Vanguard Managed Solutions Vanguard 6500PLUS Installation Manual
Notice ©2002 Vanguard Managed Solutions, LLC 575 West Street Mansfield, Massachusetts 02048 (508) 261-4000 All rights reserved Printed in U.S.A. Restricted Rights Notification for U.S. Government Users The software (including firmware) addressed in this manual is provided to the U.S.
Notice (continued) Proprietary Material Information and software in this document are proprietary to Vanguard Managed Solutions (or its Suppliers) and without the express prior permission of an officer of VanguardMS, may not be copied, reproduced, disclosed to others, published, or used, in whole or in part, for any purpose other than that for which it is being made available. Use of software described in this document is subject to the terms and conditions of the VanguardMS Software License Agreement.
Contents About This Manual Chapter 1. About the 6500PLUS Software Features ......................................................................................... Hardware ...................................................................................................... Enclosures and Backplanes ...................................................................... 6500PLUS Processor Cards ..................................................................... 6500PLUS Auxiliary Processor Cards .......
Contents (continued) Chapter 2 Installation (Continued) Installing Software Options .......................................................................... Accessing Node Serial Number from Node Statistics ............................. Enabling A Software Access Key ............................................................ Installing New Software Options in an Existing Network ....................... Enhanced LAN Option .............................................................................
About This Manual Overview Introduction This manual describes features, hardware, specifications, and applications for the 6500PLUS. Note For information on operating system software and configuration, see the Vanguard Basics Manual. Audience This manual is intended for operators of the 6500PLUS. How To Use This Manual The following table describes the contents of this manual. This Chapter...
About This Manual (continued) Special Notices The following notices emphasize certain information in the manual. Each serves a special purpose and is displayed in the format shown: special purpose and is displayed in the format shown: Note Note is used to emphasize any significant information. Caution Caution provides you with information that, if not followed, can result in damage to software, hardware, or data.
Chapter 1 About the 6500PLUS Overview Introduction About the 6500PLUS The 6500PLUS is a family of networking devices that can operate in private networks or over public data networks. A 6500PLUS node can have from 6 to 54 ports, with terminal port speeds of up to 38.4 kbps and network port speeds of up to 384 kbps.
Software Features Software Features Introduction You can configure, administer, and troubleshoot a 6500PLUS node from a local or remote terminal acting as a control terminal. The terminal calls into the node's Control Terminal Port (CTP), a software module that acts as the logical control terminal port. In addition, configurations can be saved and restored when a PC (with Kermit protocol) is used as the local or remote control terminal.
Hardware Hardware Introduction A 6500PLUS node consists of at least one processor card, one or more optional support cards, and, optionally, a TRIM card. A node can be contained in a standalone enclosure, which can support only a processor card, or in a Modulus nest enclosure, which can support one or more processor cards and several support cards.
Hardware Enclosures and Backplanes Introduction The two types of enclosures for the 6500PLUS are: • Standalone • Modulus Standalone Enclosure A standalone enclosure (Figure 1-1) holds just one card, which must be a processor card. A standalone unit supports up to six X.25 or terminal ports depending on the type of processor card installed. Figure 1-1.
Hardware Supports Other VanguardMS Products A Modulus enclosure contains plug-in card versions of VanguardMS products, including Network Access Products, providing common housing and power to multiple products. A single Modulus enclosure can include, for example, 35xx DSU/ CSUs, 326x dial modems, or 33xx leased-line modems in addition to 65xx nodes. Types of Modulus Enclosures There are four types of Modulus enclosures.
Hardware 6500PLUS Processor Cards Introduction The 6500PLUS processor card provides the main processing power in a 6500PLUS node. There are three types of processor cards: • 6505PLUS Asynchronous Access Server • 6507PLUS Multifunctional Access Server • 6525PLUS Network Concentrator Description 6500PLUS processor cards are shipped with Single Inline Memory Modules (SIMMs) in sockets U79 and U80. The processor card cannot operate without SIMMs. Each processor card has six ports.
Hardware 6525PLUS Network Concentrator A 6525PLUS is a multifunction/multiprotocol packet assembler/disassembler (PAD) and X.25 switch. If your node is based on the 6525, you can: • Have up to nine 6525PLUS processor cards in a node. • Have a maximum number of 54 ports per node (combination of processor cards, AIO, or UIO cards). • Have a maximum number of 54 network ports per node. • Have a maximum number of 53 DTE ports per node. • Configure any or all ports as X.
