748 Tech Ref Manual
748 Tech Ref Manual
748 Tech Ref Manual
August, 1997
Legal Notices
Manual Content
Information in this manual is subject to change without notice.
Hewlett-Packard makes no warranty of any kind about this manual, including, but not lim-
ited to, the implied warranties of merchantability and fitness for a particular purpose.
Hewlett-Packard shall not be liable for errors contained herein or direct, indirect, special,
incidental, or consequential damages about the furnishing, performance, or use of this mate-
rial.
Copyright © Hewlett-Packard Company 1994, 1995, 1996, 1997, 1999. This document con-
tains information which has been protected by copyright. All rights are reserved. Reproduc-
tion, adaptation, or translation without prior written permission is prohibited, except as
allowed under the copyright laws.
Software mentioned and documentation is based in part on the Fourth Berkeley Software
Distribution under license from the Regents of the University of California.
ii
Printing History
Printing History
The printing date and edition number shown is the current edition of this manual. The print-
ing date changes when a new edition is printed. Minor changes may be made at reprint with-
out changing the printing date.
August 1994, Edition 1
April 1995, Edition 2
September 1995 Edition 3
June 1996, Edition 4
December 1996, Edition 5
March 1997, Edition 6
August 1997, Edition 7
iii
Safety Symbols and Conventions
NOTE: Notes contain important information set off from the text.
CAUTION: Caution messages indicate procedures which, if not observed, could result in damage to
equipment. Do not proceed beyond a CAUTION sign until the indicated conditions are fully
understood and met.
WARNING: Warning messages indicate procedures or practices which, if not observed, could result
in personal injury. Do not proceed beyond a WARNING sign until the indicated
conditions are fully understood and met.
iv
Contents
1 General Information
2 References
HP Hardware Manuals 2-2
Contents-1
Contents
3 Quality
Acoustics 3-11
Sound Power Levels 3-11
Contents-2
Contents
4 Mechanical Information
5 Electrical Information
Video Connector Pinouts 5-3
Audio Connector Pinouts 5-8
HP Parallel Connector Pinouts 5-10
RS-232 Connector Pinouts 5-12
AUI LAN Connector Pinouts 5-14
Single-Ended SCSI Connector Pinouts 5-16
FW SCSI Connector Pinout 5-18
PS/2 Connector Pinouts 5-20
VME Connector Pinouts 5-21
Real-Time Clock (RTC) Battery Information 5-37
Battery Specifications 5-37
Video Output Signal Specifications 5-37
Video Timing Specifications 5-37
6 Power Requirements
Contents-3
Contents
Contents-4
1
General Information
The General Information Chapter provides general information on the Model 743 and Model
744 VME Board Computers, the Model 748 Ruggedized Workstation, environmental speci-
fications for the supported monitors, and OEM support.
1-1
General Information
Model 743 and Model 744 VME Board Computers
Product Description
HP Model 744 VME Board Computers are based on the PA 7300LC CPU. HP Model 743
VME Board Computers are based on the PA 7100LC CPU. Running either HP-UX or HP-RT
operating systems, they are typically installed in a VME backplane.
• Model 744/165L: HP-UX operating system, 165 MHz system clock
• Model 744rt/165L: HP-RT operating system, 165 MHz system clock
• Model 744/132L: HP-UX operating system, 132 MHz system clock
• Model 744rt/132L: HP-RT operating system, 132 MHz system clock
• Model 743i/64: HP-UX operating system, 64 MHz system clock
• Model 743i/100: HP-UX operating system, 100 MHz system clock
• Model 743rt/64: HP-RT operating system, 64 MHz system clock
• Model 743rt/100: HP-RT operating system, 100 MHz system clock
Each board computer is complete with the core I/O of an HP-PA workstation in a single-slot
VME solution with expandability for more I/O or RAM in a two-slot or three-slot VME solu-
tion. The core design includes application-specific integrated circuits (ASICs) that add VME
and real-time features.
Figure 1-1 illustrates the front panel of Model 743 and Model 744 Board Computers.
Figure 1-1 Model 743 and Model 744 VME Board Computer Front View
Table 1-2 lists the feature sets of the Model 743i VME Board Computer
1-2
General Information
Model 743 and Model 744 VME Board Computers
.
Table 1-1 Model 743i (A4260A) and 743rt (A4261A) Features
Feature Specifications
Compatibility Source and binary code compatible with the Series 700 product family
Monitors Single or multiple display depending on the number of installed graphics options (on-
board and/or external). HP-UX 9.x supports up to two displays and HP-UX 10.x supports
up to three displays.
Color monitors
17-inch, 1280 x 1024
19-inch, 1280 x 1024
Terminals - Text only connected to RS-232C port
Two Slot Upgrades PMC Bridge Adapter (A4504A) with two PMC sites
GSC Expansion kit (A4219A) with two GSC sites
1-3
General Information
Model 743 and Model 744 VME Board Computers
Feature Specifications
Three Slot Upgrades PMC Expansion Adapter (A4509A) with two additional PMC sites
ATM card (J3420A) (Requires GSC expansion kit A4262A - one additional site supported
for 3x5 GSC card) (Not available with HP-RT)
Table 1-2 lists the feature sets of the Model 744/132L VME Board Computer
.
Table 1-2 Models 744/132L (A4500A) and 744rt/132L (A4520A) Features
Feature Specifications
Compatibility Source and binary code compatible with the Series 700 product family
Monitors Single or multiple display depending on the number of installed graphics options
(on-board and/or external)
Color monitors
17-inch, 1280 x 1024
19-inch, 1280 x 1024
Terminals - Text only connected to RS-232C port
Main Memory Single VME Slot Configuration - 64 to 256 MB A4503A, A4449A, A6005A)
Two VME Slots Configuration - 64 to 1024 MB
1-4
General Information
Model 743 and Model 744 VME Board Computers
Feature Specifications
Two Slot Upgrades PMC Bridge Adapter (A4504A) with two PMC sites
GSC Expansion kit (A4219A) with two GSC sites)
Table 1-3 lists the feature sets of the Model 744/165L VME Board Computer
.
Table 1-3 Model 744/165L (A4511A) and 744rt/165L (A4512A) Features
Feature Specifications
Compatibility Source and binary code compatible with the Series 700 product family
1-5
General Information
Model 743 and Model 744 VME Board Computers
Feature Specifications
Monitors Single or multiple display depending on the number of installed graphics options
(on-board and/or external)
Color monitors
17-inch, 1280 x 1024
19-inch, 1280 x 1024
Terminals - Text only connected to RS-232C port
Main Memory Single VME Slot Configuration - 64, 128, or 256 MB (A4503A, A4449A or
A6005A)
Two VME Slots Configuration - 64 MB to 1024 MB
Two Slot Upgrades PMC Bridge Adapter (A4504A) with two PMC sites
GSC Expansion kit (A4219A) with two GSC sites
1-6
General Information
Model 743 and Model 744 VME Board Computers
Supported Configurations
This section discusses the following supported configurations: memory, system graphics,
external devices, cables, and keyboard and mouse.
Hewlett-Packard only supports products having Hewlett-Packard approved parts, accesso-
ries, peripherals, operating systems, and application programs.
1-7
General Information
Model 743 and Model 744 VME Board Computers
System Graphics
The Model 743 and Model 744 Board Computers can be ordered with optional on-board
graphics.
The Model 744 supports up to four optional PMC Visualize-EG graphics cards.
The HP-UX 10.20 ACE operating system supports up to four displays.
The HP-RT operating system supports only one graphics display.
Table 1-4 shows the display resolutions and refresh rates that are supported on current and
older graphics devices.
NOTE: The HCRX graphics options support a Frame Buffer of 1280 by 1024; therefore, the monitor
selected must support a resolution of 1280 by 1024.
1280x1024* 75 Hz •* •* •
72 Hz •
1024 x 768* 75 Hz •* •*
70 Hz
800 x 600 75 Hz • •
640 X 480 75 Hz • •
60 Hz
With the D8900A monitor, HP-UX 10.20 ACE or 11.00, and the A4267A graphics card or
Model 743 onboard graphics, these resolutions are not supported.
1-8
General Information
Model 743 and Model 744 VME Board Computers
Product
Interface Cable Type
Number
Conversion cables provide a way to connect a standard cable to the high-density connectors
on the Model 743 and Model 744 front panels.
All conversion cables, except the A4167A, are 762 plus/minus 30mm (30 plus/minus 1.18
inch) long. The A4167A cable is 250 mm (10 inches) long.
1-9
General Information
Model 743 and Model 744 VME Board Computers
Product
Interface Cable Type
Number
1-10
General Information
Model 743 and Model 744 VME Board Computers
1-11
General Information
Model 743 and Model 744 VME Board Computers
PCMCIA Connector
I/O Controller
Boot ROM
Optional Onboard
Graphics Controller
PCMCIA Connector
GSC Bus Connector
CPU (under heatsink)
VME Controller
EEPROM
IODC
I/O Controller
Audio CODEC
Video RAM
Optional Onboard (optional onboard graphics)
Graphics Controller
1-12
General Information
Model 743 and Model 744 VME Board Computers
Figure 1-4 illustrates the functional architecture of the Model 743 system board.
1-13
General Information
Model 743 and Model 744 VME Board Computers
Backplane RAM
Controller Card
ASIC 64–256 MB
CPU RAM
EEPROM
RAM Stack Card
64–256 MB
Firmware
REGs RAM Bus
Controller
1-14
General Information
Model 743 and Model 744 VME Board Computers
CPU Circuit
The Model 743 uses a Hewlett-Packard PA-RISC 7100-LC CPU chip and the Model 744
uses a Hewlett-Packard PA-RISC PA7300-LC CPU chip. The CPU chip is the heart of the
CPU circuit. It executes instructions and controls the other circuits.
