVO ports are connected to an external device that converts one protocol to another. Examples of this are TV-out encoders, external DACs, LVDS transmitters, and TMDS transmitters. Each display port has control signals that may be used to control, configure and/or determine the capabilities of an external device. The data that is sent out the display port is selected from one of the two possible sources, Pipe A or Pipe B. 3.2.5. Intel 855GME GMCH Analog Display Port Intel 855GME GMCH has an integrated 350MHz, 24bit RAMDAC that can directly drive a progressive scan analog monitor pixel resolution up to 2048x1600 at 85Hz refresh and up to 2048x1536 at 72Hz refresh. The analog display port can be driven by Pipe A or Pipe B. 3.2.6. Intel 855GME GMCH Integrated DVO Ports The DVO B/C interface is compliant with the DVI Specification 1.0. When combined with a DVI compliant external device (e.g., TMDS Flat Panel Transmitter, TV-out encoder, etc.), the GMCH provides a high-speed interface to a digital or analog display (e.g., flat panel, TV monitor, etc.). The GMCH provides two DVO ports that are each capable of driving a 165MHz pixel clock at the DVO B or DVO C interface. When DVO B and DVO C are combined into a single DVO port, then an effective pixel rate of 330MHz can be achieved. The DVO B/C ports can be driven by Pipe A or Pipe B. If driven on Pipe B, then the LVDS port must be disabled. 3.2.7. Hub Interface A proprietary interconnect connects the GMCH to the ICH4-M. All communication between the GMCH and the ICH4-M occurs over the Hub Interface 1.5. The Hub Interface runs at 66MHz (266MB/s). 3.2.8. Address Decode Policies Host initiated I/O cycles are positively decoded to the GMCH configuration space and subtractively decoded to the Hub Interface. Host initiated System Memory cycles are positively decoded to DDR SDRAM and are again subtractively decoded to the Hub Interface if under 4GB. System Memory accesses from the Hub Interface to DDR SDRAM will be snooped on the PSB.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 43 3.3. IO Control Hub Intel-ICH4M / ICH4 Features: PCI Bus Interface Supports PCI Revision 2.2 Specification at 33MHz 133MB/sec maximum throughput Supports up to six master devices on PCI One PCI REQ/GNT pair can be given higher arbitration priority (intended for external 1394 host controller) Support for 44bit addressing on PCI using DAC protocol Integrated LAN Controller WfM 2.0 and IEEE 802.3 compliant LAN Connect Interface (LCI) 10/100Mbit/sec ethernet support Integrated IDE Controller Supports "Native Mode” register and interrupts Independent timing of up to 4 drives, with separate primary and secondary IDE cable connections Ultra ATA/100/66/33, BMIDE and PIO modes Tri-state modes to enable swap bay USB Includes three UHCI host controllers that support six external ports New: Includes one EHCI high-speed USB 2.0 Host Controller that supports all six ports New: Supports a USB 2.0 high-speed debug port Supports wake-up from sleeping states S1-S5 Supports legacy keyboard/mouse software AC-Link for Audio CODECs Supports AC ’97 2.3 New: Third AC_SDATA_IN line for three codec support New: Independent bus master logic for seven channels (PCM In/Out, Mic 1 input, Mic 2 input, modem in/out, S/PDIF out) Separate independent PCI functions for audio and modem Support for up to six channels of PCM audio output (full AC3 decode) Supports wake-up events Interrupt Controller Support up to eight PCI interrupt pins Supports PCI 2.2 message signaled interrupts Two cascaded 82C59 with 15 interrupts Integrated I/O APIC capability with 24 interrupts Supports serial interrupt protocol Supports processor system bus interrupt delivery New: 1.5 V operation with 3.3 V I/O 5V tolerant buffers on IDE, PCI, USB overcurrent and legacy signals Timers Based on 82C54 System timer, refresh request, speaker tone output