Hardware Processor Card Figure 1-3 shows the front panel display for the processor card. From the front panel, you can reset the card, test the lights, and monitor data transmissions by observing the lights. Physically, the processor cards are identical. The ID Module of each processor card (located in socket U40) is unique and provides the functions specific to each type of processor card.
Hardware Optional FLASH Module Optionally, a FLASH memory module can be attached to a processor card to provide software distribution and software download capabilities. This optional daughtercard contains up to 3 Mbytes of nonvolatile FLASH memory and is used for remote software distribution and software download.
Hardware 6500PLUS Auxiliary Processor Cards Introduction 6500PLUS auxiliary processor cards increase throughput for 6507PLUS and 6525PLUS nodes. They provide additional processing power, as well as six additional ports. Description A 6500PLUS auxiliary processor card is a 6507PLUS or 6525PLUS processor card without a FLASH module, meaning that the card lacks software storage capabilities. Optionally, you can purchase a FLASH module for a 6500PLUS auxiliary processor card for downloading software.
Hardware 6500PLUS Asynchronous and Universal I/O Cards Introduction Two types of I/O cards are: • Asynchronous I/O (AIO) • Universal I/O (UIO) AIO Card You can use an AIO card with all 6500PLUS processor cards. It provides six asynchronous ports that can be configured as PAD ports. This card supports PAD port speeds from 50 to 19200 bps and split speed operation (75 bps inbound and 1200 bps outbound) on all ports. UIO Card You can use a UIO card with 6507PLUS and 6525PLUS cards.
Hardware Front Panel Display Figure 1-4 shows the front panel display, which is the same for both types of I/O cards. . 6500 I/0 TEST (Red) Indicates status and result of test affecting any part of node. Tests can be locally or remotely initiated.
Hardware 6500PLUS Network Storage Option Card Introduction The 6500PLUS network storage option (NSO) card expands basic node memory for support of large packet sizes. NSO Card Description The NSO card has a 3.5-inch high-density floppy disk drive with a storage capacity of 1.4 Mbytes (MS-DOS–formatted disks). The disk drive is used to download new and optional software to the node. The card contains 1 Mbyte of DRAM, which can be increased in 2-Mbyte increments to 5 Mbytes by inserting SIMMs.
Hardware NSO Card Figure 1-5 shows the NSO card. TEST (Red) Indicates status of internal tests. On: Test failed Off: Normal condition Flashing: Test in progress 6500 NSO TEST MEM (Yellow) Indicates amount of memory available on this card MEM 1: 1 Mbyte RAM MEM 3: 3 Mbyte RAM MEM1 MEM3 MEM5 MEM 5: 5 Mbyte RAM DISK On when disk is being accessed. P.C. 68908 Figure 1-5.
Hardware 6500PLUS Token Ring Interface Module Option Introduction The Token Ring Interface Module (TRIM) card is an option card that lets you route LAN traffic through your network.
Hardware TRIM-Compatible Processor Card Upgrade 1-16 Not all 6500PLUS processor cards can support the TRIM card. A TRIM-compatible processor card has a “LAN COMPATIBLE” marking on the lower front panel (Figure 1-3). If your processor card does not have this marking, see your VanguardMS Sales representative to order a LAN-capable processor card.
Hardware 6500PLUS Integral DSU Introduction The 6500PLUS Integral DSU option is intended for use in installations requiring connection to a DDS interface, conforming to AT&T 62310 or ANSI T1E1.4/91-006, and running at a rate of 56 kbps. At present, this optional DSU interface is only available with VanguardMS 6500PLUS enclosures using a 25-pin D connector interface.
Chapter 2 Installation Overview Introduction This chapter contains installation procedures for: • 6500PLUS Series standalone enclosures • 6500PLUS processor card components • Software options A description of the processor front panel LED power-up sequence and software upgrade procedures are also included. This chapter also contains instructions for installing TRIM cards in Modulus enclosures.
Installing Standalone Units Installing Standalone Units Introduction This section explains how to set up a 6500PLUS standalone enclosure. When you receive the enclosure, it already contains a 6505PLUS, 6507PLUS, or 6525PLUS card. Unpacking Before you unpack the 6500 standalone enclosure, check the outside of the package. If the package is damaged, contact the shipping agent.
Installing Standalone Units Installation Procedure The standalone enclosure already contains a 6505PLUS, 6507PLUS, or 6525PLUS card. To install the unit, follow these steps: Step Action Description/Result 1 Place the unit at its designated site and plug the power cord into a suitable primary power source. 2 Switch on the power, located at the The front panel lights turn on rear of the unit. as described in the “Power-Up Verification” section on page 2-74.
