Drop Installation Manual (WEStation Equipped)
Section
Title
Page
Section 1. Introduction
1-1.
1-2.
1-3.
Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
Contents of This Document . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3
Reference Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4
Section 2. General Drop Installation Guidelines
2-1.
2-2.
2-3.
2-4.
2-5.
2-6.
Section Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1
Shipping Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
2-2.1. General Shipping Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
2-2.2. Air Export Shipping Guidelines. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3
2-2.3. Ocean Export Shipping Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-4
2-2.4. Delicate Component Shipping Guidelines. . . . . . . . . . . . . . . . . . . . . . . . . . 2-4
2-2.5. Hoisting Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-4
2-2.6. Off-Loading and Unpacking Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5
2-2.7. Repacking for Return Shipment Guidelines . . . . . . . . . . . . . . . . . . . . . . . . 2-6
2-2.8. Transporting to the Specific Installation Location Guidelines . . . . . . . . . . 2-6
2-2.9. Tilting Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-6
Storage Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-7
Drop and Cabling Identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9
2-4.1. Drop Identification. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9
2-4.2. Determining Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-10
2-4.3. Cabling Conventions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-10
Installing Equipment at Permanent Site . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-11
2-5.1. General Guidelines. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-11
2-5.2. Wiring Access and Ground Connections. . . . . . . . . . . . . . . . . . . . . . . . . . 2-14
Power Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-15
2-6.1. Multibus-based Drop Power Connections . . . . . . . . . . . . . . . . . . . . . . . . . 2-15
2-6.2. WEStation Drop Power Connections (Rack-Mount). . . . . . . . . . . . . . . . . 2-19
2-6.3. WEStation Drop Power Connections (Cube) . . . . . . . . . . . . . . . . . . . . . . 2-20
2-6.4. Peripheral Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-22
Section 3. WEStation Drop Configurations
3-1.
3-2.
3-3.
Section Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
WEStation Enclosures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-2
VME WEStation Electronics, Cards, and Devices . . . . . . . . . . . . . . . . . . . . . . . . . . 3-6
3-3.1. Base Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-8
3-3.2. WEStation Cards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-9
3-3.3. Optional Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-13
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Section
Title
Page
Section 3. WEStation Drop Configurations, Cont’d
3-4.
3-5.
Peripheral Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-16
3-4.1. CRT Monitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-16
3-4.2. User Input Devices. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-18
3-4.3. Printers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21
3-4.4. Administration Tool to Set Up Printers . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-42
3-4.5. Storage Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-48
3-4.6. PROM Programmer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-57
WEStation Drop Configurations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-58
Section 4. Desktop WEStation Configuration
4-1.
4-2.
4-3.
4-4.
4-5.
4-6.
Section Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
WEStationDT Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
Hardware Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
4-3.1. WEStationDT Enclosure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
4-3.2. SGI (Sbus to Gbus Interface) PC board. . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
4-3.3. Gbus Interface Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
4-3.4. Data Highway Adapter Cables and Transition Panel . . . . . . . . . . . . . . . . . 4-6
Software Requirements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-7
Installation Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
4-5.1. SGI Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
4-5.2. WEStation Enclosure Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10
4-5.3. Data Highway Cable Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-15
Status Indicators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Section 5. Distributed Processing Unit (DPU)
5-1.
5-2.
5-3.
5-4.
Section Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
5-1.1. DPU Cabinets. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2
386 DPU Configurations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-3
5-2.1. Power, Ground, and Signal Wiring (386 DPUs) . . . . . . . . . . . . . . . . . . . . . 5-6
5-2.2. Standard 386 DPU Illustrations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-7
5-2.3. Enhanced 386 DPU Illustrations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-16
486 DPU Configurations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-25
5-3.1. Power, Ground, and Signal Wiring (486 DPU) . . . . . . . . . . . . . . . . . . . . . 5-27
5-3.2. 486 DPU Illustrations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-28
Field Mounted Controller (FMC 1000) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-37
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Section
Title
Page
Section 6. Drop Start-up Procedures
6-1.
6-2.
6-3.
6-4.
6-5.
6-6.
6-7.
6-8.
6-9.
Section Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
WEStation Drop Start-up (VME Based). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2
Card-Handling Precautions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10
DPU Pre-Power-Up Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10
Recommended DPU Card Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-11
6-5.1. MBU Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-11
6-5.2. MDX Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-13
6-5.3. MSE Card. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-15
6-5.4. MSM Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-17
6-5.5. MSX Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18
Removing and Installing the MSX Card. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-20
DPU Power-up Procedure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-23
6-7.1. LED Patterns . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-24
Multibus Power Supplies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-28
6-8.1. Todd or Deltron Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-28
6-8.2. MBPS Power Supply Card (Enhanced 386 DPU) . . . . . . . . . . . . . . . . . . . 6-30
6-8.3. MDPS Power Supply Card (486 DPU) . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-33
CIU Start-up (Multibus-based) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-36
Appendix B. Drop Cabinets
B-1.
B-2.
B-3.
B-4.
B-5.
Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-1
386 DPU Cabinets. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-2
486 DPU Cabinets. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-16
NEMA Enclosures (Multibus-based Drops). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-30
WEStation Enclosures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-37
Glossary
Index
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Table of Contents, Cont’d
List of Figures
Figure
Title
Page
Section 1. Introduction
1-1.
WDPF System Installation Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2
Section 2. General Drop Installation Guidelines
2-1.
2-2.
2-3.
2-4.
Power Connection to Multibus-based Drop (Standard Version 386 DPU) . . . . . . 2-17
Power Connection to Multibus-based Drop (Enhanced Version 386 DPU
and 486 DPU) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-18
Power Connection to Rack-Mount WEStation . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-19
Power Connections to AC Input Box for WEStation Drop (Cube) . . . . . . . . . . . . 2-21
Section 3. WEStation Drop Configurations
3-1.
3-2.
3-3.
3-4.
3-5.
3-6.
3-7.
3-8.
3-9.
3-10.
3-11.
3-12.
3-13.
3-14.
3-15.
3-16.
VME WEStation Cube. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-2
VME WEStation Cube with Small Desk . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3
VME WEStation Cube with Large Desk . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4
Rack-mounted VME WEStation in Back-to-Back Cabinet. . . . . . . . . . . . . . . . . . . 3-5
Sample VME WEStation (in Cube enclosure). . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7
AC Distribution Panel Assembly (rack-mounted VME WEStation) . . . . . . . . . . . 3-8
Typical Connector Types. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-11
Connectors for Input Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-19
Connectors for Serial Devices (Printers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-23
Connectors for Screen Copy Printers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-24
Administration Tool Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-43
Printer Manager Window. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-43
Printer Manager: Local Printer Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-45
SCSI Device Connection — Single SCSI Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-50
SCSI Device Connection — Two Separate SCSI Busses . . . . . . . . . . . . . . . . . . . 3-51
SCSI Device Connection — Two SCSI Busses (Cube) (Rear View) . . . . . . . . . . 3-52
Section 4. Desktop WEStation Configuration
4-1.
4-2.
4-3.
4-4.
4-5.
4-6.
4-7.
Typical WEStationDT (Front View) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
WEStationDT Enclosure (Front and Rear view) . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4
SGI (Sbus to Gbus Interface) PC board. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
Removal of SGI backplate mounting tab hooks . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
GHC Removal from WEStationDT Enclosure . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
GHC Card Jumper Locations (for WEStationDT). . . . . . . . . . . . . . . . . . . . . . . . . 4-12
SGI and WEStationDT Cable Connection (Rear View) . . . . . . . . . . . . . . . . . . . . 4-14
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Table of Contents, Cont’d
List of Figures, Cont’d
Figure
Title
Page
Section 4. Desktop WEStation Configuration, Cont’d
4-8. Data Highway Cable Adapters. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-15
4-9. Disconnecting Data Highway Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17
4-10. Status Indicators — Rear View of WEStationDT . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Section 5. Distributed Processing Unit (DPU)
5-1.
5-2.
5-3.
5-4.
5-5.
5-6.
5-7.
5-8.
5-9.
5-10.
5-11.
5-12.
5-13.
5-14.
5-15.
5-16.
5-17.
5-18.
5-19.
5-20.
5-21.
5-22.
5-23.
5-24.
5-25.
DPU Component Locations (Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . 5-4
DPU Component Locations (Enhanced Version 386) . . . . . . . . . . . . . . . . . . . . . . 5-5
DPU AC Power Cable Connections (Standard Version 386). . . . . . . . . . . . . . . . . 5-7
DPU Grounding Wiring (Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . 5-8
13 VDC Power Supply Wiring (Q-Line I/O) (Standard Version 386) . . . . . . . . . . 5-9
Signal Cable Connections for Single DPU (Q-Line I/O)
(Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-10
Signal Cable Connections for Redundant DPU (Q-Line I/O)
(Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-11
Single DPU Q-Line Expansion Connections (Standard Version 386) . . . . . . . . . 5-12
Redundant DPU Q-Line Expansion Connections (Standard Version 386) . . . . . . 5-13
Q-Crate Wiring (Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-14
Signal Cable Connections for Single DPU (Remote I/O)
(Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-15
Signal Cable Connections for Redundant DPU (Remote I/O)
(Standard Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-15
DPU AC Power Cable Connections (Enhanced Version 386) . . . . . . . . . . . . . . . 5-16
DPU Grounding Wiring (Enhanced Version 386). . . . . . . . . . . . . . . . . . . . . . . . . 5-17
13 VDC Power Supply Wiring (Q-Line I/O) (Enhanced Version 386). . . . . . . . . 5-18
Signal Cable Connections for Single DPU (Q-Line I/O)
(Enhanced Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-19
Signal Cable Connections for Redundant DPU (Q-Line I/O)
(Enhanced Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-20
Single DPU Q-Line Expansion Connections (Enhanced Version 386). . . . . . . . . 5-21
Redundant DPU Q-Line Expansion Connections (Enhanced Version 386) . . . . . 5-22
Q-Crate Wiring for DPU (Enhanced Version 386) . . . . . . . . . . . . . . . . . . . . . . . . 5-23
Signal Cable Connections for Single DPU (Remote I/O)
(Enhanced Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-24
Signal Cable Connections for Redundant DPU (Remote I/O)
(Enhanced Version 386) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-24
486 DPU Component Locations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-26
486 DPU AC Power Cable Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-28
486 DPU Grounding Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-29
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v
9/98
Table of Contents, Cont’d
List of Figures, Cont’d
Figure
Title
Page
Section 5. Distributed Processing Unit (DPU), Cont’d
5-26.
5-27.
5-28.
5-29.
5-30.
5-31.
5-32.
5-33.
5-34.
486 13 VDC Power Supply Wiring (Q-Line I/O) . . . . . . . . . . . . . . . . . . . . . . . . . 5-30
Signal Cable Connections for Single 486 DPU (Q-Line I/O) . . . . . . . . . . . . . . . . 5-31
Signal Cable Connections for Redundant 486 DPU (Q-Line I/O) . . . . . . . . . . . . 5-32
Single 486 DPU Q-Line Expansion Connections . . . . . . . . . . . . . . . . . . . . . . . . . 5-33
Redundant 486 DPU Q-Line Expansion Connections. . . . . . . . . . . . . . . . . . . . . . 5-34
Q-Crate Wiring for 486 DPU. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-35
Signal Cable Connections for Single 486 DPU (Remote I/O). . . . . . . . . . . . . . . . 5-36
Signal Cable Connections for Redundant 486 DPU (Remote I/O) . . . . . . . . . . . . 5-36
Field Mounted Controller (FMC 1000) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-37
Section 6. Drop Start-up Procedures
6-1.
6-2.
6-3.
6-4.
6-5.
6-6.
6-7.
6-8.
6-9.
6-10.
6-11.
6-12.
6-13.
True Time GPS VME Card Switch Locations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-5
EHS Card Switch Location . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7
Sun 4600MP Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-9
MBU Card Switch and Connector Locations . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-12
MDX Card Faceplate and Jumper Locations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-13
MSE Card Jumper and Connector Locations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-15
MSM Card Jumper and Connector Locations . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-17
MSX Card Jumper and LED Locations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18
MSX Card Connector Locations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-22
MHC/MHR LED Patterns (Normal Operation). . . . . . . . . . . . . . . . . . . . . . . . . . . 6-25
Todd/Deltron Power Supply Faceplate (Standard 386 DPU) . . . . . . . . . . . . . . . . 6-28
MBPS Power Supply Faceplate (Enhanced 386 DPU) . . . . . . . . . . . . . . . . . . . . . 6-30
MDPS Power Supply Faceplate (486 DPU) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-33
Appendix B. Drop Cabinets
B-1.
B-2.
B-3.
B-4.
B-5.
B-6.
B-7.
B-8.
B-9.
Single Cabinet - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-3
Plan View of Single Cabinet - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-4
Floor Bolt and Cable Entry Locations for Single Cabinet - 386 DPU. . . . . . . . . . . B-5
Back-to-Back Cabinet - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-6
Plan View of Back-to-Back Cabinets - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . B-7
Floor Bolt and Cable Entry Locations for Back-to-Back Cabinets - 386 DPU . . . . B-8
Side-by-Side Cabinets - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-9
Plan View of Side-by-Side Cabinets - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . B-10
Floor Bolt and Cable Entry Locations for Side-by-Side Cabinets - 386 DPU . . . B-11
9/98
vi
M0-8005
Table of Contents, Cont’d
List of Figures, Cont’d
Figure
Title
Page
Appendix B. Drop Cabinets, Cont’d
B-10. Plan View of Back-to-Back/Side-by-Side Cabinets - 386 DPU . . . . . . . . . . . . . . B-12
B-11. Floor Bolt and Cable Entry Locations for Back-to-Back/Side-by-Side
Cabinets - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-13
B-12. Plan View of Dual Side-by-Side Cabinets - 386 DPU . . . . . . . . . . . . . . . . . . . . . B-14
B-13. Floor Bolt and Cable Entry Locations for Dual Side-by-Side
Cabinets - 386 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-15
B-14. Single Cabinet - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-17
B-15. Plan View of Single Cabinet - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-18
B-16. Floor Bolt and Cable Entry Locations for Single Cabinet - 486 DPU. . . . . . . . . . B-19
B-17. Back-to-Back Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-20
B-18. Plan View of Back-to-Back Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . B-21
B-19. Floor Bolt and Cable Entry Locations for Back-to-Back Cabinets - 486 DPU . . . B-22
B-20. Side-by-Side Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-23
B-21. Plan View of Side-by-Side Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . B-24
B-22. Floor Bolt and Cable Entry Locations for Side-by-Side Cabinets - 486 DPU . . . B-25
B-23. Plan View of Back-to-Back/Side-by-Side Cabinets - 486 DPU . . . . . . . . . . . . . . B-26
B-24. Floor Bolt and Cable Entry Locations for Back-to-Back/Side-by-Side
Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-27
B-25. Plan View of Dual Side-by-Side Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . B-28
B-26. Floor Bolt and Cable Entry Locations for Dual Side-by-Side
Cabinets - 486 DPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-29
B-27. Two-Door NEMA 4 Cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-31
B-28. Plan View of Two-Door NEMA 4 Cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-32
B-29. Two-Door NEMA 3R Cabinet. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-33
B-30. Plan View of Two-Door NEMA 3R Cabinet. . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-34
B-31. Four-Door NEMA 3R Cabinet. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-35
B-32. Plan View of Four-Door NEMA 3R Cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-36
B-33. VME WEStation Cube. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-38
B-34. Floor Bolt Locations for VME WEStation Cube. . . . . . . . . . . . . . . . . . . . . . . . . . B-39
B-35. Plan View and Cable Entry Locations for WEStation Cube . . . . . . . . . . . . . . . . . B-40
B-36. Bolt Locations for Table-Top Mounting (WEStation Cube). . . . . . . . . . . . . . . . . B-41
B-37. VME WEStation Rack-Mounted Enclosure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-42
B-38. Plan View of VME WEStation Rack-Mounted Enclosure . . . . . . . . . . . . . . . . . . B-43
B-39. Floor Bolt and Cable Entry Locations for VME WEStation
Rack-Mounted Enclosure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-44
M0-8005
vii
9/98
Table of Contents, Cont’d
List of Tables
Table
Title
Page
Section 1. Introduction
1-1.
Reference Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4
Section 3. WEStation Drop Configurations
3-1.
3-2.
3-3.
3-4.
3-5.
3-6.
3-7.
3-8.
3-9.
3-10.
3-11.
3-12.
3-13.
3-14.
3-15.
3-16.
3-17.
3-18.
3-19.
3-20.
3-21.
3-22.
3-23.
3-24.
3-25.
3-26.
3-27.
Serial Port Connectors and Device Names . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-15
Recommended Line Printer Settings for Genicom 4440XT Line Printer . . . . . . . 3-25
Recommended Macro #1 Settings for EPSON LQ-2550 Printer . . . . . . . . . . . . . 3-26
Recommended Default Settings for EPSON LQ-2550 Printer . . . . . . . . . . . . . . . 3-27
Genicom 1040 DIP Switch Configuration for Engineering WEStation . . . . . . . . 3-28
Genicom 1040 DIP Switch Configuration for Log Server WEStation
(Printer Manager). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-29
Ribbon Selection with DIP Switch 2, Position 5 . . . . . . . . . . . . . . . . . . . . . . . . . . 3-29
Genicom 1040 DIP Switch Configuration for Operation WEStation and
Log Server Alarm Printing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-30
Genicom 1220 Menu Recommended Settings. . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-32
Hewlett Packard Laserjet 4M and 4M+ Hardware Settings . . . . . . . . . . . . . . . . . 3-35
Settings for Tektronix Phaser IIDX (4694) Printer . . . . . . . . . . . . . . . . . . . . . . . . 3-37
Settings for Tektronix 220i Printer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-39
Settings for Hewlett Packard 1200 C/PS Printer . . . . . . . . . . . . . . . . . . . . . . . . . . 3-41
UNIX Printer Manager Window Settings (for Local Printer) . . . . . . . . . . . . . . . . 3-46
Recommended SCSI Addressing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-53
Recommended SCSI Addressing for WEStations with Additional SCSI . . . . . . . 3-56
Engineering WEStation Hardware Configurations . . . . . . . . . . . . . . . . . . . . . . . . 3-59
WEStation Software Server Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-60
Combined Engineering WEStation/Software Server Hardware Configurations . . 3-61
Operator WEStation Hardware Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-62
Log Server WEStation Hardware Configurations . . . . . . . . . . . . . . . . . . . . . . . . . 3-63
Historian WEStation (HSR) Hardware Configurations. . . . . . . . . . . . . . . . . . . . . 3-64
Combined HSR/Logger Hardware Configurations . . . . . . . . . . . . . . . . . . . . . . . . 3-65
Stand-alone HSR/Logger Hardware Configurations . . . . . . . . . . . . . . . . . . . . . . . 3-66
Computational Server WEStation Hardware Configurations . . . . . . . . . . . . . . . . 3-67
Relational Database Server Hardware Configurations . . . . . . . . . . . . . . . . . . . . . 3-67
WEStation Data Link Server Hardware Configurations . . . . . . . . . . . . . . . . . . . . 3-68
M0-8005
viii
9/98
Table of Contents, Cont’d
List of Tables, Cont’d
Table
Title
Page
Section 4. Desktop WEStation Configuration
4-1.
GHC Card J5/J6 Jumper Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Section 6. Drop Start-up Procedures
6-1.
6-2.
6-3.
6-4.
6-5.
TrueTime GPS VME Card Jumper Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-6
EHS VME Address (SW1) Switch Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-8
MDX Jumper Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-14
MSE Jumpers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-16
MSX Jumpers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-19
Appendix A. Electrical and Environmental Specifications
A-1.
A-2.
A-3.
A-4.
A-5.
Electrical Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-2
Typical Input Power Requirements for 115 VAC . . . . . . . . . . . . . . . . . . . . . . . . . . A-4
Typical Input Power Requirements for 230 VAC . . . . . . . . . . . . . . . . . . . . . . . . . . A-7
Weight and Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-10
Temperature and Humidity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-11
9/98
ix
M0-8005
Summary of Changes
This revision of “Drop Installation Manual (WEStation Equipped)” (M0-8005)
includes the following changes:
• Information in the manual has been reorganized.
• Section 4 provides an overview of the WEStationDT.
• Illustrations for wiring and cabinets have been included for the 386 and 486
DPUs.
• Configuration and information on new printed circuit cards have been added.
• All figures have been redone to reflect corrections and changes.
• Information for configuring the new dot matrix printer, Genicom 1220, has been
added.
• Peripheral specifications in Appendix A are only representative due to the
frequent model changes by the various vendors.
9/98
Changes-1
Westinghouse Proprietary Class 2C
M0-8005
Section 1. Introduction
1-1. Overview
The WDPF system consists of individual processing units (called drops) which
communicate over networks (called highways). Two basic types of drops are
available:
• WEStation drops, based on a RISC workstation (Sun SPARC) with added
Westinghouse hardware supporting highway communication.
• Multibus-based drops, based on Westinghouse boards including the
functional processor (based on an Intel 80X86 processor) and highway
communication hardware.
The WEStation drops provide a variety of functions, including all man-machine
interface functions (for system configuration as well as operation) and server
functions.
The Distributed Processing Unit (DPU) and Clock Interface Units (CIUs) provide
data acquisition, control functions, and timekeeping functions.
An overview of the recommended procedure for WDPF installation is shown in
Figure 1-1. As Figure 1-1 shows, this manual is one of several which describe the
installation of a WDPF system. In combination, these manuals describe the
planning required before the equipment arrives at the permanent site, and explain
installation procedures from receipt of the equipment to power-up for all drops and
peripheral devices. For a complete listing of related documents, see Section 1-3.
This document describes the drop configurations and installation instructions for
WEStation drops and the applicable Multibus-based drops.
9/98
1-1
Westinghouse Proprietary Class 2C
M0-8005
Phase 1:
Plan system layout, as
described in M0-8000.
Phase 1
Plan system
layout
Phase 2:
Prepare site as described
in M0-8000 and M0-8005.
Phase 2
Prepare site
Phase 3:
Receive termination
cabinets as described in
M0-8005.
Phase 3
Receive
termination
cabinets
Phase 4b
Phase 4a
Install Highways
Install field wiring
Phase 4a:
Install Highways, as
described in M0-8000.
Phase 4b:
Install field wiring, as
described in M0-0053
or NLAM-B204.
Phase 5:
Receive/install drops,
as described in M0-8005.
Phase 5
Receive/install
drops
Phase 6:
Start-up Highways, as
described in M0-8000.
Phase 6
Start-up
Highways
Figure 1-1. WDPF System Installation Overview
M0-8005
1-2
Westinghouse Proprietary Class 2C
9/98
1-2. Contents of This Document
1-2. Contents of This Document
This manual is organized into the following sections:
• Section 1. Introduction describes the scope and content of this document and
provides a list of additional reference material.
• Section 2. General Drop Installation Guidelines provides information on
drop equipment storage and installation.
• Section 3. WEStation Drop Configurations describes the available
WEStation configurations, including the printed-circuit card slot assignments
and available peripheral devices.
• Section 4. Desktop WEStation Configuration describes the configuration for
the WEStationDT.
• Section 5. Distributed Processing Unit (DPU) describes the available DPU
configurations, including the printed-circuit card switch/jumper settings and
slot assignments.
• Section 6. Drop Start-up Procedures provides general start-up instructions for
WEStation and Multibus-based drops.
• Appendix A. Electrical and Environmental Specifications provides electrical
specifications and environmental requirements for drops and peripherals.
• Appendix B. Drop Cabinets provides illustrations and dimensions for the drop
cabinets.
9/98
1-3
Westinghouse Proprietary Class 2C
M0-8005
1-3. Reference Documents
1-3. Reference Documents
While using this document, it may be helpful to refer to the documents listed in
Table 1-1.
Table 1-1. Reference Documents
Document
Number
Title
Description
M0-0053
Q-Line Installation Manual
Provides descriptions and installation
instructions for Q-Line I/O.
M0-0054
Remote Q-Line Installation
Manual
Describes Remote Q-Line I/O, including
field wiring and card addressing.
M0-8000
WDPF System Planning and
Highway Installation Manual
Provides descriptions and installation
instructions for the Westnet Data
Highway and Information Highway.
NLAM-B204
Distributed I/O Installation
Manual
Provides descriptions and installation
instructions for 700 Series I/O.
U0-0131
Record Types User’s Guide
Describes WDPF point record types,
including the Drop Status Record (DU
type).
U0-0132
Custom and Non-Standard Text
Algorithm User’s Guide
Describes the procedures for creating
custom DPU algorithms and
programming them into PROMs.
U0-2101
Clock Interface Unit User’s
Guide
Provides detailed information on the
Chronolog Time Code Reader Clock
Interface Unit drop.
U0-2110
Computime Clock Interface Unit Provides detailed information on the
User’s Guide
Computime Clock Interface Unit drop.
U0-2111
TrueTime Clock Interface Unit
(CIU) User’s Guide
Provides detailed information on the
TrueTime Clock Interface Unit drop.
U0-8001-x.x
WEStation Software Load Kit
Discusses loading the WDPF and
operating system software for the
WEStation system (x.x = the revision
number of the operating system).
U0-8110
Operator WEStation
Configuration Manual
Provides instructions for configuring the
Operator WEStation.
M0-8005
1-4
Westinghouse Proprietary Class 2C
9/98
1-3. Reference Documents
Table 1-1. Reference Documents (Cont’d)
Document
Number
Title
Description
U0-8205
System Point Directory User’s
Guide
Describes the System Point Directory
and associated utilities, and the
WEStation drop database compiler.
U0-8700
Data Link Server Manager User’s Describes the configuration and
Guide
operation of the WEStation Data Link
Server.
IEEE 802.3
Ethernet specification
Standard Ethernet documentation
applicable to the Information Highway.
In addition to the documents listed in Table 1-1, this manual may refer to
“applicable vendor documentation”, which is defined on a project basis. These
documents may include:
• Operating system (UNIX/Solaris) manuals.
• Window manager (OpenWindows) documentation
• Workstation hardware (Sun) documentation.
• Peripheral device documentation.
Man pages (standard UNIX on-line documentation) are also available for operating
system functions and certain WDPF functions.
9/98
1-5
Westinghouse Proprietary Class 2C
M0-8005
Section 2. General Drop Installation
Guidelines
2-1. Section Overview
This section provides general guidelines for the shipping, storage, and installation
of WDPF equipment. It also discusses drop and peripheral wiring connections.
The following topics are included in this section:
• Shipping guidelines (Section 2-2).
• Storage guidelines (Section 2-3).
• Drop and cabling identification (Section 2-4).
• Installing equipment at permanent site (Section 2-5).
• Power wiring (Section 2-6).
11/94
2-1
Westinghouse Proprietary Class 2C
M0-8005
2-2. Shipping Guidelines
2-2. Shipping Guidelines
The following general guidelines are provided to assist those responsible for
shipping, receiving, and transporting WDPF system equipment.
2-2.1. General Shipping Guidelines
1. Since many pieces of a WDPF system are large and heavy, adequate off-loading
equipment (along with experienced personnel to operate the equipment) must
be provided at the site.
2. The best manner and route to transport the equipment (after it is off-loaded),
should be planned in advance. Any problem obstacles, such as stairways,
doorways, or difficult turns should be considered.
3. Any components that are contained in the main housing of a drop (that is, a
Multibus cabinet) are shipped fully assembled.
4. Any components that are not attached to the main housing (that is, peripheral
devices such as CRTs) are shipped along with the main housing, but in a
separate package.
Note
Hard disks are removed from some drops
prior to shipment.
5. Any cables connected entirely within the main housings, are connected prior to
shipment.
6. Any cables used to connect external components together, are packed in a
separate package, and shipped along with the main enclosure.
7. Cabinet housings are mounted on pallets.
8. All internal cables are secured to prevent rubbing or chafing, and stress is
relieved with cable ties.
9. All internal components, that are not secured, are locked in place by anchoring
devices.
10. All temporary cushioning, blocking, bracing, and anchoring material must be
removed before powering the system.
11. The housings are wrapped in heavy-duty plastic wrap.
M0-8005
2-2
Westinghouse Proprietary Class 2C
11/94
2-2. Shipping Guidelines
12. Domestic shipments are routed by air-ride/electronic vans directly to the point
of destination, if possible, to eliminate any unnecessary unloading and
reloading.
13. Shipping containers are marked as follows:
• Front and back are identified.
• Destination.
• Return address.
• Package numbers showing the purchase order number, followed by the
package number and the total number of packages.
• Material identification number.
• Handling instructions (for example, Fragile, Center of Gravity, Keep Dry,
This Side Up, Sling Here, Do Not Freeze, and stacking limitations if
appropriate).
• Weight of packages.
• Special instructions (for example, Desiccant Inside; special inspections;
storage or unpacking restrictions as appropriate).
2-2.2. Air Export Shipping Guidelines
1. Shipments for export are prepared in the same manner as domestic shipments,
except that internal bracing and anchoring are done in a manner suitable for the
shock and vibration encountered during air shipment.
2. Cabinets, that are normally shipped in an upright position, are placed on their
side on a heavy-duty pallet and covered with heavy-duty plastic and waterproof
paper. The top side of the cabinet is covered with cardboard packaging and
banded with high-strength banding.
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2-2. Shipping Guidelines
2-2.3. Ocean Export Shipping Guidelines
1. Shipments, to be made by ocean carrier, are secured internally (as described for
domestic shipment). A desiccant is placed in each enclosure.
2. Cabinets are locked, and the keys are taped to the cabinets. The enclosure is
wrapped with plastic bubble wrap and enclosed in a sealed barrier.
3. All equipment is enclosed in barrier bags.
4. The sealed enclosure is encased in a military-type plywood crate. The crate is
marked to indicate the center of balance, fork lift and sling handling points, and
cautioning mark and symbols.
5. Each crate is marked on two sides and on the top with customer identifications
and all other information as specified for domestic shipments.
2-2.4. Delicate Component Shipping Guidelines
1. For all shipments, both foreign and domestic, all components that are
considered too delicate to be transported in the enclosure are removed, and
packaged separately.
2. These components are placed in a location on the carrier that is subject to the
least shock.
