Motorola 68436 - Vanguard 100I - Remote Access Server, 68471 - Vanguard 100 - Remote Access Server, Vanguard 100 PC Operator's Manual
Vanguard 100 PC Operator's Guide
Notice
1995 Motorola Inc.
20 Cabot Boulevard
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. Government under agreement which grants the government the minimum
"restricted rights" in the software, as defined in the Federal Acquisition
Regulation (FAR) or the Defense Federal Acquisition Regulation Supplement
(DFARS), whichever is applicable.
If the software is procured for use by the Department of Defense, the following
legend applies:
Restricted Rights Legend
Use, duplication, or disclosure by the Government is subject to restrictions as set
forth in subparagraph (c)(1)(ii) of the Rights in Technical Data and Computer
Software clause at DFARS 252.227-7013.
If the software is procured for use by any U.S. Government entity other than the
Department of Defense, the following notice applies:
Notice
Notwithstanding any other lease or license agreement that may pertain to, or
accompany the delivery of, this computer software, the rights of the Government
regarding its use, reproduction, and disclosure as set forth in FAR 52.227-19(C).
Unpublished - rights reserved under the copyright laws of the United States.
Proprietary Material
Information and software in this document are proprietary to Motorola Inc. (or its
Suppliers) and without the express prior permission of an officer of Motorola Inc.,
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 Motorola Software License Agreement.
This document is for information purposes only and is subject to change without
notice.
Radio Frequency Interference Regulations
This equipment has been tested and found to comply with the limits for a Class B
digital device, pursuant to Part 15 of the FCC Rules, CISPR 22 and EN 55022.
These limits are designed to provide reasonable protection against interference in
a residential installation. This equipment generates, uses, and can radiate radio
frequency energy and, if not installed and used in accordance with the
instructions, may cause harmful interference to radio communications. However,
there is no guarantee that interference will not occur in a particular installation. If
this equipment does cause harmful interference to radio or television reception,
which can be determined by turning the equipment off and on, the user is
encouraged to try to correct the interference by one or more of the following
measures:
• Reorient or relocate the receiving antenna.
• Increase the separation between the equipment and receiver.
• Connect the equipment into an outlet on a circuit different from that to
which the receiver is connected.
• Consult the dealer or an experienced radio/TV technician to help.
Changes or modifications not expressly approved by Motorola could void the
user's authority to operate the equipment.
This Class B digital apparatus meets all requirements of the Canadian
Interference-Causing Equipment Regulations.
This product was FCC certified under test conditions that included use of shield ed
data terminal equipment cables. Use of different cables will invalidate FCC
certification and increase the risk of causing interference to radio and TV
reception.
You can obtain the proper cables from Motorola.
Writer: Donna McLean
Project Editor: Susan L. Roswit
Publication Specialist: Denise Skinner
Illustrator: Tim Kinch
Manual is current for Release 4.50 of the 6500 Series Operating Software.
To comment on this manual, please send email to: LAM001@email.mot.com or use the
Customer Response Card located in this manual.
Internet Information
Additional company and product information can be found on our Internet Web
page at:
http://www.mot.com/MIMS/ISG/
Part No.: 09974, Rev A
Publication Code: RC
First Printing: Oct. 1995
Introduction
This manual describes installation and configuration of the Motorola Vanguard
100 PC Frame Relay Access Device (PC FRAD). This manual is intended for
persons who are installing and setting up the Motorola Vanguard 100 PC.
The Vanguard 100 PC provides all of the functionality of a Vanguard 100 Frame
Relay Access Device (FRAD), in a high -speed PC serial card that is installed in
your desktop PC.
Software Revision Level
The Vanguard 100 PC runs Release 4.50 or higher of Motorola 6500 Series
operating software.
Special Notices
The following notices emphasize certain information in the manual. Each serves a
special purpose and is displayed in the format shown:
IMPORTANT: Important is used to emphasize any significant procedural information.
Caution provides you with information that, if not followed, can result in
damage to software, hardware, or data.
About This Guide
Warning is the most serious notice, indicating that you can be physically hurt.
How To Use This Manual
Use the following table to help you find information in this manual on a particular
task or subject.
This section... Describes
Chapter 1 Audience definition, PC hardware and software
Chapter 2 Warnings and cautions, unpacking, DSU connection
Chapter 3 Optional DIM and Daughtercard hardware installation and
Chapter 4 PC COM software configuration, accessing the Control Port
Chapter 5 Sample applications and configurations.
Appendix A Specifications, including power and environmental
requirements, and an overview of Vanguard 100 PC features.
information, COM port and interrupt settings, Vanguard 100
PC board settings, and placing the Vanguard in your PC.
configuration.
to manipulate the Vanguard 100 PC, and saving and
downloading configurations.
requirements.
Appendix B Details of the sample configurations given in Chapter 5.
Related Documentation
The following documentation is not provided with the Motorola Vanguard 100
PC; it can be ordered separately. To acquire any of these sets of documentation,
refer to the following product codes:
Product Code Documentation Kit Includes:
17460 6500 Series Documentation
Kit
The printed documentation
set including:
6500 Series Introduction
Manual (Part No. 09871,
Rev D)
6500 Series Configuration
and Administration Manual
(Part No. 09873, Rev D)
6500 Installation Manual
(Part No. 09872, Rev E)
6520 Installation Manual
(Part No. 09901, Rev C)
17461 Documentation Change
Notices
Documentation for all
software releases since the
last printing of the main
documentation set.
17313 Multi-Product CD-ROM All 6500 Series
documentation and some
Vanguard user
documentation, as was
available at the time of
release.
6500 Series documentation is prepared using FrameMaker document publishing
software.
Additional Related Documentation
The following documents contain information related to the installation and
operation of 65xx and Vanguard platforms:
• The 6500 Series Options and Protocols Binder (Part No. 09950)
Vanguard Operator's Guides
• Vanguard 100 Operator's Guide (Part No. 09962, Rev A)
• Vanguard 200 Operator's Guide (Part No. 09968, Rev A)
• Vanguard 300/305 Operator's Guide (Part No. 09965, Rev B)
Software Download Guides
• 6520 Software Download Guide (Part No. 09901-6, Rev A)
• 6500 PLUS Software Download Guide (Part No. 09872-2, Rev A)
• Vanguard 100 Software Download Guide (Part No. 09962-2, Rev A)
• Vanguard 200 Software Download Guide (Part No. 09968-1, Rev A)
• Vanguard 300/305 Software Download Guide (Part No. 09965-1, Rev B)
Trademarks
The following are trademarks or registered trademarks of their respective
companies or organizations.
Crosstalk / Digital Communications Associates, Inc.
Pentium / Intel Corporation
ProComm / Datastorm Technologies, Inc.
Overview
The Motorola Vanguard 100 PC is a multi-protocol Frame Relay Access Device
(FRAD) housed on a PC serial card. It installs in a 16-bit ISA or VESA slot in
your Personal Computer, and allows you to connect your PC to a Frame Relay,
X.25, or ISDN network, as shown in Figure 0-1.
About the Vanguard 100 PC
The Vanguard 100 PC has all the functionality of a Vanguard 100, and uses the
same software images. However, the Vanguard 100 PC provides the following
benefits over the Vanguard 100:
• Built-in 16550 high-speed COM card
• Uses standard 16550 COM drivers and software packages
• Software upgrades are available for additional protocol support (via CD-
ROM or Internet Web Site)
• Plug-and-Play capability
• Port #1 daughtercards are available for DSU, DIM S ite, and ISDN
Figure 0-1. The Motorola Vanguard 100 PC
• Port #2 on-board DIM is available to support V.11, V.24, V.35, or V.36
DIMs
• Eliminates the RS232 cable by internally connecting Port #3 to your PC
COM port
• Eliminates the need for an external Frame Relay device, power supply,
and configuration terminal
The Vanguard 100 PC appears to the PC and communications software as if it
were a 16550 high-speed COM card.
Intended Audience
This manual is intended for those who are installing and configuring the
Vanguard 100 PC. It assumes that you are familiar with installing cards in your
PC and have an understanding of communications software in general.
PC Hardware and Software Requirements
The following hardware and software must be available before you install your
Vanguard 100 PC:
• An IBM or IBM Compatible PC (286, 386, 486, or Pentium) with an
unobstructed full card ISA or VESA slot
• A commercial communications software package (i.e., ProComm)
• A Frame Relay, X.25, or ISDN connection supplied by your service
provider
Features
The Motorola Vanguard 100 PC is a FLASH-based mono FRAD or duo FRAD
available with an optional integral DSU, ISDN U or S/T, or DIM Site
daughtercard. An optional second port can be used for Dial Backup or as another
user port.
Vanguard 100 PC Software
The Vanguard 100 PC has all the functionality of a Vanguard 100. All Vanguard
100 software images from Release 4.50 and higher will run on a Vanguard 100
PC.
All Vanguard 100 PCs are shipped with the Release 4.50 Toronto software
option preinstalled. This software includes the following operating feature set:
Software option... ...includes these protocols
Toronto
Source Filename: 450c17.xrc
Version String: V4.50-Toronto-
V100
Description Filename: 450c17.des
DSU Functionality
The DSU daughtercard provides a 56 kbps point-to-point DDS1 interface that
conforms to AT&T 62310 or ANSI T1E1.4/91-006.
The DSU is FCC Part 68 registered.
Diagnostic loopbacks from the telephone company are supported; local
diagnostics are activated from the Control Terminal Port (CTP) of the Vanguard
itself. See Chapter 4, Software Configuration and Control Port Access, for
information about accessing the CTP.