Table 1-7 lists the CPU performance figures of the Model 743 with HP-UX and Table 1-7
lists the CPU performance figures for the Model 744 with HP-UX.
1-15
General Information
Model 743 and Model 744 VME Board Computers
NOTE: The workstation's LAN ID number's last 6 characters are labeled on the EEPROM. The first
group of six digits are typically “080009” or “0060b0” (the HP-owned prefix).
A PLL Clock Module generates the system clock, on which all timing is based.
Graphics Circuit
System boards with on-board graphics or graphics cards have a graphics controller ASIC and
the display RAM. Resolution and refresh rate can be configured using the boot console han-
dler for several types of monitors.
A keyboard must be connected to the PS/2 0 port if graphics are used as part of the console
path. When a graphics device is specified as the console path, the boot ROM first checks for
a keyboard by using the keyboard search list. If a keyboard is not found in this search list,
graphics are not enabled.
Table 1-9 summarizes the graphics performance figures for the Model 743 with HP-UX and
Table 1-9 summarizes the graphics performance figures for the Model 744 with HP-UX.
HCRX 8 HCRX 8
8 Plane 8 Plane
and 24 and 24
PLBsurf 19 21 23 32
Triangles/sec 26K 25K 40K 40K
1-16
General Information
Model 743 and Model 744 VME Board Computers
On-board
132 MHz 165 MHz
HP Visualize-EG Graphics
1-17
General Information
Model 743 and Model 744 VME Board Computers
RAM Cards When mixing RAM cards of different capacities that include 128 MB and 256
MB cards, the 128 MB and 256 MB cards must be installed into the lowest numbered mem-
ory sites. Memory mapping at turn on determines the size of the card in each location.
LED Displays
Model 743 and 744 VME Board Computers have two LEDs that indicate various system
functions: a system failure LED and a functional LED. See Table 1-11.
Table 1-11 LED Meanings
SYSFAIL POWER
Meaning Possible Solution
(Red) (Green)
Off Off No Power Check for board seating in
chassis.
On 2Hz Flash Normal Power-on/self-
test
On Off Memory Failure Troubleshoot for failed RAM
card or problem with the
RAM connection.
On 1 Flash/sec. CPU (board) Failure Replace the system board.
On 4 Flash/sec. No console identified Check the console search
path and keyboard connec-
tions. If no problem is found,
replace the system board.
On On OS is booted with Check the Operating System
VME services failure VME services. Check that
VME services is configured
in the kernel.
Off On OS is booted with
VME services OK
1-18
General Information
Model 743 and Model 744 VME Board Computers
Table 1-12 summarizes I/O performance figures for the Model 743.
Table 1-12 Model 743 I/O Performance
I/O Type Performance Notes
20 MB/second Synchronous
Table 1-13 summarizes I/O performance figures for the Model 744
Table 1-13 Model 744 I/O Performance
I/O Type Performance Notes
20 MB/second Synchronous
LAN 10 Mb/second
1-19
General Information
Model 743 and Model 744 VME Board Computers
Table 1-14 lists the Model 743 and Model 744 audio specifications.
Function Range
1-20
General Information
Model 743 and Model 744 VME Board Computers
AUI LAN LAN circuits use the Ethernet/IEEE 802.3 standard interface. Only the Attach-
ment Unit Interface (AUI) version is used; no BNC connector is provided for ThinLAN. The
AUI connector enables connections to an external MAU using the HP A4303A adapter cable.
Table 1-15 summarizes the LAN AUI interface specifications.
Single-Ended SCSI The 8-bit single-ended implementation is compatible with the current
Series 700 products and supports 5 MB/sec data transfer rates.
The SCSI bus is terminated to 3.3 volts through 127 ohms on the system board. If the board
computer is used in a VME chassis having internal mass storage devices, all devices except
the last one must have their terminator removed. If an external disk drive is used, an active
terminator must be used on the last drive’s uncabled connector.
Table 1-16 summarizes the specifications for the single-ended SCSI interface.
Device limits 7 internal and/or external devices plus the host controllera
1-21
General Information
Model 743 and Model 744 VME Board Computers
HP Parallel The parallel port is compatible with Centronics standards, plus some additional
features found in HP Series 700 workstations. It supports a bi-directional register model
interface. An 8-bit parallel, synchronous interface is used.
A high-density micro D-sub connector is used for the HP Parallel interface. An HP A4300A
adaptor cable is required to convert to standard PC compatible 25-pin female D-sub.
Table 1-17 summarizes the specifications for the HP parallel interface.
PS/2 Ports 1 and 0 There are two PS/2 style serial ports: one PS/2 keyboard port and one
PS/2 mouse port.
RS-232 There are two serial interfaces. The I/O controller ASIC controls port A, and the
VME controller ASIC controls port B. Each supports CTS/RTS hardware handshaking. An
HP A4301A adaptor cable is required to convert it to a standard PC compatible, 9-pin male
D-sub. The maximum baud rate listed in Table 1-18 is the hardware limit. Actual transfer
rates depend upon the operating system and application load.
Table 1-18 summarizes the specifications for RS-232-C.
NOTE: The RS-232 port B is not active until VME Services is up and running.
Battery-Backed Real-Time Clock The battery-backed clock is implemented in the I/O con-
troller ASIC. Once power is applied to the system board, the battery-backed clock time is
read by the operating system only during system initialization. Once the operating system is
booted, real time is kept by using the timer built into the CPU. The battery-backed real-time
clock is updated by the operating system only when the user (“root” or “super-user”) explic-
itly requests it though the date command. The clock has a resolution of 1 second. The accu-
racy of the clock is within ±5 seconds every 24 hours when the operating temperature is from
0 to 55 Deg.C.
1-22
General Information
Model 743 and Model 744 VME Board Computers
Function Capabilities
D32
D16 Block
D32
D64
1-23
General Information
Model 743 and Model 744 VME Board Computers
D32 MBLT
Master 10 12 38 44
Slave 9 13 33 38
Interval Timers Three interval timers are part of the VME controller ASIC. These timers
provide interrupts on terminal count and interrupt and restart on terminal count capability.
Table 1-22 summarizes the specifications for the interval timer.
Resolution Drift
Watchdog Timer The VME controller ASIC also includes a watchdog timer used with the
HP-RT operating system.
1-24
General Information
Model 743 and Model 744 VME Board Computers
I/O Expansion
The Model 743 and Model 744 board computers are capable of accepting expansion adapters
allowing greater functionality through expansion I/O cards. The PMC bridge adapter (for
HP-UX systems only) occupies an additional VME slot directly above or adjacent to the
board computer, and has two sites for industry standard +5V signalling PMC cards. The
PMC expansion adapter occupies another VME slot adjacent to or above the PMC bridge
adapter, and provides two additional sites for PMC cards. The GSC expansion adapter has
two sites for GSC expansion cards, and occupies one VME slot adjacent to or above the
board computer. The PMC adapters and the GSC adapter cannot function together.
HP provides three GSC solutions for expanded I/O:
• 8-plane color graphics controller
• FWD SCSI controller
• ATM network controller
Fast, Wide, Differential SCSI (GSC) (HP-UX only) The FWD 16-bit implementation supports
20 MB/sec data transfer rates.
The internal, removable, differential bus terminators allow the card to be located at either end
or between the ends of a SCSI bus. The host SCSI ID for the port is set by the user by way of
the 4-position address selector DIP-type switch.
By default, the FWD SCSI card terminates one end of the SCSI bus by using removable ter-
minator resistors that are on the card. Remove these terminator resistors if the card is in the
middle of the bus.
Table 1-23 summarizes the FWD SCSI interface specifications.
1-25
General Information
Model 743 and Model 744 VME Board Computers
1-26
General Information
Model 748 Ruggedized Workstation
Product Description
Hewlett-Packard offers the following HP 9000 products:
• Model 748/132L Ruggedized Workstation
• Model 748/165L Ruggedized Workstation
The 748/132L and 748/165L model incorporates the HP 744/132L and HP 744/165L VME
Board Computers that are based on the PA-RISC 7300LC central processing unit (CPU). All
models provide a variety of interface, graphics, mass storage, and accessory card configura-
tions. Table 1-24 summarizes the features of the Model 748.
Table 1-24 Model 748 Ruggedized Workstation Features
Feature Functionality
Supported Configurations
This section discusses the following supported configurations: mass storage, monitors, GSC
mezzanine slot, built-in interfaces, EISA module, PCI module, and VME module.
1-27
General Information
Model 748 Ruggedized Workstation
Mass Storage
Model 748 uses several factory-installed mass storage devices. One or two removable media
devices may be installed. Model 748 mass storage devices are factory installed with the
removable media drives accessed from the front. Users may reconfigure devices to reverse
the access. Hard disk drives are typically installed behind the removable media devices.
Mass storage devices are also available as the following upgrades:
• HP A4484A 4 GB SE SCSI Hard Drive Upgrade
• HP A5006A 9 GB SE SCSI Hard Drive Upgrade
• HP A2643A 2 - 4 GB DDS (DDS-1, 2 GB native, 4 GB with data compression) Tape Drive
Upgrade
• HP A4307A 4-8 GB DDS (DDS-2, 4 GB native, 8 GB with data compression) Tape Drive
Upgrade
• HP A4252A 12 - 24 GB DDS (DDS-3, 12 GB native, 24 GB with data compression) Tape
Drive Upgrade
• HP A2645A 3.5-inch Flexible Disk Drive Upgrade
• HP A4496A Fast CD-ROM Disk Drive Upgrade
Monitors
Table 1-25 lists the monitors supported. Grayscale monitors are not supported.