2-2.5. Hoisting Guidelines
1. If it is necessary to lift equipment by crane or other hoisting devices, this service
is provided at an extra expense to the customer.
2. Westinghouse can provide rigging and rigging supervision to ensure a complete
and safe off-loading. For more information, contact your Westinghouse
representative.
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Westinghouse Proprietary Class 2C
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2-2. Shipping Guidelines
2-2.6. Off-Loading and Unpacking Guidelines
1. All shipments of WDPF equipment should be off-loaded with Roll-A-Lift jacks,
hydraulic lift trucks, or four-wheel dollies. It is recommended that domestic
shipments not be hoisted, but overseas shipments may be hoisted at the
center-of-gravity marks, shown on the container.
2. The packing list for all shipments is attached to crate number 1. The packing list
should be located, and the shipment should be checked against the list to be sure
that all items have been delivered. If any of the shipment is missing, the driver
should be notified of the shortage, and proof of the shortage should be obtained.
3. The complete shipment should be inspected for visible damage to any of the
packing containers, and any damage should be verified with the driver.
4. The equipment should be unpacked by cutting any banding and removing all
exterior packaging such as cardboard and plastic wrap. Any drops that were
shipped on their side should be placed upright. The shipment should be
inspected again for visible damage such as dents, scrapes, and severely
scratched paint work. Any damage should be verified with the driver.
5. All reusable packing material (that is, pallets, containers, and so on) should be
saved in case the shipment must be returned (see Section 2-2.7).
6. All cabinet doors should be opened and all shipping materials should be
removed. The interior of all drop enclosures should be inspected for obvious
mechanical damage. Any damage verified with the driver.
WARNING
Do not allow, under any circumstances,
any equipment to sit in an area exposed to
the weather.
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2-2. Shipping Guidelines
2-2.7. Repacking for Return Shipment Guidelines
1. If a WDPF drop must be returned to the factory, it should be repackaged in a
manner similar to the way it was shipped. The guidelines for packaging are
outlined in Section 2-2.1 through Section 2-2.4.
In general, the drop should be packaged so that no damage will occur during
transportation, which means that exteriors must be protected, and interior
devices must be secured.
2. Before returning any equipment to Westinghouse, a Westinghouse Sales
Representative should be contacted.
3. Documentation, which states the reason for the return, should be attached to the
returned equipment.
2-2.8. Transporting to the Specific Installation Location Guidelines
1. Equipment should be transported to the final installation location with
Roll-A-Lift jacks, hydraulic lift trucks, or four-wheeled dollies.
2. Hoisting is not recommended for final installation. Only certain cabinet
enclosures are designed with holes to attach eye bolts (see Appendix B) for
hoisting.
2-2.9. Tilting Guidelines
1. If necessary, a WDPF drop can be tilted from its normal vertical position so that
the drop can be moved into a space with a low entrance or transported up and
down stairways.
If this is required, care must be taken to ensure that all unsecured parts are made
stationary. This is especially true of devices that are mounted on sliding rails.
2. If possible, the drop should be tilted so that printed-circuit cards are held in
place by gravity.
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2-3. Storage Guidelines
2-3. Storage Guidelines
A WDPF system may be stored for up to two years before being installed. If a
system is to be stored, observe the following guidelines:
1. Connect power supplies to full line voltage for one hour per year to
maintain the voltage rating on the electrolytic capacitors. This prevents shorts
when the system is powered up.
2. Observe the following ambient temperature guidelines:
Minimum
Optimum
Maximum
4°C (40°F)
25°C (77°F)
70°C (160°F)
3. Restrict the temperature rate of change to 6°C (11°F) in 30 minutes.
4. Observe the following humidity (non-condensing) guidelines:
Minimum
Optimum
Maximum
20%
50%
80%
5. Restrict the humidity rate of change to 10% in 30 minutes.
6. Verify that the storage area will be:
• Rodent- and pest-free.
• Insect controlled.
• Equipped with a fire prevention system and a fire sensing and alarm system.
• Located in a key-lock-controlled area.
• Located in a personnel-controlled area.
• Kept free of all combustible material except essential packing materials.
• Protected from airborne dust.
• Free from water leaks and water accumulation.
• Free of corrosive gases.
• Free of excessive vibration.
• Stored in the non-energized state with desiccant bags in each enclosure.
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2-3. Storage Guidelines
• Stored with the cabinet doors locked.
• Stored with dust covers intact.
• Stored in the ‘last in - first out’ manner to avoid rehandling.
7. Stack cables on two-inch-by-four-inch lumber to a maximum height of three
feet.
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2-4. Drop and Cabling Identification
2-4. Drop and Cabling Identification
A standard approach is used for identifying drops and cables. The identifying
markings include assembly drawing numbers for easy reference to manufacturing
data.
2-4.1. Drop Identification
Each WDPF drop has a nameplate that is attached at assembly. The location of the
nameplate for the various configurations is shown in Appendix B.
The following information is given on each nameplate:
• UNIT TYPE - This data gives the drop type and the enclosure type.
• ASSY. DWG. - This gives the assembly drawing number which is used by the
Westinghouse manufacturing facility to assemble the drop.
• SO NO. - This is the general shop order number used for manufacturing
purposes.
• SERIAL NO. - This is a sequential number that is used for record keeping by
the manufacturing facility.
If any inquiries are made concerning a specific drop, please supply all nameplate
information.
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2-4. Drop and Cabling Identification
2-4.2. Determining Input Voltage
WDPF drops can be supplied for either 115 VAC, 60 Hz or 230 VAC, 50 Hz input
voltages. The correct voltage for a specific drop can be determined by checking the
project drawings.
General power-line frequency range for a WDPF system is as specified in Appendix A.
Note that specific peripherals (such as disk drives or printers) require the line frequency
to be maintained close to the nominal frequency (50 or 60 Hz).
A fluctuation from the peripheral device’s specification will generally not impact
the control function of the system, since the DPU’s will not be affected. However,
if a particular disk or printer function is critical to the operation of a system and
fluctuations greater than specified are known to exist in the local power system,
equipment that will maintain the frequency specification should be installed for the
critical drops that use the disk or printer.
2-4.3. Cabling Conventions
All cables provided by Westinghouse are identified by item number (or drawing
number). This item number is shown on the system drawings and the cable
identification list. These item numbers are also used by the Westinghouse
manufacturing facility.
Typically, the cable has a label on or near each connector (usually two per cable;
however, multiple-connector cables are sometimes used). This label shows the
cable item number and typically gives a ‘FROM’ and ‘TO’ identification.
WDPF ribbon cables use the standard colored-line convention for locating pin 1 on
the attached connector. The colored-line convention means that the edge of the
ribbon cable that is marked with a colored line (either red or blue) corresponds with
pin 1 on the connector.
Some connectors are keyed and can only be connected to a mating connector with
the desired pin alignment. However, some connectors can be reversed under certain
conditions. Precautions should be taken to be sure that, if a cable is removed, it is
reconnected properly. To do this, find pin 1 on the male connector and align it with
pin 1 on the female connector.
For example, Q-Line cards have mating connectors with pin numbers printed or
etched near the card-edge ports. The card-edge ports are also marked with a number
that is usually prefixed with a J (such as J1 or J3).
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2-5. Installing Equipment at Permanent Site
2-5. Installing Equipment at Permanent Site
The procedures for locating a drop at its permanent site depend on the physical
configuration of the drop. Illustrations of each physical configuration are provided
in Appendix B.
In general, the location for each drop should be planned in advance. Once
transported to its permanent site, the drop may be leveled or bolted into place
(depending on the physical configuration). Once the drop hardware is in place, drop
wiring can be connected, followed by the drop-specific pre-power-up and power-up
procedures (see Section 6).
2-5.1. General Guidelines
While performing the installation procedures in this document, keep in mind that
additional requirements for power, grounding, and other essential information can
be found in “WDPF System Planning and Highway Installation Manual”
(M0-8000). This document should also be available for reference during drop
installation. Advance planning should include the following considerations:
• Adequate space must be provided around each drop to allow the wiring to be
connected and to allow for maintenance. Recommended access spacing
requirements are given in plan view drawings in Appendix B.
• Most of the electronic hardware in WDPF equipment is cooled by forced air
from fans that are installed within the equipment enclosure. Care must be taken
to provide unobstructed intake and exhaust ports. Air flow is shown in the plan
view drawings in Appendix B.
• Consideration should be given to possible expansion of the control system. A
WDPF system can contain up to 254 drops and can be expanded to that number
at any time; therefore, some planning should be done to effect an orderly and
efficient expansion if one is anticipated.
• If space is not available to allow the recommended access area for operation and
maintenance of the drop, provisions such as extra length wiring for service
loops and methods to move the drop in order to gain access should be planned.
Procedures for the various types of physical configurations are discussed below.
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2-5. Installing Equipment at Permanent Site
VME WEStation Cube
The VME WEStation cube is designed to set on rigid floors. The cube has legs and
leveling feet which may be removed, depending on site requirements.
Notes
If the legs and leveling feet are removed, make sure
to allow sufficient space under the WEStation cube to
maintain proper airflow.
For information on installing the Rack-Mounted
VME WEStation, see the section below on Cabinet
installation.
The following options may be used when installing workstation enclosures:
• The WEStation cube may be bolted into place with enclosure legs and leveling
feet in place.
• The WEStation cube may be bolted into place after removal of the legs and
leveling feet.
• The WEStation cube may be placed on the floor (without bolting), using the
enclosure legs and leveling feet.
To install cube enclosures, unfasten the lag screws or carriage bolts that fasten the
device to the shipping pallet and lift the device from the shipping pallet to the
desired location.
When the cabinet legs are to be used, adjust the leveling screws on the legs so that
the enclosure is level (left-to-right and front-to-back).
Caution
The cube enclosures should not be slid into place if
sufficient friction exists between the leveling feet
and the sliding surface to cause the legs to bend.
Care should also be taken to avoid excessive force
on the legs when the drop is being lifted into place,
in order to avoid bending the legs.
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2-5. Installing Equipment at Permanent Site
To bolt the cube enclosure into place, use one bolt (with appropriately sized flat
washer and split ring lockwasher) in each of the four mounting holes in the cabinet
frame (see Appendix B). Bolts of the following type are recommended: 1/2 in. SAE
Grade 5, 13 threads per inch. The bolts should be of sufficient length to protrude
beyond the enclosure and into tapped holes in steel mounting rails (the bolt length
required will depend on whether the enclosure legs have been removed).
It is recommended that the mounting rails should be at least 13 mm (0.5 in.) thick.
If thinner rails are used, place a nut and appropriate washers on the other side of the
rail. When the cube enclosure is to be installed without legs, the mounting rails must
raise the workstation at least 38 mm (1.5 in.) off of the floor (to maintain required
air flow).
Cabinets (Multibus-based Drops and Rack-Mounted VME WEStation)
To install cabinets, remove the lag screws or carriage bolts from the shipping
pallets. If hoisting is required, remove the top cover of the cabinet, place four
5/8 inch - 12 NC eye bolts in the holes provided, and rig the cabinet.
If the cabinet is to be bolted to the floor, and studs are not already in place, lay out
the bolt locations, and prepare the locations to accept bolts. Lift the cabinet over the
studs, center, and carefully lower the cabinet into place. Then insert the bolts and
tighten.
Remove all packing materials still in place, such as cable ties, anchoring devices,
and braces.
Note
The standard Cabinets are not NEMA-rated. If
NEMA-rated cabinetry is required, use the optional
NEMA-rated enclosures (described below).
NEMA Enclosures (Option for Multibus-based Drops)
To install NEMA enclosures, remove the lag screws or carriage bolts from the
shipping pallets. Rig the cabinet using the 3/4 in. eyebolts provided.
If the cabinet is to be bolted to the floor, and studs are not already in place, lay out
the bolt locations, and prepare the locations to accept bolts. Lift the cabinet over the
studs, center, and carefully lower the cabinet into place. Then insert the bolts and
tighten.
Remove all packing materials still in place, such as cable ties, anchoring devices,
and braces.
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2-5. Installing Equipment at Permanent Site
2-5.2. Wiring Access and Ground Connections
Wiring access ports are provided in all standard WDPF enclosures. These physical
configurations are described and illustrated in Appendix B. When wiring a drop,
check the physical configuration in order to determine appropriate routing.
In addition, all standard WDPF enclosures provide grounding terminals (Cabinet
Ground, CG). The terminal provides a convenient method for connecting the drop
to the customer-supplied earth ground. For more information on grounding, see
“WDPF System Planning and Highway Installation Manual” (M0-8000).
Additional information on the wiring required for each type of drop can be found in
Section 3 and Section 5. Power wiring is described in Section 6.
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2-6. Power Wiring
2-6. Power Wiring
The following sections describe drop power connections and peripheral power
connections (for all drop configurations). For additional information on planning
WDPF power requirements, see “WDPF System Planning and Highway
Installation Manual” (M0-8000).
2-6.1. Multibus-based Drop Power Connections
1. If not previously done during installation planning, select power sources at the
drop location. Inspect all wiring outlets for proper grounding, voltage, and
polarity.
Note
It is recommended that two separate AC
power source feeds, primary and secondary
(backup), be used for each Multibus-based
drop. Each feed should have a dedicated
circuit breaker.
WARNING
Power should be off when making these
connections or when the AC distribution
assembly cover is removed. Hazardous
potentials are present when these circuits
are live, which can be harmful to
personnel.
2. Power connections are made to TB1 on the front, lower left-hand corner of the
AC Distribution Panel (AC Distribution Panel is located on the bottom of the
Multibus cabinet), using 12 AWG conductor cable, as shown in Figure 2-1.
(Dress the conductor ends and clamp in terminal block, TB1.)
Caution
Verify that the drop power source is
grounded in accordance with the WDPF
grounding requirements, as described in
“WDPF System Planning and Highway
Installation Manual” (M0-8000).
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2-6. Power Wiring
3. If using only a primary feed, place jumpers from PRI X to SEC X and PRI N to
SEC N. Connect the hot and neutral to PRI X and PRI N on TB1, respectively.
4. If both primary and secondary feeds are used, connect as follows:
• Verify that jumpers are not in place from PRI X to SEC X and PRI N to
SEC N.
• Make primary feed connections to PRI X and PRI N on TB1.
• Make secondary feed connections to SEC X and SEC N on TB1.
Caution
When both a primary and secondary feed
are present, both primary to secondary
jumpers must be removed.
Figure 2-1 shows power connections for the Standard Version 386 DPU. Figure 2-1
shows power connections for the Enhanced Version 386 DPU and 486 DPU. For more
information on DPUs, see Section 5.
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2-6. Power Wiring
Primary and
Secondary AC
*
Ground
Left-hand corner of
AC Distribution Panel
Secondary
Neutral
Primary
Line
Primary
Neutral
Secondary
Line
Ground
*
Primary AC Only
Left-hand corner of
AC Distribution Panel
*To determine if Ground connection
Primary
Neutral
is to be made at these terminals,
refer to M0-0051.
Primary
Line
Ground
*
Figure 2-1. Power Connection to Multibus-based Drop (Standard Version 386 DPU)
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2-6. Power Wiring
TB1
Primary
Line
Primary and
Secondary AC
X
Primary
Neutral
N
Ground*
G
Secondary
Line
X
Secondary
Neutral
N
Left-hand corner of
G
AC Distribution Panel
Ground*
Primary AC Only
Primary
Line
TB1
Primary
Neutral
X
N
Ground*
G
X
N
Left-hand corner of
AC Distribution Panel
G
*To determine if Ground connection
is to be made at these terminals,
refer to M0-8000.
Figure 2-2. Power Connection to Multibus-based Drop (Enhanced Version 386 DPU
and 486 DPU)
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2-6. Power Wiring
2-6.2. WEStation Drop Power Connections (Rack-Mount)
1. If not previously done during installation planning, select power sources at the
drop location. Inspect all wiring outlets for proper grounding, voltage, and
polarity.
Warning
Power should be off when making these
connections or when the AC assembly
cover is removed. Hazardous potentials
are present when these circuits are live,
which can be harmful to personnel.
2. Power connections are made to TB1 on the front, lower left-hand corner of the
AC Distribution Panel (AC Distribution Panel is located on the bottom of the
cabinet), using 12 AWG conductor cable, as shown in Figure 2-1. (Dress the
conductor ends in terminal block, TB1.)
Note, the WEStation rack-mount cabinets do not have redundant AC feeds.
Only primary AC is required. Users should connect to one set of AC inputs (X,
N, G), and the internal jumpers supplied with the assembly should not be
removed (see Figure 2-3).
X
N
G
X
N
G
To Customer Wiring
Figure 2-3. Power Connection to Rack-Mount WEStation
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2-6. Power Wiring
2-6.3. WEStation Drop Power Connections (Cube)
1. If not previously done during installation planning, select power sources at the
drop location. Inspect all wiring outlets for proper grounding, voltage, and
polarity.
Warning
Power should be off when making these
connections or when the AC assembly
cover is removed. Hazardous potentials
are present when these circuits are live,
which can be harmful to personnel.
2. Power connections are made to the terminal block at the rear of the workstation
enclosure using 12 AWG conductor cable, as shown in Figure 2-4. The rear
panel must be removed to gain access to this terminal block (the terminal block
is located on the right-hand wall of the workstation enclosure). Dress the
conductor ends and clamp in terminal block TB1.
Caution
Verify that the drop power source is
grounded in accordance with the WDPF
grounding requirements, as described in
“WDPF System Planning and Highway
Installation Manual” (M0-8000).
Note
Currently, the WEStation only provides for 1
AC source. Redundant (dual) AC feeds are
not supported.
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2-6. Power Wiring
Wall of
Workstation
Enclosure
Internal power cables to
WEStation Power Distribution
Tray Assembly
L N
G
Customer wiring connects
to lower terminals.
Figure 2-4. Power Connections to AC Input Box for WEStation Drop (Cube)
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2-6. Power Wiring
2-6.4. Peripheral Connections
Two methods may be used for peripheral power connections:
1. Recommended Method - Plug each peripheral into the power distribution
assembly’s AC receptacles (of the interfacing drop) using a three-conductor
IEC320 power cord.
2. Alternative Method - Plug each peripheral into a user-supplied wall receptacle
using a standard three-conductor power cord.
Note
When using the alternative method, the user should
provide a separate load breaker panel, with a
dedicated circuit breaker and, optionally, an isolation
transformer for each receptacle used with a
freestanding peripheral device.
Because the signal cable between the peripheral and the drop usually contains a
ground wire, connecting the power ground to a separate receptacle can create a
ground loop. Because of this risk, the alternative method is not recommended.
Caution
See Appendix A on electrical specifications for AC
power requirements. These requirements should
be followed so as not to overload the circuit
breakers.
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Section 3. WEStation Drop
Configurations
3-1. Section Overview
The hardware for a VME-Based WEStation drop consists of an enclosure (cube or
cabinet), AC input box, power distribution tray, fan panel assembly, and 12-slot
VME chassis containing WEStation cards and electronics. Depending on the drop’s
function, peripheral devices many be added.
Several hardware configurations are available for the WEStation drop. This section
discusses the base components, cards, and optional peripheral devices that the user
can choose from to make a complete VME-Based WEStation drop.
The following topics are included in this section:
• WEStation enclosures (Section 3-2).
• VME WEStation electronics, cards, and devices (Section 3-3).
• Peripheral devices (Section 3-4).
• WEStation drop configurations (Section 3-5).
Note
This section discusses the VME cube and cabinet
configurations. The Sbus Desktop WEStation
(WEStationDT) is discussed in Section 4.
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3-2. WEStation Enclosures
3-2. WEStation Enclosures
The following types of WEStation enclosures are available:
• VME WEStation Cube (fits under a small or large desk).
• 19” Rack-mounted VME WEStation (WEStation cards and electronics placed
in a standard Westinghouse back-to-back cabinet).
• Custom enclosure (designed by the user).
• Sbus Desktop WEStation (discussed in Section 4).
With the exception of the Sbus Desktop WEStation, the same cards and electronics
are used with each type of enclosure (cube, cabinet, and custom).
Figure 3-1 shows the VME WEStation cube. Figure 3-2 and Figure 3-3 show the
WEStation cube with the various desk configurations. Figure 3-4 shows the Rackmounted WEStation in the back-to-back cabinet. Appendix B provides dimensions,
access spacing, and cable routing information for Westinghouse standard cabinets
and the VME WEStation cube.
Figure 3-1. VME WEStation Cube
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3-2. WEStation Enclosures
....
Nameplate
Power Distribution Tray
Cabinet Ground (CG)
VME
Chassis
AC Input
Box
Fan Panel Assembly
Front View
Rear View
Figure 3-2. VME WEStation Cube with Small Desk
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3-2. WEStation Enclosures
....
Power Distribution Tray
Nameplate
VME
Chassis
Fan Panel Assembly
Front View
Cabinet Ground (CG)
AC Input
Box
Rear View
Figure 3-3. VME WEStation Cube with Large Desk
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3-2. WEStation Enclosures
Nameplate
Highway
Transition Panel
Power Distribution
VME
Chassis
Fan
Highway
Transition Panel
Power Distribution
Cabinet Ground (CG)
VME
Chassis
Fan
AC Distribution
Panel
Front View
Figure 3-4. Rack-mounted VME WEStation in Back-to-Back Cabinet
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3-3. VME WEStation Electronics, Cards, and Devices
3-3. VME WEStation Electronics, Cards, and Devices
Inside the selected VME WEStation enclosure, a base configuration is standard.
Other items, such as cards and devices, are chosen by the user. The following
sections discuss the required and optional parts of the VME WEStation:
• Base configuration (Section 3-3.1).
• WEStation cards (Section 3-3.2).
• Optional devices (Section 3-3.3).
Figure 3-5 shows a sample VME WEStation (in a cube enclosure).
Note
The items discussed in this section are used for VME
WEStation enclosure (cube, cabinet, or custom). The
Desktop WEStation is discussed in Section 4.
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3-3. VME WEStation Electronics, Cards, and Devices
Nameplate
AC IN 2
Power Distribution Tray
CB2
GND
+12V
AUX
GND
+5V
DISK
CB1
OFF
-12V
+5V
AC IN 1
AC OUT 2
ON
+12V
OFF
AC OUT 1
ON
(Open Area)
11
SBUS-0
12
P11
P11
Truetime
GPS-VME
J7
J
1
ENA
ENA
ENA
CH1
CH1
CH1
CH0
CH0
CH0
SCAN
13
P11
NORMAL
DIAGNOSTIC
14
DIAGNOSTIC LEDs
15
DIAG
PRI 1
DIAG
DIAG
2
HI
HI
LO
LO
LO
SHC
STATUS
SHC
STATUS
STATUS
J
HI
DISPLAY
SELECT
1PPS PWR
9
SBUS-1
SERIAL A
10
8
6
4
P5
PAR
CH0
RLY
CH0
RLY
P5
J
AMP
RATIO
GEN
PHASE CODE
P5
4
OUT GND
PRI 2
J
SCSI
SBUS-3
2
5
CH1
RLY
3
1
PAR
J1
CODE INGEN CODE
ETHERNET
5
3
ANTENNA
EXT EVENT 1PPS
SBUS-2
SCSI IN 0
7
J
CH0
RLY
KEYBOARD AUDIO
PORT
PAR
SERIAL B
SCSI OUT 0
PORT
SEC 1
LOCK ERR
CH1
RLY
P6
P6
CH1
RLY
(Open Area)
P6
SEC 2
J
6
0
SCSI
Serial Port
Expansion
Option
Disk
Assembly
Sun 4600MP
Card
Second
SHC Card
(Optional)
SHC
Card
EHS
Card
(Optional)
GHC
Card
Fan Panel
Assembly
TrueTime
GPS VME
Card
Figure 3-5. Sample VME WEStation (in Cube enclosure)
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3-3. VME WEStation Electronics, Cards, and Devices
3-3.1. Base Configuration
This section discusses the items that are “standard” in a WEStation enclosure.
• AC Input
— For the 19” rack-mounted VME WEStation in a cabinet, AC input from an
AC distribution panel (typically, located at the bottom of the cabinet). The
AC distribution panel contains the terminal block for the user’s hardwired
AC input. It includes four 10 amp circuit breakers and sixteen IEC 320
female receptacles. Each circuit breaker is connected to four separate female
IEC receptacles. The AC receptacles are used for powering the cabinet’s two
WEStation drops and their peripherals. Note, no AC line filters or inrush
limiting devices are provided in this AC distribution panel. Users
connecting any devices to this AC distribution panel are responsible for their
own AC filtering. Figure 3-6 shows a AC Distribution Panel Assembly for a
rack-mounted VME WEStation in a cabinet.
E1
CB2
CB1
CB3
J5
J1
DANGER
ON
ON
CB4
J9
ON
J6
J2
J13
ON
J10
J14
HIGH VOLTAGE
J7
J3
OFF
OFF
J11
OFF
J8
J4
J15
OFF
J12
J16
Figure 3-6. AC Distribution Panel Assembly (rack-mounted VME WEStation)
— For the VME WEStation cube, an AC Input Box (see Figure 2-4) is provided
at the back of the cube. It contains the terminal block for the user’s
hardwired AC input. A detachable IEC power cord delivers the AC power
to the WEStation’s Power Distribution Tray Assembly.
• Power Distribution Tray
The Power Distribution Tray assembly contains the following items:
— 2 AC 10 Amp circuit breakers
— 8 IEC 320 female receptacles
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3-3. VME WEStation Electronics, Cards, and Devices
— Workstation power supply
— DC power monitoring board with status LEDs
— Test points for workstation’s DC voltages.
Slides and detachable AC and DC power connectors are provided for easy
maintenance. Circuit breaker CB1 controls the AC to the workstation’s power
supply, and one row of four AC receptacles. CB2 controls the remaining four
receptacles. Note that an AC line filter is provided between the main AC and the
power supply’s AC input.
• Fan Panel Assembly
The Fan Panel Assembly is used to cool VME boards and Disk Tray Assembly
electronic components.
• 12-Slot VME WEStation Chassis
The VME Chassis holds the WEStation cards and devices. It contains eight 9U
VME slots, four 6U VME slots, as well as space for the WEStation Disk Tray
Assembly and SCSI Serial Port Expansion option. Note that Slot #9 of the
chassis contains the separation plate between the 9U and 6U VME slots and
cannot be used to house a VME board. Slots are numbered from left to right.
Section 3-3.2 discusses the required and optional cards that can be housed in the
VME WEStation Chassis.
3-3.2. WEStation Cards
The following cards can be housed inside the VME Chassis. Some cards are
required while others are chosen by the user.
• Sun
TM
4600MP 9U VME Multi-Processing Card
This required card contains the WEStation’s central processing unit and resides
in slots 1 and 2 of the VME chassis. It has two Mbus (Sun processor bus) slots
for single and multiple processing configurations. In addition, up to 4 Sbus (Sun
I/O bus) expansion slots are available for the board’s I/O expansion. Each
4600MP card is equipped with 64MB of DRAM standard and can be expanded
to a maximum of 512MB.
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3-3. VME WEStation Electronics, Cards, and Devices
The following standard I/O ports included on this board are:
— Keyboard/mouse
— Audio
— Ethernet (Single)
— Two Serial Ports (A and B)
— SCSI
The two Mbus slots of the 4600MP board allow for CPU expandability and multiprocessing power. Each Mbus slot can contain either 1 or 2 CPUs. Improved
processing power can be achieved by changing or adding an Mbus processor
daughter card on the 4600MP. The following processor board options are currently
available:
— (1) Sun M40 Mbus Processor Board (40 MHz CPU with 0 MB Cache)
— (2) Sun M51 Mbus Processor Boards (50 MHz CPU with 1 MB Cache)
The Sbus expansion ports of the 4600MP board are used for various I/O
functions. The supported Sbus board options include:
— Graphics Cards (one required for each monitor)
Sun GX Graphics Sbus card (uses 13W3 female connector)
Sun TGX Graphics Sbus card (uses 13W3 female connector)
Sun Monochrome Monitor Sbus card (uses 13W3 female connector)
— Parallel Port Cards
Aurora 10SJ Parallel Port Sbus card (uses Mini DB25 female connector)
Sun Parallel Port Interface Sbus card (uses Mini D28 female connector)
— SCSI Host Adapter Cards
Sun SCSI Host Adapter Card (uses Mini D50 SCSI II connector)
Sun Fast SCSI2 / Buffered Ethernet Sbus card (uses Mini D50 SCSI II
connector)
These cards are only used with the Historian WEStation drop.
Figure 3-7 shows the different types of connectors that the Sbus cards use.
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3-3. VME WEStation Electronics, Cards, and Devices
SBUS-0
DIAGNOSTIC LEDs
NORMAL
DIAGNOSTIC
13W3 female connector
(Video)
SCAN
SBUS-1
SERIAL A
DB25 female connector
DB25 female connector
(Parallel or Serial Port)
SERIAL B
SBUS-3
SCSI
Mini D50 female connector
Mini D28 female connector
(Parallel Port)
ETHERNET
D15 female connector
SBUS-2
KEYBOARD AUDIO
Mini DIN 8
female connector
Mini D50 female connector
(additional SCSI Port)
Figure 3-7. Typical Connector Types
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3-3. VME WEStation Electronics, Cards, and Devices
• VME Westnet II Data Highway Controller Board(s)
The following two types of boards are available to connect the VME WEStation
to the Westnet II Data Highways:
— SHC is used in applications requiring remote connections to the Data
Highway.
— GHC is used when direct (local) Westnet II connections are available.
Each board is a single slot 9U VME board. At least one of these boards is
required in a VME WEStation. However, the user has the option of having up
to four boards, either of one type or a combination of the two.
• VME Ethernet Highway Switch Card (EHS)
This optional 9U card is used when redundant Ethernet highways are to be
connected to the VME WEStation.
• VME TrueTime Clock Interface Card (GPS-VME)
This optional card requires two VME 6U slots. It is used by a WEStation drop
that is acting as a timekeeper. The TrueTime card comes with an antenna for
installation on the roof of a plant to pick up signals from the NAVSTAR
satellites. It takes the Global Positioning System Time and provides it to the
WEStation.