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 44 Power Management Logic ACPI 2.0 compliant ACPI-defined power states (C1-C2, S3-S5) Supports Desktop S1 state (like C2 state, only STPCLK# active) ACPI power management timer PCI PME# support SMI# generation All registers readable/restorable for proper resume from 0V suspend states External Glue Integration Integrated pull-up, pull-down and series termination resistors on IDE, processor interface Integrated pull-down and series resistors on USB Enhanced Hub Interface Buffers improve routing flexibility (Not available with all MemController Hubs) Firmware Hub (FWH) Interface supports BIOS memory size up to 8MB Low Pin Count (LPC) Interface Supports two Master/DMA devices Enhanced DMA Controller Two cascaded 8237 DMA controllers PCI DMA: Supports PC/PCI (Includes two PC/PCI REQ#/GNT# pairs) Supports LPC DMA Supports DMA collection buffer to provide Type-F DMA performance for all DMA channels Real-Time Clock 256Byte battery-backed CMOS RAM System TCO Reduction Circuits Timers to generate SMI# and Reset upon detection of system hang Timers to detect improper processor reset Supports ability to disable external devices SMBus New: Hardware packet error checking New: Supports SMBus 2.0 Specification Host interface allows processor to communicate via SMBus Slave interface allows an external microcontroller to access system resources Compatible with most 2-wire components that are also I2C compatible GPIO TTL, open-drain, inversion

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 45 4. BUS SIGNALS 4.1. PC104 Bus Note... Not all of the signals are available on this board (please see Chapter 6 for a description of the connectors). AEN, output Address Enable: used to degate the microprocessor and other devices from the I/O channel to allow DMA transfers to take place. low = CPU Cycle, high = DMA Cycle BALE, output Address Latch Enable: provided by the bus controller and used on the system board to latch valid addresses and memory decodes from the microprocessor. This signal is used so that devices on the bus can latch LA17-23. The SA0-19 address lines latch internally according to this signal. BALE is forced high during DMA cycles. /DACK[0, 5-7], output DMA Acknowledge: 0 to 3 and 5 to 7 are used to acknowledge DMA requests (DRQO through DRQ7). They are active low. This signal indicates that the DMA operation can begin. DRQ[0, 5-7], input DMA Requests: 0 through 3 and 5 through 7 are asynchronous channel requests used by peripheral devices and the I/O channel microprocessors to gain DMA service (or control of the system). A request is generated by bringing a DRQ line to an active level. A DRQ line must be held high until the corresponding DMA Request Acknowledge (DACK/) line goes active. DRQO through DRQ3 will perform 8bit DMA transfers; DRQ5-7 are used for 16 accesses. /IOCHCK, input IOCHCK/: provides the system board with parity (error) information about memory or devices on the I/O channel. low = parity error, high = normal operation IOCHRDY, input I/O Channel Ready: pulled low (not ready) by a memory or I/O device to lengthen I/O or memory cycles. Any slow device using this line should drive it low immediately upon detecting its valid address and a Read or Write command. Machine cycles are extended by an integral number of one clock cycle (67 nanoseconds). This signal should be held in the range of 125-15600nS. low = wait, high = normal operation /IOCS16, input I/O 16 Bit Chip Select: signals the system board that the present data transfer is a 16bit, 1 wait-state, I/0 cycle. It is derived from an address decode. /IOCS16 is active low and should be driven with an open collector (300 ohm pull-up) or tri-state driver capable of sinking 20mA. The signal is driven based only on SA15-SAO (not /IOR or /IOW) when AEN is not asserted. In the 8bit I/O transfer, the default transfers a 4 wait-state cycle. /IOR, input/output I/O Read instructs an I/O device to drive its data onto the data bus. It may be driven by the system microprocessor or DMA controller, or by a microprocessor or DMA controller resident on the I/O channel. This signal is active low. /IOW, input/output I/O Write: instructs an I/O device to read the data on the data bus. It may be driven by any microprocessor or DMA controller in the system. This signal is active low.