1-28
General Information
Model 748 Ruggedized Workstation
NOTE: Only one of the Human Interfaces (HP-HIL or PS/2) can be used at a time. Use of one interface
excludes the other interface.
Product Quantity
Product Name Notes
Number Supported
PCI Module The Model 748 is available with a module that provides four slots for customer
provided PCI accessory cards. The module supports the +5 Vdc PCI bus signalling card type.
VME Module A variety of VME accessory cards can be installed in the Model 748 ’s 8-slot
VME module (slots 3 through 8 are for add-on cards). The slots conform to the 6U form fac-
tor. Slot numbers are 8 through 1, top to bottom. The VME backplane provides an intercon-
nect connector for the EISA module.
NOTE: A Model 743 or 744 must be installed in VME Slot 1 to provide VME Slot 1 controller
functions (bus arbitration) for any VME boards installed in VME slots 3 through 8.
1-29
General Information
Model 748 Ruggedized Workstation
EISA Bus Performance The ideal slave read/write transfer rate is 25/25 MB/sec.
Block Diagram
Figure 1-8 shows the functional architecture of the Model 748 workstation.
1-30
General Information
Model 748 Ruggedized Workstation
1-31
General Information
Model 748 Ruggedized Workstation
Standard Support
OEMs may obtain the following standard hardware and software support through their local
Hewlett-Packard Sales and Service Office:
• Customer support programs for servicing Hewlett-Packard products
• System/product hardware/software configurations
• System support options, including the following:
• HP SupportLine electronic support
• License to use software updates
• Media and document updates
• On-site response
1-32
2
References
This chapter lists the titles and part numbers for hardware and software manuals associated
with the Model 743/744 and Model 748.
2-1
References
HP Hardware Manuals
This section contains tables listing the hardware installation guides, service manuals, and
diagnostic manuals for the Model 743/744 and Model 748.
Installation Guides
Table 2-1 lists the hardware installation guides available for the Model 743 and Model 748.
Table 2-1 System Installation/Owner’s Manuals
Service Manuals
Table 2-2 lists the hardware service manuals available for the Model 743/744 and Model
748.
Table 2-2 Related Service Manuals
Part
Manual Title
Number
2-2
References
Diagnostic Manuals
Table 2-3 lists the hardware diagnostic manuals available for the Model 743/744 and Model
748.
PA-RISC Support Tools Manual Licensed Users Volume 8, ISL Sup- 5960-3163
port Tools
Support Tools Manager User’s Manual; HP 9000 Series 700 and 800 5961-1612
2-3
References
HP Software Manuals
This section contains tables listing the software system usage manuals and development
manuals for the Model 743/744 and Model 748.
Table 2-4 lists the software system usage manuals available for the Model 743/744 and
Model 748.
Table 2-5 lists the software development manuals available for the Model 743/744 and
Model 748.
2-4
3
Quality
3-1
Quality
Safety Compliance Programs
Introduction
Models 743, 744, and 748 are designed, manufactured, and marketed in compliance with the
published safety standards stated below. Validation testing was done with one unit represen-
tative of the product shipped to the customer. Continued compliance is measured by periodic
regulatory audits; production units are tested for each audit. Models 743, 744, and 748 are in
compliance with adopted safety standards issued by the following standards bodies:
• Underwriter's Laboratories (USA)
• Canadian Standards Association (Canada)
• TUV Rheinland (Germany)
The sections that follow explain each standard.
3-2
Quality
Electromagnetic Compatibility Programs
Introduction
Models 743, 744 and 748 comply with published standards for Electromagnetic Compatibil-
ity (EMC). In general, testing to required standards was performed using statistically signifi-
cant quantities of typical Models 743, 744 and 748 configurations representative of the
product shipped to customers. These tests’ statistical basis demonstrates that with 80% confi-
dence, at least 80% of the production population meets the specified margins to each stan-
dard. Additional configurations are also tested to reduce the probability that non-conforming
configurations exist. Continued compliance is measured by periodic regulatory audits; pro-
duction units are tested for each audit. The Models 743, 744 and 748 are in compliance with
adopted EMC standards issued by the following standards bodies:
• Federal Communications Commission (USA)
• European Community
• Voluntary Control Council for Interference (Japan)
European Community
• Compliance Date: 6 November 1992 (dates of subsequent revisions available upon re-
quest)
• Compliant to the EMC Directive 89/33/EEC and 92/31/EEC for Information Technol-
ogy Equipment (ITE) per EN55022, and for Industrial, Scientific, and Medical Equip-
ment (ISM) per EN55011
As evidence of compliance, products are marked with the CE mark, and the product manuals
include a Declaration of Conformity.
3-3
Quality
Electromagnetic Compatibility Programs
Overview
The sections that follow summarize the Electromagnetic Compatibility Programs. The fol-
lowing is a list of those programs:
1 Electromagnetic field emissions test suite
• Radiated emissions (Table 3-1)
• Conducted emissions (Table 3-2)
• Magnetic emissions (Table 3-3 and Table 3-4)
2 Electromagnetic field immunity/susceptibility test suite
• Electro-Static discharge field immunity (Table 3-5)
• Radiated field immunity (Table 3-6)
• Magnetic field immunity (Table 3-7)
3 Line transients immunity/susceptibility test suite
• Electrical fast transients (Table 3-8)
• Surge transients (Table 3-9)
• Conducted immunity (Table 3-10)
• Line sag (Table 3-11) Line surge (Table 3-12)
• Line blackout/dropout (Table 3-13)
• Line brownout (Table 3-14)
• Line brownout/recovery (Table 3-15)
Standard Level
Standard Level
3-4
Quality
Electromagnetic Compatibility Programs
Standard Level
Table 3-3 summarizes the magnetic emissions tests while the equipment is not operating.
Table 3-3 Magnetic Emissions Tests While Non-Operating
Standard Level
Standard Level
NOTE: All tests in this suite were performed while the product was operating.
Standard Level
Standard Level
3-5
Quality
Electromagnetic Compatibility Programs
Standard Level
NOTE: All tests in this suite were performed while the product was operating.
Standard Level
Standard Level
Standard Level
Standard Level
3-6
Quality
Electromagnetic Compatibility Programs
Standard Level
Standard Level
HP Standard 765.003 20 ms
Standard Level
Standard Level
3-7
Quality
Climatic and Dynamic Environmental Ruggedness
Introduction
Models 743, 744 and 748 are designed for use in an environment that involves moderately
high and low temperatures, humidity variations, and occasional vibration. Many of the test
limits the workstations are subjected to during development are more severe than those docu-
mented.
The tests were developed to cause product failure so that product weaknesses are identified,
understood, and eliminated, when possible and to provide greater assurance of long-term
compliance to product specifications.
An effective qualification program establishes appropriate assurances. Our development and
manufacturing process capabilities are well understood.
Significant quantities of Models 743, 744, and 748 were tested prior to release for volume
production. Representative samples of customer-shippable workstations were tested in vari-
ous configurations through the environmental tests to evaluate corner-case conditions.
NOTE: Presentation of these test suites does not imply a guarantee of product performance, nor a
guarantee of performance to these levels by the entire population of Models 743, 744, and 748
computer systems.
Overview
The following is a list of the climatic and environmental ruggedness tests suites summarized
in this section:
1 Temperature, humidity, and altitude test suite
• Temperature (Table 3-16 and Table 3-17)
• Humidity (Table 3-18 and Table 3-19)
• Altitude (Table 3-20 and Table 3-21)
2 Vibration and shock test suite
• Vibration (Table 3-22)
• Shock (Table 3-23 and Table 3-24)
3-8
Quality
Climatic and Dynamic Environmental Ruggedness
Standard Level
Standard Level
Table 3-18 and Table 3-19 summarize the humidity tests suite.
Table 3-18 Humidity Tests While Non-Operational
Standard Level
Standard Level
Table 3-20 and Table 3-21 summarize the altitude test suite.
Table 3-20 Altitude Tests While Non-Operating
Standard Level
Standard Level
3-9
Quality
Climatic and Dynamic Environmental Ruggedness
Standard Level
HP Standard 759 (class B1)(exceeds IEC 654-3/VH2) 7.4 m/s2 (0.75 g 0-p)
swept sine
Table 3-23 and Table 3-24 summarizes the shock tests suite.
Table 3-23 Shock Tests While Non-Operational
Standard Level
Standard Level
HP Standard 760 (class B), IEC 654-3 150 cm/s < 3ms 1/2 half sine
3-10
Quality
Acoustics
Acoustics
This section summarizes the sound power level test suite.
3-11
Quality
Statistical Reliability
Statistical Reliability
The sections that follow explain the Annualized Failure Rate (AFR) and the Mean Time
Between Failure (MTBF) computations.
Example AFR
1
= 159,381 hours
0.055 / 8766 hours
3-12
Quality
Statistical Reliability
The H-MTBF numbers in the following tables are rounded to the nearest 100 hours.
Table 3-27 Model 748 Ruggedized Workstation With Model 743 CPU AFR Projections (%/Year)
Projected
Hardware Configurations AFR (%/Yr.)
Table 3-28 Model 748 Ruggedized Workstation With Model 744 CPU AFR Projections (%/Year)
Projected
Hardware Configurations AFR (%/Yr.)