For information on the TrueTime system, see “TrueTime Clock Interface Unit
User’s Guide” (U0-2111).
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3-3. VME WEStation Electronics, Cards, and Devices
Card Handling and Component Power Precautions
Observe the following precautions to avoid damage to the WDPF equipment:
• Do not remove cards from the VME chassis without first removing power.
• Avoid touching any card components. A anti-static strap must be used when
handling the boards.
• If boards are to be shipped or stored, they should be placed in anti-static bags.
Never pack printed circuit boards in styrofoam “peanuts”.
• Before adding or removing SCSI devices or peripherals, power down the
workstation and peripherals.
Caution
Failure to observe the guidelines listed
above can result in printed-circuit board
damage.
3-3.3. Optional Devices
The following optional devices are also housed within the 12-slot VME Chassis.
• VME WEStation Disk Tray Assembly
This assembly contains the hard disk storage for the VME WEStation drop.
Each WEStation requires a Disk Tray Assembly; however, the configuration
will vary depending upon the drop’s storage requirements. The storage devices
inside the Disk Tray Assembly are SCSI devices that connect to the 4600MP
board’s main SCSI port or an additional SCSI host adapter board. The user can
choose from the following available configurations:
For applications with single SCSI bus:
— (1) 1Gb Disk Drive
— (1) 2Gb Disk Drive
— (1) 4 Gb Disk Drive
— (1) 26B Disk Drive and 8mm Tape Drive:
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3-3. VME WEStation Electronics, Cards, and Devices
For applications with two separate SCSI buses:
— (2) 16B Disks on separate SCSI Buses
— (2) 26B Disks on separate SCSI Buses
— (2) 46B Disks on separate SCSI Buses
• SCSI Serial Port Expansion Option
This is an optional kit used when the VME WEStation requires more than the
two serial ports that comes standard on the SUN 4600MP board. The kit
contains a single drive bay unit mounted inside of the disk drive assembly along
with either 8 or 16 ports on the side of the disk drive assembly.
See the following section on Hardware and Software Configuration for SCSI
Serial Port Expansion Option for more information.
Hardware and Software Configuration for SCSI Serial Port Expansion Option
For workstation enclosure configurations which incorporate more than two serial
devices, the SCSI serial port expansion option (Central Data SCSI Terminal Server)
is used. It is recommended that this device be configured to reside at SCSI target
ID 0. The SCSI ID jumper on the device is factory-shipped with this default address
as shown below:
Jumper
Setting
W3
Remove
W2
Remove
W1
Remove
For additional information on the SCSI serial port expansion option, see the
applicable vendor documentation.
The required device driver must be loaded in the workstation enclosure for correct
operation of the additional serial ports. For instructions on loading the device driver,
the system load procedures documentation.
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3-3. VME WEStation Electronics, Cards, and Devices
Table 3-1 lists the device names (as defined by the device files in the /dev directory)
associated with each of the possible serial port connectors. The 8- and 16-port
versions of the SCSI serial port expansion option are shown.
Table 3-1. Serial Port Connectors and Device Names
Location
Connector
Label
Device Name
Sun 4600MP Card
SERIAL A
ttya
Sun 4600MP Card
SERIAL B
ttyb
SCSI Serial Expansion 8-Port and 16-Port Versions
SCSI Serial Expansion
Port 0
ttyc00
SCSI Serial Expansion
Port 1
ttyc01
SCSI Serial Expansion
Port 2
ttyc02
SCSI Serial Expansion
Port 3
ttyc03
SCSI Serial Expansion
Port 4
ttyc04
SCSI Serial Expansion
Port 5
ttyc05
SCSI Serial Expansion
Port 6
ttyc06
SCSI Serial Expansion
Port 7
ttyc07
SCSI Serial Expansion 16-Port Version
9/98
SCSI Serial Expansion
Port 8
ttyc08
SCSI Serial Expansion
Port 9
ttyc09
SCSI Serial Expansion
Port 10
ttyc0a
SCSI Serial Expansion
Port 11
ttyc0b
SCSI Serial Expansion
Port 12
ttyc0c
SCSI Serial Expansion
Port 13
ttyc0d
SCSI Serial Expansion
Port 14
ttyc0e
SCSI Serial Expansion
Port 15
ttyc0f
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3-4. Peripheral Devices
3-4. Peripheral Devices
The following sections describe the peripheral devices which may be added to the
base workstation enclosure:
• CRT monitors (see Section 3-4.1).
• User input devices (see Section 3-4.2).
• Printers (see Section 3-4.3).
• Administration Tool to set up printers (see Section 3-4.4).
• Storage devices (see Section 3-4.5).
• PROM Programmer (see Section 3-4.6).
3-4.1. CRT Monitors
WEStation drops which provide a direct user interface can be equipped with one or
more CRTs. The following types of monitors are available:
• 20-Inch (19 inch viewable) Intecolor Models (with or without bonded
touchscreen)
— Desktop monitor
— Rack-mounted monitor (for use in cabinet and panel enclosures)
The Intecolor monitors are industrial style monitors which can be placed near
or at a distance of up to 150 ft. from the WEStation electronics. These monitors
support at least 1152 x 900 resolution. Each monitor requires a color Sbus
graphics card (TGX).
For information on how to configure touchscreen monitor, refer to “Operator
WEStation Configuration Manual” (U0-8110).
• 20-Inch Sony Color Desktop Model
This a standard monitor is for office environments for best viewing. It must be
located within 15 ft. of the WEStation chassis. This monitor supports at least
1152 x 900 resolution. Each monitor requires a color Sbus graphics card (TGX).
Integral touch screens are not available on this monitor.
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3-4. Peripheral Devices
• 17 inch Zenith Monochrome Desktop Model
This monitor must be located within 15 ft. of the WEStation chassis. Each
monitor requires a Sbus graphics card (monochrome monitor card).
• 27 inch Conrac Color Shelf Monitor (Some software packages require color
monitor.)
This monitor can be placed at distances of up to 150 ft. from the WEStation
electronics. It supports 1152 x 900 resolutions. A TGX card is required.
Currently, touchscreen is not available for large screen CRTs.
Several other monitors are capable of interfacing to the WEStation. Contact
Westinghouse representative for more information on the available monitors for
WEStation drops.
All graphics boards have 13W3M connectors. Locations of the Sbus graphics
boards on the Sun 4600 MP card may vary with drop configurations. The monitors
can be connected to any Sbus slot on the Sun 4600MP Adapter card.
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3-4. Peripheral Devices
3-4.2. User Input Devices
WEStation drops which provide a direct user interface are equipped with one or
more input devices. The following types of input devices are available:
• Keyboard — Only available as a desktop device. Several languages are
supported.
• Mouse — Must be used with optical pad.
• Trackball — Used in place of a mouse
• Membrane Keyboard — Available in desktop or flushmount configurations.
• Unmouse touchpad — Only available as a desktop device.
• Alarm Panel — Desk top device only
These input devices are connected to the following locations:
Keyboard
Plugs into the 4600MP keyboard connector
(Mini Din 8). No software configuration is required.
Mouse
Plugs into the connector on the keyboard. If no
keyboard is used, it can be plugged directly into the
4600MP keyboard connector (Mini Din 8). No
software configuration is required.
Trackball
Plugs into the connector on the keyboard. If no
keyboard is used, it can be plugged directly into the
4600MP keyboard connector (Mini Din 8). No
software configuration is required.
Membrane Keyboard Plugs into Serial A, Serial B, or expansion serial
connector on Sun 4600MP card. Must have AC power.
Software configuration is required.
Unmouse Touchpad
Plugs into Serial A, Serial B, or expansion serial
connector on Sun 4600MP card. Must have AC power.
Software configuration is required.
Alarm Panel
Serial A, Serial B, or expansion serial connector on
Sun 4600MP card. Must have AC power. Software
configuration is required.
Figure 3-8 shows the location of these connections.
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3-4. Peripheral Devices
SBUS-0
DIAGNOSTIC LEDs
NORMAL
DIAGNOSTIC
SCAN
SBUS-1
SERIAL A
SERIAL B
Unmouse Touchpad
Membrane Keyboard
Alarm Panel
DB25 female connector
SBUS-2
KEYBOARD AUDIO
Keyboard, Mouse, or
Trackball
Mini DIN 8 female
connector
ETHERNET
SBUS-3
SCSI
Figure 3-8. Connectors for Input Devices
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3-4. Peripheral Devices
Software Configuration for Input Devices
The standard operating system software provides all required drivers for the
keyboard, mouse and trackball. No special software configuration is required for
these devices.
The membrane keyboard, unmouse touchpad, and alarm panel will require
configuration files for proper operation. For information on how to configure these
input devices, refer to the “Operator WEStation Configuration Manual” (U0-8110).
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3-4. Peripheral Devices
3-4.3. Printers
The following types of printing devices are presently supported:
Note
The printers described in this section are
subject to change. Refer to the Peripheral
Equipment Manual for additional
information on printers.
• Line printer (Genicom 4440XT)
• Dot Matrix printers (EPSON LQ-2550, Genicom 1040, and Genicom 1220)
• Laser printer (Hewlett Packard Laserjet III and Hewlett Packard Laserjet 4M
and 4M+)
• Screen copy printer (Tektronix Phaser IIDX (4694), Tektronix 220i, and
Hewlett Packard 1200C/PS)
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3-4. Peripheral Devices
The line printers, dot matrix printers, and laser printers are connected as serial
devices. In configurations which require a graphics adapter (CRT monitor) and no
more than two serial devices, the serial ports on the Sun 4600MP card may be used
(SERIAL A and SERIAL B). For configurations which do not require a graphics
adapter, SERIAL A is reserved by the operating system and cannot be used for any
serial devices. Therefore, only SERIAL B is available for a printer or other serial
device.
If more than one serial device is required, or if it is desirable to allow for later
addition of serial devices, then the WEStation enclosure configuration should
include the SCSI serial port expansion option. Either 8 or 16 serial ports can be
added. Any of these ports may be used to connect a line printer, dot matrix printer,
or laser printer.
For the dot matrix printers, color is an option. The color option is a separate kit for
the printer that requires installation. Except for alarm printouts, color is not used.
The screen copy printers use a separate parallel port card, which is placed in an Sbus
slot of the Sun 4600MP card. The printer then connects directly to the parallel port
board, as shown in Figure 3-10. In some cases, the printer can be connected directly
on the network without a parallel port card.
Note
Certain software configuration may be required
depending on the type of drop to which a printer is
connected. In addition, a printer may require specific
hardware configuration for correct operation.
Hardware and software configuration for each model
of printer is discussed on the following pages.
Figure 3-9 illustrates the options for connection of serial devices.
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3-4. Peripheral Devices
12
11
10
8
Port
SBUS-1
SERIAL A
9
NORMAL SCAN
DIAGNOSTIC
13
SBUS-0
14
DIAGNOSTIC LEDs
15
SERIAL B
7
6
5
ETHERNET
4
SBUS-2
KEYBOARDAUDIO
Port
3
1
SCSI
0
SBUS-3
2
C0-C7 for 8-Port Version
(DB25 female connectors)
SERIAL A
(DB25 female connector)
C0-C15 for 16-Port Version
(DB25 female connectors)
SERIAL B
(DB25 female connector)
SCSI Serial Port Expansion Option
Figure 3-9. Connectors for Serial Devices (Printers)
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3-4. Peripheral Devices
SBUS-0
DIAGNOSTIC LEDs
NORMAL
DIAGNOSTIC
SCAN
SBUS-1
SERIAL A
SERIAL B
SBUS-2
KEYBOARD AUDIO
Connections for
Parallel Interface Card:
Aurora 10SJ Card
(DB25 female connector)
or
Sun II Port Card
(Mini D28 connector)
ETHERNET
SBUS-3
SCSI
Figure 3-10. Connectors for Screen Copy Printers
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3-4. Peripheral Devices
Hardware and Software Configuration for Line Printer
The Genicom 4440XT line printer provides a variety of configuration options, set
using the printer control panel which is located on the top, right-hand side of the
printer. The required settings depend on the drop function which will interface with
the printer. Table 3-2 shows the recommended settings for each drop.
Table 3-2. Recommended Line Printer Settings for Genicom 4440XT Line Printer
Engineering WEStation
Option
Log Server
Setting
Option
Setting
Form length
8.5
Form length
11.0 (user-defined)
Top margin
.6
Top margin
0.0 (user-defined)
Bottom margin
.6
Bottom margin
0.0 (user-defined)
Interface straps A
Set bits 5, 13, 21, 29
to 1
Interface straps A
Set bits 7, 15, 23, 29,
31 to 1
Interface straps B
Set bits 1, 2, 6 to 1
Interface straps B
Set bits 1, 2, 6 to 1
Speed
9600 baud
Speed
9600 baud
Parity
Even
Parity
None
Printer straps A
Set bits 12, 19, 20, 24, Printer straps A
26, 29, 31 to 1
Set bits 19, 20, 24, 26,
29, 31 to 1
Printer straps B
Set all bits to 0
Set all bits to 0
Printer straps B
For additional information on setting these and other line printer options, see the
applicable vendor documentation.
As noted previously, the printer may be connected to one of the Sun 4600MP card
serial port connectors or to one of the additional connectors provided by the SCSI
serial port expansion option. Table 3-1 lists the device names associated with each
of the possible serial port connectors.
The software configuration required for correct line printer operation depends on
the drop function. For the Log Server WEStation, the printer serial port and other
configuration settings are defined in the $WDPF_HOME/ls/config/defaults file
(see “Log Server WEStation User’s Guide” (U0-8400) for additional information).
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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3-4. Peripheral Devices
Hardware and Software Configuration for Dot Matrix Printers
The following dot matrix printers are available:
• EPSON LQ-2550
• Genicom 1040
• Genicom 1220
The EPSON LQ-2550 dot matrix printer provides a variety of configuration
options, set by using the printer control panel which is located at the bottom, righthand side of the printer. This printer offers four preset macros which store such
settings as font and form length. For purposes in this manual, only Macro #1 is used.
In addition, there are default settings which define parity and baud rate.
Table 3-4 and Table 3-4 lists the settings for Macro #1 and the recommended default
settings.
Table 3-3. Recommended Macro #1 Settings for EPSON LQ-2550 Printer
M0-8005
Option
Setting
FONT
Draft
PITCH
12CPI
CONDENSED
Off
FORM LNG
Tractor 66LINE
CSF bin1 132LINE
CSF bin2 132LINE
1” SKIP
Off
AUTO TEAR OFF
Off
LEFT MARGIN
0
RIGHT MARGIN
136
CG TABLE
Italic
COUNTRY
USA
PRINT DIR.
Bi-d (Bi-Directional)
COLOR
Black (user-defined)
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3-4. Peripheral Devices
Table 3-4. Recommended Default Settings for EPSON LQ-2550 Printer
Option
Setting
INTERFACE
Serial
BAUD RATE
9600BPS
PARITY
None
AUTO LINE FEED
(See Note.)
DC1/DC3
Disable
DEFAULT MACRO
#1
Note:
Set AUTO LINE FEED to ‘On’ for alarm printing or ‘Off’ for Log Server WEStation (Printer
Manger) functions.
For additional information on setting these and other printer options, see the
applicable vendor documentation.
As noted previously, the printer may be connected to one of the Sun 4600MP card
serial port connectors or to one of the additional connectors provided by the SCSI
serial port expansion option. Table 3-1 lists the device names associated with each
of the possible serial port connectors.
The software configuration required for correct printer operation depends on the
drop function.
For the Operator WEStation and Log Server (alarm printing), the configuration
settings are defined in the $WDPF_HOME/mmi/config/alarm_config.dat file.
See “Operator WEStation Configuration Manual” (U0-8110) for information on
this file.
For the Log Server WEStation Printer Manager functions, the printer serial port and
other configuration settings are defined in the $WDPF_HOME/ls/config/defaults
file (see “Log Server WEStation User’s Guide” (U0-8400) for additional
information).
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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3-4. Peripheral Devices
The GENICOM 1040 dot matrix printer provides a variety of configuration
options, set using DIP switches on the printer. The DIP switches are found by
pulling the top front panel off the printer. The required settings depend on the drop
function which will interface with the printer. Table 3-5, Table 3-6, and Table 3-8
show the various DIP switch settings.
For additional information on setting the printer configuration switches, see the
applicable vendor documentation.
Table 3-5. Genicom 1040 DIP Switch Configuration for Engineering WEStation
DIP Switch 1
Pos.
Set.
1
OFF
2
ON
Selection
DIP Switch 2
DIP Switch 3
Pos.
Set.
Selection
Pos.
Set.
1
OFF
Unslashed zero
1
ON
2
OFF
Paper out
sensor enabled
2
ON
3
OFF
Paper length
11"
3
OFF
9600 baud
3
ON
4
OFF
8 data bits
4
ON
Skip over
perforation
4
OFF
5
OFF
Parity disabled
5
ON
Color ribbon
5
OFF
6
OFF
Even parity
6
OFF
Buffer disabled
6
OFF
7
OFF
ETX/ACK
disabled
7
ON
Auto CR after
LF enabled
7
OFF
8
ON
XON/XOFF
protocol
8
ON
Auto LF after
CR enabled
8
OFF
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Selection
ANSI
emulation
Character set
(US)
9/98
3-4. Peripheral Devices
Table 3-6. Genicom 1040 DIP Switch Configuration for Log Server WEStation
(Printer Manager)
DIP Switch 1
Pos.
Set.
1
OFF
2
ON
DIP Switch 2
Selection
Pos.
Set.
Selection
Pos.
Set.
Selection
1
OFF
Unslashed zero
1
OFF
2
OFF
Paper out sensor
enabled
2
OFF
3
OFF
Paper length 11"
3
ON
EPSON
Emulation (for
IBM emulation
set switch
position 2 to
ON)
4
ON
Skip over
perforation
4
OFF
Character set 2
5
ON
See Table 3-7.
5
OFF
CAN code
disabled
6
OFF
Buffer disabled
6
OFF
AGM code
disabled
7
OFF
Auto CR after LF
enabled
7
OFF
Line length
13.6 in.
8
OFF
Auto LF after CR
disabled
8
OFF
Character set
normal
9600 baud
3
ON
4
OFF
5
OFF
6
OFF
7
OFF
8
OFF
8 data bits
Parity disabled
Even parity
ETX/ACK
disabled
DTR
DIP Switch 3
Table 3-7. Ribbon Selection with DIP Switch 2, Position 5
Setting
9/98
Ribbon Type
ON
1/2" Multistrike (Black)
ON
1" Fabric Black (Automatic Ribbon Shift mode to minimize wear).
OFF
1" Color and 1/2" fabric black
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3-4. Peripheral Devices
Table 3-8. Genicom 1040 DIP Switch Configuration for Operation WEStation and
Log Server Alarm Printing
DIP Switch 1
Pos.
Set.
1
2
Selection
DIP Switch 2
DIP Switch 3
Pos.
Set.
Selection
Pos.
Set.
Selection
OFF
1
OFF
Unslashed zero
1
OFF
ON
2
OFF
Paper out
sensor enabled
2
OFF
3
OFF
Paper length
11"
3
ON
EPSON
Emulation (for
IBM emulation
set switch
position 2 to
ON)
9600 baud
3
ON
4
OFF
8 data bits
4
ON
Skip over
perforation
4
OFF
5
OFF
Parity disabled
5
ON
See Table 3-7.
5
OFF
6
OFF
Even parity
6
OFF
Buffer disabled
6
OFF
7
OFF
ETX/ACK
disabled
7
OFF
Auto CR after
LF enabled
7
OFF
8
OFF
DTR
8
ON
Auto LF after
CR enabled
8
OFF
Character set
(US)
As noted previously, the printer may be connected to one of the Sun 4600MP card
serial port connectors or to one of the additional connectors provided by the SCSI
serial port expansion option. Table 3-1 lists the device names associated with each
of the possible serial port connectors.
The software configuration required for correct printer operation depends on the
drop function.
For the Operator WEStation and Log Server (alarm printing), the printer
serial port and other configuration settings are defined in the
$WDPF_HOME/mmi/config/alarm_config.dat file (see “Operator WEStation
Configuration Manual” (U0-8110) for additional information). For correct
operation of the alarm printer functions, the selections in this file for printer device
(port) and printer emulation must match the hardware switch settings.
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For the Log Server WEStation Printer Manager functions, the printer serial port and
other configuration settings are defined in the $WDPF_HOME/ls/config/defaults
file (see “Log Server WEStation User’s Guide” (U0-8400) for additional
information).
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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The GENICOM 1220 dot matrix printer provides a variety of configuration options
using menus. A control panel on front of the printer displays the parameter
selections on a LCD screen. The setting for printer Emulation selection from the
Operational Parameters menu must be EPSON. Table 3-4 lists only the
recommended System Parameter menu settings for printer operation. Other
parameters may be changed to the user’s preference for different applications.
Table 3-9. Genicom 1220 Menu Recommended Settings
System Parameters
Parameter Selection
Setting for Parameter Selection
CHARACTER SET
EPSON
CS2
NATIONAL SET
EPSON
USA
CHARACTER TABLE
EPSON
CODE437
OTHER OPTIONS
AUTO LF
(See Note 1.)
RIBBON
(See Note 2.)
BUFFER SETUP
SIZE
256
INTERFACE
TYPE
SERI
AFXT
NO
SLCT-IN
NO
PARA. INIT
NO
BAUD RT
9600
DATA BITS
8
PARITY
NONE
RCV DC1/DC3
NO
ETX/ACK
NO
ROBUST XON/XOFF
NO
Notes:
1. Select ‘YES’ for Alarm Subsystem printing or ‘NO’ for Log Server WEStation (Printer
Manager) functions.
2. Select ‘PROCESS’ if the color option kit and a color ribbon is installed in the printer.
Otherwise, select ‘0.5 BLACK’ if using a black ribbon installed in the printer.
For additional information on setting these and other printer options, see the
applicable vendor documentation.
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3-4. Peripheral Devices
As noted previously, the printer may be connected to one of the Sun 4600MP card
serial port connectors or to one of the additional connectors provided by the SCSI
serial port expansion option. Table 3-1 lists the device names associated with each
of the possible serial port connectors.
The software configuration required for correct printer operation depends on the
drop function.
For the Log Server WEStation Printer Manager functions, the printer serial port and
other configuration settings are defined in the $WDPF_HOME/ls/config/defaults
file (see “Log Server WEStation User’s Guide” (U0-8400) for additional
information).
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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Hardware and Software Configuration for Laser Printers
The Hewlett Packard Laserjet Series III printer provides a variety of
configuration options, set using the printer control panel. As a base setup, the
following options are recommended:
Option
Recommended Setting
AUTO CONT
ON
I/O
SERIAL
SERIAL
RS-232
BAUD RATE
9600
ROBUST XON
OFF
DTR POLARITY
HI
STARTPAGE
ON
RET
MEDIUM
For additional information on setting these and other laser printer options, see the
applicable vendor documentation.
As noted previously, the laser printer may be connected to one of the Sun 4600MP
Adapter assembly serial port connectors or to one of the additional connectors
provided by the SCSI serial port expansion option. Table 3-1 lists the device names
associated with each of the possible serial port connectors.
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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3-4. Peripheral Devices
The Hewlett Packard Laserjet 4M and 4M+ printers provide a variety of
configuration options, set by using the printer control panel. Table 3-10 lists the
recommended menu configurations (note that those menus not mentioned here can
be configured by user preference):
Table 3-10. Hewlett Packard Laserjet 4M and 4M+ Hardware Settings
Printing Menu:
PLC Menu:
PS Menu:
Copies
1
Font Source I (Internal)
Paper
Letter
Font #
0
Orientation
P (Portrait)
Pitch
10.00
Form
60 Lines
Sym Set
Roman-8
Manual Feed
Off
Ret
Medium
Job Menu:
Config Menu:
PRT PS Errs
On
Parallel Menu:
Pageprotect
Off
MP Tray
Cass
High Speed
No
Resolution
600
Lock
None
Adv Fnctns
Off
Personality
Auto
Clr Warn
On
Timeout
15
Auto Cont
On
Density
3
Low Toner
On
Serial Menu:
Serial
RS-232
Pacing
DTR/DSR
Baud Rate
9600
Robust Xon
Off
DTR Polarity Hi
For additional information on setting these and other laser printer options, see the
applicable vendor documentation.
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3-4. Peripheral Devices
As noted previously, the laser printers may be connected to one of the Sun 4600MP
Adapter assembly serial port connectors or to one of the additional connectors
provided by the SCSI serial port expansion option. Table 3-1 lists the device names
associated with each of the possible serial port connectors.
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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3-4. Peripheral Devices
Hardware and Software Configuration for Screen Copy Printers
The Tektronix Phaser IIDX (4694) Color Thermal Printer (Screen Copy
Printer) is used with a parallel interface board installed on the Sbus of the Sun 4600MP
card (see Figure 3-10). The screen copy printer is connected directly to the Sbus parallel
interface board.
Table 3-11 details the required settings to be made using the front panel of the
Tektronix Phaser IIDX (4694) Color Printer. See the applicable user documentation
for additional details.
Table 3-11. Settings for Tektronix Phaser IIDX (4694) Printer
Window
Number
Setting
0
MAKE SELECTION FOR USER
CONNECTED TO:
PARALLEL PORT 1
1
COPY LAST PICTURE PRINTED:
Make 001 additional prints
2
SELECT GRAPHICS APPLICATION MODE:
Color shaded solids/images
3
LIGHTEN OR DARKEN IMAGE:
(Do not adjust.)
4
SELECT MIRROR IMAGE:
Print as received
5
SELECT PICTURE POSITION ON MEDIA:
Landscape and centered
6
EXCHANGE COLORS:
Print colors as received
7
SELECT MEMORY USAGE:
Maximum memory available
8
SET INTERFACE COMPATIBILITY MODE:
Centronics compatibility
8a
SET PRINTER COMPATIBILITY MODE:
Tektronix Phaser IIDX (4694)
8b
SET HOST ABORT MEANING:
Print partial pictures
9
SPECIFY HOST PIXEL ASPECT RATIO:
PIXELS ARE 32 HIGH BY
32 WIDE
10
SELECT PAPER:
(Project specific.)
11
SELECT FRONT PANEL LANGUAGE:
(Project specific.)
12 - 16
9/98
Menu Item
Various
(No user action required.)
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The required interface device driver, S-Print software, and application programs
must be installed on the Log Server. For instructions on loading the device driver,
see the applicable vendor documentation and “WEStation Software Load Kit” (U08001-x.x). For information on installing the S-Print software, see “Log Server
WEStation User’s Guide” (U0-8400).
Certain of the device configuration settings must be defined in the drop’s
$WDPF_HOME/ls/config/defaults file. See “Log Server WEStation User’s
Guide” (U0-8400) for more information.
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The Tektronix 220i Color Thermal Printers (Screen Copy Printer) is used with
a parallel interface board installed on the Sbus of the Sun 4600MP card (see
Figure 3-10). The screen copy printer is connected directly to the Sbus parallel
interface board.
In addition to parallel port connection on the Sun 4600 MP card, the Tektronix 220i
printer can be connected directly to the Ethernet network. If the Ethernet network
option is used, a special network card is required and included with the printer kit.
Table 3-12 details the required hardware settings that are made using the rear panel
DIP switches on the printer.
Table 3-12. Settings for Tektronix 220i Printer
Switch
Setting
Selection
1
Down
Reset/Run. The printer performs a self-test,
then proceeds to run normally. Leave switch
down for normal operation.
2
Down
3
Down
Configuration Page/Sample Prints. These are
the default settings for normal operation.
4
Down
5
Down
Start Job. The Sys/Start job runs.
6
Unused
Unused
7
Down
Baud Rate. Variable. Lets the user change the
serial communication parameters. The factory
setting is 9600 baud, software flagging, and
ignore parity.
8
Down
9
Down
Color Correction. No color correction (factory
default).
See the applicable user documentation for additional details.
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The required interface device driver, and application programs must be installed on the
Log Server. For instructions on loading the device driver, see the applicable vendor
documentation and “WEStation Software Load Kit” (U0-8001-x.x). For information
on installing the S-Print software, see “Log Server WEStation User’s Guide”
(U0-8400).
Certain of the device configuration settings must be defined in the drop’s
($WDPF_HOME/ls/config/defaults) file. See “Log Server WEStation User’s
Guide” (U0-8400) for more information.
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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3-4. Peripheral Devices
The Hewlett Packard 1200 C/PS Color Ink Jet Printer (Screen Copy Printer)
is used with a parallel interface board installed on the Sbus of the Sun 4600MP card
(see Figure 3-10). The screen copy printer is connected directly to the Sbus parallel
interface board.
In addition to parallel port connection on the Sun 4600 MP card, the Hewlett
Packard 1200 C/PS printer can be connected directly to the Ethernet network. If the
network option is used, a special network card, JetDirect, is required. For
information on installing the network card and software, see the Hewlett Packard
installation notes that are provided with the order.
Table 3-13 details the required hardware settings that are made using the rear panel
on the printer.
Table 3-13. Settings for Hewlett Packard 1200 C/PS Printer
Switch
Setting
Selection
1
Up
PostScript
2
Up
PostScript
3
Down
Context On
4
Down
Fast Cent
5
Down
Roman8
6
User-defined
10 cpi or 12 cpi
7
User-defined
Letter or A4
8
Not used
Not used
See the applicable user documentation for additional details.
The required interface device driver and application programs must be installed on the
Log Server. For instructions on loading the device driver, see the applicable vendor
documentation and “WEStation Software Load Kit” (U0-8001-x.x). For information
on installing the S-Print software, see “Log Server WEStation User’s Guide”
(U0-8400).
Certain of the device configuration settings must be defined in the drop’s
$WDPF_HOME/ls/config/defaults file. See “Log Server WEStation User’s
Guide” (U0-8400) for more information.
For printing operations that use the UNIX spooling system, the Solaris
Administration Tool application or the lpadmin command must be used. See
Section 3-4.4 for information on Administration Tool.