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 46 IRQ [10, 12, 14, 15], input These signals are used to tell the microprocessor that an I/O device needs attention. An interrupt request is generated when an IRQ line is raised from low to high. The line must be held high until the microprocessor acknowledges the interrupt request. /Master, input This signal is used with a DRQ line to gain control of the system. A processor or DMA controller on the I/0 channel may issue a DRQ to a DMA channel in cascade mode and receive a /DACK. /MEMCS16, input MEMCS16 Chip Select: signals the system board if the present data transfer is a 1 wait-state, 16bit, memory cycle. It must be derived from the decode of LA17 through LA23. /MEMCS16 should be driven with an open collector (300 ohm pull-up) or tri-state driver capable of sinking 20mA. /MEMR, input/output These signals instruct the memory devices to drive data onto the data bus. /MEMR is active on all memory read cycles. /MEMR may be driven by any microprocessor or DMA controller in the system. When a microprocessor on the I/0 channel wishes to drive /MEMR, it must have the address lines valid on the bus for one system clock period before driving /MEMR active. These signals are active low. /MEMW, input/output These signals instruct the memory devices to store the data present on the data bus. /MEMW is active in all memory read cycles. /MEMW may be driven by any microprocessor or DMA controller in the system. When a microprocessor on the I/O channel wishes to drive /MEMW, it must have the address lines valid on the bus for one system clock period before driving /MEMW active. Both signals are active low. OSC, output Oscillator (OSC): a high-speed clock with a 70 nanosecond period (14.31818 MHz). This signal is not synchronous with the system clock. It has a 50% duty cycle. OSC starts 100µs after reset is inactive. RESETDRV, output Reset Drive: used to reset or initiate system logic at power-up time or during a low line-voltage outage. This signal is active high. When the signal is active all adapters should turn off or tri-state all drivers connected to the I/O channel. This signal is driven by the permanent Master. /REFRESH, input/output These signals are used to indicate a refresh cycle and can be driven by a microprocessor on the I/0 channel. These signals are active low. SA0-SA19, LA17 - LA23 input/output Address bits 0 through 19 are used to address memory and I/0 devices within the system. These 20 address lines, allow access of up to 1MBytes of memory. SAO through SA19 are gated on the system bus when BALE is high and are latched on the falling edge of BALE. LA17 to LA23 are not latched and addresses the full 16MByte range. These signals are generated by the microprocessors or DMA controllers. They may also be driven by other microprocessor or DMA controllers that reside on the I/0 channel. The SA17-SA23 are always LA17-LA23 address timings for use with the MSCS16 signal. This is advanced AT96 design. The timing is selectable with jumpers LAxx or SAxx. /SBHE, input/output Bus High Enable (system): indicates a transfer of data on the upper byte of the data bus, XD8 through XD15. Sixteen-bit devices use /SBHE to condition data-bus buffers tied to XD8 through XD15. SD[0-15], input/output These signals provide bus bits 0 through 15 for the microprocessor, memory, and I/0 devices. D0 is the least significant bit and D15 is the most significant bit. All 8bit devices on the I/O channel should use D0 through D7 for communications to the microprocessor. The 16bit devices will use D0 through D15. To support 8bit devices, the data on D8 through D15 will be gated to D0 through D7 during 8bit transfers to these devices; 16bit microprocessor transfers to 8bit devices will be converted to two 8bit transfers.