Table 3-29 Model 743 VME Board Computer AFR Projections (%/Year)
Projected
Hardware Configurations
AFR (%/Yr.)
743 VME Board Computer, and on-board 8-plane color graphics 3.8
Memory 8 MB RAM card (one card using 4 Mbit DRAM) 0.6
16 MB RAM card (one card using 4 Mbit DRAM) 1.2
32 MB RAM card (one card using 16Mbit DRAM) 0.7
64 MB RAM card (one card using 16Mbit DRAM) 1.5
3-13
Quality
Statistical Reliability
Table 3-30 Model 744 VME Board Computer AFR Projections (%/Year)
Projected
Hardware Configurations
AFR (%/Yr.)
No On-Board On-Board
Hardware Graphics Graphics
(Includes Model 743 VME Board
Computer) MTBF (Hours) MTBF (Hours)
3-14
4
Mechanical Information
This chapter contains mechanical information about the components of the Model 743 and
Model 744 VME Board Computers and the Model 748 Ruggedized Workstation. Included is
air flow requirements, interface connector manufacturing data, system board and accessory
card dimensions, chassis and module dimensions and weights, mounting and support, and
mechanical drawings.
4-1
Mechanical Information
Model 743 and Model 744 VME Board Computers
Key Components
Figure 4-1 shows key components on the Model 743 VME Board Computer.
PCMCIA Connector
Boot ROM
EEPROM
Optional Onboard
Graphics Controller
4-2
Mechanical Information
Model 743 and Model 744 VME Board Computers
Figure 4-2 shows key components on the Model 744 VME Board Computer.
VME Controller
EEPROM
IODC
I/O Controller
Audio CODEC
Video RAM
Optional Onboard (optional onboard graphics)
Graphics Controller
4-3
Mechanical Information
Model 743 and Model 744 VME Board Computers
NOTE: Model 743 and Model 744 VME Board Computers are to be operated only in an environment
that is free from conductive pollution, including dry non-conductive pollution which could
become conductive due to expected condensation.
CAUTION: Integrated circuit case and junction temperatures must not exceed those shown in
Figure 4-3 and Figure 4-4.
4-4
Mechanical Information
Model 743 and Model 744 VME Board Computers
Tj = 95 (744/132L)
= 102 (744/165L)
Tj = 85
Tj = 100
Tj = 85
Tc= 75
4-5
Mechanical Information
Model 743 and Model 744 VME Board Computers
Interface Connectors
Table 4-1 lists the interface connector manufacturing data.
Manufacturing
Connector Manufacturing Part Number
Data
4-6
Mechanical Information
Model 743 and Model 744 VME Board Computers
Mechanical Dimensions
Figure 4-5 and Figure 4-6 show the dimensions of the Model 743 board computer.
4-7
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-8
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-9
Mechanical Information
Model 743 and Model 744 VME Board Computers
Figure 4-8 through Figure 4-12 show the dimensions of the Model 744 system board.
4-10
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-11
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-12
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-13
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-14
Mechanical Information
Model 743 and Model 744 VME Board Computers
Figure 4-13 through Figure 4-15 show the dimensions of a Model 744 RAM card.
4-15
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-16
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-17
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-18
Mechanical Information
Model 743 and Model 744 VME Board Computers
4-19
Mechanical Information
Model 748 Chassis and Modules
4-20
Mechanical Information
Model 748 Chassis and Modules
Figure 4-20 shows the dimensions of the Model 748 outside wall.
4-21
Mechanical Information
Model 748 Chassis and Modules
Figure 4-22 shows the dimensions of the Model 748 mass storage module chassis.
4-22
Mechanical Information
Model 748 Chassis and Modules
Figure 4-23 shows the dimensions of the Model 748 VME module chassis.
4-23
Mechanical Information
Model 748 Chassis and Modules
Figure 4-24 shows the dimensions of the Model 748 PCI/EISA module chassis.
4-24
Mechanical Information
Model 748 Chassis and Modules
Figure 4-25 shows the dimensions of the Model 748 EISA converter board.
Figure 4-26 shows the dimensions of the Model 748 PCI converter board.
4-25
Mechanical Information
Model 748 Chassis and Modules
Figure 4-27 shows the dimensions of the Model 748 VME backplane board.
Figure 4-28 shows the dimensions of the Model 748 power distribution board.
4-26
Mechanical Information
Model 748 Chassis and Modules
Weights
Table 4-2 lists the weights of the components of the Model 748 workstation.
Metric English
Part Name
Weight Weight
Model 748 Ruggedized Workstation chassis including power distribution board, 9.50 Kg 21 lbs. 2.0 oz.
on/off switch, and front cover (does not include modules or board computer)
SE Mass storage module including SCSI and power cables 2.03 Kg 4 lbs. 8.1 oz.
FWD Mass storage module including SCSI and power cables 2.25 Kg 5 lbs. 0 oz.
Disk drives (maximum weight) 0.95 Kg 2 lbs. 1.6 oz.
VME module (including six slot cover) 1.91 Kg 4 lbs. 4.0 oz.
Model 744 Board Computer with on-board graphics (no other options) 0.62 Kg 1 lb. 1.7 oz.
PMC bridge board with mounting hardware (no blank bezels) 0.27 Kg 7.6 oz.
PMC expansion board with mounting hardware (no blank bezels or sleeves) 0.24 Kg 6.8 oz.
4-27
Mechanical Information
Model 748 Chassis and Modules
Mechanical Drawings
For OEMs that have signed a Hewlett-Packard non-disclosure agreement, the mechanical
drawings are available by request from the Workstation Systems Group through your
Hewlett-Packard OEM Sales Representative. These drawings are Hewlett-Packard confiden-
tial and cannot be redistributed.
When you ask for drawings, please specify the following:
• Drawing part number, size, and page number, if needed
• Name, assembly or subassembly
The drawings are sent to your Sales and Service Office.
Conversion Cables
All conversion cables are 762 plus or minus 30 mm (30 plus or minus 1.18 inch) long. The
end of the cable that connects to the board computer uses a micro D-sub male (MDSM) con-
nector. The other end of the cable uses a standard D-sub or other connector.
4-28
Mechanical Information
Model 748 Chassis and Modules
Subassembly Drawing
Assembly Group Included Subassemblies
Number
Chassis D-A4309-00011-10
4-29
Mechanical Information
Model 748 Chassis and Modules
4-30
5
Electrical Information
The Electrical Information Chapter contains information on the connector pinouts, real-time
clock battery, and video output signal specifications.
5-1
Electrical Information
The sections that follow contain figures and tables of the connector pinouts and the wiring
tables for video, audio, HP parallel, RS-232, AUI LAN, single-ended SCSI, FW SCSI, PS/2,
and VMEbus; specifications for the real-time battery clock, video output signals, and video
timing.
5-2
Electrical Information
Table 5-1 identifies the pins on the Model 743 and Model 744 I/O backplane video connec-
tor.
5-3
Electrical Information
Figure 5-2 illustrates the connector pin locations on each end of the HP A4304A conversion
video cable.
Pin 1
Pin 2
Pin 3 Pin 1
Pin 4 Pin 6
Pin 5 Pin 2
Pin 6 Pin 7
Pin 7 Pin 3
Pin 8 Pin 8
Pin 9 Pin 10
Pin 10 Pin13
Pin 11
Pin 12
Pin 13
Pin 14
Pin 15 Pin 14
5-4
Electrical Information
Figure 5-3 illustrates the connector pin locations on each end of the HP A4223A conversion
video cable.
Pin 1 Pin 12
Pin 2
Pin 3 Pin 1
Pin 4 Pin 6
Pin 5 Pin 2
Pin 6 Pin 7
Pin 7 Pin 3
Pin 8 Pin 8
Pin 9 Pin 10
Pin 10 Pin13
Pin 11 Pin 9
Pin 12
Pin 13
Pin 14
Pin 15 Pin 14
5-5
Electrical Information
Figure 5-4 illustrates the connector pin locations on each end of the HP A4305A conversion
video cable.
C5
WIRING DIAGRAM
PIN 15 C2 C4
PIN 8 1 1
2 2
3 3 C1 C3
4 4
5 5
6 6
7 7 PIN 10
8
9
8
9
PIN 30
10 10
11 11
12 12
13 13
14 14
15 15
16
PIN 9 PIN 1 17
18
19
20
21
22
23 PIN 1
24 PIN 21
25
26
27
28
29
PIN 11
30
C1
C2
C3
1.8K Resistor
C4
C5
OUTER SHELL
Pin 1 Pin 26
Pin 2 Pin 25
Pin 3 Pin C1
Pin 4 Pin C5
Pin 5 Pin C2
Pin 6 Pin C5
Pin 7 Pin C4
Pin 8 Pin C5
Pin 9 Pin 4
Pin 10 Pin 5
Pin 11 Pin 28
Pin 12
Pin 13
Pin 14
Pin 15 Pin 6
5-6
Electrical Information
Figure 5-5 illustrates the connector pin locations on each end of the HP A4167A conversion
video cable.