Installing Standalone Units Replacing Processor Cards in Standalone Enclosures Introduction This section describes how to replace a 6500PLUS processor card in a standalone enclosure. Warning Before opening the enclosure, be sure that it is unplugged from the power source. Caution 6500PLUS cards and their components are sensitive to static discharge, which can damage components. Use proper handling and grounding precautions, including the use of an anti-static grounding strap, whenever you handle a card.
Installing Standalone Units Door Removal Figure 2-3 shows how to remove the door on the standalone enclosure. Front Door To remove door, separate mounting tabs from base and remove. Figure 2-3.
Installing Standalone Units Enclosure Resting on Cover Figure 2-4 shows the bottom of the standalone enclosure. Squeeze Plastic Locking Clip Locking Tab Slots Locking Tab Slots Figure 2-4.
Installing Standalone Units Locking Tabs Figure 2-5 shows how to release the tabs. Figure 2-5.
Installing Standalone Units Retaining Screws Figure 2-6 shows the retaining screws on the processor card. Backplane Front Spacer Panel Retaining Screw 6500PLUS Processor Card Standalone Base Figure 2-6. 6500PLUS Processor Card with Retaining Screw Procedure to Add a Follow these steps to add a processor card to the standalone enclosure: Replacement Card 2-26 Step Action 1 Carefully insert the replacement card into the backplane's connector.
Installing Standalone Units Step Installation Action 5 Take the enclosure cover and connect the power cable to the backplane connector. Be sure to align the keyed pin on the cable to the connector. 6 Align the enclosure cover and bottom, and press the two gently together. This requires alignment of the backplane and the locking tabs. Be sure that the cables are not pinched between the enclosure and metal parts. When all elements are correctly aligned, the locking tabs snap into place.
Installing Nodes in Modulus Enclosures Installing Nodes in Modulus Enclosures Introduction Installing 6500PLUS cards into Modulus enclosures is the same as installing any other type of Modulus product card. Additional Information For general information on setting up Modulus 8/18 enclosures, attaching product backplanes, inserting cards, and attaching front and rear filler panels to the enclosures, refer to the Modulus Planning and Installation Guide .
Installing Nodes in Modulus Enclosures Multiprocessor Nodes Introduction A node based on the 6507PLUS or the 6525PLUS processor card can contain more than one processor card to improve reliability and availability. The two processor cards provide backup support to each other. Multiprocessor Node Example Figure 2-7 shows a multiprocessor node where an enclosure is configured for two 6507PLUS or two 6525PLUS cards.
Installing Nodes in Modulus Enclosures Replacing Master Processor of Multi-Processor Node Introduction This section describes how to replace a failed master processor in a multiprocessor node without losing your configuration. Keeping the Original Node Configuration All processor cards in a node contain identical copies of CMEM.
Installing Nodes in Modulus Enclosures Installation 2-31
Installing Nodes in Modulus Enclosures Adding a Secondary 6500PLUS Processor with FLASH Introduction When adding another 6500PLUS processor card to a node, be sure that all processor cards are running the same software revision. 6500PLUS processor cards redistributed within a network may contain different revisions of software.
Installing Nodes in Modulus Enclosures Maintaining the Current Software Revision Follow these steps to add a processor card with FLASH memory to your node and download the current software revision to the new processor’s FLASH memory: Step Action 1 At the control terminal port, use the Node Statistics to confirm that the node is running software from RAM and that FLASH is enabled.
Installing Nodes in Modulus Enclosures Upgrading with Software From the New Processor Card 2-34 Follow these steps to ensure that the node’s configuration is not lost. If you do not follow this procedure, CMEM will be overwritten. Step Action 1 At the control terminal, use the Node Statistics to confirm that the node is running software from RAM and that FLASH is enabled. If FLASH is disabled, enable FLASH by doing the following: a) Select FLASH Memory from the Main menu b) Select Enable FLASH.
Installing Nodes in Modulus Enclosures Installing/Replacing Processor Cards Introduction You can insert and remove any 6500PLUS processor card from a powered-up Modulus nest without damage. Caution 6500PLUS cards and their components are sensitive to static discharge, which can damage components. Use proper handling and grounding precautions, including the use of an anti-static grounding strap, whenever you handle a card.