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3-4.4. Administration Tool to Set Up Printers
The Solaris 2.3 Administration Tool program allows users to configure printers to
print using the UNIX spooling system. The UNIX spooling system is not used when
the printer is configured for alarm printing (configured with $WDPF_HOME/mmi
/config/alarm_config.dat) or Log Server Printer Manager printing when using the
custom (not generic) handler (configured with $WDPF_HOME/ls/config
/defaults). For all other applications, the Administration Tool program must be used
to configure the printers.
To use the Administration Tool, follow the steps below:
Note
The steps below discuss configuring printers to work
with WDPF software. For general information on
using the Administration Tool program for printer
programming, see “Solaris 2.3 Setting Up User
Accounts, Printers, and Mail”.
1. From a command tool prompt, become superuser by typing su and the
applicable password (see the System Administrator for information on
becoming superuser).
2. Type the following command and press the Return key on the keyboard:
admintool&
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The Administration Tool window displays (see Figure 3-11).
Figure 3-11. Administration Tool Window
3. Select the Printer Manager icon on the Administration Tool window.
The Printer Manager window displays (see Figure 3-12).
Figure 3-12. Printer Manager Window
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4. Pull down the Edit menu on the Printer Manager window and highlight Add
Printer. Slide the cursor to the right to display another menu. From this menu,
select Add Local Printer.
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The Add Local Printer menu item accesses the Printer Manager: Local
Printer window (see Figure 3-13).
Figure 3-13. Printer Manager: Local Printer Window
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Table 3-14 shows the recommended settings for each supported printer.
Table 3-14. UNIX Printer Manager Window Settings (for Local Printer)
Hewlett Packard Laserjet Series III
Hewlett Packard Laserjet 4M/4M+
Tektronix 220i Color Printer
Hewlett Packard 1200 C/PS Color Printer
(Any Post Script Printer)
Genicom 1220
Genicom 4440XT
Genicom 1040
EPSON LQ-2550
Option
Setting
Option
Setting
Printer Name
User-defined
Printer Name
User-defined
Printer Server
User-defined
Printer Server
User-defined
Comment
User-defined
Comment
User-defined
Printer Port
ttya, ttyb, or ttyc0 ttyc0f
Printer Port
For serial printers: ttya,
ttyb, or ttyc0 - ttyc0f
For printers using the
Sun parallel port
interface card: use
/dev/bpp0
For printers using the
Aurora 10SJ parallel
port Sbus card, use
/dev/pp0
Printer Type
Epson 2500
Printer Type
Postscript
File Contents
ASCII
File Contents
Postscript
Fault Notification
Write to superuser
Fault Notification
Write to superuser
System Default
No
System Default
No
Printer Banner
Not required
Printer Banner
Not required
Register w/NIS
User-defined
Register w/NIS
User-defined
User Access List
User-defined
User Access List
User-defined
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After configuring the UNIX Printer Manager window, the user must set the printer
communication parameters. (The following procedures only apply to printers that
connect to a serial port — they are not used with parallel port printers.)
Perform the following procedure to set the communication parameters when using
either a dot matrix printer or laser printer.
1. From a command tool prompt, become superuser by typing su and the
applicable password (see the System Administrator for information on
becoming superuser).
2. Enter the following command to set up the communication parameters for the
printer (for this example, the printer name is lp1):
lpadmin -plp1 -o “stty=‘9600 -cstopb cs8 -parenb -ixon crtscts’”
The following procedure is used to specify the page length of 8.5 inches (6 lines per
inch for a total of 8.5 inches) when using a dot matrix printer.
1. From a command tool prompt, become superuser by typing su and the
applicable password (see the System Administrator for information on
becoming superuser).
2. Enter the following command to specify the page length for the printer (for this
example, the printer name is lp1):
lpadmin -plp1 -o length=51
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3-4.5. Storage Devices
In addition to the hard disk drive(s) which are incorporated into every base
workstation configuration, the following storage devices are available:
• 1/4 in. magnetic tape drive
• 8 mm magnetic tape drive
• 3.5 in. floppy disk drive
• CD-ROM drive
• Optical disk drive
Connections to a SCSI Bus
All of the storage devices can be connected to a SCSI bus. Certain configurations
provide two SCSI busses. All other configurations include one SCSI bus. The
additional SCSI bus provides improved throughput for the multiple hard disk
configuration. The second SCSI bus is not required for the additional storage
devices listed above.
The VME WEStation cube provides a 50-pin female D connector for SCSI
expansion, located at either the front or rear of the disk tray assembly. Multiple
SCSI devices can be connected to a SCSI bus in a daisy chained manner. Observe
the following rules:
Warning
Violating these rules can result in data
corruption.
1. The maximum number of allowable SCSI devices on a single bus is 8.
2. The maximum SCSI bus length including both internal and external cabling
must not exceed 6 m (19.6 ft.).
3. Only the end device on the bus must be terminated.
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3-4. Peripheral Devices
For all WEStations with single SCSI bus, the following measurements for the SCSI
bus apply:
• Internal Sun 4600 MP card = 304 mm (12 in.).
• Sun 4600 MP card to disk tray assembly (front) SCSI_IN cable = 279 mm
(11 in.).
• Disk tray assembly (front) SCSI_IN to disk tray assembly (front) SCSI_OUT
internal cable = 1676 mm (66 in.).
For the WEStation with two separate SCSI buses (SCSI0 and SCSI1), only SCSI1
allows for expansion (SCSI0 does not allow for expansion). Expansion to the SCSI1
bus is made at the D connector at the rear of the disk tray assembly. Measurements
for SCSI1 are listed below:
• Internal Sun 4600 MP card = 304 mm (12 in.).
• Sun 4600 MP card to disk tray assembly (front SCSI1_IN cable = 304 mm (12 in.).
• Disk tray assembly (front SCSI1_IN to disk tray assembly (rear) SCSI1_OUT
internal cable = 1219 mm (48 in.).
Figure 3-14 illustrates the SCSI device connections for the WEStation with one
SCSI bus. Figure 3-15 and Figure 3-16 show the SCSI device connections for
WEStations with two SCSI busses.
Caution
For correct operation of any SCSI device, the
SCSI address must be set correctly on the device
hardware and in the corresponding
configuration/driver software.
Table 3-15 lists the recommended SCSI target IDs for each of the available SCSI
devices. Table 3-16 lists the recommended SCSI target IDs for WEStations with
two SCSIs. For additional information on setting the SCSI address on the
peripherals, see the applicable vendor documentation and “WEStation Software
Load Kit” (U0-8001-x.x). For information on the WDPF drop configuration files,
see “Engineering WEStation User’s Guide” (U0-8200) or the applicable drop
documentation.
Note
Some SCSI devices require additional vendor
software for correct operation, as discussed in
the following pages.
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SBUS-0
DIAGNOSTIC LEDs
NORMAL
DIAGNOSTIC
SCAN
SCSI OUT Port
on Disk Assembly
(DB50 female
connector).
Remove
terminator to
connect SCSI
devices.
SERIAL A
SBUS-1
SERIAL B
Terminator
SBUS-2
KEYBOARD
AUDIO
SCSI IN Port
on Disk Assembly
(DB50 female
connector).
ETHERNET
SBUS-3
SCSI
Note: Cable provided with base workstation.
Figure 3-14. SCSI Device Connection — Single SCSI Bus
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SBUS-0
DIAGNOSTIC LEDs
NORMAL
DIAGNOSTIC
SCAN
SERIAL A
SBUS-1
SCSI IN 1
(DB50 female
connector)
1
SERIAL B
0
SBUS-2
(Mini D50
female connector)
SBUS-2
KEYBOARD
SCSI IN 0
(DB50 female
connector)
AUDIO
ETHERNET
SBUS-3
SCSI
SCSI (Mother Board)
(Mini D50
female connector)
Figure 3-15. SCSI Device Connection — Two Separate SCSI Busses
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DISK-J1
SCSI OUT 0
(VME Backplane)
3-4. Peripheral Devices
SCSI OUT 0
(DB50 female
connector)
(Disk Tray
Power Connector)
(Disk Tray)
Figure 3-16. SCSI Device Connection — Two SCSI Busses (Cube) (Rear View)
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Table 3-15. Recommended SCSI Addressing
Device
Sony WDC 610
Optical disk
controller
SCSI Target ID
1
SCSI Device1
Name(s)
See optical disk
drive for SCSI
device name
Hardware Settings
Use the following switch settings on
the controller unit:
Switch
Setting
6
7
8
OFF
OFF
ON
(Switches 1 through 5 are OFF.)
Sony WDD 600
Optical disk
drive(s)
See optical disk
controller for
SCSI target ID
so0
Use the following switch settings on
the drive unit for 1 drive:
Switch
Setting
6
7
8
OFF
OFF
OFF
(Switches 1 through are OFF.)
-OR-
so1 (for a second Use the following switch settings on
optical disk
the disk units for 2 drives:
drive)
Switch
Setting
6
7
8
OFF
OFF
ON
(Switches 1 through 5 are OFF.)
Artecon
1
Tahiti 2M (1GB)
Optical Disk
Drive
eod0
Use the following switch settings on
the enclosure:
Switch
Setting
1
ON
(Switches 2 through 8 are OFF.)
Note 1:
The SCSI Device Name(s) column represents the default settings in the kernel as provided by
Westinghouse (see System & Network Administration for more information on the kernel). If the
user suspects that these defaults are not being used, see the System Administrator.
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Table 3-15. Recommended SCSI Addressing (Cont’d)
Device
SCSI Target ID
Artecon
1
Tahiti 3 (1.3 GB)
Optical Disk
Drive
SCSI Device1
Name(s)
eod0
Hardware Settings
Use the following switch settings on
the enclosure:
Switch 1
Setting
1
8
ON
ON
(Switches 3 through 7 are OFF.)
Switch 2
Setting
1
ON
(Switches 2 through 7 are OFF.)
Hewlett Packard 1
1300T (1.3 GB)
Optical Disk
Drive
Sq1
Press the applicable pushbutton on rear
of enclosure until numeral ‘1’ is
displayed. Also, press the pushbutton
on the rear panel labeled “MO
MODE/Direct Access” until the
numeral ‘1’ is displayed.
Artecon 3.5 in.
floppy disk
2
afd0
Press the applicable pushbutton on the
enclosure front panel until the
numeral 5 is displayed. (Even though
the SCSI Target ID setting for this
device is 2, the hardware setting should
be set to 5. This should not be confused
with the 8 mm SCSI Target ID setting of
5 listed below.)
Internal hard
disk
(First disk)
3
sd0
Set at factory.
Internal hard
disk
(Second disk)
2
sd2
Set at factory.
Note 1:
The SCSI Device Name(s) column represents the default settings in the kernel as provided by
Westinghouse (see System & Network Administration for more information on the kernel). If the
user suspects that these defaults are not being used, see the System Administrator.
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Table 3-15. Recommended SCSI Addressing (Cont’d)
SCSI Target ID
SCSI Device1
Name(s)
4
st0
Press the applicable pushbutton on the
enclosure front panel until the
numeral 4 is displayed.
Artecon Exabyte 5
8200
8 mm magnetic
tape (2GB)
st1
For the single device enclosure, use the
following switch settings on the rear of
enclosure:
Device
Artecon 1/4 in.
magnetic tape
Hardware Settings
Switch
Setting
1
2
3
ON
OFF
ON
(Switches 4 through 8 are OFF.)
Sun 8 mm
magnetic tape
(5GB)
5
st1
Press the applicable pushbutton on the
enclosure rear panel until the numeral 5
is displayed.
Internal 8 mm
mag tape
5
st1
Set at factory
Sun-CD and
Sun-CD 2 Plus
6
sr0
Press the applicable pushbutton on the
enclosure rear panel until the numeral 6
is displayed.
ttyc00-ttyc07
SCSI ID jumpers should be set as
follows:
-OR-
Jumpers
Setting (for default)
ttyc00-ttyc0f
W3
W2
W1
Remove
Remove
Remove
SCSI serial port 0
expansion option
Note 1:
The SCSI Device Name(s) column represents the default settings in the kernel as provided by
Westinghouse (see System & Network Administration for more information on the kernel). If the
user suspects that these defaults are not being used, see the System Administrator.
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3-4. Peripheral Devices
For the additional SCSI, the addressing is shown in Table 3-16. Notice that the
addresses remain the same except for the hard disk. The SCSI Target ID settings for
the hard disks are shown below:
Table 3-16. Recommended SCSI Addressing for WEStations with Additional SCSI
Device
SCSI Target ID
SCSI Device
Name(s)
Hard disk SCSI0
3
sd0
Set at factory.
Hard disk SCSI1
3
sd4
Set at factory.
Hardware Settings
Hardware Configuration for Storage Devices
The 1/4 in. magnetic tape drive, 8 mm magnetic tape drive, optical disk, and 3.5 in.
floppy disk drive can be packaged in an enclosure for desktop use. In addition, the
8 mm magnetic tape drive may be provided as part of the disk assembly. The
CD-ROM drive is enclosed in a separate desktop device. All of these devices are
then connected directly to the SCSI connector on the workstation enclosure disk
assembly.
Note
A CD-ROM player is required to load the
Solaris operating system.
Software Configuration for 3.5" Floppy Disk
The required device driver and application programs must be loaded in the
workstation enclosure for correct operation of the floppy disk drive. For instructions
on loading the device driver, see the applicable vendor documentation and
“WEStation Software Load Kit” (U0-8001-x.x).
Software Configuration for Optical Disk
The required device driver and application programs must be loaded in the
workstation enclosure for correct operation of the optical disk drive. For
instructions on loading the device driver, see the applicable vendor documentation
and “WEStation Software Load Kit” (U0-8001-x.x).
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3-4. Peripheral Devices
3-4.6. PROM Programmer
A PROM Programmer is used for programming or ‘burning’ WDPF programs into
programmable memory (PROM) devices. PROMs are used in the Multibus-based
drops (Distributed Processing Unit (DPU) and the Clock Interface Unit (CIU)).
Depending on the user’s system configuration and available hardware, the
instructions for programming PROMs may vary. See “Custom and Non-Standard
Text Algorithm User’s Guide” (U0-0132) for information on burning PROMs.
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3-5. WEStation Drop Configurations
3-5. WEStation Drop Configurations
Table 3-17 through Table 3-27 describes the hardware configuration for each
WEStation drop function, including minimum required hardware and options.
If a WEStation drop is to perform multiple functions, the most restrictive minimum
requirements must be met.
For example, the Engineering WEStation requires the following:
• 1 GB (minimum) base workstation configuration (with applicable cards and
devices as defined by the user),
• Color monitor
• Keyboard
• Mouse or Trackball.
A variety of peripherals are optional (see Table 3-17 through Table 3-27). The
Software Server function requires a 1 GB (minimum) base workstation
configuration with an 8 mm tape drive, 1/4” magnetic tape drive, and CD-ROM
player. If these two functions are combined in a single WEStation drop, all of the
required items of both drops must be used and all of the optional peripheral devices
are applicable.
Note
The WEStation Data Link Server functions
can co-exist with any of the other WEStation
configurations. Refer to the “Data Link
Server Manager User’s Guide” (U0-8700) for
more information.
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3-5. WEStation Drop Configurations
Table 3-17. Engineering WEStation Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
1 GB (minimum) base
workstation configuration
with applicable cards and
devices as defined by the user.
•
Color monitor
•
•
Keyboard
Color monitor requires workstation enclosure configured
with TGX card.
Mouse or Trackball
Optional:
•
Any of the following serial
devices:
— Membrane Keyboard
— Alarm Panel
— Touchpad
— Line Printer
— Dot matrix printer
— Laser printer
•
•
3 1/2 in. floppy disk drive
•
•
Optical disk drive
9/98
SCSI serial port expansion
If more than two serial devices are required, the workstation
enclosure must be configured with the SCSI serial port
expansion option.
Second color monitor (with or Second color monitor requires workstation enclosure
without touchscreen)
configured with second TGX card. Monitor with
touchscreen requires serial port.
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3-5. WEStation Drop Configurations
Table 3-18. WEStation Software Server Configurations
Hardware
Comments/Prerequisites
Required:
•
1 GB (minimum) base
8 mm tape drive may be included in the base workstation
workstation configuration
disk assembly, or may be a desktop device.
with applicable cards and
devices as defined by the user.
•
1/4 in. magnetic tape drive
(portable)
•
CD-ROM (portable)
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3-5. WEStation Drop Configurations
Table 3-19. Combined Engineering WEStation/Software Server Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
1 GB (minimum) base
8 mm tape drive may be included in the base workstation
workstation configuration
disk assembly, or may be a desktop device.
with applicable cards and
devices as defined by the user.
•
1/4 in. magnetic tape drive
(portable)
•
•
CD-ROM (portable)
•
•
Keyboard
Color monitor
Color monitor requires workstation enclosure configured
with TGX card.
Mouse or Trackball
Optional:
•
•
•
3 1/2 in. floppy disk drive
•
Any of the following serial
devices:
Optical disk drive
SCSI serial port expansion
If more than two serial devices are required, the workstation
must be configured with the SCSI serial port expansion
option.
— Membrane Keyboard
— Alarm Panel
— Touchpad
— Line printer
— Dot matrix printer
— Laser printer
•
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Second color monitor (with or Second color monitor requires workstation enclosure
without touchscreen)
configured with second TGX card. Monitor with
touchscreen requires serial port.
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3-5. WEStation Drop Configurations
Table 3-20. Operator WEStation Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
1 GB (minimum) base
workstation configuration
with applicable cards and
devices as defined by the user.
•
Color monitor
•
Mouse or Trackball
Color monitor requires workstation enclosure configured
with TGX card.
Optional:
•
•
•
•
•
Touchpad
SCSI serial port expansion
If more than two serial devices are required, the workstation
enclosure must be configured with the SCSI serial port
expansion option.
•
•
Color dot matrix printer
Color printer is required for alarm printing function.
Keyboard
Membrane Keyboard
Alarm Panel
Second color monitor (with or Second color monitor requires workstation enclosure
without touchscreen)
configured with second TGX card. Monitor with
touchscreen requires serial port.
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3-5. WEStation Drop Configurations
Table 3-21. Log Server WEStation Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
1 GB (minimum) base
workstation configuration
with applicable cards and
devices as defined by the user.
Optional:
•
SCSI serial port expansion
•
One or more of the following
printers:
— Line printer
If more than one text printer is used, the workstation
enclosure must be configured with the SCSI serial port
option.
Line printer used for Printer Manager functions.
— Dot matrix (black ribbon) Black ribbon printer used for Printer Manager functions.
printer
9/98
— Dot matrix color printer
Color printer used for Alarm printing functions.
— Laser printer
Laser printer used for Printer Manager functions.
— Screen copy printer
Color printer required for screen copy function. Requires
workstation enclosure configured with parallel port interface
card. In some cases, a printer can be connected directly on
the network without a parallel interface card.
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3-5. WEStation Drop Configurations
Table 3-22. Historian WEStation (HSR) Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
(2) 1 GB base workstation
configuration with applicable
cards and devices as defined
by the user.
Optional:
•
Color monitor
•
•
•
Keyboard
Dual SCSI bus architecture
Dual SCSI bus architecture provides improved throughput
for faster data acquisition.
•
Optical disk drive
Optical disk drive provides extended off-line
storage/retrieval capability.
Color monitor requires workstation enclosure configured
with TGX card.
Mouse or Trackball
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3-5. WEStation Drop Configurations
Table 3-23. Combined HSR/Logger Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
Base workstation
configuration with (2) 1 GB
hard disks on separate SCSIs,
and devices as defined by the
user.
•
Dual SCSI bus architecture
Dual SCSI bus architecture provides improved throughput
for faster data acquisition.
Optional:
•
•
•
•
Color monitor
•
•
Optical disk drive
Keyboard
Membrane keyboard
SCSI serial port expansion
option
Refer to Section 3-4.3 for information on the printer types
and the number of serial expansion ports when using a
hardware configuration with/without a CRT monitor.
One or more of the following
printers:
— Line printer
Line printer used for Printer Manager functions.
— Dot matrix (black ribbon) Black ribbon printer used for Printer Manager functions.
printer
9/98
— Dot matrix color printer
Color printer used for Alarm printing functions.
— Laser printer
Laser printer used for Printer Manager functions.
— Screen copy printer
Color printer required for screen copy function. Requires
workstation enclosure configured with parallel port interface
card. In some cases, a printer can be connected directly on
the network without a parallel interface card.
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3-5. WEStation Drop Configurations
Table 3-24. Stand-alone HSR/Logger Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
Base workstation
configuration with (2) 2GB
hard disks on separate SCSIs,
and devices as defined by the
user.
•
Dual SCSI bus architecture
Dual SCSI bus architecture provides improved throughput
for faster data acquisition.
•
Color monitor
Color monitor requires workstation enclosure configured
with TGX card.
•
•
•
Keyboard
Mouse or Trackball
•
CD-ROM (portable)
1/4 in. magnetic tape drive
(portable)
Optional:
•
One or more of the following
printers:
— Line printer
Line printer used for Printer Manager functions.
— Dot matrix (black ribbon) Black ribbon is used for Printer Manager functions.
printer
— Dot matrix color printer
Color printer used for Alarm printing functions.
— Laser printer
Laser printer used for Printer Manager functions.
— Screen copy printer
Color printer required for screen copy function. Requires
workstation enclosure configured with parallel port interface
card. In some cases, a printer can be connected directly on
the network without a parallel interface card.
•
•
3 1/2 in. floppy disk drive
Optical disk drive
Optical disk drive provides extended off-line
storage/retrieval capability.
•
SCSI serial port expansion
option
If more than two serial devices are required, the workstation
must be configured with the SCSI serial port expansion
option.
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3-5. WEStation Drop Configurations
Table 3-25. Computational Server WEStation Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
1GB (minimum) base
workstation configuration
with applicable cards and
devices as defined by the user.
Table 3-26. Relational Database Server Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
Base workstation
configuration with (3) 1 GB
hard disks on two separate
SCSIs, and devices as defined
by the user.
Optional:
•
Color monitor
•
•
•
•
•
Keyboard
9/98
Color monitor requires workstation enclosure configured
with TGX card.
Membrane keyboard
Mouse or trackball
Laser printer
SCSI serial port expansion
If more than two serial devices are used, the workstation
enclosure must be configured with the SCSI serial port
expansion option.
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3-5. WEStation Drop Configurations
Table 3-27. WEStation Data Link Server Hardware Configurations
Hardware
Comments/Prerequisites
Required:
•
1GB (minimum) base
workstation configuration
with applicable cards and
devices as defined by the user.
Optional:
•
Secondary Ethernet
Controller (Sbus or VME)
Secondary Ethernet Controller used to connect Data Link
Server to other systems (for examples, VAX and PC)
through an Ethernet.
•
Monochrome Monitor
Monochrome monitor requires workstation enclosure
configured with a Monochrome Monitor card.
•
SCSI serial port expansion
option
If more than one serial device is used, the workstation
enclosure must be configured with the SCSI serial port
expansion option.
•
Clock Interface
Requires VME TrueTime Clock Interface Kit.
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Section 4. Desktop WEStation
Configuration
4-1. Section Overview
The Desktop WEStation (WEStationDT) combines the functionality of a full-scale
drop in compact desktop enclosures. The WEStationDT can be connected to only
SUNTM workstation with Sbus expansion capabilities.
The following topics are included in this section:
• WEStationDT overview (Section 4-2).
• Hardware requirements (Section 4-3).
• Software requirements (Section 4-4).
• Installation procedures (Section 4-5).
• Status indicators (Section 4-6).
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4-2. WEStationDT Overview
4-2. WEStationDT Overview
Each drop in the WDPF system incorporates a Data Highway Controller (DHC),
which controls the drop’s interaction with the Westnet II Data Highway. The DHC
functions include the following:
• Receiving and transmitting Data Highway messages.
• Building Data Highway messages.
• Reading and writing shared memory with Data Highway information.
• Performing diagnostic self tests and maintaining Data Highway status
information.
For most WDPF drops, the DHC and shared memory are contained on PC boards
and housed in the main chassis along with the drop’s processor and other cards.
However, for the WestationDT, the Data Highway Controller and shared memory
are contained on the GHC (Generic Highway Controller) board inside the
WEStationDT enclosure. An interface cable connects the WEStationDT enclosure
with an SGI (Sbus to Gbus Interface) card which is located on the Sbus of the host
workstation. The host workstation accesses shared memory through this Sbus to
Gbus (Generic bus) shared memory interface.
Figure 4-1 depicts a typical WEStationDT.
..
WEStation DT
SUN
SPARCstation 20
Figure 4-1. Typical WEStationDT (Front View)
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4-3. Hardware Requirements
4-3. Hardware Requirements
To use a SUN workstation as a desktop WEStation drop, the following
Westinghouse hardware is required:
• WEStationDT enclosure (Section 4-3.1).
• SGI (Sbus to Gbus Interface) PC board (Section 4-3.2).
• Gbus Interface cable (Section 4-3.3).
• Data Highway Adapter Cables and Transition Panel (Section 4-3.4).
In addition to the hardware listed above, each type of drop requires a minimum
amount of memory and hard disk storage requirements for proper operation of the
WEStation software and WDPF files. Additional storage and retrieval devices (for
examples, optical disks, CD-ROM and so forth) also may be required based upon
the WEStation drop function. See Section 3 for a list of these requirements for
specific types of drops.
4-3.1. WEStationDT Enclosure
The following user control indicators and connectors are illustrated in Figure 4-2.
• Power OK Indicator LED
• AC Power Switch and IEC 320 AC Input Connector
• Gbus Connector
• Status LEDs and Hexidecimal Displays
• Data Highway Coaxial Connectors
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4-3. Hardware Requirements
Power OK
LED
WEStation DT
FRONT VIEW
406
(16)
406
(16)
ON/OFF
Switch
Gbus Interface
Connector
RAID
ENA
CH1
CH0
DIAG
GBUS
STATUS
HI LO
CH0
PAR RLY
P5
CH1
RLY
92
(3.63)
P6
AC IN
REAR VIEW
Data Highway
Coaxial Connectors
All dimensions in millimeters (inches).
Figure 4-2. WEStationDT Enclosure (Front and Rear view)
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4-3. Hardware Requirements
4-3.2. SGI (Sbus to Gbus Interface) PC board
The Westinghouse SGI PC board provides the communications interface between
the WEStationDT enclosure and the Sbus of the Sun workstation. The Sbus SGI
card is placed in any available Sbus slot of the workstation. The SGI supports 25 or
28 bit Sbus addressing on workstations with Sbus clock rates of 16.667 to 25 Mhz.
The SGI contains no external status indicators and no user configurable jumpers.
Figure 4-3 depicts the SGI card.
Figure 4-3. SGI (Sbus to Gbus Interface) PC board
For SGI installation information, see Section 4-5.1.
4-3.3. Gbus Interface Cable
Westinghouse supplies an 80-pin interconnect cable to connect the WEStationDT
enclosure to the SGI card inside the workstation. Two lengths are available — 2 ft.
or 10 ft. For additional installation instructions, see Section 4-5.
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4-3. Hardware Requirements
4-3.4. Data Highway Adapter Cables and Transition Panel
The GHC card in the WEStationDT enclosure contains two BNC style connectors
for the redundant Westnet II Data Highway connections. The WEStationDT kit
provides ‘T’ adapters and transition adapter cables to connect these two connectors
to the Westnet II Data Highway. A transition cable (see Figure 4-8) is used to
convert the thin RG-59/U cable of the WEStationDT to the larger RG11 cable of the
main Westnet II Data Highway through a transition connector panel.
Note
RG-59/U cable is only suitable for short distances
(such as internal cabinet circuitry). For longer
distances, RG11, semi-rigid coaxial cable, is
required. For more information on Data Highway
cable types, see “WDPF System Planning and
Highway Installation Manual” (M0-8000).
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4-4. Software Requirements
4-4. Software Requirements
Each WDPF drop is loaded with software configured for a project. The number and
type of drops on a project determines the application software that is required. Since
all of the functionality available in a full-size drop is available in the WEStationDT,
the software configuration is dependent on the drop type, not the drop hardware.
Only the $WDPF_HOME/shc/config/CONFIG.SHC file must be set specifically
to work with the WEStationDT. The parameter, Westnet.Network_x.Dipswitch,
must be commented out with the “!” character and replaced with the parameter
Westnet.Network_x.Sbus. The Westnet.Network_x.Sbus parameter defines
which Sbus slot on the workstation is used to hold the SGI card. Valid values for
this parameter are 0 through x (where x can be 3 or 4 depending on the type of Sun
workstation being used).
See “WDPF System Planning and Highway Installation Manual” (M0-8000) for
more information on the CONFIG.SHC file. See “WEStation Software Load Kit”
(U0-8001-x.x) for information on loading the applicable operating system and
WDPF application software on a drop.
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4-5. Installation Procedures
4-5. Installation Procedures
The following sections describe installation procedures for the WEStationDT.
• SGI PC Board installation (Section 4-5.1).
• WEStationDT Enclosure installation (Section 4-5.2).
• Data Highway cabling (Section 4-5.3).
4-5.1. SGI Installation
Use the following procedures to install the SGI (Sbus to Gbus Interface board) into
the Sbus workstation.
1. Verify that the workstation is powered off and unplugged.
2. Install the SGI PC board according to the instructions in the Sun “Hardware
Owner’s Guide”. Depending upon the type of Sbus workstation being used, the
installation may vary slightly.
Note
Depending on the model of the Sun workstation, the
top portion (adapter bracket) of the SGI backplate
containing the mounting tab hooks may need to be
removed before installation (see Figure 4-4).
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4-5. Installation Procedures
Adapter Bracket
(Remove)
Tab
Backplate
Screws
Backplate
Figure 4-4. Removal of SGI backplate mounting tab hooks
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4-5. Installation Procedures
4-5.2. WEStation Enclosure Installation
After installing the SGI PC board, use the following procedures to connect the
WEStationDT enclosure to the workstation.
1. Determine an appropriate location for the enclosure.
For “Pizza-Box” sized (16 inch wide by 16 inch depth) workstations, the
WEStationDT unit will fit under or on top of the workstation without requiring
additional desk space. Clearance of at least 2 inches on each side of the unit
must be maintained for proper air circulation. Also, be sure to allow clearance
in back of the unit to provide enough space for exiting cables.