C5
WIRING DIAGRAM
PIN 15 C2 C4
Pin 6 PIN 8 1 1
2 2
Pin 11 Pin 1 3 3 C1 C3
4 4
5 5
6 6
7 7 PIN 10
8
9
8
9
PIN 30
10 10
11 11
12 12
13 13
14 14
15 15
16
PIN 9 PIN 1 17
18
19
20
21
Pin 5 22
Pin 15 23 PIN 1
24 PIN 21
25
Pin 10 26
27
28
29
PIN 11
30
C1
C2
C3
C4
C5
OUTER SHELL
Pin 1 Pin C1
Pin 2 Pin C2
Pin 3 Pin C4
Pin 4
Pin 5 Pin 25
Pin 6 Pin C5
Pin 7 Pin C5
Pin 8 Pin C5
Pin 9 Pin 28
Pin 10 Pin 4
Pin 11
Pin 12 Pin 26
Pin 13 Pin 5
Pin 14 Pin 6
Pin 15 Pin 27
5-7
Electrical Information
Pin
Signal
Number
1 Mic in GND
2 Line in left
3 Line in right
4 Headset right
5 Headset left
6 Mic in A
7 Mic Vref
8 Line in GND
9 Headset GND
5-8
Electrical Information
Figure 5-7 illustrates the connector pin locations on each end of the HP A4302A conversion
audio cable.
5-9
Electrical Information
Pin Pin
Signal Signal
Number Number
1 STROBE 14 AFD
2 Data 0 15 ERROR
3 Data 16 INIT
4 Data 17 SCT IN
5 Data 18 GND
6 Data 19 GND
7 Data 20 GND
8 Data 21 GND
9 Data 22 GND
10 ACK 23 GND
11 BUSY 24 GND
12 PE 25 GND
13 SLCT
5-10
Electrical Information
Figure 5-9 illustrates the connector pin locations on each end of the HP A4300A conversion
HP parallel cable
Pin 13 Pin 13
5-11
Electrical Information
Pin Pin
Signal Signal
Number Number
1 DCD 6 DSR
2 RXD 7 RTS
3 TXD 8 CTS
4 DTR 9 RI
5 GND
5-12
Electrical Information
Figure 5-11 illustrates the connector pin locations on each end of the HP A4301A conversion
RS-232 cable.
Table 5-10 is the wiring table for the HP A4301A conversion RS-232 cable.
Pin 1 Pin 1
Pin 2 Pin 2
Pin 3 Pin 3
Pin 4 Pin 4
Pin 5 Pin 5
Pin 6 Pin 6
Pin 7 Pin 7
Pin 8 Pin 8
Pin 9 Pin 9
5-13
Electrical Information
5-14
Electrical Information
Figure 5-13 illustrates the connector pin locations on each end of the HP A4303A conversion
LAN cable.
Table 5-12 is the wiring table for the HP A4303A conversion LAN cable.
5-15
Electrical Information
5-16
Electrical Information
Pin Pin
Signal Signal
Number Number
1 GND 26 DATA 0
2 GND 27 DATA 1
3 GND 28 DATA 2
4 GND 29 DATA 3
5 GND 30 DATA 4
6 GND 31 DATA 5
7 GND 32 DATA 6
8 GND 33 DATA 7
9 GND 34 Data Parity
10 GND 35 GND
11 GND 36 GND
12 GND 37 GND
13 GND 38 Term_Pwr
14 GND 39 GND
15 GND 40 GND
16 GND 41 ATN
17 GND 42 GND
18 GND 43 BSY
19 GND 44 ACK
20 GND 45 RST
21 GND 46 MSG
22 GND 47 SEL
23 GND 48 CD
24 GND 49 REQ
25 GND 50 IO
5-17
Electrical Information
5-18
Electrical Information
Pin Pin
Signal Signal
Number Number
1 FW_SD12+ 35 FW_SD12-
2 FW_SD13+ 36 FW_SD13-
3 FW_SD14+ 37 FW_SD14-
4 FW_SD15+ 38 FW_SD15-
5 FW_SD1+ 39 FW_SP1-
6 GND 40 GND
7 FW_SD0+ 41 FW_SD0-
8 FW_SD1+ 42 FW_SD1-
9 FW_SD2+ 43 FW_SD2-
10 FW_SD3+ 44 FW_SD3-
11 FW_SD4+ 45 FW_SD4-
12 FW_SD5+ 46 FW_SD5-
13 FW_SD6+ 47 FW_SD6-
14 FW_SD7+ 48 FW_SD7-
15 FW_SP0+ 49 FW_SP0-
16 FW_DIFFSENS 50 GND
17 FW_TERM POWER 51 FW_TERM POWER
18 FW_TERM POWER 52 FW_TERM POWER
19 NC 53 NC
20 FW_SATN+ 54 FW_SATN-
21 GND 55 GND
22 FW_SBSY+ 56 FW_SBSY-
23 FW_SACK+ 57 FW_SACK-
24 FW_SRST+ 58 FW_SRST-
25 FW_SYMSG+ 59 FW_SMSG-
26 FW_SSEL+ 60 FW_SSEL-
27 FW_SCD+ 61 FW_SCD-
28 FW_SREQ+ 62 FW_SREQ-
29 FW_SIO+ 63 FW_SIO-
30 GND 64 GND
31 FW_SD8+ 65 FW_SD8-
32 FW_SD9+ 66 FW_SD9-
33 FW_SD10+ 67 FW_SD10-
34 FW_SD11+ 68 FW_SD11-
5-19
Electrical Information
Pin
Signal
Number
1 Data
2 Not used
3 GND
4 +5
5 Clock
6 Not used
5-20
Electrical Information
5-21
Electrical Information
Table 5-16 Model 743 and 744/Model 748 VME P1/J1 Pin Assignments and Signal Mnemonics
Pin
Row A Row B Row C
Number
5-22
Electrical Information
Table 5-17 identifies the VMEbus connector pin assignments and signal mnemonics for the
Model 748 VME P2/J2, slots 2 - 8.
Table 5-17 Model 748 VME P2/J2 Pin Assignments and Signal Mnemonics
Pin
Row A Row B Row C
Number
1 User defined +5Vdc User defined
2 User defined GND User defined
3 User defined Reserved User defined
4 User defined A24 User defined
5 User defined A25 User defined
6 User defined A26 User defined
7 User defined A27 User defined
8 User defined A28 User defined
9 User defined A29 User defined
10 User defined A30 User defined
11 User defined A31 User defined
12 User defined GND User defined
13 User defined +5Vdc User defined
14 User defined D16 User defined
15 User defined D17 User defined
16 User defined D18 User defined
17 User defined D19 User defined
18 User defined D20 User defined
19 User defined D21 User defined
20 User defined D22 User defined
21 User defined D23 User defined
22 User defined GND User defined
23 User defined D24 User defined
24 User defined D25 User defined
25 User defined D26 User defined
26 User defined D27 User defined
27 User defined D28 User defined
28 User defined D29 User defined
29 User defined D30 User defined
30 User defined D31 User defined
31 User defined GND User defined
32 User defined +5Vdc User defined
5-23
Electrical Information
Table 5-18 identifies the VMEbus connector pin assignments and signal mnemonics for the
Model 743 P2.
Table 5-18 Model 743 P2/J2 Pin Assignments and Signal Mnemonics - Slot 1
Pin
Row A Row B Row C
Number
3 NC Reserved GSC_AD[2]
5 NC A25 GSC_AD[4]
8 NC A28 GSC_AD[7]
11 NC A31 GSC_AD[10]
16 NC D18 GSC_AD[15]
21 NC D23 GSC_AD[20]
26 NC D27 GSC_AD[25]
27 NC D28 GSC_AD[26]
5-24
Electrical Information
Table 5-19 identifies the VMEbus connector pin assignments and signal mnemonics for the
Model 744 VME P2.
Table 5-19 Model 744 VME P2 Pin Assignments and Signal Mnemonics
Pin
Row A Row B Row C
Number
1 SYNCHWAXL +5 V GSC_AD0
2 SYNCHWAXH GND GSC_AD1
3 NC Reserved GSC_AD2
4 WAX_RST_L VME_A24 GSC_AD3
5 NC VME_A25 GSC_AD4
6 GSC_BR_L(2) VME_A26 GSC_AD5
7 GSC_BG_L(2) VME_A27 GSC_AD6
8 NC VME_A28 GSC_AD7
9 GSC_ADDV_L VME_A29 GSC_AD8
10 GSC_READY_L VME_A30 GSC_AD9
11 NC VME_A31 GSC_AD10
12 GSC_ERROR_L GND GSC_AD11
13 GSC_PARITY_ +5 V GSC_AD12
L
14 GSC_XQ_L VME_D16 GSC_AD13
15 GSC_LS_L VME_D17 GSC_AD14
16 NC VME_D18 GSC_AD15
17 GSC_TYPE0 VME_D19 GSC_AD16
18 GSC_TYPE1 VME_D20 GSC_AD17
19 GSC_TYPE2 VME_D21 GSC_AD18
20 GSC_TYPE3 VME_D22 GSC_AD19
21 NC VME_D23 GSC_AD20
22 SYNCTTL GND GSC_AD21
23 SP_DETECT VME_D24 GSC_AD22
24 ALT_BR_L VME_D25 GSC_AD23
25 ALT_BG_L VME_D26 GSC_AD24
26 NC VME_D27 GSC_AD25
27 NC VME_D28 GSC_AD26
28 TDO VME_D29 GSC_AD27
29 TDI VME_D30 GSC_AD28
30 TCK VME_D31 GSC_AD29
31 TMS GND GSC_AD30
5-25
Electrical Information
Table 5-19 Model 744 VME P2 Pin Assignments and Signal Mnemonics
Pin
Row A Row B Row C
Number
32 TRST +5 V GSC_AD31
Table 5-29 identifies the PMC JN1 signals on the PMC Bridge J21 connectors.
