- LG Software Innovations Coffeemaker User Manual
Table Of Contents
- Title Page
- Revision history
- Contents
- About this guide
- Description
- System requirements
- List of ITG ISDN components
- Ordering rules and guidelines
- ITG ISL Trunk card description
- ITG ISL Trunk card physical description
- ISDN Signaling Link
- Dialing plans
- Quality of Service
- Fallback to alternate facilities
- Type of Service
- Fax support
- Remote Access
- Per-call statistics support using RADIUS Client
- SNMP MIB
- Codec profiles
- Security passwords
- ITG Engineering Guidelines
- Introduction
- Network engineering guidelines overview
- ITG traffic engineering
- Configuration of Meridian 1 routes and network translation
- Assess WAN link resources
- QoS Evaluation Process Overview
- Set QoS
- Measure intranet QoS
- Implement QoS in IP networks
- ITG Trunk DSP profile settings
- Post-installation network measurements
- Estimate QoS level
- ITG MAT PC management configuration
- Install and configure ITG ISL Trunk node
- Before you begin
- Installation Procedure Summary
- Create the ITG Trunk Installation Summary Sheet
- Install and cable ITG trunk cards
- Install NTCW84JA Large System I/O Panel 50-Pin filter adapter
- Install NTMF94EA and NTCW84KA cables
- D-channel cabling for the NT0961AA 24-Port ITG Trunk card
- Set NT6D80 MSDL switches
- Install filter and NTND26 cable (for MSDL and DCHIP cards in same Large System equipment row)
- Install filter and NTND26 cable (for MSDL and DCHIP cards in different Large System equipment rows)
- Configure ITG Trunk data on the Meridian 1
- Configure dialing plans within the corporate network
- Configure ITG Trunk data on MAT
- Transmit ITG trunk card configuration data from MAT to the ITG trunk cards
- Set date and time for the ITG ISL Trunk node
- Change the default ITG shell password to maintain access security
- Change default ESN5 prefix for non-ESN5 IP telephony gateways
- Check card software
- Configure MAT Alarm Management to receive SNMP traps from ITG ISL Trunk cards
- Make test calls to the remote ITG nodes
- Upgrade an ITG Trunk 1.0 node to support ISDN signaling trunks
- Upgrade procedure summary
- Before you begin
- Install the DCHIP hardware upgrade kit
- Upgrade the 8-port ITG basic trunk software to ITG ISL trunk software
- Remove ITG 1.0 configuration data from Meridian 1
- Configure the Meridian 1 ITG ISL Trunk data: upgrade considerations
- Verify ROM-BIOS version
- Upgrade Troubleshooting
- OA&M using MAT applications
- OA&M using the ITG shell CLI and overlays
- Maintenance
- Appendix A: Calbe description and NT8D81BA cable replacement
- NTMF94EA E - LAN, T - LAN and Serial Port cable
- NTCW84KA E-LAN, T-LAN, DCH & Serial cable
- NTAG81CA Faceplate Maintenance cable
- NTAG81BA Maintenance Extender cable
- NTCW84EA DCH PC Card Pigtail cable
- NTMF04BA MSDL extension cable
- NTCW84LA and NTCW84MA upgrade cables
- Prevent ground loops on connection to external customer LAN equipment
- Replace cable NT8D81BA with NT8D81AA
- Tools list
- NT8D81BA cable removal procedures
- Appendix B: Environmental and electrical regulatory data
- Appendix C: Subnet mask conversion from CIDR to dotted decimal format
- Appendix D: Configure a Netgear RM356 modem router for remote access
- Index
- Back
ITG Engineering Guidelines Page 89 of
378
ITG Trunk 2.0 ISDN Signaling Link (ISL) Description, Installation and Operation
assumptions are made to project the Leader Card real time capacity: the
number of probe packets per Leader Card is 25, the average holding time is
180 seconds, the number of calls per hour per port (on the Follower Cards) is
15.3.
8-Port Leader and DCHIP Card Real Time Capacit
y
The 8-Port ITG Trunk Card is the NTCW80 based on the Intel 486 CPU.
Table 7 shows the forecast for the number of nodes, ports and calls per hour
that can be supported by the 8-Port ITG Trunk Leader/DCHIP Card when the
Leader Card is not configured with any ports. Case I assumes that the call mix
is 50% call origination and 50% call termination and as a result it takes
approximately 200 ms per call on average for the Leader Card to assist in the
call setup/tear-down process. If, for example, the network size is 25 nodes,
then the Leader Card can support 10648 calls per hour (or 19166 CCS,
assuming 180 second average holding time). Assuming 15.3 calls per hour
per port, that translates into 695 ports, which is approximately 87 Follower
Cards. If, however, the calls are 100% incoming calls (see Case II below),
then the call processing assistance real time is approximately 400 ms per call
and the Leader Card can support 43 Follower Cards.
Note that the Leader Card capacity that is expressed in terms of the number
of calls per hour is derived from the real time measurements and is
independent of customer traffic assumptions. The Leader Card capacity
expressed in terms of the number of CCS and the number of ports (and the
number of Follower Cards) is derived from the calls per hour value, based on
the traffic assumptions of 180 second average holding time (AHT) and 15.3
calls per hour per port, respectively. If these parameters do not reflect a
specific customer’s traffic requirements, the capacities in terms of CCS, the
number of ports, and the number of Follower Cards can be re-computed using
the following procedures:
Number_of_Ports = Calls_per_hour / Customer_calls_per_hour_per_port
Number_of_Follower_Cards = Number_of_Ports / 8
Table 8 shows the forecast of the Leader Card real time capacity for the case
that four or eight ports are configured to carry voice traffic with G.711 codec
and 10 ms voice sample size and Table 9 shows the forecast for the case with
the G.729A codec with Voice Activity Detection (VAD) and Silence
Suppression, and 30 ms voice sample size. For both tables, 40% voice activity
is assumed.