For applications which require the WEStationDT enclosure to be located
remotely from the workstation, the maximum cable length that can be used for
the Gbus communication connections is 10 feet.
2. Typically, the GHC PC boards inside the WEStation enclosure does not need to
be configured. However, the board must be reconfigured for the following
special cases:
• If the WEStationDT is being connected to a WDPF Westnet II Data
Highway which contains fiber optic repeaters.
• If the WEStationDT is being connected to a non-redundant single Westnet
II Data Highway and the user does not want single highway operation to be
reported as an error.
To access the GHC PC board, loosen the captive screws located on the top rear of
the WEStationDT and slide the GHC/SGI Power Supply assembly out the rear of
the WEStationDT enclosure. See Figure 4-5 for a view of GHC removal from the
WEStationDT. See Figure 4-6 for GHC jumper module locations.
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4-5. Installation Procedures
RAID
ENA
CH1
CH0
DIAG
GBUS
STATUS
HI LO
PAR
CH0
RLY
P5
CH1
RLY
P6
AC IN
Figure 4-5. GHC Removal from WEStationDT Enclosure
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JS10
SW1
0123
ON
OFF
4-5. Installation Procedures
JS8
DIS
CLK
ENA
JS3
DIS
JS4
JS6
JS5
CLK
DIS
JS1
JS2
Figure 4-6. GHC Card Jumper Locations (for WEStationDT)
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4-5. Installation Procedures
Jumper modules JS5 and JS6 are used to configure both Channel 0 (CH0) and
Channel 1 (CH1) Data Highway Timekeeper Time-out periods. Use the following
chart to set the jumpers accordingly. Default positions for these modules is JS5 and
JS6 installed. Table 4-1 shows the various jumper settings for JS5 and JS6.
Table 4-1. GHC Card J5/J6 Jumper Settings
Jumper
Setting
JS5 - Installed
JS6 - Installed
JS5 - Out
JS6 - Out
JS5 - Installed
JS6 - Out
JS5 - Out
JS6 - Installed
Mode
Standard Time-out Extended Timeout
Option C
Extended Timeout
Option A
Extended Timeout
Option B
Normal
Timekeeper A
Timekeeper B
Timekeeper C
Analysis
112 - 116 us
243 us
441 us
640 us
96 us
496 - 500 us
1215 us
2205 us
3200 us 96 us
976 - 980 us
243- us
4410 us
6400 us
96 us
256 - 260 us
608 us
1103 us
1600 us
96 us
Jumper module JS4 controls the operation of channel 1 (CH1) communications. For
single channel operation, Jumper module JS4 must be located in the ‘DIS’ (2-3)
position. For Dual channel operation, jumper module JS4 ‘CH1’ must be located in
‘ENA’ (1-2) position (this is the default position).
All other jumper control modules should be left in their default position as follows:
JS1
32MHz
‘CLK’ position 2-3
JS8
40MHz
‘CLK’ position 1-2
JS10
256KHz
‘CLK’ position 1-2
JS2
CAL0
Not installed
JS3
CAL1
Not installed
JS7
Not Used
Not installed
SW1
DHC CONF
Switch setting (1H):
0 - OFF
1 - ON
2 - ON
3 - ON
3. Re-install the GHC board in the WEStation enclosure after setting the board
configurations.
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4-5. Installation Procedures
4. Connect the Gbus interface cable between the SGI and WEStationDT
connectors (see Figure 4-7). Press the latches in (on the sides of the connector
housing) while making the connection. Cable lock will engage when the cable
is properly installed.
RAID
ENA
CH1
CH0
DIAG
GBUS
STATUS
HI LO
PAR
CH0
RLY
P5
CH1
RLY
P6
AC IN
To
Keyboard
GBus Interface
Cable
To
Voltage Source
Figure 4-7. SGI and WEStationDT Cable Connection (Rear View)
5. Connect the Westinghouse supplied AC input cord to the AC-IN connector
input of the WEStationDT enclosure.
6. Before applying power, install the DHC Data Highway cables as described in
Section 4-5.3.
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4-5. Installation Procedures
4-5.3. Data Highway Cable Installation
The WEStationDT kit includes the following standard components for Data
Highway installation.
• (2) BNC T connectors.
• (4) BNC to N adapter cables.
The components are illustrated in Figure 4-8.
N
BNC
Figure 4-8. Data Highway Cable Adapters
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Westinghouse Proprietary Class 2C
M0-8005
4-5. Installation Procedures
The user must determine and obtain the required amount of Westinghouse Data
Highway cable to link the WEStationDT to the balance of the Data Highway. A
Westinghouse cable transition panel is recommended for mounting adapter cable
‘N’ connectors and properly grounding the Data Highway. If the Data Highway
physically ends at this drop, the required standard 75 ohm terminators
(Westinghouse 404A835) must also be ordered.
1. Connect the ‘T’ adapters to the BNC connectors of the WEStationDT
enclosures.
2. Connect a BNC to N adapter cable (BNC end) to the end of each ‘T’ adapter.
The ‘N’ style connector end of the cable is to be connected to the WDPF Data
Highway. See “WDPF System Planning and Highway Installation Manual”
(M0-8000) for information on proper connection. It is recommended that cable
markers be used to label each end of the transition cables to avoid confusion
whenever the cables are removed.
WARNING
The WEStationDT installation must meet all the
WDPF Westnet II Data Highway requirements for
drop and Data Highway installation. In addition, all
system and Data Highway grounding rules must be
observed. Failure to observe the WDPF installation
requirements or Data Highway grounding rules can
result in communication failures.
3. Once the cables are connected to the WEStationDT, the AC input switches of the
workstation and WEStationDT can be turned ‘on’ to apply power. The
WEStationDT Power OK indicator on the front of the enclosure should light.
Disconnecting Data Highway Cables
If the Data Highway cables are to be disconnected for any reason, be certain to
disconnect the ‘T’ adapter from the WEStationDT connector. This approach will
preserve the continuity of the Data Highway for other drops communicating on the
highway. Do not remove the BNC-to-N adapter or WEStationDT cable from the
T-adapter (see Figure 4-9).
Caution
If the continuity of the Data Highway is
broken, communications between other
drops will be disrupted.
M0-8005
4-16
Westinghouse Proprietary Class 2C
9/98
4-5. Installation Procedures
Figure 4-9. Disconnecting Data Highway Cables
9/98
4-17
Westinghouse Proprietary Class 2C
M0-8005
4-6. Status Indicators
4-6. Status Indicators
The rear of the WEStationDT enclosure contains status indicators (see Figure 4-10).
RAID
ENA
CH1
CH0
DIAG
GBUS
STATUS
HI LO
PAR
CH0
RLY
P5
CH1
RLY
P6
AC IN
REAR VIEW
Figure 4-10. Status Indicators — Rear View of WEStationDT
Power Up and Normal Operation Status
When power is first applied to the WEStationDT enclosure and the Sbus
workstation is powered up, the hexadecimal display of the unit will read ‘7F’. This
indicates that the GHC PC board is waiting for the Sbus processor to enable the
GHC’s access to the shared memory. During software initialization, the (RED)
DIAG LED will blink several times before the highway controller is enabled onto
the Data Highways.
M0-8005
4-18
Westinghouse Proprietary Class 2C
9/98
4-6. Status Indicators
When the WEStationDT is connected to both highways during normal operation
and activity is detected on both channels, the indicators will be illuminated as
follows:
LED
Color
Status
Description
ENA
Red
Blinking
Indicates highway controller is on-line and
active.
CH1
Yellow
Lit
Indicates activity detected on highway 1.
CH0
Green
Lit
Indicates activity detected on highway 0.
DIAG
Red
Off
This LED is lit only when in Off-line
Diagnostic mode.
PAR
Red
Off
This LED indicates a shared memory parity
error. It should never be on.
CH0
RLY
Green
Lit
Indicates WEStationDT is connected to
highway 0.
CH1
RLY
Yellow
Lit
Indicates WEStationDT is connected to
highway 1.
The hexadecimal displays of the GHC will remain off in the normal operating state.
Should an error be detected, the display will light for a few seconds with an error
code. The meaning of these error codes is identical to those posted on the SHC PC
board as described in “WDPF System Planning and Highway Installation Manual”
(M0-8000).
Note
When the WEStationDT is in a reset state (such as
during a workstation boot up or if the workstation
power is off), the hexadecimal display may be lit with
a code. This code is random and should be ignored.
9/98
4-19
Westinghouse Proprietary Class 2C
M0-8005
Section 5. Distributed Processing Unit
(DPU)
5-1. Section Overview
In addition to the WEStation drops, a WDPF system can include Multibus-based
drops (DPU and CIU). The Multibus-based CIU is described in “Computime Clock
Interface Unit User's Guide” (U0-2110). The WEStation-based CIU is described in
“TrueTime Clock Interface Unit User’s Guide” (U0-2111). This section provides
information on the available DPU configurations.
The following topics are included in this section:
• 386 DPU Configurations (Section 5-2).
• 486 DPU Configurations (Section 5-3).
• Field Mounted Controller (FMC 1000) (Section 5-4).
9/98
5-1
Westinghouse Proprietary Class 2C
M0-8005
5-1.1. DPU Cabinets
A DPU cabinet is named in accordance with the type of hardware that is contained
in the cabinet. Cabinets that contain electronic hardware are called “A” cabinets,
and the associated termination cabinet is called a “B” cabinet.
If a cabinet is used as an expansion cabinet, an “x” is added to the designation. For
example, an expanded “A” cabinet is called an “Ax” cabinet.
The DPU is available in various combinations of standard cabinets. These
combinations are listed below (refer to Appendix B for DPU dimensions):
• Single quad cabinet.
• Back-to-back cabinets.
• Side-by-side cabinets.
• Back-to-back/side-by-side cabinets.
• Dual side-by-side cabinets.
• Wall-mounted cabinet.
DPU field connections for Q-Line I/O can be made at a separate termination (B)
cabinet. The separate B cabinet connections are made of heavy-duty terminal strips
which can accept 10 AWG wiring (if using 10 AWG wiring, be sure to use the
proper ring terminal). The B cabinet terminals are connected to the Q-cards via
cables and standard edge connectors. For additional information, refer to “Q-Line
Installation Manual” (M0-0053).
A DPU can interface to the WDPF Remote Q-Line I/O subsystem. The Remote QLine I/O subsystem allows Q-Line I/O cards to be located outside the confines of an
“A” cabinet or an “Ax” expansion cabinet. A redundant serial communications link
connects remote Q-Line I/O cards to the DPU. The Remote Q-Line I/O subsystem
employs a serial, multi-node communications architecture. A “master” mode is
located within a DPU drop. “Remote” nodes contain Q-Line I/O cards. For more
information, see “Remote Q-Line Installation Manual” (M0-0054).
A DPU can also interface to remote, rack-mounted Numa-Logic 700 Series I/O
cards, via a high-speed communications link, Serial Interface Modules (SIMs), and
Input/Output Processor (IOP) cards. The IOP card provides the interface between
the communications link and the DPU. The SIM, located in a Numa-Logic 700
Series I/O rack, provides the interface between the I/O cards and the
communications link. A maximum of 16 SIMs are permitted for each IOP. For more
information on these 700 Series I/O components, see “Distributed I/O Installation
Manual” (NLAM-B204).
M0-8005
5-2
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
5-2. 386 DPU Configurations
Note
The information contained in this section pertains to
two types of 386 DPUs:
• Standard 386 DPU — Uses a tray-mounted
power supply. See Section 5-2.2 for illustrations.
• Enhanced 386 DPU — Uses a plug-in power
supply. See Section 5-2.3 for illustrations.
When not specified, the information or illustration
applies to both types of DPUs.
The 386 DPU is an Intel 86 (80x86) based process controller housed in a standard
Westinghouse cabinet. Various DPU configurations may require single or multiple
cabinet combinations within a single WDPF system.
The 386 DPU consists of the following rack-mountable assemblies:
• A 483 mm (19-in.) crate containing one or two Multibus chassis (two for
redundant DPUs).
• A power supply assembly for each Multibus chassis.
• Up to three or four (depending on the type of 386 DPU) 483 mm (19-in.)
Q-crates containing Q-cards (for DPUs which use Q-Line I/O).
• One 483 mm (19-in.) assembly containing the power supplies for the Q-cards
(for DPUs which use Q-Line I/O).
• An AC Distribution Panel which provides circuit breakers for the two AC power
inputs.
A single cabinet, along with component locations, is illustrated in Figure 5-1
(Standard 386 DPU) and Figure 5-2 (Enhanced 386 DPU). Appendix B provides
dimensions, access spacing, and cable routing information for the possible
configurations.
9/98
5-3
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Nameplate
13 V
Power
Supply
Primary
13 V
Power
Supply
Secondary
Single or Dual
MultibusTM Chassis
Power Ground
MultibusTM
Power
Supply
(1st DPU)
MultibusTM
Power
Supply
(2nd DPU)
Q Crate Q1
Q Crate Q2
Q Crate Q3
AC Distribution
Center
Cabinet Ground
Front
Figure 5-1. DPU Component Locations (Standard Version 386)
M0-8005
5-4
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Nameplate
13V
POWER
SUPPLY
PRIMARY
13V
POWER
SUPPLY
SECONDARY
P
O
W
E
R
P
O
W
E
R
MULTIBUS
CHASSIS
S
U
P
P
L
Y
MULTIBUS
CHASSIS
S
U
P
P
L
Y
Q CRATE Q1
Power Ground
Q CRATE Q2
Cabinet Ground
Q CRATE Q3
Q CRATE Q4
AC DISTRIBUTION
CENTER
Front
Figure 5-2. DPU Component Locations (Enhanced Version 386)
9/98
5-5
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
5-2.1. Power, Ground, and Signal Wiring (386 DPUs)
WARNING
Hazardous voltage (115/230V) is employed
by these units.
Once the drop is installed at its permanent location, the power, ground, and Data
Highway connections to the drop can be made.
Cabinet wiring is brought into the area as shown in Appendix B. All wiring should
comply with national, state and local ordinances.
The enclosure should be grounded in accordance with the grounding procedures
given in “System Planning and Data Highway Installation Manual” (M0-0051). The
main and back-up AC power cables should be connected to the AC distribution
panel. Be sure that the correct voltage is available and that the hot, common, and
ground wires are identified before the AC service is connected.
Caution
Verify that the drop power source is
grounded in accordance with the WDPF
grounding requirements, as described in
“System Planning and Data Highway
Installation Manual” (M0-0051).
Additional power wiring instructions can be found in Section 3. Additional
information on Data Highway connections can be found in “System Planning and
Data Highway Installation Manual” (M0-0051).
For DPUs which use the distributed 700 Series I/O, connect the IOP
communications link as described in “Distributed I/O Installation Manual”
(NLAM-B204). For DPUs which use the Remote Q-Line I/O subsystem, see
“Remote Q-Line Installation Manual” (M0-0054).
Section 5-2.2 provides figures that apply to the Standard 386 DPU. Section 5-2.3
provides figures that apply to the Enhanced 386 DPU.
M0-8005
5-6
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
5-2.2. Standard 386 DPU Illustrations
Figure 5-3 through Figure 5-12 illustrate wiring, grounding, and cable connections
for the Standard 386 DPU.
13 V DC P.S. AC Input
Terminal Block Arrangements
X=
N=
G=
230
115
CMN
GND
L
N
115
230
HI = X
LO = N
GND = G
Selector
Switch
PRI 13 V P.S.
SEC 13 V P.S.
(Optional)
X NG
X NG
This arrangement has
voltage level wired-in as
either 115V or 230 V
MULTIBUS POWER SUPPLIES
These arrangements have
input voltage level set by
means of a selector switch
PRIMARY
SECONDARY
(Optional)
OPTIONAL
PRI AC SEC AC PRI AC SEC AC
Cable
supplied
at project
level
QTB
Card
Cables supplied
with Multibus
Power Supplies
To door
fans
(Cable
supplied
with door
assembly)
J1
PRI X
PRI N
PRI G
SEC X
SEC N
SEC G
If Secondary AC
not present,
jumper PRI X to
SEC X and
PRI N to SEC N.
A
A
B
B
J2
J3
PRI AC
J4
SEC AC
J5
J6
J7
J8
SWITCHED AC
TB1
Primary
Line
Primary
Neutral
Secondary
Neutral
Secondary
Line
Figure 5-3. DPU AC Power Cable Connections (Standard Version 386)
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5-7
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Data Highway
Connection Panel
E1
MultibusTM
Chassis
Power Ground
Copper bus bar
at side of cabinet.
Q Crate Q1
Q Crate Q2
Q Crate Q3
AC Distribution
E1
Cabinet Ground
Customer-Supplied
Earth Ground
Copper bus bar at
bottom of cabinet.
Figure 5-4. DPU Grounding Wiring (Standard Version 386)
M0-8005
5-8
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Primary 13 VDC
Power Supply
Secondary 13 VDC
Power Supply
Power Ground
Copper bus
bar at side
of cabinet
Q Crate Q1
Q Crate Q2
Q Crate Q3
Optional
Figure 5-5. 13 VDC Power Supply Wiring (Q-Line I/O) (Standard Version 386)
9/98
5-9
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Multibus Chassis
Q Crate
Q1
1
2
P2
TB
Card
*
QBE
Slot
1 ... 12
13
MHC/MHR
Slot
MSE
Card
MSX
Q-Line Expansion
P9L
3
4
5
6
7
8
P3
P2
Q-Crate
Q2
Card
Slot
*
QBE
1 ... 12
13
P3
P2
Q-Crate
Q3
Card
*
QBE
Slot
1 ... 12
13
P3
systems referred to the 12 Q-Crate slot
* Previous
designations as 02, 04, 06, ... 24.
Figure 5-6. Signal Cable Connections for Single DPU (Q-Line I/O)
(Standard Version 386)
M0-8005
5-10
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Dual Multibus Chassis
P2
TB
Q Crate
Q1
Card
*
Slot
1 ... 12
6
7
8
1
MHC/MHR
5
MSE
MHC/MHR
4
MSX
MSE
3
1
Secondary
P9R
Q-Line Expansion
MSX
2
Card
Slot
Primary
Q-Line Expansion
P9L
2
3
4
5
6
7
8
QBE
13
P3
P2
Q Crate
Q2
Card
*
QBE
Slot
1 ... 12
13
P3
P2
Q Crate
Q3
Card
*
Slot
1 ... 12 13
QBE
P3
systems referred to the
* Previous
12 Q-Crate slot designations as
TB
02, 04, 06, ... 24.
Figure 5-7. Signal Cable Connections for Redundant DPU (Q-Line I/O)
(Standard Version 386)
9/98
5-11
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Multibus Chassis (in “A” Cabinet)
MHC/MHR
1
MSE
Slot
MSX
Card
MBU
P9L
2
3
4
5
*
QBE
Q Crate Q1
(in “Ax” Cabinet)
Card
P2
Slot
1 .. 12
13
6
7
8
TB
P3
To Remaining
Q-Crates
systems referred to the
* Previous
12 Q-Crate slot designations as
02, 04, 06, ... 24.
Figure 5-8. Single DPU Q-Line Expansion Connections (Standard Version 386)
M0-8005
5-12
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Dual Multibus Chassis (in “A” Cabinet)
Primary
P9L
P9R
Secondary
5
6
7
8
1
MHC/MHR
4
MSE
3
MSX
2
MBU
1
MHC/MHR
Slot
MSE
Card
MSX
MultibusTM
Chassis (in
“A” Cabinet)
MBU
Dual
2
3
4
5
6
7
8
Q Crate Q1
(in “Ax” Cabinet)
Card
*
QBE
P2
Slot
1 .. 12
13
TB
P3
Q Crate Q2
(in “Ax” Cabinet)
Card
*
QBE
P2
Slot
1 ..1 2
13
P3
Q Crate Q3
(in “Ax” Cabinet)
Card
*
QBE
P2
Slot
1 .. 12
13
P3
TB
systems referred to the
* Previous
12 Q-Crate slot designations as
02, 04, 06, ... 24.
Figure 5-9. Redundant DPU Q-Line Expansion Connections (Standard Version 386)
9/98
5-13
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Cables from Multibus
Chassis
A OR Ax
1
2
3
4
5
6
7
8
9
10
11
12
13
1
2
3
4
5
6
7
8
9
10
11
12
13
1
2
3
4
5
6
7
8
9
10
11
12
13
B OR Bx
A OR Ax
B OR Bx
A OR Ax
B OR Bx
Cables from
Multibus Chassis
Notes
Previous systems referred to the 12 Q-Crate slot designations as 02, 04, 06, ... 24.
When the B cabinet is supplied, the field signals are terminated at the half shell
terminals. When the B cabinet is not supplied, the field signals are terminated at
the card edges on special card-edge connectors.
Figure 5-10. Q-Crate Wiring (Standard Version 386)
M0-8005
5-14
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Multibus Chassis
MHC/MHR
1
MSE
Slot
MSX
Card
MRC
P9L
2
3
4
5
6
7
8
Remote I/O
Termination Panel
or TFR Panel
Figure 5-11. Signal Cable Connections for Single DPU (Remote I/O) (Standard Version 386)
Dual Multibus Chassis
5
6
7
8
1
MHC/MHR
4
MSE
3
MSX
2
Secondary
P9R
MRC
MHC/MHR
1
MSE
Slot
MSX
Card
Primary
MRC
P9L
2
3
4
5
6
7
8
Remote I/O
Termination Panel
or TFR Panel
Figure 5-12. Signal Cable Connections for Redundant DPU (Remote I/O)
(Standard Version 386)
9/98
5-15
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
5-2.3. Enhanced 386 DPU Illustrations
Figure 5-13 through Figure 5-12 illustrate wiring, grounding, and cable connections
for the Enhanced 386 DPU.
13 V DC P.S. AC Input
Terminal Block Arrangements
X=
N=
G=
230
115
CMN
GND
115
230
HI = X
LO = N
GND = G
L
N
Selector
Switch
PRI 13 V P.S.
SEC 13 V P.S.
(Optional)
X NG
X NG
This arrangement has
voltage level wired-in as
either 115 V or 230 V
MULTIBUS POWER SUPPLIES
These arrangements have
input voltage level set by
means of a selector switch
PRIMARY
SECONDARY
(Optional)
PRI DC SEC DC PRI DC SEC DC
OPTIONAL
Cable
supplied
at project
level
QTB
Card
Cables supplied
with Multibus
Power Supplies
To door
fans
(Cable
supplied
with door
assembly)
If Secondary AC not
present, jumper PRI X
to SEC X and PRI N
to SEC N.
Primary Line
TB1
Primary Neutral
Secondary Line
Secondary Neutral
X
N
G
X
N
G
PRI
J1
J2
J3
J4
J5
J6
J8
J9
J10
J11
J12
J13
J15
J16
J17
J18
SEC
PRIMARY
SECONDARY
SWITCHED
Figure 5-13. DPU AC Power Cable Connections (Enhanced Version 386)
M0-8005
5-16
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
E1
Data Highway
Connection Panel
Multibus
Chassis
Power Ground
Q Crate Q1
Copper bus
bar at side
of cabinet
Q Crate Q2
Q Crate Q3
Cabinet Ground
Q Crate Q4
E1
Customer Supplied Earth Ground
AC Distribution
Cable installed per system grounding configuration, refer to “Highway
Installation Manual” (M0-0051).
Figure 5-14. DPU Grounding Wiring (Enhanced Version 386)
9/98
5-17
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Primary 13 VDC
Power Supply
(-)
Secondary 13 VDC
Power Supply
(+)
(-)
(+)
Power Ground
A B
C
Copper bus
bar at side
of cabinet
D E
F
Q Crate Q1
A B
C
D E
F
Q Crate Q2
A B
C
D E
F
Q Crate Q3
A B
C
D E
F
Q Crate Q4
Figure 5-15. 13 VDC Power Supply Wiring (Q-Line I/O) (Enhanced Version 386)
M0-8005
5-18
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Multibus Chassis
MSE
MHC/MHR
Slot
MSX
Card
Q-Line
Expansion
P9L
2
3
4
5
1
POWER
SUPPLY
TB
P2
Card
Q Crate Q1
Slot
*
Q
B
E
1 ... 12 13
P3
P2
Card
*
Slot
1 ... 12
Q Crate Q2
Q
B
E
13
P3
P2
Card
*
Q
B
E
Slot
1 ... 12
13
Q Crate Q3
P3
P2
Card
*
Q
B
E
Slot
1 ... 12
13
Q Crate Q4
P3
systems referred to the 12 Q-Crate slot
* Previous
designations as 02, 04, 06, ... 24.
Figure 5-16. Signal Cable Connections for Single DPU (Q-Line I/O) (Enhanced Version 386)
9/98
5-19
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Dual Multibus Chassis
Primary
P9R
5
1
MHC/MHR
4
MSE
3
MSX
MHC/MHR
2
POWER
SUPPLY
Q-Line
Expansion
MSE
1
MSX
Slot
Q-Line
Expansion
P9L
Card
Secondary
2
3
4
5
POWER
SUPPLY
TB
P2
Q Crate Q1
Card
*
Q
B
E
Slot 1 ... 12 13
P3
TB
P2
Q Crate Q2
Card
*
Q
B
E
Slot 1 ... 12 13
P3
P2
Q Crate Q3
Card
*
Q
B
E
Slot 1 ... 12 13
P3
P2
Q Crate Q4
Card
*
Q
B
E
systems referred to the 12 Q-Crate slot
* Previous
designations as 02, 04, 06, ... 24.
Slot 1 ... 12 13
P3
Figure 5-17. Signal Cable Connections for Redundant DPU (Q-Line I/O)
(Enhanced Version 386)
M0-8005
5-20
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
MultibusTM Chassis (in “A” Cabinet)
MHC/MHR
1
MSE
Slot
MSX
Card
MBU
P9L
2
3
4
5
POWER
SUPPLY
TB
*
QBE
Q Crate Q1
(in “Ax” Cabinet)
Card
P2
Slot
1 ... 12
13
P3
Cable to Remaining
Q-Crates
systems referred to the 12 Q-Crate slot
* Previous
designations as 02, 04, 06, ... 24.
Figure 5-18. Single DPU Q-Line Expansion Connections (Enhanced Version 386)
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5-21
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
1
MHC/MHR
5
MSE
4
POWER
SUPPLY
MSX
MHC/MHR
3
Secondary
P9R
MBU
MSE
2
1
Slot
2
3
4
5
POWER
SUPPLY
TB
Q Crate Q1
(in “Ax” Cabinet)
Card
MSX
Card
Primary
MBU
Dual Multibus Chassis (in “A” Cabinet)
P9L
P2
*
Q
B
E
Slot 1 ... 12 13
P3
TB
Q Crate Q2
(in “Ax” Cabinet)
Card
P2
*
Q
B
E
Slot 1 ... 12 13
P3
Q Crate Q3
(in “Ax” Cabinet)
Card
P2
*
Slot 1 ... 12
Q
B
E
13
P3
Q Crate Q4
(in “Ax” Cabinet)
Card
P2
*
Q
B
E
Slot 1 ... 12 13
systems referred to the
* Previous
12 Q-Crate slot designations as
P3
02, 04, 06, ... 24.
Figure 5-19. Redundant DPU Q-Line Expansion Connections (Enhanced Version 386)
M0-8005
5-22
Westinghouse Proprietary Class 2C
9/98
5-2. 386 DPU Configurations
Cables from
Multibus Chassis
A or Ax
Cabinet
TB
Q Crate Q1
P2
Card
Q
B
E
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
13
P3
B or Bx Half Shell A1
Cabinet Zone A & B
B1
A2
B2
A3
B3
A4
B4
A5
B5
A6
Cable from
Multibus Chassis
B6
TB
A or Ax
Cabinet
Q Crate Q2
P2
Card
Q
B
E
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
13
P3
B or Bx Half Shell C1 D1 C2 D2 C3 D3 C4 D4 C5 D5 C6 D6
Cabinet Zone C & D
A or Ax
Cabinet
Q Crate Q3
P2
Card
Q
B
E
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
13
P3
B or Bx Half Shell E1
Cabinet Zone E & F
A or Ax
Cabinet
F1
E2
F2
E3
F3
E4
F4
E5
F5
E6
F6
Q Crate Q4
P2
Card
Q
B
E
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
13
P3
B or Bx Half Shell G1 H1 G2 H2 G3 H3 G4 H4 G5 H5 G6 H6
Cabinet Zone G & H
Cable from
Multibus Chassis
Notes
Previous systems referred to the 12 Q-Crate slot designations as 02, 04, 06, ... 24.
When the B cabinet is supplied, the field signals are terminated at the half shell
terminals. When the B cabinet is not supplied, the field signals are terminated at
the card edges on special card-edge connectors.
Figure 5-20. Q-Crate Wiring for DPU (Enhanced Version 386)
9/98
5-23
Westinghouse Proprietary Class 2C
M0-8005
5-2. 386 DPU Configurations
Multibus Chassis
MHC/MHR
1
MSE
Slot
MSX
Card
MRC
P9L
2
3
4
5
POWER
SUPPLY
Remote I/O
Termination Panel
or TFR Panel
Figure 5-21. Signal Cable Connections for Single DPU (Remote I/O) (Enhanced Version 386)
Dual Multibus Chassis
Primary
5
SUPPLY
1
MHC/MHR
4
POWER
MSE
3
Secondary
MSX
2
P9R
MRC
MHC/MHR
1
MSE
Slot
MSX
Card
MRC
P9L
2
3
4
5
POWER
SUPPLY
Remote I/O
Termination Panel
or TFR Panel
Figure 5-22. Signal Cable Connections for Redundant DPU (Remote I/O)
(Enhanced Version 386)
M0-8005
5-24
Westinghouse Proprietary Class 2C
9/98
5-3. 486 DPU Configurations
5-3. 486 DPU Configurations
The 486 DPU is an Intel 86 (80x86) based process controller. Some of its features
include:
• Snap in filters and high reliability fans that require no tools to service.
• Large, easy-to-read part numbers and mnemonics are clearly displayed on the
faceplates of the processor and power supply modules.