• Async PAD, Transparent Polled Async
• Frame Relay Interface (FRI)
• ISDN D Packet, Leased Line
• Point to Point Protocol (PPP)
• Serial Line Internet Protocol (SLIP)
• Simple Network Management Protocol
(SNMP)
• Switched Internet Protocol (SW-IP)
• Trivial File Transfer Protocol (TFTP)
• X.25 DCE/DTE
Port Characteristics
Vanguard 100 PC is available in two and three serial port versions. Ports have the
following characteristics.
Port Interface Connector Default Speed DTE/DCE
Daughtercard
1
DIM on
2
motherboard
Motherboard Internal Async ?115.2 kbps (async) N/A
3
DSU: RJ48S Frame Relay 56 kbps (sync) N/A
ISDN U/ST RJ45 Frame Relay 128 kbps N/A
DIM Site: DB25 Frame Relay V.24:
- ?80 kbps (sync)
- ?115.2 kbps (async)
V.35, V.11, or V.36:
- ?384 kbps int. clock
- ?1.54 Mbps ext. clock
DB25 Frame Relay V.24:
- ?80 kbps (sync)
- ?115.2 kbps (async)
V.35, V.11, or V.36:
- ?384 kbps int. clock
- ?1.54 Mbps ext. clock
Selectable
Selectable
The default node configuration is PPP on Port #3, and Frame Relay Bypass on
Ports #1 and #2. The PVC connection is to Port #1, if a daughtercard is installed,
or Port #2 if there is no optional daughtercard.
Note: To return the node to the default settings (default the node), you must do
the following:
Step Action
1 Power up the PC with the Vanguard 100 PC installed and wait 1 minute
for the node to initialize.
2 Enable the Default Node switch.
3 Press the reset button and allow the Vanguard 100 PC to reboot. Wait 1
minute for the node to initialize.
4 Disable the Default Node switch. The Node default is complete.
Memory
The board contains 1 Mbyte of FLASH memory and 2 Mbytes of DRAM.
Note: Memory is not upgradeable on a Vanguard 100 PC.
For More Information
For additional information, refer to the "Related Documentation" section in About
This Guide.
Overview
This chapter describes how to unpack your Motorola Vanguard 100 PC, order
your DSU connect ion, and install, test, and monitor the Vanguard 100 PC. If you
are installing any optional hardware components (DIMs or daughtercards), also
refer to the procedures in Chapte r 3, Optional Hardware Installation.
Warnings and Cautions
The following special notices apply to all equipment handling procedures in this
operator's guide.
Motorola Vanguard 100 PC daughtercards and DIMs are sensitive to static
discharge, which can damage components. You must use proper handling and
grounding precautions when handling a Motorola Vanguard 100 PC
daughtercard or DIM.
Ports capable of connecting to ports on other apparatus are defined as Safety
Extra Low Voltage (SELV). To conform with EN60950, ensure that these
ports are only connected to ports of the same type on other apparatus.
Les ports qui sont susceptibles d'être connectés a des équipements sont
désignés comme TBTS. Pour garantir la conformité à la norme EN 60950,
n'interconnecte ces ports qu'avec des ports du même type sur des autres
matériels.
Standard Hardware Installation
Anschlusse, die mit anderen Geraten verbindet werden konnen, sind als SELV
beschrieben. Um Konformitat mit EN 60950 zu versichern, sichern Sie es, daß
diese Anschlusse nur mit den des selben Type auf anderen Geraten verbindet
werden.
Lightning Protection
All Motorola Vanguard devices should be used in environments designed for
computers and electronic equipment. In areas susceptible to lightning, take
precautions to prevent damage to electronic equipment. Contact your telephone
company, or an electronic accessories vendor, fo r information on lightning
protection equipment.
Unpacking
Motorola Vanguard 100 PC is packaged in shock-absorbent packing material with
the contents shown in Figure 1-1 :
Figure 1-1. Unpacking the Vanguard 100 PC
When You Receive Your Vanguard 100 PC
Upon receipt of the Motorola Vanguard 100 PC, check the shipping carton and its
contents for damage. Then inventory the contents of the shipping container
against the diagram of parts shown in Figure 1-1.
In Case of Damage
If the equipment is damaged in transit, contact the shipper.
If you have additional concerns in case of failure, about missing parts, or to return
equipment, contact your nearest Motorola ISG representative.
To Return Equipment
For locations contact...
Inside the United States Motorola ISG Customer Administration
20 Cabot Blvd. Mansfield, MA 02048-1193
Phone (508) 261-4000, Ext. 4745
Outside the United States the nearest Motorola ISG distributor.
See "Motorola Information Systems Sales and
Service Offices" at the end of this guide for a list
of distributors.
FCC Part 68 and Telephone Company Procedures and Requirements
for DSU
Before the Motorola Vanguard 100 PC can be connected to the network, you
must:
• Provide the local telephone company with the equipment's DSU FCC Part
68 registration number, located on the mounting rail of the DSU
daughtercard (see Figure 1-2).
Figure 1-2. DSU FCC Part 68 Number
• Order the proper connections.
How To Order Connections
To order the proper connections, provide the telephone company with the
following information:
DSU FCC
Part 68
Interface
Type
Number
AT9USA22886-DD-N
56-kbps
digital
interface
Troubleshooting Your Connection
If any of your equipment is not operating correctly, immediately remove it from
the telephone line before it harms the network. If the telephone company notes the
problem, they may temporarily disconnect your service. They will notify you in
advance of the disconnection, when possible.
USOC Jack
Connector
Service Code Facility
Interface
Code
RJ48S 6.0F 04DU5-56
If advance notice is not feasible, you will be notified as soon as possible. When
you are notified, you will be given the chance to correct the problem and be
informed of your right to file a complaint with the FCC.
Customer-Provided Telephone Equipment
FCC regulations and telephone company procedures prohibit connection of
customer-provided equipment to telephone company-provided coin service
(central 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. If these changes affect your equipment or service, the
telephone company will provide written notice so you can make the necessary
changes to maintain uninterrupted service. Contact your telephone company if
you have any questions about your telephone line.
In some circumstances, the telephone company may ask you for information
about your equipment that is connected to the telephone line. Within the United
States (at the request of the telephone company), you should provide your
equipment's FCC registration number.
Note: This is a different number than the DSU FCC Part 68 registration number
discussed earlier. The FCC registration number is located on the surface of
the Vanguard 100 PC board.
DSU Telco Cable
The DSU telco cable is unshielded twisted-pair 19 to 26 AWG. The DSU cable is
shipped with the DSU daughtercard. The DSU cable has an RJ48S (keyed 8
position jack) and terminates in RJ48S plugs at both ends.
Pins Definition
1 and 2 TX
7 and 8 RX
Installing the Vanguard 100 PC
Installation of the Vanguard 100 PC requires opening and manipulating your PC
hardware. Exercise caution at all times when working with AC -powered
equipment. Turn off and unplug your PC before installation.
Static electricity discharge can severely damage your Vanguard 100 PC or
equipment. Discharge any static electric charge from your body by touching
any metal surface. It is also recommended that you attach a grounding strap,
or similar device, while you are working with the equipment. Please consult a
professional if you are uncertain about working with this equipment.
IMPORTANT: Before installation, consult the reference manual that came with your
computer to locate the PC's internal expansion slots. Read additional
information in the computer manual regarding specific instructions on
using the expansion slots before installation.
Step Action
1 If you will be running in Plug-and-Play mode (see the "ISA/Plug-and-
Play Mode" section on page -11), skip to Step 3. If you will be running
in ISA mode, determine a COM port and IRQ that is not already
assigned in your computer. This can be done using a hardware
diagnostics application such as MSDOS' MSD utility.
2 If you need to set a different COM and/or IRQ than the default,
reconfigure your Vanguard 100 PC according to the directions given in
the "COM Port and Interrupt Settings" section on page -12.
Note: The Vanguard 100 PC is shipped set to COM 4 and IRQ 3.
3 If you have ordered an optional DIM or daughtercard, install it on the
Vanguard 100 PC according to the directions given in Chapter 3,
Optional Hardware Installation.
4 Ensure that the Control Port (CP) switch on the Vanguard is set to the
ENABLED position to allow you to access the Control Port when the
PC starts up. (See Figure 1-8 for the location of this switch.) See
Chapter 4, Software Configuration and Control Port Access, for more
information about accessing your Control Port.
Note: This step is only necessary if the default configuration is different
from your desired configuration.
5 Turn off the computer and unplug it from the AC outlet.
6 Remove your computer's cover. (Refer to your PC User's Guide.)
7 Select any available, full and unobstructed ISA or VESA slot and
remove the blanking panel.
Note: If you have installed an optional daughtercard, you must install
the Vanguard 100 PC in 2 consecutive slots in the PC. Therefore, you
must remove the blanking panels from both slots, but the second ISA
connector will not be used.
8 Carefully slide the Vanguard 100 PC into the slot(s) you have chosen,
applying even pressure until the card is completely seated in the
connector and aligned in the slot (see Figure 1-3).
9 Fasten the back panel retaining bracket(s) to the PC chassis with the
screw(s) from the blanking panel(s).
10 Replace the computer cover and plug in your computer.
11. Turn your computer on
Jumper Locations
To change from ISA to Plug-and-Play mode, or to change the default COM port
or IRQ settings from the default to another setting, locate the jumpers on the
surface of your Vanguard 100 PC. (See Figure 1-4 for the location of the
jumpers.)
Figure 1-3. Seating the Vanguard 100 PC
ISA/Plug-and-Play Mode
Vanguard 100 PC supports Plug-and-Play capability. A set of jumpers on the
Vanguard 100 PC motherboard allows you to select between ISA and Plug-andPlay, as shown in Figure 1-5.
Figure 1-5. ISA/Plug-and-Play Jumper Settings
For Plug-and-Play to be in effect, the jumper must be set to PnP Mode, and you
must be running software on your PC that supports Plug-and-Play. Then the COM
and IRQ settings on the Vanguard 100 PC are ignored, and the PC software
determines the settings to configure the board.