Installing Nodes in Modulus Enclosures Requirements for Installing a TRIM Card Introduction This section describes the requirements for installing a TRIM card. TRIM cards are suitable only in a Modulus enclosure and only with 6507PLUS and 6525PLUS cards. A 6500PLUS node can support only one TRIM card. Modulus 8 and Modulus 9 enclosures can support just one node containing a TRIM card. Modulus 18 and 21 enclosures can support up to three nodes containing TRIM cards.
Installing Nodes in Modulus Enclosures Modulus 8/18 Nests The TRIM card has its own backplane and attaches to the solder side of the 6500PLUS processor card. The TRIM card requires two Modulus slots. The TRIM filler panel for Modulus 8/18 nests is two slots wide as shown in Figure 2-8. 65xx 18-Port Backplane Rear View Attach backplane using a Phillips-head screwdriver.
Installing Nodes in Modulus Enclosures Guidelines for Installing a TRIM Card in a Modulus 8/18 Consider the following if you install a TRIM card in a Modulus 8/18 enclosure: Note Before you add a TRIM card to an existing node, be sure the enclosure has room for it as described above. To make space, you may need to rearrange cards and backplanes, which requires a node shutdown first. • A processor card with attached TRIM card requires four slots — two slots for the TRIM card and two for the processor card.
Installing Nodes in Modulus Enclosures Modulus 18 Figure 2-9 shows the TRIM card spacing in a Modulus 18 enclosure. TRIM Card Filler Panel 6500 Node 18-Port Backplane Modulus 18-Slot Nest Top View Slots 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 Note: 6500PLUS installed in leftmost position in Modulus 18. The TRIM card requires two slots for its backplane.
Installing Nodes in Modulus Enclosures Modulus 9/21 Nests The TRIM card has its own backplane and attaches to the solder side of the 6500PLUS processor card. The TRIM card requires two Modulus slots. The TRIM filler panel for Modulus 9/21 nests is one slot wide as shown in Figure 2-10.
Installing Nodes in Modulus Enclosures • To install a node with a TRIM card in the left-most position of a nest, attach the backplane at Slot 3 of the nest. Insert the TRIM/processor card into Slot 3. The TRIM card takes up Slot 2 and Slot 1 (the width of the card does not permit it to be installed in Slot 1). The TRIM card rear filler panel, which has cutouts for the LAN port connectors, covers the backplane in Slot 2; a standard Modulus 9/21 rear filler panel covers the back of Slot 1.
Installing Nodes in Modulus Enclosures TRIM Card in LeftMost Position Figure 2-11 shows the TRIM card in the left-most position of the Modulus 21 enclosure. Modulus 21-Slot Nest Top View Modulus 9/21 TRIM Card Filler Panel 6500 Node 54-Port Backplane Slots 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 Modulus 9/21 Filler Panel TRIM Card Front of Nest Modulus 9/21 Filler Panels Processor Card Note: TRIM card installed in left-most position in Modulus 21.
Installing Nodes in Modulus Enclosures TRIM Card Between Two Backplanes Figure 2-12 shows A TRIM card between two backplanes in Modulus 21. Modulus 21-Slot Nest Top View 9/21Trim Card Filler Panel 6500 Node 54-Port Backplane Slots 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 3360 Modem Backplane 3360 Modem Card TRIM Card 3360 Modem Front Panel Front Modulus 9/21 Filler Panels Figure 2-12.
Installing Nodes in Modulus Enclosures 2-44 Installation
Installing Nodes in Modulus Enclosures Installing and Connecting a TRIM Card Introduction This section describes how to install a TRIM card in a 6500PLUS node. Caution 6500PLUS cards and their components are sensitive to static discharge, which can damage components. Use proper handling and grounding precautions, including the use of an anti-static grounding strap, whenever you handle a card.
Installing Nodes in Modulus Enclosures Installing and Follow these steps to install and connect the TRIM card: Connecting a TRIM Card Step 2-46 Action PLUS 1 processor/TRIM card combination into the lowestInsert the 6500 numbered slot of the node backplane. You can insert the processor/TRIM card combination in a powered-on nest. However, power to other cards in the nest may be disturbed because of the inrush of current to the TRIM card.
Installing Nodes in Modulus Enclosures Attaching the TRIM Figure 2-13 shows the attachment of the TRIM card to the processor card. Card Trim Card Trim Card Standoff Interboard Connector System Header Pins Bottom of Card CPU Plus Board (Solder Side) Fastener Screw Place the 4 non-ferrite pins toward top of processor card. Ferrite Figure 2-13. Attaching the TRIM Card to the Processor Card Attaching the Cables Installation The LAN port is Port 55, regardless of how many active X.