The 486-DPU consists of the following rack-mountable assemblies:
• A 483 mm (19-in.) crate containing one or two 4-slot Multibus chassis (two for
redundant DPUs).
• A power supply assembly for each Multibus chassis.
• Up to four 483 mm (19-in.) Q-crates containing Q-cards (for DPUs which use
Q-Line I/O).
• One 483 mm (19-in.) assembly containing the power supplies for the Q-cards
(for DPUs which use Q-Line I/O).
• An AC Distribution Panel which provides circuit breakers for the two AC power
inputs.
The 486 DPU can be housed in a standard cabinet, a custom-built NEMA-rated
cabinet, or a wall/pipe-mounted enclosure (see Section 5-4 for information on the
wall/pipe-mounted enclosure). Various DPU configurations may be combined
within a single WDPF system.
A single 486 DPU cabinet and component locations are shown in Figure 5-23.
Appendix B provides dimensions, access spacing, and cable routing information for
the possible configurations.
9/98
5-25
Westinghouse Proprietary Class 2C
M0-8005
5-3. 486 DPU Configurations
Nameplate
13V
POWER
SUPPLY
PRIMARY
13V
POWER
SUPPLY
SECONDARY
P
O
W
E
R
P
O
W
E
R
MULTIBUS
CHASSIS
S
U
P
P
L
Y
MULTIBUS
CHASSIS
S
U
P
P
L
Y
Q CRATE Q1
Power Ground
Q CRATE Q2
Cabinet Ground
Q CRATE Q3
Q CRATE Q4
AC DISTRIBUTION
CENTER
Front
Figure 5-23. 486 DPU Component Locations
M0-8005
5-26
Westinghouse Proprietary Class 2C
9/98
5-3. 486 DPU Configurations
5-3.1. Power, Ground, and Signal Wiring (486 DPU)
WARNING
Hazardous voltage (115/230V) is employed
by these units.
Once the drop is installed at its permanent location, the power, ground, and Data
Highway connections to the drop can be made.
Cabinet wiring is brought into the area as shown in Appendix B. All wiring should
comply with national, state and local ordinances.
The enclosure should be grounded in accordance with the grounding procedures
given in “System Planning and Highway Installation Manual” (M0-0051). The
main and back-up AC power cables should be connected to the AC distribution
panel. Be sure that the correct voltage is available and that the hot, common, and
ground wires are identified before the AC service is connected.
Caution
Verify that the drop power source is grounded in
accordance with the WDPF grounding
requirements, as described in “System Planning
and Highway Installation Manual” (M0-0051).
Additional power wiring instructions can be found in Section 3. Additional
information on Data Highway connections can be found in “System Planning and
Highway Installation Manual” (M0-0051).
For DPUs which use the Remote Q-Line I/O subsystem, see “Remote Q-Line
Installation Manual” (M0-0054). For DPUs which use the Numa-Logic Distributed
700 Series I/O, connect the IOP communications link as described in “Distributed
I/O Installation Manual” (NLAM-B204).
Section 5-3.2 provides figures that apply to the 486 DPU.
9/98
5-27
Westinghouse Proprietary Class 2C
M0-8005
5-3. 486 DPU Configurations
5-3.2. 486 DPU Illustrations
Figure 5-13 through Figure 5-33 illustrate wiring, grounding, and cable connections
for the 486 DPU.
13 V DC P.S. AC Input
Terminal Block Arrangements
X=
N=
G=
230
115
CMN
GND
115
230
HI = X
LO = N
GND = G
L
N
Selector
Switch
PRI 13 V P.S.
SEC 13 V P.S.
(Optional)
X NG
X NG
This arrangement has
voltage level wired-in as
either 115 V or 230 V
MULTIBUS POWER SUPPLIES
These arrangements have
input voltage level set by
means of a selector switch
PRIMARY
SECONDARY
(Optional)
PRI DC SEC DC PRI DC SEC DC
OPTIONAL
QTB
Card
Cable
supplied
at project
level
Cables supplied
with Multibus
Power Supplies
To door
fans
(Cable
supplied
with door
assembly)
If Secondary AC not
present, jumper PRI X
to SEC X and PRI N
to SEC N.
Primary Line
TB1
Primary Neutral
Secondary Line
Secondary Neutral
X
N
G
X
N
G
PRI
J1
J2
J3
J4
J5
J6
J8
J9
J10
J11
J12
J13
J15
J16
J17
J18
SEC
PRIMARY
SECONDARY
SWITCHED
Figure 5-24. 486 DPU AC Power Cable Connections
M0-8005
5-28
Westinghouse Proprietary Class 2C
9/98
5-3. 486 DPU Configurations
E1
Data Highway
Connection Panel
Multibus
Chassis
Power Ground
Q Crate Q1
Copper bus
bar at side
of cabinet
Q Crate Q2
Q Crate Q3
Cabinet Ground
Q Crate Q4
E1
Customer Supplied Earth Ground
AC Distribution
Cable installed per system grounding configuration, refer to “Highway
Installation Manual” (M0-0051).
Figure 5-25. 486 DPU Grounding Wiring
9/98
5-29
Westinghouse Proprietary Class 2C
M0-8005
5-3. 486 DPU Configurations
Primary 13 VDC
Power Supply
(-)
Secondary 13 VDC
Power Supply
(+)
(-)
(+)
Power Ground
A B
C
Copper bus
bar at side
of cabinet
D E
F
Q Crate Q1
A B
C
D E
F
Q Crate Q2
A B
C
D E
F
Q Crate Q3
A B
C
D E
F
Q Crate Q4
Figure 5-26. 486 13 VDC Power Supply Wiring (Q-Line I/O)
M0-8005
5-30
Westinghouse Proprietary Class 2C
9/98
5-3. 486 DPU Configurations
Multibus Chassis
M
D
X
M
H
C
/
M
H
R
2
3
4
J8
J5
Card
Slot
1
Power
Supply
J6
Q Crate Q1
P14
P15
Q Crate Q2
P14
P15
Q Crate Q3
P14
P15
Q Crate Q4
P14
P15
Figure 5-27. Signal Cable Connections for Single 486 DPU (Q-Line I/O)
9/98
5-31
Westinghouse Proprietary Class 2C
M0-8005
5-3. 486 DPU Configurations
Dual Multibus Chassis
Primary
M
D
X
2
3
4
J8
J5
Card
Slot
1
Secondary
M
H
C
/
M
H
R
M
D
X
M
H
C
/
M
H
R
2
3
4
J8
J5
Power
Supply
1
J6
Power
Supply
J6
Q Crate Q1
P15
P14
Q Crate Q2
P15
P14
Q Crate Q3
P15
P14
Q Crate Q4
P15
P14
Figure 5-28. Signal Cable Connections for Redundant 486 DPU (Q-Line I/O)
M0-8005
5-32
Westinghouse Proprietary Class 2C
9/98
5-3. 486 DPU Configurations
Multibus Chassis
M
D
X
M
H
C
/
M
H
R
2
3
4
J9
J5
Card
Slot
1
Power
Supply
J6
Q Crate Q1
(in "Ax" Cabinet)
P14
P15
To Remaining
Q-Crates
Figure 5-29. Single 486 DPU Q-Line Expansion Connections
9/98
5-33
Westinghouse Proprietary Class 2C
M0-8005
5-3. 486 DPU Configurations
Dual Multibus Chassis
Primary
M
D
X
2
3
4
J9
J5
Card
Slot
1
Secondary
M
H
C
/
M
H
R
M
D
X
M
H
C
/
M
H
R
2
3
4
J9
J5
Power
Supply
1
J6
Power
Supply
J6
Q Crate Q1
(in "Ax" Cabinet)
P15
P14
Q Crate Q2
(in "Ax" Cabinet)
P15
P14
Q Crate Q3
(in "Ax" Cabinet)
P15
P14
Q Crate Q4
(in "Ax" Cabinet)
P15
P14
Figure 5-30. Redundant 486 DPU Q-Line Expansion Connections
M0-8005
5-34
Westinghouse Proprietary Class 2C
9/98
5-3. 486 DPU Configurations
Cables from
Multibus Chassis
P14 P15
Q Crate Q1
A or Ax
Cabinet
Card
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
B or Bx Half Shell A1
Cabinet Zone A & B
B1
A2
B2
A3
B3
A4
B4
A5
B5
A6
B6
P14 P15
Q Crate Q2
A or Ax
Cabinet
13
Card
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
13
B or Bx Half Shell C1 D1 C2 D2 C3 D3 C4 D4 C5 D5 C6 D6
Cabinet Zone C & D
P14
Q Crate Q3
A or Ax
Cabinet
Card
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
B or Bx Half Shell E1
Cabinet Zone E & F
F1
E2
F2
E3
F3
E4
F4
E5
F5
E6
F6
13
P14
Q Crate Q4
A or Ax
Cabinet
Cable from
Multibus Chassis
Card
Card Edge
1
2
3
4
5
6
7
8
9
10
11
12
13
B or Bx Half Shell G1 H1 G2 H2 G3 H3 G4 H4 G5 H5 G6 H6
Cabinet Zone G & H
Cable from
Multibus Chassis
Notes
Previous systems referred to the 12 Q-Crate slot designations as 02, 04, 06, ... 24.
When the B cabinet is supplied, the field signals are terminated at the half shell
terminals. When the B cabinet is not supplied, the field signals are terminated at
the card edges on special card-edge connectors.
Figure 5-31. Q-Crate Wiring for 486 DPU
9/98
5-35
Westinghouse Proprietary Class 2C
M0-8005
5-3. 486 DPU Configurations
Multibus Chassis
1
MHC/MHR
Slot
MDX
Card
MRC
P9L
2
3
4
POWER
SUPPLY
Remote I/O
Termination Panel
or TFR Panel
Figure 5-32. Signal Cable Connections for Single 486 DPU (Remote I/O)
4
MHC/MHR
3
MDX
2
Secondary
P9R
MRC
1
MHC/MHR
Slot
Primary
MDX
Card
P9L
MRC
Dual Multibus Chassis
2
3
4
POWER
SUPPLY
1
POWER
SUPPLY
Remote I/O
Termination Panel
or TFR Panel
Figure 5-33. Signal Cable Connections for Redundant 486 DPU (Remote I/O)
M0-8005
5-36
Westinghouse Proprietary Class 2C
9/98
5-4. Field Mounted Controller (FMC 1000)
5-4. Field Mounted Controller (FMC 1000)
The Field Mounted Controller (FMC 1000) incorporates the speed and performance
of the 486 DPU and encloses it in a modular wall-mounted or pipe-mounted
package. With the reduced design size and weight, the FMC 1000 can be installed
in locations in which there is reduced space.
Designed for exclusive use with the Remote Q-Line I/O subsystem, the new unit
offers many of the same enhanced features of the 486 DPU such as modular
faceplates, simplified maintenance features, and slide-in multi-voltage power
supplies.
For more information on the FMC 1000, see “Field Mounted Controller Installation
Manual” (M0-0055).
Figure 5-34 shows an example of the FMC 1000.
WDPF II MRC
MDX
MHC
DIOB
J2
DIOB
J1
Alive
DIOB Cntrl
Battery OK
WDPF II MRC
DH0
+5 Volt DC
DIOB
J1
Common
J2
J1
EN
AL
Primary Input
Secondary Input
DH1
Alive
DIOB Cntrl
Battery OK
Primary Fuse
3A 250V
Online
DH0
DH1
Reset
FP2 Alive
FP1 Alive
+12 Volt DC
DH0
+5 Volt DC
Flash Memory
Download
-12 Volt DC
Common
Secondary DIOB
Enabled
Primary Input
Secondary Input
DIOB Activity
Primary
Secondary
DIOB Power OK
Primary
Secondary
Secondary Fuse
3A 250V
Power Supply
7
6
5
4
3
2
1
0
Shared Memory
Parity Error
-12 Volt DC
DIOB Activity
Primary
Secondary
DIOB Power OK
Primary
Secondary
MHC
DIOB
J2
Reset
FP2 Alive
FP1 Alive
+12 Volt DC
Secondary DIOB
Enabled
MDX
Status
Online
DH0
DH1
Shared Memory
Parity Error
J2
J1
EN
AL
Power Supply
7
6
5
4
3
2
1
0
Status
DH1
Primary Fuse
3A 250V
Secondary Fuse
3A 250V
Flash Memory
Download
WDPF II
Figure 5-34. Field Mounted Controller (FMC 1000)
9/98
5-37
Westinghouse Proprietary Class 2C
M0-8005
Section 6. Drop Start-up Procedures
6-1. Section Overview
This section provides start-up procedures for WEStation drops, the Distributed
Processing Unit, and the Multibus-based Clock Interface Unit. It is assumed that the
software required for drop start-up has previously been loaded on disk (for WEStation
drops) or installed in PROM (for Multibus-based drops). For additional information
on loading system software, see “WEStation Software Load Kit” (U0-8001-x.x).
The following topics are included in this section:
• WEStation Drop Start-up (Section 6-2).
• Card-Handling Precautions (Section 6-3)
• DPU Pre-Power-Up Procedure (Section 6-4)
• Recommended DPU Card Configurations (Section 6-5)
• Removing and Installing the MSX Card (Section 6-6)
• DPU Power-up Procedure (Section 6-7)
• Multibus Power Supplies (Section 6-8)
• CIU Start-up (Section 6-9)
9/98
6-1
Westinghouse Proprietary Class 2C
M0-8005
6-2. WEStation Drop Start-up (VME Based)
6-2. WEStation Drop Start-up (VME Based)
The following sections describe pre-power-up and power-up procedures for all
WEStation drops.
Pre-Power-up Procedure
1. Check the AC voltage sources at the distribution box. Verify that the power
meets the drop specifications (shown in Appendix A) and that the wires are
connected to the correct terminals. Also, be certain that the equipment is
properly grounded.
2. Set-up and test the external peripheral devices to be used with this drop. For
additional information, see the applicable vendor documentation.
3. Connect the peripheral devices to the drop. Be certain that all cable connections
are made with the specified cables to the correct terminals. (See Section 3 for
illustrations of the peripheral cable connections.)
4. Check all printed-circuit cards for proper seating in the backplane connectors.
Power-up Procedure
Successful power-up of a WEStation drop can be determined by the indications
described below. If the drop fails to come up as described, refer to “Self-Test
Diagnostics” (M0-0003) for possible causes.
1. Turn power distribution assembly circuit breaker CB1 and CB2 to ON. Observe
the following indications on the power distribution assembly LEDs:
• For WEStations LEDs (+5V, +12V, -12V, +5DSK) should be lit, and
(+12VAUX) is not lit.
2. The start-up sequence takes several minutes. If the drop is equipped with a CRT,
the following indications can be observed:
• A heading will appear identifying the processor.
• Memory test information will be displayed.
• The boot routine will indicate that it is accessing the hard disk (device
sd@3).
• The operating system version will be displayed.
M0-8005
6-2
Westinghouse Proprietary Class 2C
9/98
6-2. WEStation Drop Start-up (VME Based)
• Information about the WEStation will be displayed, including the amount of
memory and processor type.
• SCSI devices will be initialized. If an error occurs, a message will appear
indicating that the device did not respond.
• Disk initialization and test messages will be displayed for each hard disk
partition. If any error occurs during the disk test, the boot routine will
restart.
• The current operating system date and time will be displayed.
• Operating system tasks (including Ethernet access) will be started.
• File systems defined in /etc/vfstab will be mounted. If the remote drop
(Software Server) is not on-line, error messages will be displayed.
• Drop daemons will be started.
• The SHC(s) and GHC (s) will be initialized and the daemons will be started.
As each Westnet II Highway is initialized, a message will appear in the form
“Initializing SHC x”, where x = network ID as defined in the
CONFIG.SHC file. If any errors occur during initialization, an error
message will appear.
Note
The software will always display messages
with “SHC” regardless of whether SHC or
GHC cards are used in the system.
The message “Final SHC init status xxxx” will then appear, where
xxxx = hexadecimal representation of the successfully initialized networks.
To interpret this value, convert the hexadecimal value into a 16 bit binary
value representing the possible network IDs. For example, a single Data
Highway identified as network 1 should result in a status value of 0002, as
shown below:
Bit
15
⇓
0000
0000
Bit
0
⇓
0010 = 0002H
0000
⇑
Network 1 initialized
• The drop login prompt will appear. For certain drops (such as the Operator
WEStation), login will occur automatically, and the appropriate display will
appear.
9/98
6-3
Westinghouse Proprietary Class 2C
M0-8005
6-2. WEStation Drop Start-up (VME Based)
3. The status indicators on the Data Highway Controller (SHC or GHC card)
should display the normal pattern, as described in “WDPF System Planning and
Highway Installation Manual” (M0-8000). In addition, the other cards in the
system should display their normal initialization pattern:
• TrueTime Card — See the TrueTime vendor manual for initialization
procedures. Refer to “TrueTime Clock Interface Unit (CIU) User’s Guide
(U0-2111) for more information. See Figure 6-4 for locations of switches on
the TrueTime Card.
• EHS Card — PRI1 should be lit with a green light. SEC1 should be lit with
a yellow light. PRI2 and SEC2 should not be lit. See Figure 6-2 for location
of switch on the EHS card.
• Sun 4600MP Card — LEDs will be lit as it “counts” through the diagnostic
tests. See Figure 6-3 for view of component locations on the SUN 4600MP
card.
M0-8005
6-4
Westinghouse Proprietary Class 2C
9/98
6-2. WEStation Drop Start-up (VME Based)
U2
JP1
ON
3
2
1
OFF
ON
3
2
1
OFF
JP2
Figure 6-1. True Time GPS VME Card Switch Locations
9/98
6-5
Westinghouse Proprietary Class 2C
M0-8005
6-2. WEStation Drop Start-up (VME Based)
Table 6-3 lists the TrueTime jumpers along with their valid settings. All of these
jumpers are user-configurable.
Table 6-1. TrueTime GPS VME Card Jumper Settings
Jumper(s)
Description
Default Setting(s)
JP1
RS 422 Termination
Enabled (position 2-3)
JP2
Battery
Shipped in the disabled (position 1-2).
Make sure that this is set to enabled
(position 2-3) when system is
powered up.
U2 Switch
VME Addressing
All 8 switches should be set to off.
The address is 0FFXXX.
M0-8005
6-6
Westinghouse Proprietary Class 2C
9/98
6-2. WEStation Drop Start-up (VME Based)
Figure 6-2 illustrates the location of switch (SW1) on the EHS card.
LEDs
SW1
1234
Spur Cable
Connector for
Primary
Information
Highway
ON
OFF
Input Connector
for Information
Highway
(Internal Cable)
Spur Cable
Connector for
Backup
Information
Highway
Additional
Ethernet
Connectors
(Currently
not
Supported)
LEDs
Figure 6-2. EHS Card Switch Location
9/98
6-7
Westinghouse Proprietary Class 2C
M0-8005
6-2. WEStation Drop Start-up (VME Based)
Table 6-2 illustrates the use of switch SW1 to specify the EHS card VME address
selection.
Caution
For successful Information Highway
operation, this switch must correspond to
the VME address selection specified. Refer
to “WDPF System Planning and Highway
Installation Manual” (M0-8000) for more
information.
Table 6-2. EHS VME Address (SW1) Switch Settings
Switch SW1
VME Address Selection
(from CONFIG.SHC)
4
3
2
1
0
ON
ON
ON
ON
1
ON
ON
ON
OFF
2
ON
ON
OFF
ON
3
ON
ON
OFF
OFF
4
ON
OFF
ON
ON
5
ON
OFF
ON
OFF
6
ON
OFF
OFF
ON
7
ON
OFF
OFF
OFF
8
OFF
ON
ON
ON
9
OFF
ON
ON
OFF
10
OFF
ON
OFF
ON
11
OFF
ON
OFF
OFF
12
OFF
OFF
ON
ON
13
OFF
OFF
ON
OFF
14
OFF
OFF
OFF
ON
15
OFF
OFF
OFF
OFF
Switch markings may vary:
OPEN = OFF = 1
CLOSED = ON = 0
M0-8005
6-8
Westinghouse Proprietary Class 2C
9/98
6-2. WEStation Drop Start-up (VME Based)
Mbus0
Mbus1
SPARC
SPARC
Figure 6-3 shows the component locations on the SUN 4600MP Card.
Sbus0
Sbus1
Sbus2
Sbus3
Figure 6-3. Sun 4600MP Card
Caution
Users should NOT make any changes to
this board.
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M0-8005
6-3. Card-Handling Precautions
6-3. Card-Handling Precautions
Observe the following precautions to avoid damage to the WDPF equipment:
1. Do not remove cards from the Multibus chassis when the chassis DC power is
ON.
Caution
Use an anti-static wrist strap when
handling the cards.
2. To remove a printed circuit board from the Multibus chassis, hold it by the white
“ears” or by the card edge. Avoid touching any card components.
3. If cards are to be shipped or stored, they should be placed in anti-static bags.
Never pack printed circuit boards in styrofoam “peanuts”.
Caution
Failure to observe the guidelines listed
above can result in printed-circuit board
damage.
6-4. DPU Pre-Power-Up Procedure
1. Check the AC voltage sources at the distribution box. Verify that the power
meets the drop specifications (shown in Appendix A) and that the hot and
neutral wires are connected to the correct terminals.
2. Be certain that the equipment is properly grounded.
3. Be certain that all cable connections are made with the specified cables to the
correct terminals (if necessary, refer to the applicable figures in Section 5-2
through Section 5-4 for illustrations of cable connections).
4. Check all printed circuit cards for proper seating in the backplane edge
connectors.
Section 6-5 describes the recommended card configurations:
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6-5. Recommended DPU Card Configurations
6-5. Recommended DPU Card Configurations
The DPU cards that need to be configured are listed alphabetically in this section:
• MBU card (I/O Interface)
• MDX card (32-bit 486 processor)
• MSE card (Memory)
• MSX card (32-bit 386 processor)
Note
Refer to “WDPF System Planning and
Highway Installation Manual” (M0-8000) for
information on configuring the switch and
jumper settings for the Data Highway
Controller cards (MHC/MHR).
6-5.1. MBU Card
For DPUs using Q-Line I/O, in order to use an MBU card to provide a second
Distributed I/O Bus (DIOB), perform the following (refer to Figure 6-4):
• Verify that the RUN/SVC (Service) switches on the MBU card are in the RUN
position.
• Verify that the power cable (13VDC) from the QBE card is connected to the two
terminals at the top of the MBU.
• Configure the six switches in the rear-bottom of the MBU card as follows:
— Non-redundant/redundant Primary DPU
MBU Switch
Setting
1
2
3
4
5
6
Closed
Open
Open
Open
Open
Closed
1
2
3
4
5
6
Closed
Open
Open
Open
Open
Open
— Redundant Backup DPU
MBU Switch
Setting
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6-5. Recommended DPU Card Configurations
Notes
Switch 1 designates First or Second DIOB.
Open = First (5-level)
Closed = Second (all levels)
Switch 6 designates Primary or Backup DPU.
Closed = Primary
Open = Backup
Depending on the switch markings:
Closed = ON = 1
Open = OFF = 0
TB1
Terminal Block
SW1
DIP Switches
Detail
J2
123456
J1
OFF
Run/Service
Toggle Switch
P1
SW1
Figure 6-4. MBU Card Switch and Connector Locations
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6-5. Recommended DPU Card Configurations
6-5.2. MDX Card
For DPUs using an MDX card, verify the following (refer to Figure 6-5):
• Verify that jumper JS11 is in the DIS position.
• Verify that jumper JS14 is in the OFFBD (1-2) position.
JS12
JS11
JS13
JS14
MDX
OFFBD
Status
DIS ENA
Alive
DIOB Cntrl
Battery OK
JS10
Shared Memory
Parity Error
LEDs
JS8 JS9
Secondary DIOB
Enabled
JS7
DIOB Activity
Primary
Secondary
DIOB Power OK
Primary
Secondary
Flash Memory
Download
Serial Port
4256A88
JS6
JS5
JS3
JS4
JS1
Faceplate
Figure 6-5. MDX Card Faceplate and Jumper Locations
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6-5. Recommended DPU Card Configurations
Table 6-3 lists the MDX jumpers along with their valid settings. Only one of these
jumpers (JS11) is user-configurable.
Table 6-3. MDX Jumper Settings
Jumper(s)
Valid Setting(s)
JS1
Position 1-2 (ENA)
JS3, JS7, JS12, JS13
GND test points (no settings)
JS4
Position 2-3 (2.0 SEC)
JS5
Position 1-2 (ENA)
JS6
Position 1-2 (ENA)
JS8
Position 1-2 (ENA)
JS9
Position 1-2 (ENA)
JS10
Used as a battery connector
JS11
Position 1-2 (DIS)
Note: this jumper must be placed in Position 2-3 (ENA) prior to
placing the MDX on-line.
JS14
Position 1-2 (OFFBD)
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6-5. Recommended DPU Card Configurations
6-5.3. MSE Card
For DPUs using an MSE card, verify the following (refer to Figure 6-6):
• Verify that the MSE battery jumper (JS19) is in the DISBAT position (2 - 3)
during initial power-up, or power-up when no battery backup is required, until
the power-up procedures are complete.
JS16 JS17 JS18
JS19
ENBAT DISBAT
+
B
A
T
T
E
R
Y
P2
-
JS10
JS9
JS8
JS3
JS4
J1
MSLCLK DHCCLK
J1
JS1
P1
JS3
Figure 6-6. MSE Card Jumper and Connector Locations
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6-5. Recommended DPU Card Configurations
Table 6-3 lists the MSE jumpers along with their valid settings. Only one of these
jumpers (JS19) is user-configurable.
Table 6-4. MSE Jumpers
Jumper(s)
Valid Setting(s)
JS1
Position 1-2
JS3
Position 2-3
JS4
Removed
JS8, JS9, JS10
JS8 is installed
JS9, JS10 are removed
JS16, JS17, JS18
Removed
JS19
To enable the battery, place the jumper in the ENBAT (1-2) position.
To disable the battery, place the jumper in the DISBAT (2-3) position.
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6-5. Recommended DPU Card Configurations
6-5.4. MSM Card
For DPUs using Numa-Logic Distributed 700 Series I/O, verify the following (refer
to Figure 6-7):
• Verify that the MSM clock jumpers (JP7 and JP8) are installed, and (JP1) and
(JP2) are removed.
• Verify that the MSM battery jumper (JS2) is in the disabled position (2 - 3)
(during initial power-up, or power-up when no battery backup is required), until
the power-up procedures are complete
JP7 JP8
B
A
T
T
E
R
Y
+
P2
321
JS2
B
A
T
T
E
R
Y
+
Battery
Enable
Jumper
Clock
Jumpers
(Install)
P1
JP1
JP2
J2
J1
Clock Jumpers
(Remove)
Figure 6-7. MSM Card Jumper and Connector Locations
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6-5. Recommended DPU Card Configurations
6-5.5. MSX Card
JS15
JS16
JS14
For DPUs using an MSX card, verify that the jumpers (refer to Figure 6-8) are
factory-set in the positions listed in Table 6-5:
JS20
JS18
JS19
JS22
LEDs
BOK
ALV
ENB
DIOB ACTV
7
Fault
Code
JS17
JS12
JS11
JS21
0
JS10
JS5
JS6
JS7
JS9
JS8
JS2
JS4
JS1
JS3
Figure 6-8. MSX Card Jumper and LED Locations
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6-5. Recommended DPU Card Configurations
Table 6-5 lists the MSX jumpers along with their valid settings. None of these
jumpers are user-configurable.
Table 6-5. MSX Jumpers
9/98
Jumper(s)
Valid Setting(s)
Jumper(s)
JS1
Position 1-2
JS12
Installed
JS2
Installed
JS14
Position 1-2
JS3
Installed
JS15
Position 1-2
JS4
Installed
JS16
Position 1-2
JS5
Removed
JS17
Removed
JS6
Removed
JS18
Installed
JS7
Removed
JS19
Installed
JS8
Position 2-3
JS20
Removed
JS9
Position 2-3
JS21
Position 2-3
JS10
Position 2-3
JS22
Position 2-3
JS11
Installed
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Valid Setting(s)
M0-8005
6-6. Removing and Installing the MSX Card
6-6. Removing and Installing the MSX Card
In order to maintain the integrity of the data on the DIOB, the following procedures
are recommended for removing and installing an MSX card in a redundant DPU
pair.
Adherence to these procedures is only necessary when one DPU in the pair MUST
be in control while the MSX card in the other DPU is being removed or installed.
Before beginning these procedures, note the following:
• Determine which DPU in the redundant pair is in control of the I/O Bus. If the
DPU requiring service is in control, verify that its partner is in Backup status
and ready to take control.
• If the DPU being serviced is at level 7.2 or above, Diagram 109 (DIOB Test
Configuration) can be used at the Standard Operator Station to minimize the
affects of DIOB Test failure during servicing.
The “Alarm Only on Fault” option should be selected before servicing begins.
After servicing is complete, select the default option “Idle Mode on Fault.”
Caution
When removing or installing cards, always
observe static protection guidelines as
recommended in Section 6-3.
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6-6. Removing and Installing the MSX Card
Removing an MSX Card from a Redundant DPU
Perform the following procedure to remove an MSX card from a redundant DPU
while the partner DPU is in control (refer to Figure 6-9 for locations of referenced
items):
1. Power off the DPU that is to be serviced.
2. Remove the two 50-pin shared memory cables from connectors J3 and J4 on the
MSX card.
3. BEFORE removing the following cables, unseat the MSX card from the DPU
backplane.
4. Remove the 13V power cable from the J6 connector on the MSX card.
5. Remove the cross-connect cable from the J5 connector on the MSX card.
6. Remove the MSX card from the DPU chassis.
Installing an MSX Card in a Redundant DPU
Perform the following procedure to install an MSX card into a redundant DPU
while the partner DPU is in control (refer to Figure 6-9 for locations of referenced
items):
1. Place MSX card (Sub-level A or later) in the DPU chassis, but DO NOT SEAT
in backplane connectors.
2. Install the cross-connect cable on the J5 connector on the MSX card.
3. Install the 13V power cable on the J6 connector on the MSX card.
4. Seat the MSX card in the DPU backplane.
5. Install the two 50-pin shared memory cables on connectors J3 and J4 on the
MSX card.