Pin Pin
Signal Signal
Number Number
1 TCK 2 -12V
3 Ground 4 INTC
5 INTB# 6 INTA
7 BUSMODE1# 8 +5V
9 INTD# 10 PCI-RESERVED
11 Ground 12 PCI-RESERVED
13 CLK 14 Ground
15 Ground 16 GNTB#
17 REQB# 18 +5V
19 VDD(I/O) 20 AD31
21 AD28 22 AD27
23 AD25 24 Ground
25 Ground 26 C/BE3#
27 AD22 28 AD21
29 AD19 30 +5V
31 VDD(I/O) 32 AD17
33 FRAME# 34 Ground
35 Ground 36 IRDY#
37 DEVSEL# 38 +5V
39 Ground 40 LOCK#
41 SDONE# 42 SBO#
43 PAR 44 Ground
45 VDD(I/O) 46 AD15
47 AD12 48 AD11
49 AD09 50 +5V
51 Ground 52 C/BE0#
53 AD06 54 AD05
55 AD04 56 Ground
5-26
Electrical Information
Pin Pin
Signal Signal
Number Number
57 VDD(I/O) 58 AD03
59 AD02 60 AD01
61 AD00 62 +5V
63 Ground 64 REQ64#
Table 5-29 identifies the PMC JN2 signals on the PMC Bridge J22 connectors.
Pin Pin
Signal Signal
Number Number
1 +12V 2 TRST#
3 TMS 4 TDO
5 TDI 6 Ground
7 Ground 8 PCI-RESERVED
9 PCI-RESERVED 10 PCI-RESERVED
11 BUSMODE2# 12 +3.3V
13 RST 14 BUSMODE3
15 +3.3V 16 BUSMODE4
17 PCI-RESERVED 18 Ground
19 AD30 20 AD29
21 Ground 22 AD26
23 AD24 24 +3.3V
25 IDSEL(1) 26 AD23
27 +3.3V 28 AD20
29 AD18 30 Ground
31 AD16 32 C/BE2#
33 Ground 34 PMC-RSVD
35 TRDY# 36 +3.3V
37 Ground 38 STOP#
39 PERR# 40 Ground
41 +3.3V 42 SERR#
43 C/BE1# 44 Ground
45 AD14 46 AD13
47 Ground 48 AD10
49 AD08 50 +3.3V
5-27
Electrical Information
Pin Pin
Signal Signal
Number Number
51 AD07 52 PMC-RSVD
53 +3.3V 54 PMC-RSVD
55 PMC-RSVD 56 Ground
57 PMC-RSVD 58 PMC-RSVD
59 Ground 60 PMC-RSVD
61 ACK64# 62 +3.3V
63 Ground 64 PMC-RSVD
Table 5-28 identifies the PMC JN1 signals on the PMC Bridge J11 connectors.
Pin Pin
Signal Signal
Number Number
1 TCK 2 -12V
3 Ground 4 INTB
5 INTC# 6 INTD
7 BUSMODE1# 8 +5V
9 INTA# 10 PCI-RESERVED
11 Ground 12 PCI-RESERVED
13 CLK 14 Ground
15 Ground 16 GNTA#
17 REQA# 18 +5V
19 VDD(I/O) 20 AD31
21 AD28 22 AD27
23 AD25 24 Ground
25 Ground 26 C/BE3#
27 AD22 28 AD21
29 AD19 30 +5V
31 VDD(I/O) 32 AD17
33 FRAME# 34 Ground
35 Ground 36 IRDY#
37 DEVSEL# 38 +5V
39 Ground 40 LOCK#
41 SDONE# 42 SBO#
43 PAR 44 Ground
5-28
Electrical Information
Pin Pin
Signal Signal
Number Number
45 VDD(I/O) 46 AD15
47 AD12 48 AD11
49 AD09 50 +5V
51 Ground 52 C/BE0#
53 AD06 54 AD05
55 AD04 56 Ground
57 VDD(I/O) 58 AD03
59 AD02 60 AD01
61 AD00 62 +5V
63 Ground 64 REQ64#
Table 5-29 identifies the PMC JN2 signals on the PMC Bridge J12 connectors.
Pin Pin
Signal Signal
Number Number
1 +12V 2 TRST#
3 TMS 4 TDO
5 TDI 6 Ground
7 Ground 8 PCI-RESERVED
9 PCI-RESERVED 10 PCI-RESERVED
11 BUSMODE2# 12 +3.3V
13 RST 14 BUSMODE3
15 +3.3V 16 BUSMODE4
17 PCI-RESERVED 18 Ground
19 AD30 20 AD29
21 Ground 22 AD26
23 AD24 24 +3.3V
25 IDSEL(2) 26 AD23
27 +3.3V 28 AD20
29 AD18 30 Ground
31 AD16 32 C/BE2#
33 Ground 34 PMC-RSVD
35 TRDY# 36 +3.3V
37 Ground 38 STOP#
5-29
Electrical Information
Pin Pin
Signal Signal
Number Number
39 PERR# 40 Ground
41 +3.3V 42 SERR#
43 C/BE1# 44 Ground
45 AD14 46 AD13
47 Ground 48 AD10
49 AD08 50 +3.3V
51 AD07 52 PMC-RSVD
53 +3.3V 54 PMC-RSVD
55 PMC-RSVD 56 Ground
57 PMC-RSVD 58 PMC-RSVD
59 Ground 60 PMC-RSVD
61 ACK64# 62 +3.3V
63 Ground 64 PMC-RSVD
Table 5-25 identifies the PMC JN4 User Defined pin outs on the PMC Bridge J14 connector
that is wired to the VME backplane P2 connector.
Pin Pin
Signal Signal
Number Number
1 P2-C1 2 P2-A1
3 P2-C2 4 P2-A2
5 P2-C3 6 P2-A3
7 P2-C4 8 P2-A4
9 P2-C5 10 P2-A5
11 P2-C6 12 P2-A6
13 P2-C7 14 P2-A7
15 P2-C8 16 P2-A8
17 P2-C9 18 P2-A9
19 P2-C10 20 P2-A10
21 P2-C11 22 P2-A11
23 P2-C12 24 P2-A12
25 P2-C13 26 P2-A13
27 P2-C14 28 P2-A14
29 P2-C15 30 P2-A15
5-30
Electrical Information
Pin Pin
Signal Signal
Number Number
31 P2-C16 32 P2-A16
33 P2-C17 34 P2-A17
35 P2-C18 36 P2-A18
37 P2-C19 38 P2-A19
39 P2-C20 40 P2-A20
41 P2-C21 42 P2-A21
43 P2-C22 44 P2-A22
45 P2-C23 46 P2-A23
47 P2-C24 48 P2-A24
49 P2-C25 50 P2-A25
51 P2-C26 52 P2-A26
53 P2-C27 54 P2-A27
55 P2-C28 56 P2-A28
57 P2-C29 58 P2-A29
59 P2-C30 60 P2-A30
61 P2-C31 62 P2-A31
63 P2-C32 64 P2-A32
Table 5-25 identifies the PMC Bridge J3 connector that routes signals from the bridge board
to the PMC expander board.
5-31
Electrical Information
Table 5-26 identifies the PMC JN1 signals on the PMC Expander J31 connectors.
Pin Pin
Signal Signal
Number Number
1 TCK 2 -12V
3 Ground 4 INTD
5 INTA# 6 INTB
7 BUSMODE1# 8 +5V
9 INTC# 10 PCI-RESERVED
11 Ground 12 PCI-RESERVED
13 CLK 14 Ground
15 Ground 16 GNTC#
5-32
Electrical Information
Pin Pin
Signal Signal
Number Number
17 REQC# 18 +5V
19 VDD(I/O) 20 AD31
21 AD28 22 AD27
23 AD25 24 Ground
25 Ground 26 C/BE3#
27 AD22 28 AD21
29 AD19 30 +5V
31 VDD(I/O) 32 AD17
33 FRAME# 34 Ground
35 Ground 36 IRDY#
37 DEVSEL# 38 +5V
39 Ground 40 LOCK#
41 SDONE# 42 SBO#
43 PAR 44 Ground
45 VDD(I/O) 46 AD15
47 AD12 48 AD11
49 AD09 50 +5V
51 Ground 52 C/BE0#
53 AD06 54 AD05
55 AD04 56 Ground
57 VDD(I/O) 58 AD03
59 AD02 60 AD01
61 AD00 62 +5V
63 Ground 64 REQ64#
Table 5-27 identifies the PMC JN2 signals on the PMC Expander J32 connectors.
Pin Pin
Signal Signal
Number Number
1 +12V 2 TRST#
3 TMS 4 TDO
5 TDI 6 Ground
7 Ground 8 PCI-RESERVED
9 PCI-RESERVED 10 PCI-RESERVED
5-33
Electrical Information
Pin Pin
Signal Signal
Number Number
11 BUSMODE2# 12 +3.3V
13 RST 14 BUSMODE3
15 +3.3V 16 BUSMODE4
17 PCI-RESERVED 18 Ground
19 AD30 20 AD29
21 Ground 22 AD26
23 AD24 24 +3.3V
25 IDSEL(3) 26 AD23
27 +3.3V 28 AD20
29 AD18 30 Ground
31 AD16 32 C/BE2#
33 Ground 34 PMC-RSVD
35 TRDY# 36 +3.3V
37 Ground 38 STOP#
39 PERR# 40 Ground
41 +3.3V 42 SERR#
43 C/BE1# 44 Ground
45 AD14 46 AD13
47 Ground 48 AD10
49 AD08 50 +3.3V
51 AD07 52 PMC-RSVD
53 +3.3V 54 PMC-RSVD
55 PMC-RSVD 56 Ground
57 PMC-RSVD 58 PMC-RSVD
59 Ground 60 PMC-RSVD
61 ACK64# 62 +3.3V
63 Ground 64 PMC-RSVD
Table 5-28 identifies the PMC JN1 signals on the PMC Expander J41 connectors.