Installing Nodes in Modulus Enclosures Removing/Replacing TRIM Cards Introduction This section describes the removal and replacement of TRIM cards. Caution 6500 cards and their components are sensitive to static discharge, which can damage components. Use proper handling and grounding precautions, including the use of an anti-static grounding strap, whenever you handle a card.
Installing Nodes in Modulus Enclosures Preparing Modulus Enclosures for RFI Suppression Introduction To meet FCC requirements, the Modulus 18 and Modulus 21 enclosures require special RFI suppression hardware. In the Modulus 18 enclosure, the RFI suppression scheme differs depending on whether a TRIM card is installed in the unit. Modulus 18 with TRIM Card Figure 2-14 shows a Modulus 18 enclosure with a TRIM card. It also shows the suppression screen that you need to install.
Installing Nodes in Modulus Enclosures Installing RFI Suppression Screen If you have a Modulus 18 enclosure and at least one TRIM card, follow these steps to install the RFI suppression screen shown in Figure 2-14, to meet FCC requirements: Step Modulus 18: RFI Suppression without a TRIM Card Action 1 Open the door of the enclosure. If the two RFI suppression straps have been installed, as shown in Figure 2-15, remove them.
Installing Nodes in Modulus Enclosures Modulus 18 With No Trim Card Figure 2-15 shows a Modulus 18 with no TRIM cards and the RFI suppression straps. 3 Align the top of strap so that screw hole is over bar, insert the screw, and tighten. 1 Remove a screw from the left and right power supplies. 4 Tighten the bottom screw. 2 Align the bottom of the strap so it is over the screw hole, insert the screw, and finger tighten. Figure 2-15.
Installing Nodes in Modulus Enclosures Modulus 21 and RFI Suppression Bar If you are installing a TRIM card in a Modulus 21 enclosure, add the RFI suppression bar as shown in Figure 2-16. The bar is notched to fit across the inside of the door. Modulus 21 Door (Inside View) RFI Suppression Bar This Side of Bar to Face Inside of Door Figure 2-16.
Starting Up the Node Starting Up the Node Introduction After you install the node in the enclosure, you can start up the node. Node Startup Follow these steps to start up the node: Installation Step Action Result/Description 1 Power up the Modulus enclosure by connecting the power cord to a suitable primary power source. The front panel lights of the processor card turn on as described in the DSU DIM Installation section.
Replacing Processor Card Components Replacing Processor Card Components You can upgrade and replace components on the 6500PLUS processor card. In both standalone and Modulus enclosures, you can: Introduction • • • • • • • Replace DIMs (data interface modules) Set jumpers on the port interface pins Install single in-line memory modules (SIMMs) Replace a FLASH module Replace the ID Module Replace PROMs Replace the CMEM chip Figure 2-17 shows the location of these components on a 6500PLUS processor card.
Replacing Processor Card Components Replacing DIMs Introduction There are two Data Interface Modules (DIMs) on a 6500PLUS processor card. Description Each DIM is a 64-pin, dual in-line module that can be repositioned so that Ports 1 or 2 act as either DCE or DTE ports. For most cases, the DIMs are positioned so the ports act as DCEs. One DIM corresponds to Port 1 and the other to Port 2 (Figure 2-18). While most 6500PLUS processor cards contain EIA 232-D DIMs, you can purchase DIMs that will support V.
Replacing Processor Card Components Example of DIM Removal Figure 2-18 shows DIM removal. Plastic DIM Removal Strap Front Panel Port 1 Port 2 DCE DTE Figure 2-18. DIM Removal New DIM Installation 2-56 If you install a new type of DIM on the 6500PLUS processor card, you may need to change the jumpers on the port interface jumper pins. Figure 2-19 shows the location of the pins on the card.
Replacing Processor Card Components Port 1 Figure 2-19 shows where the jumpers should be placed on the pins for various applications and enclosures. Port 2 Jumpers EIA 232 V.24 V.35, V.36, X.21 for Backplanes with 26-Pin DB26 Connectors V.35, V.36, X.21 for Standalone and Backplanes with 25-Pin DB25 Connectors Figure 2-19.
Replacing Processor Card Components Jumper Installation Figure 2-20 shows how to install the jumpers. Figure 2-20.