6. Power on the DPU.
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6-6. Removing and Installing the MSX Card
13V Power
Connector
Cross
Connector
J6
Backplane
J5
P2
J4
P1
J3
Backplane
Figure 6-9. MSX Card Connector Locations
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6-7. DPU Power-up Procedure
6-7. DPU Power-up Procedure
Successful power-up of a DPU can be determined by the indications described in
the following procedure. If the DPU fails to come up as described, refer to
“Self-Test Diagnostics” (M0-0003) for possible causes.
1. Turn circuit breakers CB1, CB2, and CB3 on the AC Distribution Center to ON.
2. Turn the Multibus Power Supply switch to ON.
All LEDs on the Multibus Power Supply should be lit except for FP2 ALIVE (if
Power Supply has an Over Temperature LED, it should not be lit).
If there is no secondary AC source, the SEC AC LED will not be lit.
3. For initial power-up (or power-up after a power-down without operational backup battery), press the green RESET button on the Multibus Power Supply.
4. After a drop has been powered-up, drop status information is provided by the
LEDs on the DHC card or the processor card. These LEDs go through a startup sequence during the first few seconds after power-up (refer to
Section 6-7.1 for applicable LED patterns).
5. Verify that the (optional) I/O cards are powered-up. The voltage used by the IOP
or MBU card(s) must be present for proper operation of the DPU.
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6-7. DPU Power-up Procedure
6-7.1. LED Patterns
This section describes the various LED patterns for the different DPU cards:
Note
Refer to “WDPF System Planning and
Highway Installation Manual” (M0-8000) for
information on configuring the Data
Highway Controller cards (MHC/MHR).
LED Patterns for MHC Card
Observe the following LED patterns for an MHC card (illustrated in
Figure 6-10) to verify normal operation (for 7-level systems):
• LE8 (top LED) should flash at a constant 5 Hz rate.
• For a single (non-redundant) Data Highway, LE1 (the bottom LED in the
upper cluster of 8) and LE9 (the top LED in the lower cluster of 2) should
light steadily.
• For a redundant Data Highway, LE1 and LE2 (the bottom two LEDs in the
upper cluster of 8) should light steadily, and LE9 and LED10 (the lower
cluster of 2) should light steadily.
No other LEDs should be lit. Refer to “Self-Test Diagnostics” (M0-0003) to
interpret other LED patterns.
LED Patterns for MHR Card
Observe the following LED patterns for an MHR card (illustrated in
Figure 6-10) to verify normal operation (for 7-level systems with Remote Taps):
• LE10 (top LED) should flash at a constant 5 Hz rate.
• For a single (non-redundant) Data Highway, LE3 (the bottom LED in the
upper cluster of 8) and LE2 (the top LED in the lower cluster of 2) should
light steadily.
• For a redundant Data Highway, LE3 and LE4 (the bottom two LEDs in the
upper cluster of 8) should light steadily, and LE1 and LE2 (the lower cluster
of 2) should light steadily.
No other LEDs should be lit. Refer to “Self-Test Diagnostics” (M0-0003) to
interpret other LED patterns.
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6-7. DPU Power-up Procedure
MHC Card
MHR Card
LE8
LE10
LE7
Blinking
LE6
LE8
LE5
LE7
LE4
LE6
LE3
LE5
LE2
LE4
LE1
LE3
LE2
LE9
LE10
Blinking
LE9
Lit
Lit
LE1
Steadily
Steadily
Non-Redundant Configuration (Data Highway 0 Only)
MHC Card
LE8
MHR Card
LE10
Blinking
Blinking
LE7
LE9
LE6
LE8
LE5
LE7
LE4
Lit
LE6
Lit
LE3
Steadily
LE5
Steadily
LE2
LE4
LE1
LE3
LE9
LE2
LE10
LE1
Redundant Configuration (Data Highways 0 and 1)
Figure 6-10. MHC/MHR LED Patterns (Normal Operation)
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6-7. DPU Power-up Procedure
LED Patterns for MDX Card
Observe the following LED patterns (refer to Figure 6-5 for LED locations) for
an MDX card to verify normal operation:
• If the battery backup is enabled, the Battery OK LED should be lit.
• The Alive LED should always be lit.
• If the DPU is in CONTROL status, the DIOB Cntrl LED should be lit.
• The Parity Error LED should be off during the first power-up. This LED
may turn on briefly but should go out within 10 seconds.
• The Primary DIOB Power OK LED should be on.
• The Primary DIOB Activity LED lights when the Distributed I/O Bus is
accessed. During normal operation, this LED will flash intermittently.
• The Flash Memory Download LED should be off.
• The alphanumeric display is used to display any drop fault indication.
During normal operation, the display reads FF.
For Extended I/O Applications Only
• The Secondary DIOB Enabled LED must be lit.
• The Secondary DIOB Power OK LED must be lit.
• The Secondary DIOB Activity LED lights when the extended
Distributed I/O Bus is accessed. During normal operation, this LED will
flash intermittently.
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6-7. DPU Power-up Procedure
LED Patterns for MSX Card
Observe the following LED patterns (refer to Figure 6-8 for LED locations) for
an MSX card to verify normal operation:
• If the battery backup is enabled, the top LED (BOK) should be lit.
• The second LED (ALV) should always be lit.
• If the DPU is in CONTROL status, the third LED (ENB) should be lit.
• The fourth LED (DIOB ACTV) lights when the Distributed I/O Bus is
accessed. During normal operation, this LED will flash intermittently.
• The lower set of LEDs are used to display any drop fault indication. During
normal operation, all 8 of the lower LEDs are lit.
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6-8. Multibus Power Supplies
6-8. Multibus Power Supplies
This section lists and briefly describes the power supplies used in the DPUs.
6-8.1. Todd or Deltron Power Supply
ON
OFF
PRI AC
SEC AC
AC PWR
SEC AC Input
E
US
F
RESET
- 12 VDC
+ 5 VDC
+ 12 VDC
FP1 ALIVE
FP2 ALIVE
PRI AC Input
E
US
E
E
US
US
F
F
F
These power supplies are switching power supplies that accept AC input. Refer to
Figure 6-11 for an example of the faceplate that is used for these power supplies.
(The components of the faceplate are described following Figure 6-11.)
Figure 6-11. Todd/Deltron Power Supply Faceplate (Standard 386 DPU)
Reset Button
If the Reset button is pressed, the processor halts, and the FP1 ALIVE LED goes
out. The Data Highway halts, from this drop. When the Reset button is released, the
processor starts, the FP1 ALIVE LED lights and the Data Highway interface begins
off-line diagnostics.
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6-8. Multibus Power Supplies
LEDs
• If the second function processor is running, the FP2 ALIVE LED is lit.
• If the first function processor (MSX) is running, the FP1 ALIVE LED is lit.
• If the +12 VDC output is normal, the +12 V DC LED is lit.
• If the +5 VDC output is normal, the +5 V DC LED is lit.
• If the -12VDC output is normal, the -12 V DC LED is lit.
• If the PRI AC LED is lit, then:
— Primary input voltage is above 95 VAC.
• If the SEC AC LED is lit, then:
— Secondary input voltage is above 95 VAC.
Fuses
• The PRI AC Input Fuse is a 3AG type fuse rated at 7A and 250V
(for Primary input).
• The SEC AC Input Fuse is a 3AG type fuse rated at 7A and 250V
(for Secondary input).
On-Off Switch
This AC PWR switch is an input power switch for both Primary and Secondary
inputs.
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6-8. Multibus Power Supplies
6-8.2. MBPS Power Supply Card (Enhanced 386 DPU)
The MBPS card is a plug-in power supply that requires isolation transformers at the
AC Distribution Panel. Refer to Figure 6-11 for an example of the faceplate that is
used for this power supply. (The components of the faceplate are described
following Figure 6-11.)
Power Supply
MBPS
Reset
FP2 Alive
FP1 Alive
+12 Volt DC
+5 Volt DC
-12 Volt DC
COMMON
Over Temperature
Primary Input
Secondary Input
Primary Fuse
8A 250V
Secondary Fuse
8A 250V
Power
ON
OFF
Figure 6-12. MBPS Power Supply Faceplate (Enhanced 386 DPU)
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6-8. Multibus Power Supplies
Reset Button
If the Reset button is pressed, the processor halts, and the FP1 Alive LED goes out.
The Data Highway halts, from this drop. When the Reset button is released, the
processor starts, the FP1 Alive LED lights and the Data Highway interface begins
off-line diagnostics.
MBPS LEDs
• If the second function processor is running, the FP2 Alive LED is lit.
• If the first function processor (MSX or MDX) is running, the FP1 Alive LED is
lit.
• If the +12 VDC output is normal, the +12 Volt DC LED is lit.
• If the +5 VDC output is normal, the +5 Volt DC LED is lit.
• If the -12VDC output is normal, the -12 Volt DC LED is lit.
• If the Over Temperature LED is lit, the temperature inside the power supply is
above 80 degrees C.
• If the Primary Input LED is lit, then:
— Primary input voltage is within required range.
• If the Secondary Input LED is lit, then:
— Secondary input voltage is within required range.
Test Jacks
If there is a need to test the voltages, a voltmeter can be used by inserting the black
lead into the Common jack, and the red lead into the applicable jack:
• To test +12 VDC output, insert the red lead into the +12 Volt DC jack and the
black lead into the Common jack.
• To test +5 VDC output, insert the red lead into the +5 Volt DC jack and the black
lead into the Common jack.
• To test -12 VDC output, insert the red lead into the -12 Volt DC jack and the
black lead into the Common jack.
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6-8. Multibus Power Supplies
Fuses
• The Primary Fuse is a 3AG type fuse rated at 8A and 250V (for Primary input).
• The Secondary Fuse is a 3AG type fuse rated at 8A and 250V (for Secondary
input).
On-Off Power Switch
This switch is an input power switch for both Primary and Secondary inputs.
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6-8. Multibus Power Supplies
6-8.3. MDPS Power Supply Card (486 DPU)
The MDPS card is a plug-in Power Factor Correction (PFC) Power Supply that
accepts AC or DC inputs. Refer to Figure 6-11 for an example of the faceplate for
the MDPS (faceplates may vary slightly depending on the DPU configuration.)
MDPS
Reset
FP2 Alive
FP1 Alive
+12 Volt DC
+5 Volt DC
-12 Volt DC
Common
Primary Input
Secondary Input
Primary Fuse
3A 250V
Secondary Fuse
3A 250V
ON
OFF
Figure 6-13. MDPS Power Supply Faceplate (486 DPU)
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6-8. Multibus Power Supplies
Reset Button
If the Reset button is pressed, the processor halts, and the FP1 Alive LED goes out.
The Data Highway halts, from this drop. When the Reset button is released, the
processor starts, the FP1 Alive LED lights and the Data Highway interface begins
off-line diagnostics.
MDPS LEDs
• If the second function processor is running, the FP2 Alive LED is lit.
• If the first function processor (MSX or MDX) is running, the FP1 Alive LED is
lit.
• If the +12 VDC output is normal, the +12 Volt DC LED is lit.
• If the +5 VDC output is normal, the +5 Volt DC LED is lit.
• If the -12VDC output is normal, the -12 Volt DC LED is lit.
• If the Primary Input LED is lit, then:
— Primary input voltage is within required range.
— Temperature of the Primary input circuit is below 80 degrees C.
— Primary Power Factor Correction circuit is functioning normally.
• If the Secondary Input LED is lit, then:
— Secondary input voltage is within required range.
— Temperature of the Secondary input circuit is below 80 degrees C.
— Secondary Power Factor Correction circuit is functioning normally.
Test Jacks
If there is a need to test the voltages, a voltmeter can be used by inserting the black
lead into the Common jack, and the red lead into the applicable jack:
• To test +12 VDC output, insert the red lead into the +12 Volt DC jack and the
black lead into the Common jack.
• To test +5 VDC output, insert the red lead into the +5 Volt DC jack and the black
lead into the Common jack.
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6-8. Multibus Power Supplies
• To test -12 VDC output, insert the red lead into the -12 Volt DC jack and the
black lead into the Common jack.
Fuses
• The Primary Fuse is a 3AG type fuse rated at 3A and 250V (for Primary input).
• The Secondary Fuse is a 3AG type fuse rated at 3A and 250V (for Secondary
input).
On-Off Switch
This switch is an input power switch for both Primary and Secondary inputs.
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6-9. CIU Start-up (Multibus-based)
6-9. CIU Start-up (Multibus-based)
Use the following pre-power-up and power-up procedures for the Multibus-based
Clock Interface Unit (CIU).
Note
These procedures are for the dual 8-slot Multibusbased CIU. For WEStation CIU start-up procedures,
see Section 6-2.
Pre-Power-up Procedure
1. Check the AC voltage sources at the distribution box. Verify that the power
meets the drop specifications (shown in Appendix A) and that the hot and
neutral wires are connected to the correct terminals. Also, be certain that the
equipment is properly grounded.
2. Be certain that all cable connections are made with the specified cables to the
correct terminals. (See “Computime Clock Interface Unit User’s Guide”
(U0-2110) and “Clock Interface Unit User’s Guide” (U0-2101) for illustrations
of the CIU signal cable connections.)
Power-up Procedure
Successful power-up of a CIU can be determined by the indications described
below. If the drop fails to come up as described, refer to “Self-Test Diagnostics”
(M0-0003) for possible causes.
1. Turn circuit breakers CB1, CB2, and CB3 on the AC Distribution Center to ON.
2. Verify that the clock unit is connected and operational.
3. Turn the Multibus Power Supply switch to ON (the Multibus Power Supply is
located below Multibus chassis). All LEDs on the Multibus power supply
should be lit except for FP2 ALIVE.
4. The LED indicators on the Data Highway Controller (MHC/MHR card) will run
through the start-up pattern. After the start-up sequence, the normal pattern
should appear, as described in “WDPF System Planning and Highway
Installation Manual” (M0-8000).
M0-8005
6-36
Westinghouse Proprietary Class 2C
9/98
Appendix A.
Electrical and Environmental
Specifications
This appendix provides electrical and environmental specifications for WDPF
drops and associated peripheral devices.
• Table A-1 through Table A-3 provide electrical specifications.
• Table A-4 and Table A-5 provide environmental specifications.
Note
The specifications for the peripherals (nonWestinghouse devices) are representative
values based upon current products and are
subject to change. Refer to the Peripheral
Equipment Manual for vendor specific
information on the peripheral devices.
9/98
A-1
Westinghouse Proprietary Class 2C
M0-8005
Table A-1. Electrical Requirements
115 V Nominal Input
230 V Nominal Input
Device/
Mfg. and Model No.
Input Voltage
Range (VAC)
Input
Frequency
Range
(Hertz)
386 Standard/Enhanced and
486 DPU Drop
Westinghouse
98 to 132
48 to 63
196 to 254
48 to 63
Multibus-based CIU Drop
Westinghouse
110 to 127
48 to 63
220 to 240
48 to 63
VME WEStation
Westinghouse
90 to 132
47 to 63
180 to 264
47 to 63
WEStationDT
Westinghouse
95 to 132
47 to 63
190 to 264
47 to 63
20 " Color Monitor
100 to 120
45 to 70
200 to 240
45 to 70
27" Color Monitor
98 to 132
47 to 63
196 to 264
47 to 63
Monochrome Monitor
100 to 120
47 to 63
200 to 240
47 to 63
Membrane Keyboard
Westinghouse
105 to 120
60
210 to 240
50
Dot Matrix Printer
102 to 138
58 to 62
187 to 264
48 to 52
Line Printer
97 to 132
48 to 65
194 to 264
48 to 65
Laser Printer
100 to 127 +/10%
58 to 62
220 to 240 +/10%
48 to 52
Screen Copy Printer
100 to 130
60
200 to 240
50
Optical Disk Drive
100 to 130
60
200 to 240
50
8mm Magnetic Tape Unit
100 to 260
47 to 400
100 to 260
47 to 400
3.5" Floppy Disk Unit
90 to 260
47 to 400
90 to 260
47 to 400
1/4" Magnetic Tape Unit
90 to 260
47 to 400
90 to 260
47 to 400
CD-ROM
100 to 120
47 to 63
200 to 240
47 to 63
PROM Programmer
90 to 130
48 to 62
180 to 260
48 to 62
M0-8005
A-2
Westinghouse Proprietary Class 2C
Input
Voltage
Range (VAC)
Input
Frequency
Range
(Hertz)
9/98
Table A-1. Electrical Requirements (Cont’d)
115 V Nominal Input
230 V Nominal Input
Device/
Mfg. and Model No.
Input Voltage
Range (VAC)
Input
Frequency
Range
(Hertz)
Westnet Fiber Optic Repeater
Westinghouse
98 to 132
47 to 63
198 to 264
47 to 63
Ethernet Fiber Optic Repeater
Westinghouse
90 to 250
48 to 65
90 to 250
48 to 65
9/98
A-3
Westinghouse Proprietary Class 2C
Input
Voltage
Range (VAC)
Input
Frequency
Range
(Hertz)
M0-8005
Table A-2. Typical Input Power Requirements for 115 VAC
Steady State
Current
(Amps)
Standard/Enhanced 386
DPU Drop (with Dual
Multibus Chassis and a 39
Amp DIOB load)
Westinghouse
Power
(VA)*
Steady State
Power Input
(Watts)**
Thermal
Dissipation
(BTUs/Hr)
Inrush
Current
(Amps)
11.8
1357
987
3367
55
Standard/Enhanced 386
DPU Drop (with Dual
Multibus Chassis and a 21
Amp DIOB load)
Westinghouse
7.8
897
652
2226
50
486 DPU Drop (with Dual
Multibus Chassis and a 39
Amp DIOB load)
Westinghouse
10.6
1219
887
3028
55
486 DPU Drop (with Dual
Multibus Chassis and a 21
Amp DIOB load)
Westinghouse
6.6
759
552
1885
50
Multibus-based
CIU Drop
Westinghouse
4.4
368
1255
70
VME WEStation
(1 Disk, 1 CRT, 1 SHC, 2
RTPs, 2 EHS cards)
Westinghouse
4.8
375
1278
91
VME WEStation
(1 Disk, 2 CRTs, 1 SHC,
2 RTPs, 2 EHS cards)
Westinghouse
6.6
515
1758
111
Device Description
*(VA) This figure can be used to calculate size of UPS if required for the system.
**(Watts) This figure can be used to calculate cooling requirements for the system.
M0-8005
A-4
Westinghouse Proprietary Class 2C
9/98
Table A-2. Typical Input Power Requirements for 115 VAC (Cont’d)
Device Description
Steady State
Current
(Amps)
Power
(VA)*
Steady State
Power Input
(Watts)**
Thermal
Dissipation
(BTUs/Hr)
Inrush
Current
(Amps)
VME WEStation
(4 Disks, 1 CRT, 1 SHC,
2 RTPs, 2 EHS cards)
Westinghouse
5.8
453
1545
93
VME WEStation
(4 Disks, 2 CRTs, and
maximum VME Bus
load)
Westinghouse
9.6
749
2557
126
WEStationDT
Westinghouse
0.7
53
180
20" Color Monitor
130
444
27" Color Monitor
220
751
110
375
82
240
44
Monochrome Monitor
2.2
Membrane Keyboard
Westinghouse
0.2
24
Dot Matrix Printer
1.5-Operating
0.6-Standby
260-Operating
85-Standby
889-Operating
291-Standby
25
Line Printer
6.0-Operating
1.0-Standby
700-Operating 2394-Operating
68-Standby
232-Standby
50
Laser Printer
300-Operating 1024-Operating
85-Standby
290-Standby
22
Screen Copy Printer
180-Operating
50-Standby
Optical Disk Drive
30
614-Operating
171-Standby
8mm Magnetic Tape Unit
0.4
14 to 40
48 to 137
11
3.5" Floppy Disk Unit
0.2
14 to 40
48 to 137
11
1/4" Magnetic Tape Unit
0.2
14 to 40
48 to 137
11
*(VA) This figure can be used to calculate size of UPS if required for the system.
**(Watts) This figure can be used to calculate cooling requirements for the system.
9/98
A-5
Westinghouse Proprietary Class 2C
M0-8005
Table A-2. Typical Input Power Requirements for 115 VAC (Cont’d)
Steady State
Current
(Amps)
CD-ROM
0.8
PROM Programmer
Power
(VA)*
Steady State
Power Input
(Watts)**
Thermal
Dissipation
(BTUs/Hr)
80
40
65
0.4
60
205
10
Westnet Fiber Optic
Repeater
Westinghouse
0.3
25
86
20
Ethernet Fiber Optic
Repeater
Westinghouse
0.4
25
86
1
Device Description
Inrush
Current
(Amps)
*(VA) This figure can be used to calculate size of UPS if required for the system.
**(Watts) This figure can be used to calculate cooling requirements for the system.
M0-8005
A-6
Westinghouse Proprietary Class 2C
9/98
Table A-3. Typical Input Power Requirements for 230 VAC
Steady State
Current
(Amps)
Standard/Enhanced 386
DPU Drop (with Dual
Multibus Chassis and a
39 Amp DIOB load)
Westinghouse
Power
(VA)*
Steady State
Power Input
(Watts)**
Thermal
Dissipation
(BTUs/Hr)
Inrush
Current
(Amps)
5.9
1357
987
3367
55
Standard/Enhanced 386
DPU Drop (with Dual
Multibus Chassis and a
21 Amp DIOB load)
Westinghouse
3.9
897
652
2226
50
486 DPU Drop (with
Dual Multibus Chassis
and a 39 Amp DIOB
load)
Westinghouse
5.2
1196
870
2970
55
486 DPU Drop (with
Dual Multibus Chassis
and a 21 Amp DIOB
load)
Westinghouse
3.2
736
535
1826
50
Multibus-based
CIU Drop
Westinghouse
2.2
375
1278
91
VME WEStation
(1 Disk, 1CRT, 1 SHC, 2
RTPs, 2 EHS cards)
Westinghouse
2.4
375
1278
91
VME WEStation
(1 Disk, 2 CRTs, 1 SHC,
2 RTPs, 2 EHS cards)
Westinghouse
3.3
515
1758
111
Device Description
* (VA) This figure can be used to calculate size of UPS if required for the system.
** (Watts) This figure can be used to calculate cooling requirements for the system.
9/98
A-7
Westinghouse Proprietary Class 2C
M0-8005
Table A-3. Typical Input Power Requirements for 230 VAC (Cont’d)
Device Description
Steady State
Current
(Amps)
Power
(VA)*
Steady State
Power Input
(Watts)**
Thermal
Dissipation
(BTUs/Hr)
Inrush
Current
(Amps)
VME WEStation
(4 Disks, 1 CRT, 1 SHC, 2
RTPs, 2 EHS cards)
Westinghouse
2.9
453
1545
93
VME WEStation
(4 Disk, 2 CRTs, and
maximum VME Bus
load)
Westinghouse
4.8
749
2557
126
WEStationDT
Westinghouse
0.35
53
180
20" Color Monitor
130
444
27" Color Monitor
220
751
110
375
82
Monochrome Monitor
1.1
240
Membrane Keyboard
Westinghouse
0.1
24
Dot Matrix Printer
0.7-Operating
0.3-Standby
260-Operating
85-Standby
889-Operating
291-Standby
12
Line Printer
3.0-Operating
0.5-Standby
700-Operating 2394-Operating
68-Standby
232-Standby
46
Laser Printer
300-Operating 1024-Operating
85-Standby
290-Standby
22
Screen Copy Printer
180-Operating
50-Standby
Optical Disk Drive
30
614-Operating
171-Standby
8mm Magnetic Tape Unit
0.2
14 to 40
48 to 137
11
3.5" Floppy Disk Unit
0.1
14 to 40
48 to 137
11
1/4" Magnetic Tape Unit
0.1
14 to 40
48 to 137
11
* (VA) This figure can be used to calculate size of UPS if required for the system.
** (Watts) This figure can be used to calculate cooling requirements for the system.
M0-8005
A-8
Westinghouse Proprietary Class 2C
9/98
Table A-3. Typical Input Power Requirements for 230 VAC (Cont’d)
Steady State
Current
(Amps)
CD-ROM
0.4
PROM Programmer
Power
(VA)*
Steady State
Power Input
(Watts)**
Thermal
Dissipation
(BTUs/Hr)
80
40
65
0.2
60
205
8
Westnet Fiber Optic
Repeater
Westinghouse
0.15
25
86
40
Ethernet Fiber Optic
Repeater
Westinghouse
0.2
25
86
1
Device Description
Inrush
Current
(Amps)
* (VA) This figure can be used to calculate size of UPS if required for the system.
** (Watts) This figure can be used to calculate cooling requirements for the system.
9/98
A-9
Westinghouse Proprietary Class 2C
M0-8005
Table A-4. Weight and Dimensions
Description
Weight kg (lbs)1
Dimensions
H x W x D (mm)
Dimensions
H x W x D (inches)
386/486 DPU Cabinet
Westinghouse
190 to 260
(420 to 575)
2236x724x511
88x28.53x20.13
Multibus-based CIU Cabinet
with sides
Westinghouse
199 (440)
2236x724x511
88x28.53x20.13
VME WEStation (Small Desk)
Westinghouse
77 to 91
(170 to 200)
712x547x750
29.2x30x34
VME WEStation (Large Desk)
Westinghouse
136 to 148
(300 to 325)
712x1519x750
VME WEStation Cabinet
Westinghouse
318 to 364
(700 to 800)
223x724x1022
WEStationDT
Westinghouse
8.1 (18)
90x405.4x424.4
3.55x16.00x16.75
Membrane Keyboard
(Desktop)
Westinghouse
4.7 (10.3)
264x66.8x597
10.38x2.63x23.5
Westnet Fiber Optic Repeater
Westinghouse
12 (27)
413x616x208
16.3x24.3x8.2
Ethernet Fiber Optic Repeater
Westinghouse
6 (13)
448x483x168
17.7x19x6.62
Single-RTP Enclosure
Westinghouse
0.45 (1)
203x152x10
8x6x1.85
Highway tap panel enclosure
Westinghouse
8.1 (18)
337x616x210
13.25x24.25x8.25
Highway tap cabinet (32 taps)
Westinghouse
83.7 (185)
2236x724x511
88x28.53x20.13
–––
94x44.5x82.6
3.7x1.75x3.25
Ethernet transceiver
Westinghouse
29.2x60x34
88x28.53x40.26
1. Weight ranges reflect available hardware configurations.
M0-8005
A-10
Westinghouse Proprietary Class 2C
9/98
Table A-5. Temperature and Humidity
Description
Operating
Temp Deg C
Relative Humidity
% - Non-condensing
Storage
Temp Deg C
Operating
Storage
386/486 DPU Cabinet
Westinghouse
10 to 45
4 to 70
20 to 80
20 to 80
Multibus-based CIU
Cabinet
Westinghouse
10 to 45
4 to 70
20 to 80
20 to 80
VME WEStation
(all configurations)
Westinghouse
10 to 35
10 to 35
20 to 80
20 to 80
WEStationDT
Westinghouse
0 to 50
4 to 70
10 to 90
20 to 80
20" Color Monitor
10 to 40
-30 to 60
10 to 90
10 to 90
27" Color Monitor
5 to 45
-20 to 60
10 to 90
10 to 90
Monochrome Monitor
0 to 40
-40 to 65
10 to 90
10 to 90
Membrane Keyboard
Westinghouse
0 to 50
0 to 60
20 to 80
20 to 80
Dot Matrix Printer
5 to 40
-20 to 60
20 to 80
5 to 90
Line Printer
4 to 40
-40 to 71
15 to 90
5 to 95
Laser Printer
10 to 32.5
0 to 35
20 to 80
10 to 80
Screen Copy Printer
15 to 35
-20 to 60
20 to 80
20 to 80
Optical Disk Enclosure
5 to 30
-20 to 60
5 to 80
5 to 90
Optical Disk Drive
10 to 40
-40 to 60
5 to 90
5 to 95
8mm Magnetic Tape
Unit
10 to 40
-20 to 60
20 to 80
—
3.5" Floppy Disk Unit
0 to 40
-20 to 85
10 to 80
8 to 80
1/4" Magnetic Tape
Unit
0 to 40
-20 to 85
8 to 80
8 to 80
CD-ROM
10 to 40
-20 to 60
5 to 60
5 to 80
9/98
A-11
Westinghouse Proprietary Class 2C
M0-8005
Table A-5. Temperature and Humidity (Cont’d)
Description
Operating
Temp Deg C
Relative Humidity
% - Non-condensing
Storage
Temp Deg C
Operating
Storage
PROM Programmer
5 to 45
-20 to 60
0 to 90
0 to 90
Westnet Fiber Optic
Repeater
Westinghouse
0 to 45
0 to 70
10 to 90
10 to 90
Ethernet Fiber Optic
Repeater
Westinghouse
10 to 40
-30 to 65
10 to 90
10 to 90
Single-RTP Enclosure
Westinghouse
0 to 50
0 to 70
10 to 90
10 to 90
Highway tap panel
enclosure
Westinghouse
5 to 50
0 to 70
10 to 90
10 to 90
Highway tap cabinet
(32 taps)
Westinghouse
5 to 45
0 to 70
10 to 90
10 to 90
Ethernet transceiver
Westinghouse
5 to 55
-20 to 85
5 to 90
5 to 90
M0-8005
A-12
Westinghouse Proprietary Class 2C
9/98
Appendix B. Drop Cabinets
B-1. Overview
This appendix describes the physical configurations of WDPF drops. The following
configurations are standard:
• 386 DPU Cabinets (Section B-2).
• 486 DPU Cabinets (Section B-3).
• NEMA enclosures (Section B-4).
• WEStation Enclosures (Section B-5).
For each physical configuration, the following information is provided:
• Dimensions.
• Recommended access area.
• Ground strip location, if applicable.
• Cable entry location(s).
• Floor bolt locations, if applicable.
9/98
B-1
Westinghouse Proprietary Class 2C
M0-8005
B-2. 386 DPU Cabinets
B-2. 386 DPU Cabinets
The following cabinet configurations are standard:
• Single cabinet (Figure B-1 through Figure B-3).