Figure 1-4. Jumper Locations
If the jumper is in the ISA position, you must manually determine and set your
COM and IRQ settings, as described in the following section.
Note: If you are operating the Vanguard 100 PC in Plug-and Play mode, you
must move the IRQ jumper on the board into the "Not In Use" position, as
shown in Figure 2-6.
COM Port and Interrupt Settings
You can configure the Vanguard 100 PC to be COM 2, 3, 4, or 5. If your
computer is equipped with one or more COM ports, you may need to change the
COM port setting on the Vanguard 100 PC, or disable the PC's built-in COM port.
Most IBM compatible PCs contain two built-in ports for serial asynchronous
communication, known as COM 1 and COM 2. Most computers and software also
support COM 3 and COM 4. COM ports 3 and 4 are used whenever other devices
are using COM ports 1 and 2. COM 5 is not a standard COM port, but it can be
accessed with special software.
An IRQ (interrupt request) is a signal generated by an I/O device that notifies the
computer of incoming data. Your computer has many different IRQ lines, each
assigned a number. Your Vanguard 100 PC is capable of using IRQs 3,4, 5, 10,
11, and 15. I/O devices in your computer cannot share an IRQ with another
device at the same time. For example, your PC mouse and Vanguard 100 PC
cannot have the same IRQ setting.
The Vanguard 100 PC allows flexibility in choosing the COM port, I/O address,
and IRQ line. However, the common IRQ assignments for COM 2 to COM 5
ports are:
COM Port IRQ Addresses
2 3 02F8H
3 4 03E8H
4 3 02E8H
5 01A8H
Refer to your COM software documentation for additional information regarding
COM and IRQ settings and assignment information.
Use the shorting straps to set jumpers to the appropriate values as shown in
Figures 1-6 and 1-7. Note that an unused shorting strap should be stored on a
single post in the "Not in Use" position.
Figure 1-6. COM Port Jumper Settings
Note: Any time the COM or IRQ setting for the Vanguard 100 PC is changed,
the settings in the communications software must be changed to match.
Testing After Installat ion
To test your Vanguard 100 PC installation, you must be familiar with your
communications software. Ensure that the Vanguard 100 PC is in Control Port
(CP) mode by checking the switch on the Vanguard rear bracket. (See Figure 1-8
to locate the CP switch.)
Note: Whenever you change one of the rear bracket DIP switches, you must
press the reset button to allow the card to recognize the changes.
Rebooting the PC does not reset the Vanguard 100 PC.
The Vanguard 100 PC requires approximately 1 minute to boot after the power is
switched on. The Vanguard 100 PC is operational when the status LED is on
continuously (not flashing).
Load and start your communications software, and enter "terminal mode". Make
sure that the COM port and IRQ settings in the software are the same as the
settings on the Vanguard 100 PC. Press <CR>, and the Vanguard 100 PC should
respond with an asterisk prompt (*) or OK.
Figure 1-7. IRQ Jumper Settings
Monitoring Your Vanguard 100 PC
The Vanguard 100 PC bracket features six indicators (LEDs) that let you monitor
your equipment. It also features a 4-position DIP switch to allow control of the
various Vanguard 100 PC functions, and a reset button for card reinitialization.
A DIP switch is enabled when it is flipped towards the silk-screened lettering on
the bracket, and disabled when it is flipped away. Figure 1-8 shows the indicators
on the Vanguard 100 PC. In this figure, the enabled position is to the left, and
disabled is to the right. The switches are normally disabled during operation.
Legend for Figure 1-8
Figure 1-8. Vanguard 100 PC Rear Bracket
Item
Indicator Description
No.
¨ Control Port (CP) When enabled, overrides the stored configuration,
and sets port 3 (internal PC COM port) to 8 Bits,
No Parity, 1 Stop Bit async 9600 bps.
This will allow Control Port access via the .ctp
command (PAD) or ATDS0 command (ATPAD).
The software option installed will determine
whether port 3 is configured as a default PAD or
AT port.
¦ Diagnostic (DI) Used only for factory testing. This switch should
always remain disabled.
Æ Default Node (DN)
Used to reset all configurable parameters to default
value.
To default the node, you must:
Step Action
1 Power up the PC with the Vanguard 100
PC installed and wait 1 minute for the node
to initialize.
2 Enable the Default Node switch.
3 Press the reset button and allow the
Vanguard 100 PC to reboot. Wait 1 minute
for the node to initialize.
4 Disable the Default Node switch. The Node
default is complete.
Ø PC Control (PC) Enabled: Allows the PC to override the Vanguard
100 PC switches CP, DI, DN, and Reset button.
Disabled: Enables the CP, DI, DN switches and
Reset button.
Note: This mode requires additional software to
run on your PC, which is currently not available.
This switch should remain disabled.
×
Test (T) Indicates status of test results.
Enabled: Diagnostic Test Failed
Disabled: Normal Condition Flashing: Test in
Progress
±
Data Out (DO) Enabled: Data Leaving Port = SPACE
Disabled: Data Leaving Port = MARK
LEDs indicate Port 1 or 2.
Ð Data In (DI) Enabled: Data Entering Port = SPACE
Disabled: Data Leaving Port = MARK
LEDs indicate Port 1 or 2.
š Status (S) Enabled: Software Running
Disabled: Software Not Starting or Running
(Hardware Fault)
Flashing: Vanguard 100 PC booting, or software
download in progress
¥ Reset (R) Initiates reloading of the software and applications
Power-Up LED Sequence
There are 6 LEDs on the rear bracket of the Vanguard 100 PC. When you have
operational software installed, and press the Reset button or power cycle the PC,
the following power-up sequence occurs.
Stage when.. ...this indicates
1 All LEDs turn on for 1 second. the self-test is beginning.
stored in memory.
Note: Rebooting your PC will not reset the
Vanguard 100 PC.
2 The TEST LED blinks for
the hardware is being tested.
approximately 20 seconds.
3 All LEDs turn on for 1 second. software loading is beginning.
4 The STATUS LED blinks at a
slow rate (approximately 1 blink
the system software is being
loaded into DRAM from FLASH.
every 2 seconds) for
approximately 20 seconds.
5 All LEDs go off for
approximately 8 seconds.
the system software is reading the
configuration from configuration
memory and is initializing the
node.
6 The STATUS LED comes on and
remains on.
the node is operational and ready
to begin passing data.
A hardware problem has occurred if the following conditions exist:
Stage when... ...this indicates
1 TEST LED comes on and remains
on.
one or more of the diagnostics
tests failed.
2 Green STATUS LED blinks
continually at a rapid rate
(approximately 2 to 3 blinks per
second).
the FLASH no longer contains
valid system software, requiring
the load of new software into
FLASH. Use the coldload
procedure outlined in the software
release notice accompanying your
software.
Overview
This chapter describes the how to install any optional hardware components,
including DIMs and daughtercards, on your Vanguard 100 PC. After you have
installed the optional hardware, continue with the instructions in Chapter 2
regarding installation of the Vanguard 100 PC in your host computer.
Components on the Motorola Vanguard 100 PC Daughtercards and DIMs are
sensitive to static discharge. You must use proper handling and grounding
precautions when handling a Motorola Vanguard 100 PC daughtercard or
DIM.
Optional Hardware Components
Vanguard 100 PC optional components may include the following:
• Optional V.11, V.24, V.35, or V.36 DIM
• Optional DSU daughtercard
• Optional DIM Site daughtercard
• Optional ISDN daughtercard
Optional Hardware Installation
Serial/Network Ports
Vanguard 100 PC is available in 2 and 3 serial port versions. The first port,
located on an optional daughtercard, is defined by the type of daughtercard (DSU,
ISDN, etc.). The second port, located on the motherboard, is defined by the type
of DIM installed. The third port is internal to the PC, and connects to the PC's
COM port.
Adding or Replacing a DIM
Port 2 supports V.11, V.24, V.35, or V.36 DIMs, which are required for a
Vanguard 100 PC FRAD without a DSU daughtercard.
Before You Begin
You must power down the host PC and remove the Vanguard 100 PC. Any
installed daughtercard must be removed You must power down the host PC and
remove the Vanguard 100 PC. Any installed daughtercard must be removed
before you access and replace a DIM.
Note: DIMs fit very tightly into their sockets. Extreme care must be taken when
removing and replacing to ensure there is no damage to the DIM or the
Vanguard 100 PC.
Example of DIM Position
Figure 2-1 shows the DIM position on the Vanguard 100 PC.
DIP Switch Settings
Figure 2-1. DIM Position
The following sections describe DIP switch settings, which must be adjusted on
the Vanguard 100 PC depending on the DIM chosen for Port 2. Refer to Figure 2-
2.
For Set Switch To
V.24 DIM 1-5
6-8
9
(Note: Switch 9's only
function is Pin 22 Ring
indicator)
(Note: Switch 10's only
function is pin 25 Test
Mode indicator)
V.11, V.35,
V.36 DIMs
1-5
6-10
ON
OFF
V.24 DIM
Position
DCE
DTE
V.24 DIM
Position
DCE
DTE
OFF
ON
OUT (ON) IN (OFF)
output
input
input
input
OUT (ON) IN (OFF) 10
input
input
output
input
Figure 2-2. DIP Switch Settings
Adding or Replacing a Daughtercard
Four types of daughtercards can be added to your Vanguard 100 PC:
• DSU
• DIM Site
• ISDN U
• ISDN S/T
All four are installed in a similar manner, but may have specific requirements
before installation. After you read the following generic sections, read the section
for the specific daughtercard you wish to install before installing it on the
Vanguard 100 PC.
Rear View of Daughtercard Connectors
Figure 2-3 shows a rear view of daughtercard connectors as they appear on the
Vanguard back bracket.