Replacing Processor Card Components Installing SIMMs Introduction Guidelines Installation Procedure The 6500PLUS processor card comes with 3 Mbytes of RAM on the card. You can add additional RAM for a total of 5 Mbytes per 6500PLUS processor card. Figure 2-17 shows the location of the SIMM slots on the 6500PLUS processor card. • Install SIMMs in pairs only. • The 6500PLUS processor card is shipped with SIMMs in sockets U79 and U80. Install additional SIMMs in sockets U81 and U82.
Replacing Processor Card Components Example of SIMM Installation Figure 2-21 shows how a SIMM is installed in a slot. Insert SIMM into socket at a slight angle. Figure 2-21.
Replacing Processor Card Components Replacing FLASH Modules Introduction You can replace a FLASH module on a 6500PLUS processor card. The location of a FLASH module is shown in Figure 2-17. Caution Use proper handling and grounding precautions, including the use of an anti-static grounding strap, whenever you handle a card Replacement Procedure Follow these steps to replace a FLASH module (see Figure 2-22): Step 1 2 Installation Action Remove the card from the nest or enclosure.
Replacing Processor Card Components Installation Example Figure 2-22 shows an example of a FLASH module installation. FLASH Module Header Pins PROMs Card Socket Figure 2-22.
Replacing Processor Card Components Replacing ID Modules Replace the ID Module Perform these steps to replace the ID Module: Step Installation Action 1 Remove the card from the nest or enclosure. 2 Locate the ID Module (Figure 2-17) and note the location of the notch, which is toward the front of the card. This will help you orient the new chip. 3 Using a standard chip-puller, remove the ID Module. 4 Insert the new ID Module into the socket.
Replacing Processor Card Components Replacing PROM Chips Replace PROM Chips Follow these steps to replace a PROM chip: Step 2-64 Action 1 Remove the card from the nest or enclosure. 2 Loosen and remove the four screws that hold the FLASH module to the 6500PLUS processor card (Figure 2-22). 3 Carefully lift the FLASH module from the 6500PLUS processor card. You may have to wiggle the card until the header pins disengage from the socket. 4 Locate the PROMs as shown in Figure 2-22.
Replacing Processor Card Components Replacing the CMEM Chip Replace CMEM Chips Follow these steps to replace a CMEM chip: Step Installation Action 1 Remove the card from the nest or enclosure. 2 Locate the CMEM chip (Figure 2-17). On the CMEM chip, note the location of the dot in the lower left corner, which is toward the front of the card. This will help you orient the new chip. 3 Using a standard chip-puller, remove the CMEM chip. 4 Insert the new CMEM chip into the socket.
DSU DIM Installation DSU DIM Installation Introduction The DSU DIM is designed to be installed in the DTE position only. The DSU option will not operate if the DIM is installed in the DCE position. You can install up to two DSUs per platform using both ports 1 and 2. Example of Installing the DSU DIM Figure 2-23 shows the DSU DIM installation. DSU DIM Front Panel Port 1 DCE DTE DCE DTE Port 2 Figure 2-23.
DSU DIM Installation Installation Procedure Follow these steps to install the DSU DIM: Step Action 1 Install the DSU DIM in the DTE position only (see Figure 2-23). The DSU option does not operate if the DIM is installed in the DCE position. 2 Set the jumpers properly. This option requires the jumpers be set for the high speed 1 setting (M1/HS). This is the same jumper location listed for the V.35, V.36, and X.21 interfaces on standalone or Modulus 8/18 hardware.
DSU DIM Installation Configuring the 6500PLUS for DSU Operation Configuration Procedure You use the CTP to configure the DSU. Follow these steps to configure the 6500PLUS for DSU operation: Step 2-68 Action 1 Refer the Vanguard ONS Basics Protocols Manual (T0106).
DSU DIM Installation DSU Input and Output Signaling Introduction The input and output signaling information is useful as a debugging tool and replaces the EIA summary information associated with other DIM types. Input Signals This table describes the input signals. NIS Not In Service—This signal is normally low (L). If no signal is received, or the DSU option is in DSU Loopback mode, or if idle codes are received, NIS is listed as high (H).
DSU DIM Installation Other Reporting Differences Other differences in control terminal output are: Example of Diagnostics Menu Figure 2-24 shows the Diagnostics menu within the CTP in the control terminal. You use this menu to access the loopback options described in the next section. • Detailed Port Statistics— show DSU input and output signaling as well as note the installed DSU DIM • Detailed Node Statistics— show DSU DIM installation Node: nodename Menu: Diagnostics 1. 2. 3. 4. 5. 6. 7. 8. 9. 10.