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 47 /SMEMR, input/output These signals instruct the memory devices to drive data onto the data bus for the first MByte. /SMEMR is active on all memory read cycles. /SMEMR may be driven by any microprocessor or DMA controller in the system. When a microprocessor on the I/0 channel wishes to drive /SMEMR, it must have the address lines valid on the bus for one system clock period before driving /SMEMR active. The signal is active low. /SMEMW, input/output These signals instruct the memory devices to store the data present on the data bus for the first MByte. /SMEMW is active in all memory read cycles. /SMEMW may be driven by any microprocessor or DMA controller in the system. When a microprocessor on the I/O channel wishes to drive /SMEMW, it must have the address lines valid on the bus for one system clock period before driving /SMEMW active. Both signals are active low. SYSCLK, output This is an 8MHz system clock. It is a synchronous microprocessor cycle clock with a cycle time of 167 nanoseconds. The clock has a 66% duty cycle. This signal should only be used for synchronization. TC, output Terminal Count: provides a pulse when the terminal count for any DMA channel is reached. The TC completes a DMA-Transfer. This signal is expected by the onboard floppy disk controller. Do not use this signal, because it is internally connected to the floppy controller. /0WS, input The Zero Wait State (/0WS) signal tells the microprocessor that it can complete the present bus cycle without inserting any additional wait cycles. In order to run a memory cycle to a 16bit device without wait cycles, /0WS is derived from an address decode gated with a Read or Write command. In order to run a memory cycle to an 8bit device with a minimum of one-wait states, /OWS should be driven active one system clock after the Read or Write command is active, gated with the address decode for the device. Memory Read and Write commands to an 8bit device are active on the falling edge of the system clock. /0WS is active low and should be driven with an open collector or tri-state driver capable of sinking 20mA. 12V, +/- 5% This signal is used only for the flat panel supply. GROUND = 0V This is used for the entire system. VCC, +5V +/- 0.25V This signal is used for logic and hard/floppy disk supply. For further information about PC/104 and PC/104plus, please refer to the PC/104 Specification Manual which is available on the internet: http://www.digitallogic.com (manuals). 4.2. Expansion Bus The bus currents and maximum lengths are as follows: Output Signals Voltage / Current Maximum Length ISA-BUS  (8MHz) 5.0V @ 8mA 50cm terminated PCI-BUS (33MHz) 3.3V 30cm LPC-Bus 3.3V 2mA 5cm ATA-HD (33 Ohm termination onboard) 3.3V 20cm USB 3.3V 6meter  for bus lengths > 10cm an AC-Bus termination is required.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 48 4.3. Addressing PCI Devices 4.3.1. MSM855/HLV DEVICE IDSEL PIRQ #REG #GNT Remarks Internal Chipset PCI Devices and Resources GMCH Internal A / B / C / D - - PCI Bus 0 AGP Controller Internal A / B - - PCI Bus 0 Graphics Controller Internal A / B - - PCI Bus 0 ICH4_USB Controller Internal A / D / C / H - - PCI Bus 0 Func 0 = USB0 mapped to PIRQA Func 1 = USB1 mapped to PIRQD Func 2 = USB2 mapped to PIRQC Func 7 = USB3 mapped to PIRQH ICH4_PCI Controller Internal A / B / C / D - - PCI Bus 0 ICH4_LPC Controller C / B - - PCI Bus 0 IDE mapped to PIRQC SMB mapped to PIRQB AC97 Audio mapped to PIRQB AC97 Modem mapped to PIRQB Network AD24 E - - Internal chipset onboard device External PCI Slots PC/104+ Slot 1 AD20 E / F / G / H 0-4 0-4 PCI Bus 2 PC/104+ Slot 2 AD21 F / G / H / E 0-4 0-4 PCI Bus 2 PC/104+ Slot 3 AD22 G / H / E / F 0-4 0-4 PCI Bus 2 PC/104+ Slot 4 AD23 H / E / F / G 0-4 0-4 PCI Bus 2 Separate PCI Controller onboard: DEVICE IDSEL PIRQ #REG #GNT Remarks Firewire AD29 Not onboard MiniPCI AD27 Not onboard LAN2 AD26 Not onboard LAN3 AD25 Not onboard

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 49 4.3.2. MSM855B/B2: DEVICE IDSEL PIRQ #REG #GNT Remarks Internal Chipset PCI Devices and Resources GMCH Internal A / B / C / D - - PCI Bus 0 AGP Controller Internal A / B - - PCI Bus 0 Graphics Controller Internal A / B - - PCI Bus 0 ICH4_USB Controller Internal A / D / C / H - - PCI Bus 0 Func 0 = USB0 mapped to PIRQA Func 1 = USB1 mapped to PIRQD Func 2 = USB2 mapped to PIRQC Func 7 = USB3 mapped to PIRQH ICH4_PCI Controller Internal A / B / C / D - - PCI Bus 0 ICH4_LPC Controller C / B - - PCI Bus 0 IDE mapped to PIRQC SMB mapped to PIRQB AC97 Audio mapped to PIRQB AC97 Modem mapped to PIRQB Network AD24 E - - Internal chipset onboard device Network AD26 B 2 2 Only on MSM855B2 PCI to ISA Bridge AD22 3 3 External PCI Slots PC/104+ Slot 1 AD20 E / F / G / H 0-4 0-4 PCI Bus 2 PC/104+ Slot 2 AD21 F / G / H / E 0-4 0-4 PCI Bus 2 PC/104+ Slot 3 NOT AVAILABLE PC/104+ Slot 4 AD23 H / E / F / G 0-4 0-4 PCI Bus 2 Separate PCI Controller onboard: DEVICE IDSEL PIRQ #REG #GNT Remarks Firewire AD29 Not onboard MiniPCI AD27 Not onboard LAN2  AD26 Not onboard LAN3 AD25 Not onboard  not available on MSM855B2