Figure 2-3. Rear View of the Daughtercard Connectors
Additional Notes
To add a daughtercard to your Vanguard 100 PC, you must have two consecutive
slots available in your PC – one for the Vanguard 100 PC, and one for the
daughtercard. Figure 2-4 shows a Vanguard 100 PC with a daughtercard installed.
If you find that you cannot fit the Vanguard 100 PC, with the daughtercard
installed, into 2 consecutive slots in your PC, it is possible to install the
daughtercard on the back side of your Vanguard 100 PC. See "Placing the
Daughtercard on the Back Side of the Vanguard 100 PC" on page -12 for more
information.
Figure 2-4. Vanguard 100 PC with a Daughtercard Installe d
Daughtercard Installation Kit
The items shown in Figure 2-5 are enclosed in the Vanguard Daughtercard
package:
Figure 2-5. Daughtercard Installation Kit
Adding the Daughtercard Installation Rail
The rail on a daughtercard is not the same size as a st andard PC back panel rail,
and must be adapted to fit into the PC slot. Therefore, a special daughtercard
installation rail must be placed over the existing daughtercard rail, as shown in
Figure 2-6.
Figure 2-6. Adding the Daughtercard Installation Rail
Installing a Daughtercard on the Front Side of the Vanguard 100 PC
IMPORTANT: Power down the PC and remove the Vanguard 100 PC before you
replace any daughtercard.
Follow these procedures to add or replace a Vanguard 100 PC daughtercard on
the front side o f the Vanguard 100 PC.
Note: If you find that you cannot fit the Vanguard 100 PC, with the daughtercard
installed in the manner described here, into two consecutive slots in your
PC, it is possible to install the daughtercard on the back side of your
Vanguard 100 PC. See "Placing the Daughtercard on the Back Side of the
Vanguard 100 PC" on page -12 for more information.
Procedure to Add or Replace a Daughtercard on the Front Side of a Vanguard 100
PC
Step Action
1 Power down the PC and remove the Vanguard 100 PC before you add
or replace a daughtercard.
2 Attach the daughtercard rail to the new daughtercard using the two
screws that were shipped with the rail. (See Figure 2-6.)
3 If you are replacing an existing daughtercard, remove the daughtercard
mounting screw that attaches the daughtercard to the standoff on the
board, and remove the daughtercard from the Vanguard 100 PC,
leaving the interface header on the Vanguard 100 PC.
4 If you are adding a new daughtercard, connect the 68-pin interface
header onto the Vanguard 100 PC, and attach the standoff to the
Vanguard 100 PC using the screw that came with your daughtercard (as
shown in Figure 2-7).
5 Align the standoff on the motherboard with the hole on the
daughtercard, (as shown in Figure 2-7).
6 Push the daughtercard down onto the header connector, being careful to
align the pins.
7 Fasten the screw that attaches the daughtercard to the standoff on the
Vanguard 100 PC. Slide the Vanguard 100 PC and Daughtercard into
the two consecutive PC slots you have chosen, applying even pressure
until the Vanguard 100 PC is completely seated in the slot.
8 Fasten the PC chassis screws to the rear bracket of the Vanguard 100
PC and the daughtercard rail, and put the cover back on your PC.
9 Reconnect the interface and power cables; power on the PC.
Figure 2-7 shows how to add or replace a daughtercard.
Figure 2-7. Adding or Replacing a Daughtercard
Placing the Daughtercard on the Back Side of the Vanguard 100 PC
If you find that you cannot fit the Vanguard 100 PC, with the daughtercard
installed in the manner described above, into two consecutive slots in your PC, it
is possible to install the daughtercard on the back side of your Vanguard 100 PC
(see Figure 2-8).
Procedure to Add or Replace a Daughtercard on the Back Side of the Vanguard 100
PC
Step Action
1 Power down the PC and remove the Vanguard 100 PC before you add
or replace a daughtercard.
2 Attach the daughtercard rail to the new daughtercard using the two
screws that were shipped with the rail. (See Figure 2-6.)
3 If you are replacing an existing daughtercard, remove the daughtercard
mounting screw that attaches the daughtercard to the standoff on the
board, and remove the daughtercard from the Vanguard 100 PC.
Remove the interface header on the Vanguard 100 PC.
4 Insert the 68-pin interface header into the through-holes on the back
side of the Vanguard 100 PC, and push until the pins protrude through
the header, and the plastic support is flush with the back side of the
board.
5 Attach the standoff to the top of the daughtercard using the screw that
came with your daughtercard (as shown in Figure 2-8).
6 Align the standoff on the daughtercard with the hole on the Vanguard
100 PC, (as shown in Figure 2-8).
7 Push the daughtercard up onto the header connector, being careful to
align the pins.
8 Fasten the screw that attaches the Vanguard 100 PC to the standoff on
the daughtercard. Slide the Vanguard 100 PC and daughtercard into the
2 consecutive PC slots you have chosen, applying even pressure until
the Vanguard 100 PC is completely seated in the slot.
9 Fasten the PC chassis screws to the rear bracket of the Vanguard 100
PC and the daughtercard rail, and put the cover back on your PC.
10 Reconnect the interface and power cables; power on the PC.
Figure 2-8 illustrates how to place your daughtercard on the back side of the
Vanguard 100 PC.
Figure 2-8. Adding or Replacing a Daughtercard on the Back Side of the
Vanguard 100 PC
Adding or Replacing a DSU Daughtercard
The DSU daughtercard provides an RJ48S connector on Port 1 and comes
installed from the factory if you ordered a daughtercard. It supports speeds of 56
kbps (synchronous), and does not support multipoint.
DSU Functionality
The DSU daughtercard functionality suits an extended range of 56 kbps point-topoint DDS1 interfaces for North American service that conforms to AT&T 62310
or ANSI T1E1.4/91-006.
The DSU daughtercard is FCC Part 68 registered. The DSU normally uses
external clocking derived from the network. Diagnostic loopbacks from the
telephone company are supported; local diagnostics are activated from the CTP.
DSU Daughtercard
Figure 2-9 shows the DSU daughtercard.
DSU Configuration
The following configuration parameters are not applicable when configuring a
DSU option:
Figure 2-9. DSU Daughtercard
• Clock Speed
• Connection Type
• Port Control
To configure the Clock Source parameter as follows, refer to the "Accessing the
Port Configuration Menus" section in Chapter 4 on page 4-7.
Use To do this...
INT provide clock to the netwo rk.
EXT use the network-provided clock (usual mode for DSU operation).
DSU Reporting
CTP reporting of information differs for the DSU daughtercard in terms of input
signaling.
Use the CTP "Monitor" function from the Main menu to view these signals. "L"
stands for "Signal Low" and "H" is "Signal High".
Input Signal Value Displayed
NIS
(Not In Service)
BPV
(Bipolar Violation)
DL
(DSU Loopback)
C+
(Positive Sealing
Current)
Normally "L." Used to determine if the other end of
the connection is available.
If no signal is received, the DSU option is in DSU
loopback mode,
Or
If idle codes are received, NIS is "H."
An "L" means the DSU option has received a bipolar
violation.
An "H" is expected during normal operation.
Expected to toggle during a DSU loopback
condition.
Normally "H."
An "L" indicates entry into a DSU loopback mode.
"H" if the DC current on the telephone company
interface is not in the positive direction.
If both C+ and C- are "H", no sealing current exists,
which often occurs when connected to other DSU
type hardware.
C-
(Negative Sealing
Current)
CTP reporting of information for the DSU also differs in terms of output
signaling. Although these output signals are not directly accessible to the user, the
DSU option software manipulates these signals and may be useful for
informational purposes.
C+ would be expected to be "L" normally when
connected to central office equipment (OCU)
hardware.
"H" if the DC current on the telephone company
interface is not in the negative direction.
If both C+ and C- are "H", no sealing current exists,
which often occurs when connected to other DSU
type hardware.
C-and "L" would indicate a CSU loopback.
Use the CTP "Monitor" function from the Main menu to view these signals.
Input Signal Value Displayed
RS (Reset) Normal operating state is "H."
LL (Local Loopback) When "L", the DSU hardware is locally looping data
CL (CSU Loopback) When "L", the DSU hardware is looping the remote
IDL (Idle) An "H" informs the DSU hardware to send idle bipolar
CLK (Clock Mode) When "H", denotes network clock use.
Differences in CTP Statistics
CTP statistics output also differs in the following ways:
• Detailed Port Statistics show DSU input/output signaling, as well as
noting the installed DSU.
Resets the DSU option hardware.
back to the Vanguard hardware.
connection's receive to transmit.
violations to the remote system.
When "L", the DSU option provides the clock.
• Detailed Node Statistics show DSU installation.
CTP Loopback Modes
Two additional CTP loopback modes now exist.
Mode Function
DSU Internal
Loopback
DSU Internal and
External Loopback
DSU Troubleshooting
Use the following information to help troubleshoot installation problems.
Potential Installation Problems
Installation problems may include the following:
• Improper telephone company interface connection
Does not affect the external interface.
Loops the local transmit data back to the receive data.
Failure indicates no connection.
Performs the internal loopback by looping the external
transmit to the external receive to allow manual testing
of the remote interface.
• Incorrect DSU port Clock Source option
• No signal from telephone company interface
The following information may be derived from the CTP.
Function used to...
Node Statistics
• verify that the software is a version that contains the
DSU option modifications.
• show if the software recognizes the DSU.
Port Statistics
• ?verify that data is sent without error; error counts
may denote an error in clocking mode configuration.
• ?show if the software recognizes the DSU.
Monitor
• ?determine, via input/output signals, if the DSU
option is in a loopback mode requested by the
remote end (which would result in an inability to
send data); continuous bipolar violations indicate the
remote system is out of service.