Pin Pin
Signal Signal
Number Number
1 TCK 2 -12V
3 Ground 4 INTA
5-34
Electrical Information
Pin Pin
Signal Signal
Number Number
5 INTB# 6 INTC
7 BUSMODE1# 8 +5V
9 INTD# 10 PCI-RESERVED
11 Ground 12 PCI-RESERVED
13 CLK 14 Ground
15 Ground 16 GNTD#
17 REQD# 18 +5V
19 VDD(I/O) 20 AD31
21 AD28 22 AD27
23 AD25 24 Ground
25 Ground 26 C/BE3#
27 AD22 28 AD21
29 AD19 30 +5V
31 VDD(I/O) 32 AD17
33 FRAME# 34 Ground
35 Ground 36 IRDY#
37 DEVSEL# 38 +5V
39 Ground 40 LOCK#
41 SDONE# 42 SBO#
43 PAR 44 Ground
45 VDD(I/O) 46 AD15
47 AD12 48 AD11
49 AD09 50 +5V
51 Ground 52 C/BE0#
53 AD06 54 AD05
55 AD04 56 Ground
57 VDD(I/O) 58 AD03
59 AD02 60 AD01
61 AD00 62 +5V
63 Ground 64 REQ64#
Table 5-29 identifies the PMC JN2 signals on the PMC Expander J42 connectors.
5-35
Electrical Information
Pin Pin
Signal Signal
Number Number
1 +12V 2 TRST#
3 TMS 4 TDO
5 TDI 6 Ground
7 Ground 8 PCI-RESERVED
9 PCI-RESERVED 10 PCI-RESERVED
11 BUSMODE2# 12 +3.3V
13 RST 14 BUSMODE3
15 +3.3V 16 BUSMODE4
17 PCI-RESERVED 18 Ground
19 AD30 20 AD29
21 Ground 22 AD26
23 AD24 24 +3.3V
25 IDSEL4) 26 AD23
27 +3.3V 28 AD20
29 AD18 30 Ground
31 AD16 32 C/BE2#
33 Ground 34 PMC-RSVD
35 TRDY# 36 +3.3V
37 Ground 38 STOP#
39 PERR# 40 Ground
41 +3.3V 42 SERR#
43 C/BE1# 44 Ground
45 AD14 46 AD13
47 Ground 48 AD10
49 AD08 50 +3.3V
51 AD07 52 PMC-RSVD
53 +3.3V 54 PMC-RSVD
55 PMC-RSVD 56 Ground
57 PMC-RSVD 58 PMC-RSVD
59 Ground 60 PMC-RSVD
61 ACK64# 62 +3.3V
63 Ground 64 PMC-RSVD
5-36
Electrical Information
Battery Specifications
Table 5-30 summarizes the RTC battery specifications.
Table 5-30 RTC Battery Specifications
Battery
Battery
Manufacturer Life
Type Voltage Manufacturer HP Part No. Life
Part No Power
Power Off
On
Replace only with the same or equivalent type recommended by the manufacturer.
Dispose of used batteries according to the manufacturer’s instructions.
5-37
Electrical Information
Table 5-31 summarizes the timing specifications for the 1024 x 768 and 1280 x 1024 moni-
tors at 60 Hz, 75 Hz, and 72 Hz.
Table 5-31 Timing Specifications at 60 Hz, 75 Hz, and 72 Hz
A4330A/ A4330A/
D2806A D2806A
A4331 A4331
Signal 1024x768 1024x768
1280x1024 1280x1024
60 Hz 75 Hz
60Hz 72 Hz
Vertical sync 83.86µs (4H) 63.55µs (4H) 47.36µs (3H) 38.400µs (3H)
width
5-38
Electrical Information
Table 5-32 summarizes the timing specifications for the 1024 x 768 and 1280 x 1024 moni-
tors at VESA 75 Hz standard.
D2806A A4330A/A4331
Signal 1024x768 1280x1024
75 Hz VESA 75 Hz VESA
In the past, Hewlett-Packard workstation timing was set with sync-on-green. The VESA
standard provides separate TTL syncs, thereby providing an unambiguous way for the moni-
tor to distinguish them.
5-39
Electrical Information
5-40
6
Power Requirements
This chapter discusses power distribution, monitor ac power specifications, and power bud-
geting.
6-1
Power Requirements
Power Distribution
Power Distribution
The VMEbus chassis connectors P1 and P2 distribute power to the Model 743 and Model
744 board computer’s PC boards as follows:
Graphics cards receive power through the adapter board’s P1 and P2 connectors. RAM cards
receive power through the RAM stack connectors. The system board and RAM card receive
power through the system board’s P1 and P2 connectors.
NOTE: VME P1 and P2 connectors use two or more pins to carry power or grounds to the board
computer. Check the VME P1 and P2 pinout tables for exact pin identification for power and
grounds.
Figure 6-1 and Figure 6-2 illustrate the power distribution for the Model 743 and Model 744
VMEbus board computers. Figure 6-3 and Figure 6-4 illustrate the power distribution for the
GSC expansion adapter and the PMC adapters.
GSC Connector
Electrical SCSI
Resetable +5 Termination
Fuse Power
+3.3
Regulator
Thermal +5
Fuse PS/2–1
GND P2
+5
+5 PS/2–0
GND
RAM
+5 Stack 2
GND
GND
P1 RAM
+5 Stack 1
GND
–12
Thermal +12
Fuse AUI
+12
+5
PCMCIA Connector
6-2
Power Requirements
Power Distribution
6-3
Power Requirements
Power Distribution
GND
–12
P2
GND
GSC Card
+12
Connector
+5 +5
+3.3
P1
GND GND
–12 –12
+3.3
GSC Connector
6-4
Power Requirements
Power Distribution
GND
–12
PMC Card
P2
GND +12
Connector
+5 +5
+3.3
P1
GND GND
–12 –12
PMC Card
+12 +12 Connector
+5 +5
+3.3
+3.3
+3.3
+3.3
Regulator
GND
–12
P2
GND
PMC Card
+12
Connector
+5 +5
+3.3
P1
GND GND
–12 –12
+3.3
GSC Connector
6-5
Power Requirements
Power Distribution
+5 V +3 V
+12 V -12 V
HW Component Current Current P-total
Current Current
(VDD0) (SYS_VDL)
Voltage Type 60 Hz 50 Hz
6-6
Power Requirements
Power Distribution
Power Budgeting
If your workstation’s application requires several accessory cards and mass storage devices,
power budgeting may be required. Power budgeting ensures that the power needed for the
following internal devices does not exceed the power available:
• Mass storage devices
• Model 743 and Model 744 VMEbus Board Computer(s)
• Standard internal printed circuit boards
• PCI, PMC, VME, or EISA accessory cards
The Model 748 ruggedized workstation uses two power supplies. Each power supply pro-
vides voltages to the workstation's modules and accessory card slots as listed in Table 6-8
and Table 6-9.
These tables are also worksheets to use in determining your power budget. You may photo-
copy these tables as needed.
To determine the workstation’s power needs, follow these instructions:
1 Determine the board computer’s current requirements from the Computer Current Re-
quirements Worksheet (Table 6-5 or Table 6-6).
2 To determine the maximum current usage of the Model 744 memory cards, use Figure 6-
5 and Table 6-3 (for Model 744/132L) or Table 6-4 (for Model 744/165L). Note that some
memory cards draw current from +12V on the Model 744/165L. This is because +12
is converted to +5MEM for the 16MB, 32MB, and 64MB cards (seeFigure 6-2). You must
work with the worst case power draw to correctly determine power usage. Determine worst
case power draw by examining active memory bank configurations, using the following
steps:
a Examine your memory card configuration, noting which size card is in each memory
slot.
b The worst case active memory bank configuration depends on the slot position of the
memory cards, and the size of the cards. The 32 MB memory card has two banks per
card, and the 16, 64,128, and 256 MB cards each have only one memory bank per card.
• When 32 MB cards are used as a pair in memory slots 2 and 3 they can use three
memory banks concurrently.
• When used as a pair in slots 0, 1, or 2, the 32 MB cards can have two active memory
banks.
• The 16, 64, 128, and 256 MB cards each have only one memory bank that is active
at any one time.
The worst case power draw is when your system has two 32MB cards in slots 2 and 3
(these banks would be considered active, all other memory cards/banks would be con-
sidered inactive). The next worst case is a 256 MB card in any slot (all other memory
cards in the system would be inactive), followed by a 64 MB card in any slot (all other
memory cards in the system would be inactive), followed by two 32 MB cards in slots
0, 1, or 2 (all other memory cards in the system would be inactive), followed by a 128
MB card in any slot, and finally a 16 MB card in any slot (all other memory cards in
the system would be inactive).
6-7
Power Requirements
Power Distribution
c Inactive memory banks are those banks on cards in your configuration in addition to
the worst case active memory banks. They must also be added to the calculation.
d Fill in the information in Table 6-3 or Table 6-4.
Slot 3
Slot 2
Slot 1 Memory Slots
Slot 0
_________
2 Slot positions and amount of 32MB cards determine the number of active banks.
________ ________
2 Slot positions and amount of 32MB cards determine the number of active banks.
6-8
Power Requirements
Power Distribution
3 Write in the board computer’s current requirements in the line provided for VME slots 1
and 2 in the Lower Power Supply Worksheet (Table 6-9).