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 50 5. DETAILED SYSTEM DESCRIPTION This system's configuration is based on the ISA and PCI architecture. Read all information carefully as this is very new computer technology. 5.1. Power Requirements This product is an ATX-compatible PC and may only be provided through the power supply connector X8 or X14/X15 with 5Volts if using the ATX- or ACPI features. If you do not use the ATX- or ACPI features power may also be provided to the board through the PC104 BUS. If using the MSMPS104 power supply from DIGITAL-LOGIC, then the ATX- or ACPI features are also supported on the PC104 BUS. Attention! The Pentium-M is a very fast-changing, high-performance processor. The input current is a direct function of the selected performance. The power supply must be capable of delivering the maximum possible current (approximately 8Amp). Futhermore the supply must be able to deliver the inrush current at power-on phase. The inrush current of 15Amp is very high but short (only a few milliseconds). We recommend the following power supplies: 1. PC104 PSU: MSMPS104 Part Nr.: 806032 – without UPS function Part Nr.: 806030 – with UPS function 2. Laboratory PSU: EA-PS 1016-100 (0-16V/10A) http://www.elektroautomatik.de 3. AC/DC Switching PSU: TRACO TOL75-05 (5V/15A/75W) http://www.tracopower.com 5.1.1. Power Supply Cords Power supply cords must be capable of fulfilling the voltage tolerance over the entire performance ratio. That means not more than 100mV voltage drop at 8Ampere. Since board V1.0, we recommend using the X14/X15 connectors to supply the board! Note… If you use connector X8: it is important to connect Pin2 and Pin8 of the power supply with +5Volt and also connect Pin1 and Pin7 with ground. We recommend using a 4-wire cable, not longer than 20cm, to the power supply.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 51 5.1.2. Typical Power Consumption System with 2.5”-hard disk, CD-drive, PS2-KB&MS, 256MB-DDRAM, Pentium-M-1.6GHz CPU Mode Power Consumption CPU-Performance Remarks Booted under DOS 5V / 5Amp 1.6GHz No power management Booted under XP and idle in the desktop 5V / 2Amp Reduced to 0.6GHz ACPI power management Stress test under XP 5V / 7Amp peak 1.6GHz and full video performance Standby from XP 5V / 0.8Amp CPU sleeps Not working Average power 5V / 3Amp = 15Watt Office programs with more than 80% idle time Peripheral requirements Device Quantity Power Consumption Remarks USB 6 0.5A / 5V each Total 15W Keyboard / Mouse 1 / 1 0.1A / 5V each Total 1W HDD 80GB 1 4.7W (start-up) 2.3W (typical) CDRW-DVD combo drive 1 0.9A / 5V 4.5W 5.1.3. Minimum Power-Off Time Attention! If the power is switched off, there must be a minimum 10 second off period. All capacitors must be fully discharged before a new power-on is performed. 5.1.4. ATX–Compatible Power Function Pin Signal Pin Signal Pin 1 Main switch * Pin 2 GND Pin 3 Power button ** * J16 default setting: closed by a jumper between Pins 1 and 2. If this jumper is closed until the main supply comes up, the computer system starts by booting. If you want to use a push button to start the system: If this jumper is open until the main supply comes up, the board will not start. You must connect a push button (main button) to Pin 1-2. After pushing the main button, the board will start. (If you press the main button for more than 4 seconds, the power will switch off.) ** If you want to use the PWRBTN signal (i.e. in W2k or XP), you must connect another push button to Pins 2-3 of Jumper J16 in order to shut down the Windows OS at the push of the button. Attention! After the system is shut down using the power button; to restart, the main button (connected to Pins 1-2) must be used. The PWRBTN signal is low active and internally pulled to 3.3Volt.