DSU Internal
Loopback
• ?indicate a failure of this loopback mode, meaning a
connection has not been made.
Adding or Replacing a DIM Site Daughtercard
This section describes how to add or replace a DIM Site daughtercard.
The DIM Site daughtercard provides an optional V.24, V.35, V.36, or V.11
interface and attached DIM with a DB25 connector and comes installed from the
factory if you ordered one.
DIM Site Daughtercard
Figure 2-10 shows a DIM Site daughtercard.
Figure 2-10. DIM Site Daughtercard
Strapping the V.24 DIM Site Daughtercard
On the surface of the V.24 DIM Site daughtercard, there are 8 DIP switches and
two straps. The DIP switches are set at the factory for the particular DIM that is
installed on the daughtercard. The two straps are used only when the V.24 DIM is
installed.
The strapping on the V.24 DIM daughtercard typically comes configured from the
factory in Ring Indicator mode, which causes pin 22 on the DB25 connector to
indicate the presence of an incoming call to the attached DTE. Otherwise, the
strap is set to Test Mode (see Figures 2-11 and 2-12).
Follow these steps:
Step Action
1
Set the strapping as shown in Figures 2-11 and 2-12 for the following:
Pin 22:
Normally.defined as Ring Indicator, an output for a DCE device.
However, you can configure it as an input and use it in Test Mode when
the port is configured to connect to a dial modem. Pin 22 can o nly be
configured as an output when the DIM is in the DCE position. If the
DIM is in the DTE position, pin 22 is always an input.
Pin 25:
Normally defined as Test Mode, an output for a DCE device. However,
you can configure it as an input (Make Busy). P in 25 can only be
configured as an output when the DIM is in the DTE position. If the
DIM is in the DCE position, pin 25 is always an input.
2 Push the strap down onto the pins.
Example of Strapping the DIM Site Daughtercard
Figure 2-11 shows the strapping for the DIM Site.
Figure 2-11. Strapping DIM Site Daughtercard Example
Description of DIM Daughtercard Strapping
Figure 2-12 describes the strapping and DIP switch settings for the DIM Site
daughtercard.
Figure 2-12. DIM Daughtercard Strapping Description
Adding or Replacing an ISDN Daughtercard
The ISDN daughtercard provides an RJ45 connector on Port 1. Figure 2-13 shows
the ISDN daughtercard.
Figure 2-13. ISDN U Daughtercard
Use the following table to verify that your ISDN daughtercard is comp atible with
your Vanguard:
Platform Platform Version ISDN Daughtercard Part
Vanguard 100 71955G01 Rev B and up U card: 72291G01
Vanguard 100 PC 72351G01 Rev A and up U card: 72291G01
The daughtercard part number appears on the surface of the daughtercard, and the
platform version appears on the Vanguard motherboard. The platform version can
also be read from the CTP from the Status/Statistics menu item, Hardware Stats
screen, beside the item marked "Assembly".
Regulatory Information
The following sections provide information about compliance, safety statements,
and ISDN Type Approvals.
FCC
This equipment has been tested and found to comply with the limits for a Class B
digital device, pursuant to Part 15 of the FCC rules, CISPR Publication 22 and EN
55022. These limits are designed to provide reasonable protection against
interference when the equipment is operated in a commercial environment. This
equipment generates, uses, and can radiate radio frequency energy, and, if not
Numbers
S card: 72300G01
S card: 72300G01
installed and used in accordance with the instruction manual, may cause
interference to radio communications.
Changes or modifications not expressly approved by Motorola could void the
user's authority to operate the equipment.
Industry Canada
The following information includes the Industry Canada statement regarding
ISDN equipment use.
The Industry Canada label identifies certified equipment. This certification means
that the equipment meets certain telecommunications network protective,
operational, and safety requirements. The Department does not guarantee the
equipment will operate to the user's satisfaction.
Before installing this equipment, users should ensure that it is permissible to be
connected to the facilities of the local telecommunications company. The
equipment must also be installed using an acceptable method of connection. In
some cases, the company's inside wiring associated with a single line individual
service may be extended by means of a certified connector assembly (telephone
extension cord). The customer should be aware that compliance with the above
conditions may not prevent degradation of service in some situations.
Repairs to certified equipment should be made by an authorized Canadian
maintenance facility designated b y the supplier. Any repairs or alterations made
by the user to this equipment, or equipment malfunctions, may give the
telecommunications company cause to request the user to disconnect the
equipment.
Users should ensure for their own protection that the e lectrical ground
connections of the power utility, telephone lines, and internal metallic water pipe
system, if present, are connected together. This precaution may be particularly
important in rural areas.
Users should not attempt to make such connections themselves, but should
contact the appropriate electric inspection authority, or electrician, as
appropriate.
Notification of Canadian Requirements
This digital apparatus does not exceed the Class A limits for radio noise emissions
from digital apparatus as set out in the Radio Interference Regulations of the
Canadian Department of Communications.
Le présent appareil numérique n'émet pas de bruits radioélectriques dépassant les
limites applicables aux appareils numériques de classe A prescrites dans le
règlement sur le brouillage radioélectrique édicté par le Ministère des
Communications du Canada.
Safety Warnings
The following is important safety information regarding connecting ports,
location of the socket outlet, and PSTN direct connection:
Connecting Ports
Ports that are capable of connecting to other apparatus are defined as SELV.
To ensure conformity with EN60950 - ensure that these ports are only
connected to ports of the same type on other apparatus.
Unmapped format: variant of Warning Les ports qui sont susceptibles
d'être connectés a des équipements sont désignés comme TBTS. Pour garantir
la conformité à la norme EN 60950, n'interconnecte ces ports qu'avec des
ports du même type sur des autres matériels.
Anschlusse, die mit anderen Geraten verbinde t werden konnen, sind als SELV
beschrieben. Um Konformitat mit EN 60950 zu versichern, sichern Sie es, daß
diese Anschlusse nur mit den des selben Type auf anderen Geraten verbindet
werden.
Socket Outlet Installation
The socket outlet shall be installed ne ar the equipment and shall be accessible.
Pour mettre hors tension l'appareil debrancher la prise électrique. La prise
électrique doit être située a proximité de l'équipement et elle doit être d'accès
facile.
Die Steckdose soll nahliegend der Einrichtung installiert werden und leicht
erreichbar sein.
PSTN Direct Connection
This unit is not to be directly connected to the PSTN. A Network Interface
device meeting the requirements of EN41003 shall be used for proper
isolation.
Setting the Termination Resistance DIP Switches
On the ISDN S/T Daughtercard rear connector, there is a termination resistance
DIP switch, shown in Figure 2-14.
Figure 2-14. ISDN S/T Daughtercard Rear Connector
If your Vanguard is the final device in the configuration, you must set the
termination resistance DIP switch to the 100Ω position. For all other Vanguards
in the configuration, the DIP switch must be set to the HI Z position. The
following diagrams (Figures 2-15 to 2-17) depict the three typical wiring
configurations.
In the following diagrams, TR is the 100Ω Terminating Resistor. On the
Vanguard ISDN S/T Daughtercard, the setting of the Terminating Resistor is
controlled by the DIP switch.
Figure 2-15. Short Passive Bus Configuration
Figure 2-16. Extended Passive Bus Configuration
ISDN Connection Cables
Each ISDN daughtercard ships with an ISDN connection cable. One end of the
cable attaches directly to the daughtercard, and the other end connects to the
service provider outlet. The connector pinouts are described in the following
sections.
Figure 2-17. Point-to-Point Configuration
Connector Pin Numbers
The connector pins are numbered from right to left as indicated in the following
diagram:
Note: The daughtercard connector can accept either an RJ11 or RJ45 connector.
If you are using an RJ11, pin 1 and pin 8 are not used.
ISDN Interface RJ45 Connector
The following table shows the pinouts for the RJ45 ISDN U and S/T interface
connection cable:
U Card S Card
Pin Name Function Pin Name Function
1 Battery Status No connection 1 PS 3 + No connection
2 Battery Status No connection 2 PS 3 - No connection
3 --- No connection 3 TE NT + TE to NT pair, no
power connection
4 Signal U interface tip
or ring
5 Signal U interface tip
or ring
4 NT TE + NT to TE pair, no
power connection
5 NT TE - NT to TE pair, no
power connection
6 --- No connection 6 TE NT - TE to NT pair, no
power connection
7 Powering No connection 7 PS 2 - No connection
8 Powering No connection 8 PS 2 + No connection
ISDN Cable Connection
Figure 2-18 shows how to connect the ISDN Cable to the ISDN da ughtercard.
Do not attach the ISDN Cable until the daughtercard is installed on the Vanguard
board, and the PC is completely reassembled.
Figure 2-18. Connecting the ISDN Cable
Software Configuration and Control Port Access
Overview
This section describ es how to configure your PC communications software
package to work with your Vanguard 100 PC, how to access the Control Port to
configure your Vanguard 100 PC, and how to download pre-set configurations.
Configuring Your COM Software
Now that you have installed your Vanguard 100 PC hardware, you must configure
your communications software to access the Vanguard 100 PC and its Control
Port. This section assumes that you are familiar with the COM software package
that you are using, or have access to the software package User's Guide.
Use the following steps to configure your COM software to recognize and access
the Vanguard 100 PC.
Note: <CR> indicates a Carriage Return is required. Depending upon your PC
keyboard, this key may be marked <Enter> or <Return>.
Step Action
1 Ensure that the rear panel DIP switch is set to enable for the CP switch,
and press the Reset button. Wait 1 minute.
2 Using the operating system's port setting application, set the COM Port
and IRQ for the Vanguard 100 PC to the same setting as you
configured on the board (with the COM Port and IRQ jumper settings).