• Back-to-back cabinets (Figure B-4 through Figure B-6).
• Side-by-side cabinets (Figure B-7 through Figure B-9).
• Back-to-back/side-by-side cabinets (Figure B-10 and Figure B-11).
• Dual side-by-side cabinets (Figure B-12 and Figure B-13).
Note
These cabinets are not NEMA-rated. If NEMA
rating is required, use the optional NEMA-rated
enclosures, described in Section B-4.
Determine which configuration is to be used, and use the referenced illustrations.
The stud and wiring access locations shown are for reference only. Request outline
drawings from Westinghouse for locating mounting holes and wiring cutouts for
use in site construction.
Unless specified, all cabinets are manufactured with right-hand (left-hinge) doors.
If required, cabinet doors with left-hand (right-hinge) doors are available.
M0-8005
B-2
Westinghouse Proprietary Class 2C
9/98
B-2. 386 DPU Cabinets
724
(28.5)
Cable
Routing
Area
511
(20.12)
Nameplate
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
*Fan is required for cabinets which include Multibus cards.
Figure B-1. Single Cabinet - 386 DPU
9/98
B-3
Westinghouse Proprietary Class 2C
M0-8005
B-2. 386 DPU Cabinets
724
(28.5)
686
(27)
Recommended Access Area
914
(36)
686
(27)
Plan View of Cabinet
Height = 2235 (88)
511
(20.12)
Air Flow*
457
(18)
Ground Strip
Front
686
(27)
Recommended Access Area
914
(36)
*Air is input through the bottom vent
and exhausted from the top vent.
All dimensions in millimeters (inches).
Figure B-2. Plan View of Single Cabinet - 386 DPU
M0-8005
B-4
Westinghouse Proprietary Class 2C
9/98
B-2. 386 DPU Cabinets
Note: Bolt to extend 76 mm (3 in.) from floor.
Bolt Hole (4)
Location 0.687 Dia.
(1.745)
Typical Cable Entry Area
in top and bottom of cabinet
51
(2.0)
330
(13)
457
(18)
356
(14)
533
(21)
51
(2.0)
584
(23)
51
(2.0)
686
(27)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-3. Floor Bolt and Cable Entry Locations for Single Cabinet - 386 DPU
9/98
B-5
Westinghouse Proprietary Class 2C
M0-8005
B-2. 386 DPU Cabinets
724
(28.5)
Back
Half
Cable
Routing
Area
968
(38.12)
Front
Half
Nameplate
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
*Fan is required for cabinets which include Multibus cards.
Figure B-4. Back-to-Back Cabinet - 386 DPU
M0-8005
B-6
Westinghouse Proprietary Class 2C
9/98
B-2. 386 DPU Cabinets
724
(28.5)
686
(27)
Recommended Access Area
914
(36)
686
(27)
Plan View of Cabinet
Height = 2235 (88)
968
(38.12)
914
(36)
Air Flow*
Ground Strip
Front
686
(27)
Recommended Access Area
914
(36)
*Air is input through the bottom vent
and exhausted from the top vent.
All dimensions in millimeters (inches).
Figure B-5. Plan View of Back-to-Back Cabinets - 386 DPU
9/98
B-7
Westinghouse Proprietary Class 2C
M0-8005
B-2. 386 DPU Cabinets
Note: Bolt to extend 76 mm (3 in.) from floor.
Bolt Hole (8)
Location 0.687 Dia.
(1.745)
Typical Cable Entry Area
in top and bottom of cabinet
51
(2.0)
356
(14)
914
(36)
102
(4.0)
330
(13)
356
(14)
533
(21)
51
(2.0)
51
(2.0)
584
(23)
51
(2.0)
686
(27)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-6. Floor Bolt and Cable Entry Locations for Back-to-Back Cabinets - 386 DPU
M0-8005
B-8
Westinghouse Proprietary Class 2C
9/98
B-2. 386 DPU Cabinets
1409
(55.5)
Cable
Routing
Area
511
(20.12)
Cable
Routing
Area
Nameplate
Fan
(Optional)
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
*Fan is required for cabinets which include Multibus cards.
Figure B-7. Side-by-Side Cabinets - 386 DPU
9/98
B-9
Westinghouse Proprietary Class 2C
M0-8005
B-2. 386 DPU Cabinets
1409
(55.5)
1372
(54)
Recommended
Access Area
914
(36)
686
(27)
686
(27)
511
(20.12)
Plan View of Cabinet
Height = 2235 (88)
457
(18)
GS
GS
686
(27)
686
(27)
914
(36)
Recommended
Access Area
GS
= Ground Strip
= Air flow (air is input through the bottom vent
and exhausted from top vent.)
All dimensions in millimeters (inches).
Figure B-8. Plan View of Side-by-Side Cabinets - 386 DPU
M0-8005
B-10
Westinghouse Proprietary Class 2C
9/98
B-11
Westinghouse Proprietary Class 2C
Bolt hole location (8)
0.687 dia. (1.745)
Typical cable entry area in
top and bottom of cabinet.
51
(2)
457
(18)
330
(13)
356
(14)
533
(21)
51
(2)
102
(4)
51
(2)
584
(23)
584
(23)
51
(2)
1372
(54)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
B-2. 386 DPU Cabinets
M0-8005
Figure B-9. Floor Bolt and Cable Entry Locations for Side-by-Side Cabinets - 386 DPU
9/98
Note: Bolt to extend 76 mm (3 in.) from floor.
B-2. 386 DPU Cabinets
1409
(55.5)
1372
(54)
Recommended
Access Area
914
(36)
686
(27)
686
(27)
GS
GS
968
(38.12)
Plan View of Cabinet
Height = 2235 (88)
914
(36)
GS
GS
686
(27)
686
(27)
914
(36)
Recommended
Access Area
GS = Ground Strip
= Air flow (air is input through the bottom vent
and exhausted from top vent.)
All dimensions in millimeters (inches).
Figure B-10. Plan View of Back-to-Back/Side-by-Side Cabinets - 386 DPU
M0-8005
B-12
Westinghouse Proprietary Class 2C
9/98
B-2. 386 DPU Cabinets
914
(36)
51
(2)
356
(14)
51
(2)
356
(14)
102
(4)
51
(2)
584
(23)
1372
(54)
102
(4)
533
(21)
584
(23)
330
(13)
51
(2)
Typical cable entry area in
top and bottom of cabinet.
Bolt hole locations
0.687 dia. (1.745)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-11. Floor Bolt and Cable Entry Locations for Back-to-Back/Side-by-Side
Cabinets - 386 DPU
9/98
B-13
Westinghouse Proprietary Class 2C
M0-8005
B-2. 386 DPU Cabinets
Plan view of cabinet
Height = 2235 (88)
Recommended
Access Area
Recommended
Access Area
686
(27)
Typical
GS
2781
(109.50)
2743
(108)
GS
Front
Back
GS
686
(27)
Typical
GS
914
(36)
457
(18)
914
(36)
511
(20.12)
GS = Ground Strip
= Air flow (air is input through the bottom vent
and exhausted from the top vent.)
All dimensions in millimeters (inches).
Figure B-12. Plan View of Dual Side-by-Side Cabinets - 386 DPU
M0-8005
B-14
Westinghouse Proprietary Class 2C
9/98
B-2. 386 DPU Cabinets
51
(2)
Typical cable entry area in
top and bottom of cabinet.
584
(23)
102
(4)
584
(23)
Thickness = 64 (2.5)
2743
(108)
102
(4)
584
(23)
Bolt hole locations
0.687 dia. (1.745)
102
(4)
533
(21)
584
(23)
330
(13)
51
(2)
51
(2)
356
(14)
51
(2)
457
(18)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-13. Floor Bolt and Cable Entry Locations for Dual Side-by-Side Cabinets - 386 DPU
9/98
B-15
Westinghouse Proprietary Class 2C
M0-8005
B-3. 486 DPU Cabinets
B-3. 486 DPU Cabinets
The following cabinet configurations are standard:
• Single cabinet (Figure B-14 through Figure B-16).
• Back-to-back cabinets (Figure B-17 through Figure B-19).
• Side-by-side cabinets (Figure B-20 through Figure B-22).
• Back-to-back/side-by-side cabinets (Figure B-23 and Figure B-24).
• Dual side-by-side cabinets (Figure B-25 and Figure B-26).
Note
These cabinets are not NEMA-rated. If NEMA
rating is required, use the optional NEMA-rated
enclosures, described in Section B-4.
Determine which configuration is to be used, and use the referenced illustrations.
The stud and wiring access locations shown are for reference only. Request outline
drawings from Westinghouse for locating mounting holes and wiring cutouts for
use in site construction.
Unless specified, all cabinets are manufactured with right-hand (left-hinge) doors.
If required, cabinet doors with left-hand (right-hinge) doors are available.
M0-8005
B-16
Westinghouse Proprietary Class 2C
9/98
B-3. 486 DPU Cabinets
737
(29)
Cable
Routing
Area
562
(22.12)
Nameplate
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
*Fan is required for cabinets which include Multibus cards.
Grill adds 25 mm (1 inch) to depth to cabinet.
Figure B-14. Single Cabinet - 486 DPU
9/98
B-17
Westinghouse Proprietary Class 2C
M0-8005
B-3. 486 DPU Cabinets
737
(29)
686
(27)
Recommended Access Area
914
(36)
686
(27)
Plan View of Cabinet
Height = 2235 (88)
562
(22.12)
Air Flow*
457
(18)
Front
686
(27)
Recommended Access Area
914
(36)
*Air is input through the bottom vent
and exhausted from the top vent.
Fan is mounted on front door.
All dimensions in millimeters (inches).
Figure B-15. Plan View of Single Cabinet - 486 DPU
M0-8005
B-18
Westinghouse Proprietary Class 2C
9/98
B-3. 486 DPU Cabinets
Note: Bolt to extend 76 mm (3 in.) from floor.
Bolt Hole (4)
Location 0.687 Dia.
(1.745)
Typical Cable Entry Area
in top and bottom of cabinet
51
(2.0)
330
(13)
457
(18)
356
(14)
533
(21)
51
(2.0)
584
(23)
51
(2.0)
686
(27)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-16. Floor Bolt and Cable Entry Locations for Single Cabinet - 486 DPU
9/98
B-19
Westinghouse Proprietary Class 2C
M0-8005
B-3. 486 DPU Cabinets
737
(29)
Back
Half
Cable
Routing
Area
1019
(40.12)
Front
Half
Nameplate
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
*Fan is required for cabinets which include Multibus cards.
Grill adds 25 mm (1 inch) to depth to cabinet.
Figure B-17. Back-to-Back Cabinets - 486 DPU
M0-8005
B-20
Westinghouse Proprietary Class 2C
9/98
B-3. 486 DPU Cabinets
737
(29)
686
(27)
Recommended Access Area
914
(36)
686
(27)
Plan View of Cabinet
Height = 2235 (88)
1019
(40.12)
914
(36)
Air Flow*
Front
686
(27)
Recommended Access Area
914
(36)
*Air is input through the bottom vent
and exhausted from the top vent.
Fan is mounted on front door.
All dimensions in millimeters (inches).
Figure B-18. Plan View of Back-to-Back Cabinets - 486 DPU
9/98
B-21
Westinghouse Proprietary Class 2C
M0-8005
B-3. 486 DPU Cabinets
Note: Bolt to extend 76 mm (3 in.) from floor.
Bolt Hole (8)
Location 0.687 Dia.
(1.745)
Typical Cable Entry Area
in top and bottom of cabinet
51
(2.0)
356
(14)
914
(36)
102
(4.0)
330
(13)
356
(14)
533
(21)
51
(2.0)
51
(2.0)
584
(23)
51
(2.0)
686
(27)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-19. Floor Bolt and Cable Entry Locations for Back-to-Back Cabinets - 486 DPU
M0-8005
B-22
Westinghouse Proprietary Class 2C
9/98
B-3. 486 DPU Cabinets
1422
(56)
Cable
Routing
Area
562
(22.12)
Cable
Routing
Area
Nameplate
Fan
(Optional)
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
*Fan is required for cabinets which include Multibus cards.
Grill adds 25 mm (1 inch) to depth to cabinet.
Figure B-20. Side-by-Side Cabinets - 486 DPU
9/98
B-23
Westinghouse Proprietary Class 2C
M0-8005
B-3. 486 DPU Cabinets
1422
(56)
1372
(54)
Recommended
Access Area
914
(36)
686
(27)
686
(27)
562
(22.12)
Plan View of Cabinet
Height = 2235 (88)
457
(18)
686
(27)
686
(27)
914
(36)
Recommended
Access Area
*Air is input through the bottom vent
and exhausted from the top vent.
Fan is mounted on front door.
All dimensions in millimeters (inches).
Figure B-21. Plan View of Side-by-Side Cabinets - 486 DPU
M0-8005
B-24
Westinghouse Proprietary Class 2C
9/98
B-25
Westinghouse Proprietary Class 2C
Bolt hole location (8)
0.687 dia. (1.745)
Typical cable entry area in
top and bottom of cabinet.
51
(2)
457
(18)
330
(13)
356
(14)
533
(21)
51
(2)
102
(4)
51
(2)
584
(23)
584
(23)
51
(2)
1372
(54)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
B-3. 486 DPU Cabinets
M0-8005
Figure B-22. Floor Bolt and Cable Entry Locations for Side-by-Side Cabinets - 486 DPU
9/98
Note: Bolt to extend 76 mm (3 in.) from floor.
B-3. 486 DPU Cabinets
1422
(56)
1372
(54)
Recommended
Access Area
914
(36)
686
(27)
686
(27)
1019
(40.12)
Plan View of Cabinet
Height = 2235 (88)
914
(36)
686
(27)
686
(27)
914
(36)
Recommended
Access Area
*Air is input through the bottom vent
and exhausted from the top vent.
Fan is mounted on front door.
All dimensions in millimeters (inches).
Figure B-23. Plan View of Back-to-Back/Side-by-Side Cabinets - 486 DPU
M0-8005
B-26
Westinghouse Proprietary Class 2C
9/98
B-3. 486 DPU Cabinets
914
(36)
51
(2)
356
(14)
51
(2)
356
(14)
102
(4)
51
(2)
584
(23)
1372
(54)
102
(4)
533
(21)
584
(23)
330
(13)
51
(2)
Typical cable entry area in
top and bottom of cabinet.
Bolt hole locations
0.687 dia. (1.745)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-24. Floor Bolt and Cable Entry Locations for Back-to-Back/Side-by-Side
Cabinets - 486 DPU
9/98
B-27
Westinghouse Proprietary Class 2C
M0-8005
B-3. 486 DPU Cabinets
Plan view of cabinet
Height = 2235 (88)
Recommended
Access Area
Recommended
Access Area
686
(27)
Typical
2794
(110)
2743
(108)
Front
Back
686
(27)
Typical
914
(36)
457
(18)
914
(36)
562
(22.12)
*Air is input through the bottom vent
and exhausted from the top vent.
Fan is mounted on front door.
All dimensions in millimeters (inches).
Figure B-25. Plan View of Dual Side-by-Side Cabinets - 486 DPU
M0-8005
B-28
Westinghouse Proprietary Class 2C
9/98
B-3. 486 DPU Cabinets
51
(2)
Typical cable entry area in
top and bottom of cabinet.
584
(23)
102
(4)
584
(23)
Thickness = 64 (2.5)
2743
(108)
102
(4)
584
(23)
Bolt hole locations
0.687 dia. (1.745)
102
(4)
533
(21)
584
(23)
330
(13)
51
(2)
51
(2)
356
(14)
51
(2)
457
(18)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-26. Floor Bolt and Cable Entry Locations for Dual Side-by-Side Cabinets - 486 DPU
9/98
B-29
Westinghouse Proprietary Class 2C
M0-8005
B-4. NEMA Enclosures (Multibus-based Drops)
B-4. NEMA Enclosures (Multibus-based Drops)
The following heavy-duty cabinet enclosures are available:
• Two-door NEMA 4 cabinet (Figure B-27 and Figure B-28)
• Two-door NEMA 3R cabinet (Figure B-29 and Figure B-30)
• Four-door NEMA 3R cabinet (Figure B-31 and Figure B-32)
These cabinets are available for both 386 and 486 DPUs.
Note
The standard cabinets are not NEMA-rated.
When NEMA rating is required, use these
optional enclosures.
M0-8005
B-30
Westinghouse Proprietary Class 2C
9/98
B-4. NEMA Enclosures (Multibus-based Drops)
3/4" Eyebolts
with sealed nuts
1524
(60)
610
(24)
N
Removable
Center Post
2311
(91)
Opening
2438
(96)
102 x 432 (4 x 17) opening for
optional air conditioning.
13.34
(5.25)
Opening
51 x 51 x 6.4 (2 x 2 x 1/4)
angle for cabinet mounting
(both sides).
N = Nameplate (inside door)
All dimensions in millimeters (inches).
Figure B-27. Two-Door NEMA 4 Cabinet
9/98
B-31
Westinghouse Proprietary Class 2C
M0-8005
B-4. NEMA Enclosures (Multibus-based Drops)
Top and Bottom
of Cabinet
51
(2)
610
(24)
Plan view height of
cabinet = 2438 (96)
254 x 457 (10 x 18)
Opening
Cable Entry with
cover (gasketed).
254 x 457 (10 x 18)
Opening
Cable Entry with
cover (gasketed).
Opt.
Air
Cond.
483
(19)
387 (15.25)
762
(30)
Typical
762
(30)
Typical
1219
(48)
Recommended
Access Area
1524
(60)
All dimensions in millimeters (inches).
Figure B-28. Plan View of Two-Door NEMA 4 Cabinet
M0-8005
B-32
Westinghouse Proprietary Class 2C
9/98
B-4. NEMA Enclosures (Multibus-based Drops)
3/4" Eyebolts
with sealed nuts
1569
(61.8)
610
(24)
Dripshield
N
2311
(91)
Opening
2438
(96)
102 x 432 (4 x 17)
Openings for
optional air
conditioning.
1454
(57.25)
Opening
N = Nameplate (inside door)
All dimensions in millimeters (inches).
Figure B-29. Two-Door NEMA 3R Cabinet
9/98
B-33
Westinghouse Proprietary Class 2C
M0-8005
B-4. NEMA Enclosures (Multibus-based Drops)
Top and bottom
of cabinet
Plan view height of
cabinet = 2438 (96).
610
(24)
254 x 457 (10 x 18)
opening.
Cable entry with
cover (gasketed).
254 x 457 (10 x 18)
opening.
Cable entry with
cover (gasketed).
Opt.
Air
Cond.
483
(19)
264 (10.4)
762
(30)
762
(30)
1219
(48)
Recommended
Access Area
1569
(61.8)
All dimensions in millimeters (inches).
Figure B-30. Plan View of Two-Door NEMA 3R Cabinet
M0-8005
B-34
Westinghouse Proprietary Class 2C
9/98
B-4. NEMA Enclosures (Multibus-based Drops)
3/4" Eyebolts (4)
with sealed nuts
3139
(123)
736
(29)
736
(29)
736
(29)
736
(29)
N
610
(24)
N
2438
(96)
102 x 432 (4 x 17)
openings for
optional air
conditioning.
1455
(57.3)
Opening
1455
(57.3)
Opening
2306
(90.8)
Opening
2306
(90.8)
Opening
N = Nameplate (inside door)
All dimensions in millimeters (inches).
Figure B-31. Four-Door NEMA 3R Cabinet
9/98
B-35
Westinghouse Proprietary Class 2C
M0-8005
B-4. NEMA Enclosures (Multibus-based Drops)
483
(19)
Optional
Air Conditioning
Recommended
Access Area
264 (10.4)
Plan view
of cabinet.
Height = 2438 (96)
254 x 457
(10 x 18)
opening.
Cable entry
with cover
(gasketed).
3139
(123.6)
Top and
bottom of
cabinet
762
(30)
Typical
610
(24)
1219
(48)
All dimensions in millimeters (inches).
Figure B-32. Plan View of Four-Door NEMA 3R Cabinet
M0-8005
B-36
Westinghouse Proprietary Class 2C
9/98
B-5. WEStation Enclosures
B-5. WEStation Enclosures
Figure B-33 through Figure B-36 illustrate the VME WEStation Cube enclosure.
Figure B-37 through Figure B-39 depict the VME WEStation Rack-Mounted
enclosure.
9/98
B-37
Westinghouse Proprietary Class 2C
M0-8005
B-5. WEStation Enclosures
Cable Entry
Cabinet
Ground
Rear
Front
546
(21.5)
750
(29.6)
663
(26.1)
Without
Legs
Bolt locations
for table-top
mounting.
712
(28.1)
With
the
legs
533
(21)
Door
= Drop electronic hardware.
All dimensions in millimeters (inches).
Figure B-33. VME WEStation Cube
M0-8005
B-38
Westinghouse Proprietary Class 2C
9/98
B-5. WEStation Enclosures
25
(1)
1/4 - 20
Tapped
89
(3.5)
(4)
632
(24.88)
695
(27.38)
4
(0.625)
Bottom of Cube
Either the 1/4-20 tapped holes or the 0.625 holes can be used for floor bolting.
All dimensions in millimeters (inches).
Figure B-34. Floor Bolt Locations for VME WEStation Cube
9/98
B-39
Westinghouse Proprietary Class 2C
M0-8005
B-5. WEStation Enclosures
546
(21.5)
Recommended
Access Area
584
(23)
533
(21.0)
Cable Entry
On Bottom*
127 (5.0) x 133 (5.25)
750
(29.6)
76
(3.0)
127
(5.0)
Cut Out
133
(5.25)
Bottom
28
(1.1)
* Bottom is approximately 51 mm (2 in.) from the floor surface.
** Cut Out for cable entry is 127 (5.0) x 133 (5.25).
*** Bottom of workstation enclosure is grated for air circulation (Do Not Block).
All dimensions in millimeters (inches).
Figure B-35. Plan View and Cable Entry Locations for WEStation Cube
M0-8005
B-40
Westinghouse Proprietary Class 2C
9/98
B-5. WEStation Enclosures
(4)
0.281 x 0.500
oblong round
669
(26.35)
360
(14.17)
474
(18.69)
38
(1.5)
(2)
0.281 dia.
51
(2)
Top of Workstation Enclosure
All dimensions in millimeters (inches).
Figure B-36. Bolt Locations for Table-Top Mounting (WEStation Cube)
9/98
B-41
Westinghouse Proprietary Class 2C
M0-8005
B-5. WEStation Enclosures
737
(29)
Cable
Routing
Area
1019
(40.12)
Nameplate
2235
(88.0)
Front
Fan
(Optional)*
= Drop Electronic Hardware
All dimensions in millimeters (inches).
Dimensions include doors and side panels.
Figure B-37. VME WEStation Rack-Mounted Enclosure
M0-8005
B-42
Westinghouse Proprietary Class 2C
9/98
B-5. WEStation Enclosures
737
(29)
686
(27)
Recommended Access Area
914
(36)
686
(27)
Plan View of Cabinet
Height = 2235 (88)
1019
(40.12)
914
(36)
Air Flow*
Ground Strip
Front
686
(27)
Recommended Access Area
914
(36)
*Air is input through the bottom vent
and exhausted from the top vent.
All dimensions in millimeters (inches).
Figure B-38. Plan View of VME WEStation Rack-Mounted Enclosure
9/98
B-43
Westinghouse Proprietary Class 2C
M0-8005
B-5. WEStation Enclosures
Note: Bolt to extend 76 mm (3 in.) from floor.
Bolt Hole (8)
Location 0.687 Dia.
(1.745)
Typical Cable Entry Area
in top and bottom of cabinet
51
(2.0)
356
(14)
914
(36)
102
(4.0)
330
(13)
356
(14)
533
(21)
51
(2.0)
51
(2.0)
584
(23)
51
(2.0)
686
(27)
Dimensions do not include doors and side panels.
All dimensions in millimeters (inches).
Figure B-39. Floor Bolt and Cable Entry Locations for VME WEStation Rack-Mounted
Enclosure
M0-8005
B-44
Westinghouse Proprietary Class 2C
9/98
Index
A
Administration Tool 3-40
air export shipments 2-3
alarm panel 3-18
C
cabling conventions 2-10
card handling precautions 3-13
Clock Interface Unit (CIU) 1-1
multibus-based 6-36
WEStation 3-12
CONFIG.SHC file 4-7, 6-3
CRT monitors
availabe types 3-16
D
Data Highway Controller (DHC) 4-2
delicate component shipping 2-4
Distributed Processing Unit (DPU)
386 configurations 5-3
486 configurations 5-25
cabinet configurations (386 DPUs) B-2
cabinet configurations (486 DPU) B-16
cabinets 5-2
power supplies 6-28
power, ground, and signal wiring (386
DPUs) 5-6
power, ground, and signal wiring (486 DPU)
5-27
power-up procedure 6-23
pre-power-up procedure 6-10
drop and cabling identification
cabling convention 2-10
determining input voltage 2-10
drop identification nameplate 2-9
E
EHS (Ethernet Highway Switch) card 3-12,
6-4
VME address switch settings 6-8
electrical specifications A-1
environmental specifications A-1
F
Field Mounted Controller (FMC) 5-37
9/98
Index-1
Westinghouse Proprietary Class 2C
M0-8005
Index
G
O
Gbus 4-2
interface board (SGI) 4-5
interface cable 4-5
GHC card 3-12, 4-10
jumper settings 4-10
graphics cards
GX graphics card 3-10
monochrome monitor Sbus card 3-10
TGX graphics card 3-10
GX graphics card 3-10
ocean export shipping 2-4
off-loading and unpacking guidelines 2-5
P
H
hoisting 2-4
I
input voltage 2-10
See Appendix A
installing equipment at permanent site
general guidelines 2-11
multibus-based drop cabinets 2-13
NEMA enclosures 2-13
rack-mounted VME WEStation cabinets 213
VME WEStation cube 2-12
wiring access and ground connections 2-14
IOP cards 5-2
K
keyboard 3-18
M
MBU card 6-11
MDX card 6-13
LED patterns 6-26
membrane keyboard 3-18
MHC card
LED patterns 6-24
MHR card
LED patterns 6-24
Monochrome Sbus card 3-10
mouse 3-18
MSE card 6-15
MSM card 6-17
MSX card 6-18
connector locations 6-22
LED patterns 6-27
removing and installing 6-20, 6-21
M0-8005
parallel port cards
Aurora 10SJ 3-10
Sun parallel port interface 3-10
peripherals
CRT monitors 3-16
printers 3-21
PROM programmer 3-57
storage devices 3-48
user input devices 3-18
power supplies
386 DPU (Enhanced) 6-30
386 DPU (standard) 6-28
486 DPU 6-33
power wiring
multibus-based drops 2-15
peripheral connections 2-22
WEStation drops (cube) 2-20
WEStation drops (rack-mount) 2-19
printers
availabe types 3-21
connectors (screen copy) 3-24
connectors (serial devices) 3-23
EPSON 2550 configuration 3-26
Genicom 1040 configuration 3-28
Genicom 1220 configuration 3-32
Genicom 4440XT configuration 3-25
H/P 1200C/PS configuration 3-41
H/P Laserjet 4M/4M+ configuration 3-35
H/P Laserjet III configuration 3-34
Tektronix 220i configuration 3-39
Tektronix Phaser IIDX (4694) configuration
3-37
using Administration Tool 3-42
processor board options 3-10
PROM programmer 3-57
Q
Q-Line I/O 5-2
R
reference documents 1-4
repacking for return shipment guidelines 2-6
Index-2
Westinghouse Proprietary Class 2C
9/98
Index
S
Sbus to Gbus Interface (SGI) 4-5
installation 4-8
SCSI host adapter cards 3-10
SCSI serial port expansion option 3-14
hardware and software configuration 3-14
serial port connectors/device names 3-15
SHC card 3-12
shipping guidelines
air export shipping 2-3
delicate component shipping 2-4
general shipping 2-2
hoisting 2-4
ocean export shipping 2-4
off-loading and unpacking 2-5
repacking for return shipment 2-6
tilting 2-6
transporting 2-6
SIMs (Serial Interface Modules) 5-2
storage devices
available types 3-48
connections to SCSI bus 3-48
hardware configuration 3-56
software configuation (3.5 in. floppy disk)
3-56
software configuration (optical disk) 3-56
storage guidelines 2-7
Sun 4600MP card 3-9, 6-4
T
TGX graphics card 3-10, 3-16, 3-17
tilting a drop 2-6
trackball 3-18
transporting guidelines 2-6
TrueTime card 3-12, 6-4
TrueTime card (GPS-VME)
jumper settings 6-6
U
UNIX Printer Manager
icon 3-43
local printer settings 3-46
unmouse touchpad 3-18
user input devices
available types 3-18
connectors 3-19
9/98
Index-3
Westinghouse Proprietary Class 2C
M0-8005
Index
V
VME address 6-8
VME WEStation
AC Distribution Panel Assembly 3-8
AC Input Box 3-8
base configuration 3-8
cards 3-9
chassis 3-9
fan panel assembly 3-9
power distribution tray 3-8
W
WEStation base configuration 3-8
WEStation drop (VME based)
start-up procedures 6-2
WEStation enclosures 3-2
WEStation hardware configurations
Combined Engineering WEStation/Software
Server 3-61
Combined HSR/Logger 3-65
Computational Server WEStation 3-67
Engineering WEStation 3-59
Historian WEStation (HSR) 3-64
Log Server WEStation 3-63
Operator WEStation 3-62
Relational Database Server 3-67, 3-68
Stand-alone HSR/Logger 3-66
WEStation Software Server 3-60
WEStationDT
disconnectiong Data Highway cables 4-16
hardware requirements 4-3
power up and operation status 4-18
software requirements 4-7
status indicator descriptions 4-19
status indicators 4-18
WEStationDT hardware
Data Highway adapter cables 4-6
Gbus interface cable 4-5
SGI board 4-5
transition panel 4-6
WEStationDT installation
Data Highway cable adapters 4-15
enclosure 4-10
M0-8005
Index-4
Westinghouse Proprietary Class 2C
9/98