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 52 5.1.5. MSM855-HLV-Input (High Level Voltage Input) Note… This product is only available with a separate part number (803012). For more information, please contact your DIGITAL-LOGIC sales partner. This product is also a MIL VG 96916-5-compatible PC. The board must be supplied through the power supply connector or X14/X15 with 5-24Volt and 5V through the power pins of the PC104 bus. The power dissipation of enclosed systems usually used for military mobile applications (24VDC supply) is very critical depending on the system heat, especially in a harsh environment. For the thermal design power (TDP) of the complete system, one must also be careful of the loss of DC/DC converters. Starting with MSM855 Version 1.2, DIGITAL-LOGIC has solved this problem by providing HLV-Input which allows the possibility of supplying the CPU board directly with 5-24V (approved to MIL VG 96916-5) on the branch of the high power-consuming supply. For the additional peripheral 5V, a DC/DC converter with only 10W (instead 50-75W) can be used. We recommend the following DC/DC converter: Eracom RP10S_DEW www.recom-international.de PC104 MSM855 DC/DC +5VDC / 50Watt DC/DC +24VDC / 60Watt Other system components +20..24VDC / 100Watt PC104 Peripheral 3-6Watt loss Typical configuration with a MSM855 PC104 MSM855 with HLV-Input DC/DC +5VDC / 10Watt DC/DC +24VDC / 60Watt +20..24VDC / 100Watt PC104 Peripheral 0.5-1Watt loss Optimized configuration with the MSM855-HLV-Input Other system components

DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 53 5.1.6. MSMPS104 (PC104 power supply) Below is the description of how to connect and configure the MSMPS104 to an MSM855. 5.1.6.1. Necessary Parts  MSMPS104, Part Nr. 806032  MSM855, Part Nr. 803010  MSM855-CK Cable Kit, Part Nor. 802032  Spacerkit-PC/104, Part Nr. 802050 or  Spacerkit-PC/104-Plus, Part Nr. 802051 (if option PC/104-Plus with connector long [Part Nr. 807006] is installed) 5.1.6.2. Procedure 1. Remove Jumper J2 2. Press the two 2x20 Pin and the 2x32 Pin sockets in the PC/104 connector of the MSMPS104 board. Press the 4x30 Pin socket in the PC/104-Plus connector if that option is installed. Mount the four threaded standoffs with four nuts on the MSMPS104 board. Place the MSM855 board on the PC/104 connector of the MSMPS104 and press it down. Fix the MSM855 board with four screws on the threaded standoffs. Connect both boards together with the cables J2

$DIGITAL-LOGIC AG MSM855/HLV/B/B2 Detailed Manual V1.0A 54 5.2. Boot Time System Boot-Times: Definitions/Boot-Medium Quick Boot* Normal Boot MSM855-1600MHz with RTC-backup battery Memory 256MB shared 8MB for video time [s] time [s] From Floppy disk: Boot from Setup-Disk1 MS-DOS v6.22 to "Starting MS-DOS“-Prompt 10 26 Boot from Setup-Disk1 MS-DOS v6.22 to "Welcome Setup Screen“-Prompt 30 45 Boot from "(Sys a:)-Disk“ to "A:/>“-Prompt 18 33 From Hard disk-Toshiba MK2110MAF: Boot from Hard disk to "Starting MS-DOS“-Prompt 10 26 Boot from Hard disk to "Win2000: Windows-Login“-Prompt 80 95 From CompactFlash SunDisk SDCFB-64-101-00 64MB: Boot from CF to "Starting MS-DOS“-Prompt 10 26 Boot from CF to "C:\>“-Prompt 13 29 5.3. Interfaces 5.3.1. AT Compatible Keyboard and PS/2 Mouse Pin Signal 1 Speaker out 2 GND 3 External reset input 4 VCC 5 Keyboard Data 6 Keyboard Clock 7 GND 8 External Battery 9 Mouse Clock (PS/2) 10 Mouse Data (PS/2) 5.3.2. Line Printer Port LPT1 A standard bi-directional LPT port is integrated into the MICROSPACE PC. Further information about these signals is available in numerous publications, including the IBM technical reference manuals for the PC and AT computers and from other reference documents. The current is: IOH = 12mA IOL = 24mA The SMC 37C672 may be programmed via software commands. In the new BIOS version, this selection may be controlled with the BIOS setup screen.$

DETECTION MONITORING TECHNOLOGIES AIMSFS-05X AIMS FAST SCAN RADAR SYSTEM (AIMSFS-05X) User Manual MSM855 Detailed

DETECTION MONITORING TECHNOLOGIES, LLC (dba DMT, LLC) AIMS FAST SCAN RADAR SYSTEM (AIMSFS-05X) MSM855 Detailed

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