3 Access your commercial COM package software (i.e., ProComm). Set
your terminal emulation software to VT100, 9600 bps, 8 bit, no parity,
1 stop bit, and the designated COM port.
4 Invoke the terminal emulation. Type <CR>, and the * or OK prompt
will appear.
The Control Port
This section provides introductory information to allow you to access the Control
Terminal Port (CTP) of your Vanguard 100 PC. This enables you to perform basic
configuration or software changes that may occur due to application changes or
operating software updates.
If you need more detailed information, you can obtain additional documentation
that describes the CTP and Vanguard 100 PC software more extensively. See the
"Related Documentation" section in About This Guide for a list of relevant
materials.
The CTP is a menu-driven software utility that provides you with complete
control of your Vanguard 100 PC. Using the CTP, you have the ability to
configure, monitor, and diagnose applications supported by your Vanguard 100
PC.
This section includes the following information:
• a basic method for accessing the CTP
• an introduction to using the CTP
• accessing online help
• an introduction to the resources associated with typical applications
• how to bring new configurations online
Accessing the Control Port and Main Menu
Use the following steps to configure your COM software to recognize and access
the Vanguard 100 PC.
Step Action
1 Ensure that the rear panel DIP sw itch is set to enable for the CP switch,
and press the Reset button. Wait 1 minute.
2 Set your terminal emulation software to VT100, 9600 bps, 8 bit, no
parity, 1 stop bit.
3 Invoke the terminal emulation. Type <CR>, and the * or OK prompt
will appear.
4 Accessing the CTP depends on your prompt:
If you see *, type .ctp<CR>
If you see OK, type atds0<CR>
The CTP banner appears as shown in Figure 3-1.
If no prompt appears, verify that these steps have been followed
correctly.
5 Enter your password and type <CR>. The Main menu appears as shown
in Figure 3-2.
Note: The default password is blank. If a password has been set, and
you have forgotten it, you can use JAGPBDPW to access the node.
This feature is only available if the CP switch is enabled.
On the rear panel, the DIP switch labeled CP forces the internal Port 3 to a PAD
or ATPAD protocol running at 9600 bps, 8 bits, no parity, 1 stop bit. You must
ensure that your terminal emulation program is configured to these settings.
(VT100 terminal emulation is recommended.)
Figure 3-1 shows the Control Port Banner message.
Figure 3-1. Control Port Banner
Figure 3-2 shows the Control Port Main menu.
The Enter Selection: prompt appearing at the bottom of the screen accepts a
number corresponding to the choices in the particular menu. (For example, to
logout from the CTP back to the * or OK prompt, you would enter 1<CR>)
Figure 3-2. Control Port Main Menu
Accessing Online Help
To get a brief description of help actions that are associated with the menu control
of the CTP that you are currently in, type ?<CR>. The following information
appears:
<ESC> Escape key Escape from the current operation.
<^T> Control T Escape from the current operation and return to the
<^X> Control X Delete the current line of input.
<^R> Control R Redisplay the current line of input
<^O> Control O Enable the display of reports to the Control Port.
<^N> Control N Disable the display of reports to the Control Port.
Main menu.
<?> or
Get help at any level of input.
<"HELP"\>
To get a brief description of a parameter while configuring a record (i.e., a port
record), type ?<CR> after the prompt for the parameter in question (see Figure 3-
3).
Figure 3-3. Example of Online Help
The help information gives you:
• The range of acceptable values for the parameter in question
• The default value when a new record is created
• A basic textual description of the parameter
Note: Additional information is available in the 6500 Series documentation.
Accessing the Port Configuration Menus
You may need to make minor changes to the port information. To do this, you
must access the port configuration menus, and modify the port information.
In this example, assume that your PPP driver only supports 38.4 kbps and
Motorola-supplied CMEMs support 57.6 kbps. You will need to modify Port 3.
From the Main menu, type 6.2.3<CR>. The 3 indicates Port 3. The screen in
Figure 3-4 appears.
Note: The following sections all show the fast-path method for navigating the
CTP Menus. In all cases, you can achieve the same effect by selecting
each number and following it by <CR>. For example, 6.2.3 is equivalent
to typing 6<CR> then 2<CR> and then 3<CR>, but you will get new
menu screens after each <CR>.
<CR> steps you through the different parameters. Also, you must enter ;<CR>
for the changes to take effect. This performs an initialization function known as a
boot. See "Booting the Node" on page -7 for more information.
Figure 3-4. Example Port Configuration
Accessing Frame Relay Station Configuration
You may need to adjust the associated Station characteristics of a FRI port to
match your service provider's configuration.
For example, if you want to modify port 1 station 1 (assuming that the port is
previously defined as type FRI), from the Main menu, type 6.8.1.1<CR>. The
first 1 indicates the port number, and the second 1 indicates the station number
(see Figure 3-5).
Figure 3-5. Frame Relay Station Configuration
Booting the Node
After you change your configuration, it is recommended that you perform a warm
boot. This will ensure that all configuration changes take effect, but it is
disruptive to all connections and data passing on the node.
Note: Other types of boots (port, station, table) are less disruptive, but may not
ensure that configuration changes take effect. Refer to your additional
6500 Series documentation for details.
Before you execute a node boot, you should disable the CP switch. If you want to
perform a warm boot, from the Main menu type 7.4.y<CR>. A warm boot takes
approximately 8 seconds to complete.
Note: You may see a few spurious characters displayed, then your port will
revert back to the configured profile for Port 3. Switch from the terminal
emulator back to your regular application, and confirm that your
application is functioning as expected.
Defaulting the Node
To default the Vanguard 100 PC node, use the following procedure.
Step Action
1 Power up the PC with the Vanguard 100 PC installed, and wait 1
minute for the node to initialize.
2 Enable the Default Node switch.
3 Press the reset button and allow the Vanguard 100 PC to reboot. Wait 1
minute for the node to initialize.
4 Disable the Default Node switch. The Node default is complete.
Examining Statistics
From the Main menu, type 5<CR> to display the different choices for statistics.
You can view various node, port, station, and connection details from within the
statistics menu. Browsing in this area of the control port cannot harm your setup,
and is helpful to familiarize yourself with the available statistics.
Details of the statistics menus are available in the full 6500 Series documentation.
Software Loading
The Vanguard 100 PC is a feature-rich product that executes the code from within
approximately 1.5 Mbytes of RAM. Unfortunately, the complete set of features
that are supported by the Vanguard 100 PC software consumes approximately 4
Mbytes of RAM.
To accommodate a variety of customer applications, there are multiple software
bundles, with various associated protocol support. From release to release, the
new software is made available with a Release Notice that discusses the changes
to the software. The default shipping software with a Vanguard 100 PC is the 4.50
Toronto image, which contains PPP, SLIP, PAD, FRI, and X.25 support, for
example.
If your specific application requires a different protocol, you will need to examine
the latest Software Release Notice (SRN) to determine the software image that
matches your specific needs.
If you have access to the Internet, you can access the Vanguard 100 software
images via URL:
http://www.mot.com/MIMS/ISG/Service_Support/software.html
Here you will find the releases of software, the associated SRNs, and other
information about Motorola products and services.
Software updates will also be made available by CD-ROM. Please contact your
local service representative for updated information on the latest software version.
Software Loader
As part of the Vanguard 100 PC product kit, you have been provided with an
installation diskette. This diskette contains a readme.txt file that will assist you
with installing a version of "Software Loader" that runs under Windows.
Note: You will only need to install a different software image if you need an
application other that what is supported in the Toronto image.
Before You Begin
You must have a copy of the Vanguard CD-ROM or images provided from your
local service representative or the Motorola server.
Downloading a New Software Image
Step Action Response
1 Follow the directions in the readme.txt file
on the installation diskette to properly install
the software loading application.
2 Confirm that you can access the CTP using a
terminal application. Follow the instructions
in the "Accessing the Control Port and Main
Menu" section on page -2.
3 Exit from any terminal applications
controlling the COM port.
4 Invoke the cload16.exe or cload32.exe from
within Windows.
5 Follow the online help to transfer an image
to the Vanguard 100 PC.
* or OK should appear
Pre-Set and Default Configurations
The Vanguard 100 PC must be configured to your specific application to function
properly. To help you with this activity, several pre-set configurations have been
developed which will likely meet your needs. You will find these configurations
on the CD-ROM, the Configuration Diskette, and, eventually, on the Moto rola
Internet Web server. Review Chapter 5, Applications and Configurations, to
determine the application that meets your needs.
The default application for software images that support PPP and FRI will be a
PPP to FRI connection. The FRI network station is a Bypass station with an autolearn DLCI. The PPP will be 9600 bps. After you have installed your Vanguard
100 PC into your computer, you can ensure that you have the default
configuration by defaulting the node, as described earlier in this chapter.
If you have installed an optional daughtercard (automatically assigned to Port 1),
the defaulted node will associate the FRI port with Port 1. If there is no optional
daughtercard, the defaulted node will associate the FRI port with Port 2. The
internal Port 3, which is physically connected to your computer's COM port, will
assume the PPP role.
If your software image does not contain PPP, the next choice for a defaulted node
on Port 3 will be the SLIP protocol, then the ATPAD protocol, and finally the
PAD protocol. If your software image does not contain FRI, the default choice for
Port 1 and Port 2 will be the X.25 protocol.
Saving and Restoring Configurations
The Vanguard 100 PC allows you to save and restore a node's configuration
memory (CMEM). Saving a configuration retains a copy of your configuration on
a PC disk so you can retrieve it later, should you need to restore it. A
configuration is restored when it is retrieved from a PC disk and placed into a
node's CMEM. Restoration of a CMEM is typically used for error recovery or for
a multi-node configuration template.
The earlier part of this chapter discussed how to access the Control Port of your
Vanguard 100 PC using the commercial COM packages. From the Control Port,
you can perform the Configuration Save/Restore command.