4 Determine each device’s current requirements from the Internal Device Requirements ta-
ble and the VME accessory card’s specifications sheet (Table 6-7).
5 Write in each device’s current requirements in the spaces provided in the Upper or Lower
Power Supply current budgeting worksheets (Table 6-8 and Table 6-9).
6 Total each column in both worksheets, then write the total in the Total Current Required
line.
7 If either worksheet has a column whose current totals exceed the maximum available for
that column’s voltage, you must reduce the number of devices to lower the total current
being drawn at that voltage. You may be able to relocate VME accessory cards between
the upper eight and lower two slots to reduce the power required from either power supply.
6-9
Power Requirements
Power Distribution
6-10
Power Requirements
Power Distribution
HP J2802B ATM
6-11
Power Requirements
Power Distribution
VME Slot 8
VME Slot 7
VME Slot 6
VME Slot 5
VME Slot 4
Total Current
Required:
Maximum Available: 34.0A 8.0A 1.5A
CAUTION: If you upgrade your Model 748 Ruggedized Workstation, adding more: RAM cards, mass
storage devices, GSC, VME, EISA, PCI, or PMC accessory cards, you must recompute the
power budget to ensure the new configuration will be within the available current each power
supply can provide.
NOTE: The PCI tray provides power for option cards from both a +3.3 Vdc source and a +5 Vdc source. Cards
may use either or both power sources, up to 25W per slot. However, the +3.3 V dc source is limited to
39.8 W combined for slots 1 and 2, and 39.8 W combined for slots 3 and 4. For example, if the card in
slot 1 draws 25 W at +3.3 V dc, only 14.8 W at +3.3 V dc is available to a card in slot 2. The limits of
+ 5 Vdc is 25 W per slot.
6-12
Power Requirements
Power Distribution
Mass Storage
Device 1
Mass Storage
Device 2
Mass Storage
Device 3
Mass Storage
Device 4
EISA/PCI Slot 1
EISA/PCI Slot 2
EISA/PCI Slot 3
EISA/PCI Slot 4
6-13
Power Requirements
Power Distribution
6-14
7
The Product Design Considerations Chapter contains information on applications and sys-
tem integration.
7-1
Product Design Considerations
Application Information
Application Information
This section contains information on VME Services updates and VME system design consid-
erations.
http://www.hp.com/go/hp_vme
VME Systems Design Considerations for Models 743, 744, and 748
This section provides a brief overview of some design considerations when configuring
VME system with Models 743, 744, or 748. This overview will help you determine whether
these considerations are relevant to your VME system. More detailed information is avail-
able on request.
Data Transfer Considerations
The sections that follow discuss data transfers within the VME system.
VME Data Lines During Write Cycle The VME data lines need to remain stable during the entire
write cycle from a non-Model 743/744 VME bus master to the main memory of a Model 743/744
serving as a VME slave. This period includes the time from the assertion of the data strobe by the mas-
ter to the receipt of the DTACK from the Model 743/744. All data lines need to remain stable in all
transactions, including the higher order data lines unused in a D08 or D16 data transaction.
7-2
Product Design Considerations
Application Information
System Integration
The System Integration section provides information for system integrators who are incorpo-
rating the HP 9000 Series Model 742i into the HP 9000 Series Model 748iVME systems and
the HP 9000 Series Model 743i or 744 into the HP 9000 Series Model 747i VME systems
running HP-UX into VME systems. Topics include hardware power-on information and
VME ASIC VME sysreset behavior.
7-3
Product Design Considerations
Application Information
In a combined Models 742i and 747i and Models 743i and 748i backplane containing one or
more Models 742i and 747i VME ASICS, the address areas previously discussed must be
unpopulated to avoid conflicts prior to loading the operating system. The lowest 256 MB
region should be left unused for system use. For more information on combined systems,
refer to /etc/vme/example2.CFG and the HP-RT System Administrator Task Manual.
The VME ASIC in the Models 743i and 744 does not respond to VME cycles until it is
explicitly enabled by the HP-UX operating system.
VME ASIC VME Sysreset Behavior
When the VME ASIC is a slot 1 controller (always on the Model 747i and switch selectable
on the Model 742i/rt), it generates VME sysreset and VME sysfail at power on, but ignores
the state of these lines thereafter. If the VME ASIC is not a slot 1 controller, assertion of
VME sysreset by another VME card causes the Model 742i/rt to reboot.
The VME ASIC in the Models 743i and 744 behaves similarly but can be configured as to
whether or not a VME sysreset causes a non slot 1 controller to reboot.
Models 742i and 747i VME IACK Anomaly at Power On
Models 742i and 747i respond to the first interrupt cycle on any irq level after power-on with
an invalid status-id by the VME ASIC. This behavior occurs regardless of whether or not
Models 742i or 747i are enabled as an interrupt handler for the associated interrupt level. The
patched HP-UX Version 9.05 fixes this behavior; however, the behavior should not cause
problems because VME handles multiple interrupts on an irq level.
Models 743i and 744 do not exhibit this behavior.
VME System Configuration Information
The HP-UX vme_config program helps system integrators generate a conflict-free system
configuration. After running vme_config, which writes data into the EEPROM, the system
must be rebooted to use the new EEPROM information. For more information, refer to
"Required Entity Declarations for HP Processors" in /etc/vme/example(x).CFG and the HP-
UX 10.0 VME Device Drivers Manual.
Runtime VME ASIC Anomalies
The VME data lines need to remain stable during the entire write cycle from a non-743/744
VME bus master to the main memory of Models 743i or 744 serving as a VME slave. The
write cycle includes the time from the assertion of the data strobe by the master to the receipt
of DTACK from Model 743/744. All data lines need to remain stable in all transactions,
including higher order data lines unused in a D08 or D16 data transaction.
NOTE: If the VMEbus card bus master either drives the data lines to a known and stable state or allows
the data lines to float to VME’s stable high termination, there will be no parity errors. However,
if the VMEbus card master drives the lines for part of the cycle and allows them to float for the
remainder of the cycle, parity errors are possible on the internal Model 743/744 ’s bus, resulting
in an HP-UX panic and system crash. In HP-UX, this parity error results in a non-zero value of
the bus check displayed as part of HP-UX panic. The HP-RT error message indicates that the
7-4
Product Design Considerations
Application Information
High Priority Machine Check (HPMC) was of type bus error with the "check Type" field equal
to "20000000", the "sysReqAdd" field equal to "00109180", and the "cache", "tlb", "bus",
"assists", "asstState", "sysRsAdd" fields set to zero.
In rare circumstances, Models 742i and 747i allow non-specified data lines to float, resulting
in HP-UX panic. Most often, this behavior occurs when Models 743i and 744 are generating
IACK as a D08 or D16 interrupter. To avoid this behavior, do not have Models 743i and 744
as interrupt handlers for Models 742i and 747i or configure (in the kernel interface driver that
is generating the interrupt) Models 742i and 747i as D32 interrupters.
Models 742i and 747i have an internal (SGC) bus watchdog timer set to 1 ms by the boot
ROM (PDC) code. When the PA processor starts a read or write transaction to VME I/O
space, the watchdog timer starts. If the total time from acquiring the VME bus (arbitration
time) to cycle completion time (DTACK or BERR) exceeds 1 ms, the system crashes with a
HPMC. In HP-UX, the resulting panic dump message indicates a SGC bus error HPMC (this
behavior cannot be changed). In either HP-UX or HP-RT, the operating system cannot
recover from an HPMC error.
The system must be configured so that Models 742 or 747 always get the VME bus and com-
plete the first transaction in less than 1 ms. This is done through vme_config in HP-UX, and
by setting specific defines, such as bus request priority, to set bus behavior in HP-RT.
Models 743i and 744 have an internal bus protocol called "split" that overcomes the 1 ms
problem in Models 742i and 747i, but the processor appears hung until the VME cycle com-
pletes.
Current releases of HP-UX and HP-RT do not support the use of the location monitor capa-
bility. However, Models 742i and 747i and Models 743i and 744 handle monitoring VME
locations differently:
Models 742i and 747i ASIC, if enabled, generate a local interrupt when the VME
space that is defined for the location monitor is accessed. It also DTACKS the VME
cycle.
Models 743i and 744 ASIC, if enabled, generate a local interrupt when the space
that is defined for the location monitor is accessed. It does not+ DTACK the VME
cycle.
7-5
Product Design Considerations
Application Information
7-6
Index
Index-1
Index
acoustics 3-11
altitude 3-9
brownout 3-7
brownout/recovery 3-7
climatic and environmental 3-8
conducted immunity 3-6
electrical fast transients 3-6
electromagnetic field emissions 3-4
electromagnetic field immunity/susceptibili-
ty 3-5
electro-static discharge 3-5
humidity 3-9
line blackout/dropout 3-7
line surge 3-7
line transients immunity/susceptibility 3-6
magnetic emissions 3-5
magnetic field immunity 3-6
power level 3-11
radiated emissions 3-4
radiated field immunity 3-5
sag 3-6
shock 3-10
surge transients 3-6
temperature 3-9
vibration 3-10
TUC Rheinland 3-2
U
Underwriter’s Laboratories 3-2
upgrades, three slots 1-4, 1-5, 1-6
upgrades, two slots 1-3, 1-5, 1-6
user interface 1-3, 1-4, 1-5
V
VCCI statement 3-3
video timing 5-37
VME ASIC 7-3, 7-4
VME module 1-29
VME services updates 7-2
VME system design considerations 7-2
vme_config 7-4
Voluntary Control Council for Interference 3-3
W
watchdog timer 1-24
Index-2