DSU DIM Installation Troubleshooting DSU DIM Installation Introduction Some of the potential installation problems are listed below: • • • • • • • CTP Troubleshooting Installation Improper port connection of the EIM Improper telco interface connection DSU DIM not connected in DTE configuration Processor card jumpers not in HS1 mode DSU option software not operational DSU port clock source option not correct No signal from telco interface The following information can be derived from the control termin
DSU DIM Installation DSU DIM FCC Information Customer-Provided FCC regulations and telephone company procedures prohibit connection of Telephone customer-provided equipment to telephone company-provided coin service (central Equipment office-implemented systems). Connection to party lines is subject to state tariffs. Occasionally, the telephone company may make changes in their equipment, operations, or procedures.
DSU DIM Installation Operation of this equipment in a residential area is likely to cause interference in which case the user will be required to take adequate measures to correct the interference. This product was verified under test conditions that include use of shielded DTE cable(s). Leased line cables with 1.5 turns through a ferrite cylinder were also used. Use of different cables will invalidate verification and increase the risk of causing interference to radio and TV reception.
Power-Up Verification Power-Up Verification Introduction The front panel lights on the different 6500PLUS cards help you isolate a problem. These sections describe the light display when the enclosure is powered up. Normal Sequence The following list describes what you see on the front panel if the power-up sequence is performed correctly. • • • • • • POWER light comes on (processor and I/O cards). WATCHDOG light flashes briefly. TEST light flashes briefly. STATUS light comes on.
Power-Up Verification Power-Up Diagnostics In the event of major problems that affect the entire node, you can reboot a node to initiate the power-up diagnostics. After the power-up diagnostics are complete, check the Statistics screens to see the results To initiate power-up diagnostics, press the RESET button on the 6500PLUS processor card's front panel or issue a cold Node Boot from the control terminal.
Setting Node to Default Configuration Setting Node to Default Configuration Introduction You can set a node to the default configuration in two ways: • Set the DFLT switch on the front panel • Select the Default Node selection from the CTP Main menu Defaulting the Node Follow these steps to default the node using the DFLT switch: Step 2-76 Action 1 Push the DFLT switch to the left and press the RESET button.
Installing Software Options Installing Software Options Introduction The 6500PLUS contains all the software options available for the current release of the product. To access an option, however, you need to purchase the Software Authorization Key (SAK) for that option. Each option has its own SAK and each SAK can be used on only one specific node.
Installing Software Options Accessing Node Serial Number from Node Statistics Access Serial Number Perform these steps to find the SAK serial number using the Node Statistics: Step Action Result/Description 1 Access the CTP by entering the following at the * prompt: .ctp You are prompted to enter the password. 2 Enter the password. The default password is . After you enter the password, the Main menu appears. 3 From the Main menu, select Status/Statistics. 4 Select Node Stat.
Installing Software Options Node Stat Screen Figure 2-25 shows an example of the Node Stat screen. Serial Number Needed for SAK Node: Nodename Address: (blank) Detailed Node Statistics Date: -------- Time: -----Page: 3 of Board 1: Board Type: CPU+ Number of ports: 6 Serial #: 1806280 Memory Configuration: EPROM: 1.0 MBytes FLASH: 2.0 MBytes Flash Memory: Software: Port Configuration: Port 0 DIM: EIA-232-D Port 1 DIM: EIA-232-D 7 Status: Running DRAM: 1.
Installing Software Options Enabling A Software Access Key Follow These Steps... Follow these steps to enter the number at the node's control terminal: Step Action 1 Access the CTP. One way to do this is to connect a terminal to a local PAD port (Port 6), and enter the following at the * prompt: .ctp You are prompted to enter the password. 2 Enter the password. The default password is . After you enter the password, the Main menu appears. 3 From the Main menu, select Configure.
Installing Software Options Installing New Software Options in an Existing Network Install New Software Follow these steps if you are installing new software options in an existing network and you want to get the serial number for a remote node at a central site: Step Installation Action 1 Place a call to the CTP at a remote node. 2 Log in to the remote node. 3 Access the Node Stats and get the serial number. If you configure the key remotely, boot the node to activate the link.
Installing Software Options Enhanced LAN Option Enhanced LAN Option The Enhanced LAN Option is a Software Authorization Key (SAK) that enables IPX Routing and AppleTalk features for the 6520 and Vanguard 300, and provides IP Routing/SNMP for the 6500PLUS. What It Does for the 6520 and Vanguard 300 The Enhanced LAN Option enables IPX Routing and AppleTalk features for the 6520 and Vanguard 300, if present in the software image that is loaded.