When to Save/Restore
When a configuration is restored, the configuration in CMEM is overwritten
(except for Software Authorization Keys).
• Assign each configuration a unique name so there is no confusion about
which is the correct configuration file for a node.
• Save CMEM contents before performing an upgrade or replacing a bad
battery to avoid losing a configuration you may later need.
• The configuration that is restored is not implemented until you boot the
node using the Node Boot command.
Initiating Save/Restore Operations
The Save/Restore command is available from the Main menu.
Figure 3-6 shows the Configuration Save/Restore menu, available from the Main
menu.
Figure 3-6. Configuration Save/Restore Menu
Methods of Saving/Restoring
You can save or restore CMEM contents using:
• A computer running Kermit via a commercial communication package
• A TFTP server over a LAN connection
Kermit is the recommended procedure, and will be the only one discussed in this
section. TFTP is discussed in the full 6500 Series documentation.
Saving and Restoring Configurations Using Kermit
You can save and restore CMEM contents to a PC running terminal emulation
from a communications program such as Crosstalk or ProComm. These programs
support the Kermit file transfer protocol.
Before You Begin
You need to access the CTP as described in the "Accessing the Control Port and
Main Menu" section on page -2.
The following table describes how to save a configuration using Kermit. File sizes
for MEM files are approxima tely 4-20K, depending upon the complexity of the
configuration.
Step Action Result
1 Access the Control
Port. From the Main
Characters such as S~*@_#W appear at the
prompt.
menu, type 15.1<CR>.
2 Depending on the
communications
You receive the following message: Send
complete.
program installed, the
steps for using Kermit
may vary. Follow the
directions to receive a
file using Kermit.
If... Then...
The transfer failed
Try again.
because too much
time elapsed.
The transfer failed
due to
communications
program problems
Refer to the
communications
program documentation
for additional
information.
Use the following procedure to restore a configuration with a communications
package.
Step Action Result
1 Access the Control
Characters such as # N3 appear at the prompt.
Port. From the Main
menu, type 15.1<CR>.
2 Depending on the
communications
program installed, the
steps for using Kermit
may vary. Follow the
directions to receive a
file using Kermit.
3 Warm boot the node to
implement the
configuration that was
transferred. Refer to the
"Booting the Node"
section on page -7 for
additional information.
You receive the following message: Receive
complete: File stored successfully.
If... Then...
The transfer failed
Try again.
because too much
time elapsed.
The transfer failed
due to
communications
program problems
Refer to the
communications
program documentation
for additional
information.
Overview
This section describes a set of sample configurations that implement the various
applications for Vanguard 100 PC. It also provides a list of preconfigured
CMEMs that you can install with your Vanguard 100 PC when it is being used in
one of these configurations.
Preconfigured Application CMEMs
The following sections provide various pre-configured and tested applications
which will either completely meet the needs of your application or require minor
adjustments to suit your individual preferences.
For these configurations, Motorola has supplied a diskette containing a set of preset CMEMs that you can download to your PC for use with your Vanguard 100
PC. These CMEMs set up your Vanguard 100 PC configuration parameters
without having to go through the entire control port configuration.
Note: If you would like to submit to Motorola a preconfigured CMEM that you
believe would benefit other users of this product, Motorola would be
happy to receive it. Please use the following as a guideline for the
information you provide.
Applications and Configurations
Overview of Supplied CMEMs
The CMEMs that have been provided are all fully described in this chapter. These
descriptions are in the following format:
Configuration Diagram
• Depicts the equipment and connections in use, and the type of traffic on
the network.
Application Description
• Briefly describes the app lication and protocols in use in the environment.
Configuration Summary
• Describes the Port and Station configuration requirements that this CMEM
covers, and any additional information about the configuration that may be
useful.
Optional Application CMEMs
• Lists closely related CMEMs that have slightly different configurations
than the standard application.
Updates to the CMEMs will be provided on CD-ROM as new releases are issued.
The CMEMs will be added to the WEB page more frequently.
PPP to Frame Relay Bypass
Application Description
This application provides a permanent connection between the PPP port and the
Frame Relay Station. The Frame Relay Station uses the Control Protocol Support
ANSI T1.617 Annex D. The Station's DLCI number is automatically learned to
allow for added flexibility.
Configuration Summary
Port #1 FRI Bypass, ext clk, Annex D, 2 Auto-learn DLCI stations
Port #2 PPP RFC1490 encapsulation, 57600 bps, VJ compression
Port #3 PPP RFC1490 encapsulation, 57600 bps, VJ compression
• FRI Port #1 Station 1 connects to PPP Port #3 (FRI-1s1 - PPP-3)
• FRI Port #1 Station 2 connects to PPP Port #2 (FRI-2s2 - PPP-2)
• CTP access via CTP switch.
Optional Application CMEMs
V1000001.MEM Standard application as mentioned in Summary
V1000001.001 Port #2 PAD, CTP access via PAD or switch.
V1000001.002 Port #1 PPP, Port #2 FRI, (FRI-2s2 - PPP-1)
V1000001.003 Port #1 PAD, Port #2 FRI
V1000001.004 Port #1 NULL (no daughter card), Port #2 FRI
V1000001.005 Port #1 X.25, Port #2 FRI (ISDN Perm B1)
SLIP to Frame Relay Bypass
Application Description
This application provides a permanent connection between the SLIP port and the
Frame Relay Station. The Frame Relay Station uses the Control Protocol Support
ANSI T1.617 Annex D. The Station's DLCI number is automatically l earned to
allow for added flexibility.
Configuration Summary
Port #1 FRI Bypass, ext clk, Annex D, 2 Auto-learn DLCI stations
Port #2 SLIP RFC1490 encapsulation, 57600, Auto detect comp
Port #3 SLIP RFC1490 encapsulation, 57600, Auto detect comp
• FRI Port #1 Station 1 connects to SLIP Port #3 (FRI-1s1 - SLIP-3)
• FRI Port #1 Station 2 connects to SLIP Port #2 (FRI-1s2 - SLIP-2)
• CTP access via CTP switch
Optional Application CMEMs
V1000002.MEM Standard application as mentioned in Summary
V1000002.001 Port #2 PAD, CTP access via PAD or switch
V1000002.002 Port #1 SLIP, Port #2 FRI, (FRI-2s2 - SLIP-1)
V1000002.003 Port #1 PAD, Port #2 FRI
V1000002.004 Port #1 NULL (no daughtercard), Port #2 FRI
V1000002.005 Port #1 X.25, Port #2 FRI (ISDN Perm B1)
PPP to Frame Relay Annex G
Application Description
This application allows for a Switched Virtual Circuit connection between the
PPP port and the Frame Relay Service. The PPP connection requires the Network
to establish the connection. (Note: PPP does not support PVC Connections over
Annex G stations.)
The Frame Relay Port uses the Control Protocol Support ANSI T1.617 Annex D.
The Station's DLCI number is auto learned. The Network service will need to call
the Node with an address that has the subaddress equal to the PPP port number
(i.e., 757503 is valid for connection to PPP-3, 999902 is valid for PPP-2.)
Configuration Summary
Port #1 FRI Annex D, ext clk, 1 Auto-learn DLCI Annex G
Port #2 PPP RFC1490 encapsulation, 57600 bps, VJ compression
Port #3 PPP RFC1490 encapsulation, 57600 bps, VJ compression
• Connections achieved by the Network Service calling the PPP port.
• CTP access via CTP switch or X.25 service calling subaddress 98.
Optional Application CMEMs
V1000003.MEM Standard application as mentioned in Summary
V1000003.001 Port #2 PAD, CTP access via PAD or switch
V1000003.002 Port #1 PPP, Port #2 FRI
V1000003.003 Port #1 PAD, Port #2 FRI
V1000003.004 Port #1 NULL (no daughtercard), Port #2 FRI
V1000003.005 Port #1 X.25, Port #2 FRI (ISDN Perm B1)
SLIP to Frame Relay Annex G
Application Description
This application allows for a Switched Virtual Circuit connection between the
SLIP port and the Frame Relay Service. The SLIP connection requires the
Network to establish the connection. Please note that SLIP does not support PVC
Connections over Annex G stations.
The Frame Relay Port uses the Control Protocol Support ANSI T1.617 Annex D.
The Station's DLCI number is auto learned.
The Network service will need to call the Node with an address that has the
subaddress equal to the SLIP port number (i.e., 757503 is valid for connection to
SLIP-3, 999902 is valid for SLIP-2.)
Configuration Summary
Port #1 FRI Annex D, ext clk, 1 Auto-learn DLCI Annex G
Port #2 SLIP RFC1490 encapsulation, 57600, Auto detect comp
Port #3 SLIP RFC1490 encapsulation, 57600, Auto detect comp.
• Connections achieved by the Network Service calling the SLIP port.
• CTP access via CTP switch or X.25 service calling subaddress 98.
Optional Application CMEMs
V1000004.MEM Standard application as mentioned in Summary
V1000004.001 Port #2 PAD, CTP access via PAD or switch
V1000004.002 Port #1 SLIP, Port #2 FRI
V1000004.003 Port #1 PAD, Port #2 FRI
V1000004.004 Port #1 NULL (no daughtercard), Port #2 FRI
V1000004.005 Port #1 X.25, Port #2 FRI (ISDN Perm B1)
PPP to X. 25 (RFC877)
Application Description
This application allows for a Switched Virtual Circuit connection between the
PPP port and a X.25 Service. The PPP connection requires the X.25 Service to
establish the connection. Please note that PPP does not currently support PVC
Connections over X.25.
The X.25 service will need to call the Node with an address that has the
subaddress equal to the PPP port number (i.e., 757503 is valid for connection to
SLIP-3, 999902 is valid for SLIP-2.)
Configuration Summary
Port #1 X.25 (RFC877), ext clk, 16 svc's, DTE
Port #2 PPP RFC1490 encapsulation, 57600, VJ Compression
Port #3 PPP RFC1490 encapsulation, 57600, VJ Compression
• Connections achieved by the X.25 Service calling the PPP port.
• CTP access via CTP switch or X.25 service calling subaddress 98.
Optional Application CMEMs
V1000005.MEM Standard application as mentioned in Summary
V1000005.001 Port #2 PAD, CTP access via PAD/NET/switch
V1000005.002 Port #1 PPP, Port #2 X.25
V1000005.003 Port #1 PAD, Port #2 X.25
V1000005.004 Port #1 NULL (no daughtercard), Port #2 X.25
V1000005.005 Port #1 X.25, Port #2 X.25 (ISDN Perm B1)
SLIP to X.25 (RFC877)
Application Description
This application allows for a Switched Virtual Circuit connection between the
SLIP port and a X.25 Service. The SLIP connection requires the X.25 Service to
establish the connection to the SLIP port. Please note that SLIP does not currently
support PVC Connections over X.25.
The X.25 service will need to call the Node with an address that has the
subaddress equal to the SLIP port number (i.e., 757503 is valid for connection to
SLIP-3, 999902 is valid for SLIP-2.)
Configuration Summary
Port #1 X.25 (RFC877), ext clk, 16 svc's, DTE
Port #2 SLIP RFC1490 encapsulation, 57600, Auto detect comp.
Port #3 SLIP RFC1490 encapsulation, 57600, Auto detect comp.
• Connections achieved by the X.25 Service calling the SLIP port.
• CTP access via CTP switch or X.25 service calling subaddress 98.
Optional Application CMEMs
V1000006.MEM Standard application as mentioned in Summary
V1000006.001 Port #2 PAD, CTP access via PAD/NET/switch
V1000006.002 Port #1 SLIP, Port #2 X.25
V1000006.003 Port #1 PAD, Port #2 X.25
V1000006.004 Port #1 NULL (no daughtercard), Port #2 X.25
V1000006.005 Port #1 X.25, Port #2 X.25 (ISDN Perm B1)
Overview
This section describes the physical and environmental specifications and power
requirements for the Vanguard 100 PC.
Hardware
Vanguard 100 PC features the following:
• 15.36 MHz 68302 processor
• 2 Mbytes DRAM
• Battery-backed CMOS SRAM
• Code compressed in 1 Mbyte of FLASH memory
Environmental
The following environmental conditions are required:
• Operating temperature: 32° to 104° F maximum (0° to 40°C maximum)
• Storage temperature: -40° to +158°F (-40° to +70°C)
Specifications
• Relative humidity: 0% to 95% (noncond ensing)
Electromagnetic Compatibility
Vanguard 100 PC adheres to the following:
• FCC Part 15, Class B
• CISPR 22 and EN 55022, Class B
• AS 3548, Class B
• EN 50082-1
Safety
Vanguard 100 PC meets the following safety standards:
• EN60950
• CSA 950
• UL Listed per UL 1950
Physical
Vanguard 100 PC adheres to the following measurements:
• Height: 4.5 inches
• Length: 13.1 inches
• Width: 6.7 inches (17 cm)
Configuration Memory Battery Shelf Life
10 years
Serial Ports
Vanguard 100 PC is available in 2 and 3 serial port versions.
Power Requirements
Vanguard 100 PC typically has the following power requirements:
To determine the total power requirements of your configuration, add the columns
for the components installed on your board.
Weight
Vanguard 100 PC weighs the following:
5 Volts
mA
+12 Volts
mA
-12 Volts
mA
Total
Power W
Vanguard 100 PC 620 0 0 3.1
V.24 DIM 5 17 18 0.5
V.35 DIM 120 43 37 1.6
V.36 DIM 130 23 21 1.2
V.11 DIM 80 0 1 0.5
DSU Daughtercard 80 0 0 0.4
ISDN U Daughtercard 320 0 0 1.6
ISDN S/T Daughtercard 13 0 0 0.1
Vanguard 100 PC card (with DIM) 0.57 lb (0.26 kg)
DSU daughtercard 0.21 lb (0.1 kg)
V.24 daughtercard 0.21 lb (0.1 kg
Power Supply Description
Vanguard 100 PC does not have its own power supply. It draws from the power
supply of the host PC.
Overview
This section describes some of the port configuration parameter values that you
can use for the given application environments. The following tables show the
typical port configuration parameters and values for:
• X.25 Port
• FRI Port
• FRI Annex G Station
• FRI Bypass Station
• PPP Port
• SLIP Port
• PAD Port
• SNMP Agent
X25 Port Configuration
Parameter Value
Sample Application Configuration
Connection Type SIMP
Port Control NONE
Clock Source EXT
Clock Speed 56000
Link Address DTE
*Number of PVC Channels 0
*Starting PVC Channel Number 1
*Number of SVC Channels 16
*Starting SVC Channel Number 1
Initial Frame SABM
T1 Transmission Retry Timer (1/10 sec) 30
T4 Poll Timer 40
N2 Transmission Tries 10
Frame Sequence Counting NORM
K Frame Window 7
Packet Sequence Counting NORM
W Packet Window 2
P Packet Size 128
Maximum Negotiated Packet Size 1024
Data Queue Upper Threshold 5
Data Queue Lower Threshold 0
Restart Timer 180
Reset Timer 180
Call Timer 200
Clear Timer 180
Facilities to delete from Out bound Calls NONE
Facilities to add to Outbound Calls NONE
Facilities to bar in Outbound Calls NONE
Facilities to bar in Inbound Calls NONE
X.25 Options NONE
Number of Routing Digits in Call User Data 5
Number of Routing Digits in Call User Data 5
Number of prefix Address Digits stripped from Outgoing
0
Calls
Number of prefix Address Digits stripped from Incoming
0
Calls
Restricted Connection Destination (blank)
Port Address (blank)
CUG Membership --,--,--,--,--,--,--,-Billing Records OFF
Number of Subaddress Digits in X.25 Address 2
Idle Disconnect Timer (sec) 0
Call Security DISABLE
*Protection Level NONE
Reconnection Timeout 2
Reconnection Tries Limit 4
Facility Subscription Control NONE
Alarm Priority NETWORK
Charging Information Subscription Control
NUI Verification Timer 10
Max NUI Violations 0
Action Type for NUI Violations NONE
FRI Port Configuration
Parameter Value
Connection Type SIMP
Clock Source EXT
Clock Speed 64000
*Highest Station Number 1
Frame Sequence Counting NORM
Packet Sequence Counting NORM
Control Protocol Support ANNEX_D
FRI Annex_G Station Configuration
Parameter Value
*Station Type ANNEX_G
DLCI 0
Committed Information Rate (CIR) 16000
Committed Burst Size (BC) 16000
End-to-End Transit Delay 50
Congestion Control Mode NORMAL
Link Address DTE
*Number of PVC Channels 0
*Starting PVC Channel Number 1
*Number of SVC Channels 16
*Starting SVC Channel Number 1
Initial Frame SABM
T1 Transmission Retry Timer (1/10 sec) 30
T4 Poll Timer 40
N2 Transmission Tries 10
K Frame Window 7
W Packet Window 2
P Packet Size 128
Data Queue Upper Threshold 5
Data Queue Lower Threshold 0
Restart Timer 180
Reset Timer 180
Call Timer 200
Clear Timer 180
X.25 Options NONE
Restricted Connection Destination (blank)
CUG Membership --,--,--,--,--,--,--,-Billing Records OFF
FRI Bypass Station Configuration
Parameter Value
*Station Type BYPASS
DLCI 0
Committed Information Rate (CIR) 16000
Committed Burst Size (BC) 16000
End-to-End Transit Delay 50
Congestion Control Mode NORMAL
PPP Port Configuration
Parameter Value
Connection Type SIMP
Flow Control NONE
Clock Speed 115200
Stop Bits 1
Authentication Protocol NONE
LCP Options PFC+ACFC+
Maximum Receive Unit 1500
ACCM+MRU
Network Protocols IP+IPX
IPCP Options VJ
IPXCP Options NONE
Encapsulation PPP
SLIP Port Configuration
Parameter Value
[3] *Port Type SLIP
[3] Connection Type SIMP
[3] Flow Control NONE
[3] Clock Speed 9600
[3] Stop Bits 1
[3] VJ-compression AUTO
[3] CID compression ON
[3] Security NONE
[3] Encapsulation RFC1490
PAD Port Configuration
Parameter Value
*Port Type PAD
Connection Type SIMP
Port Control NONE
Port Speed 9600
Auto Baud Sequence CR_only
Data Bits per Character 8
Device Parity NONE
Number of Stop Bits 1
Profile Name DEFAULT
Call Control NONE
Terminal Control NONE
PAD Prompt Entry Number 0
Remote PAD Parameters Number 0
Autocall Mnemonic (blank)
Autocall Timeout (sec) 10
Maximum Number of Autocall Attempts 4
Subaddress 02
Group Subaddress 00
CUG Membership --,--,--,--,--,--,--,-Billing Records OFF
Invitation to Clear CLRWO
Call Accept Timeout (sec) 0
*Protection Level NONE
Reconnection Timeout 2
Reconnection Tries Limit 4
Maximum Receive Buffer Length 128
PAD Command Language CCITT
NUI Facility Format ODPN
NUI Verification Timer 60
Max NUI Violations 3
Action Type for NUI Violations NONE
Typical SNMP Agent Configuration
Parameter Value
*SNMP-UDP Connection Subaddress 161
*Secondary Channel Subaddress (blank)
*UDP Retry Timer (seconds) 10
*Connection Type SIP_W
*Trap Generation DISABLE
*Authentication Failure Trap Generation DISABLE
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