Appendix A Cables Introduction The tables in this appendix describe the pinouts for ports on Standalone, Modulus 8/18, and Modulus 9/21 enclosures and include this information: • Standalone, Modulus 8/18, and 9/21 enclosures: EIA 232-D signals with V.24 DIMs on the processor card • Modulus 9/21 enclosures: V.35/V.36 signals with V.35/V.36 DIMs on the processor card • Modulus 9/21 enclosures: V.11 signals with X.21 DIMs on the processor card • Standalone and Modulus 8/18 enclosures: V.35/V.
EIA 232-D Signals (Standalone, Modulus 8/18, and 9/21 Enclosures) Pin DCE Position Function/Signal Name Pin DTE Position Function/Signal Name 1 --------------- Shield/Frame Ground 1 --------------- Shield/Frame Ground 2 <------------- TXD 2 -------------> TXD 3 -------------> RXD 3 <------------- RXD 4 <------------- RTS 4 -------------> RTS 5 -------------> CTS 5 <------------- CTS 6 -------------> DSR 6 <------------- DSR 7 --------------- Signal Ground 7 ----
V.35/V.
V.11 Signals (Modulus 9/21 Enclosures) Pin DCE Position V.
V.35/V.
V.11 Signals (Standalone and Modulus 8/18 Enclosures) Pin DCE Position 1 -------------- 2 <------------ 3 V.
P1 1 2 3 4 5 6 7 8 14 15 17 18 20 22 24 25 16 21 P2 1 3 2 8 14 20 7 4 5 18 24 15 6 25 17 22 21 16 Pin Function 1 Receive+ 6 Receive– 5 Transmit– 9 Transmit+ NOTE: All other pins are reserved and should remain unconnected. Pin Function 4 Receive+ 5 Receive– 3 Transmit– 6 Transmit+ NOTE: All other pins are reserved and should remain unconnected.
Appendix B Specifications Introduction This section describes the physical and environmental specifications and power requirements for the enclosures. Additional Information For more information about Modulus 8/18 enclosures, refer to the Modulus Planning and Installation Guide (Product Code 80300). For Modulus 9/21 enclosures, see the Modulus 9 and 21 Installation and Operation Guide (Part No. 09564, Rev. B).
Unit (continued) Modulus 21 Dimensions Height: 14.0 in. (35.6 cm) Width:17.8 in. (45.2 cm) Depth: 20.75 in. (52.7 cm) Weight (Empty): 48 lb (21.8 kg) Max Number of 6500 Series Product Cards: 9 Power Requirements Standalone Enclosure 100-240 VAC nominal, 47 to 63 Hz Modulus 8 100-120 VAC, 8.0 A, 50 to 60 Hz 220-240 VAC, 6.0A, 50 to 60 Hz Modulus 9 100-120 VAC, 5.0A, 50 to 60 Hz 220-240 VAC, 3.0A, 50 to 60 Hz Modulus 18 and Modulus 21 100-120 VAC, 10.0A maximum, 50 to 60 Hz 220-240 VAC, 6.
Index A F Audience i Auxiliary processor 1-10 Features control terminal support 1-2 FLASH module adding second processor wth 2-32 replacement 2-61 Front panel lights 2-74 B Backplane 1-5 BIA 1-15 updating 2-48 BPV bilpolar violation 2-69 Burned In Address. See BIA C Cnegative sealing current 2-69 C+ positive sealing current 2-69 Cable pinouts A-1 CL CSU loopback 2-69 CLK clock mode 2-69 Configuration clock source parameter 2-68 Control terminal 1-2 D Data Interface Modules.
M MAC address updating 2-48 Modulus 18 grounding straps 2-50 Modulus enclosures 1-4 backplanes 1-5, 2-43 card replacement 2-35 description 1-5 installation 1-5, 2-19, 2-28 spacing for TRIM card 2-37, 2-40 types of 1-5 Multifunctional access server 1-6 N Network Storage Option (NSO) card 1-13 NIS not in service 2-69 O Output signals CL 2-69 CLK 2-69 IDL 2-69 LL 2-69 RS 2-69 P Pinouts A-1 Port interface pins jumpering 2-56 Power requirements B-2 Power-up diagnostics 2-75 verification failure 2-74 Processor ca