Datasheet
Table Of Contents
- Cisco ONS 15454 SDH Reference Manual
- Contents
- About this Manual
- Shelf and FMEC Hardware
- 1.1 Overview
- 1.2 Front Door
- 1.3 Front Mount Electrical Connection
- 1.4 E1-75/120 Conversion Panel
- 1.5 Coaxial Cable
- 1.6 Twisted-Pair Balanced Cable
- 1.7 Ethernet Cables
- 1.8 Cable Routing and Management
- 1.9 Fiber Management
- 1.10 Fan-Tray Assembly
- 1.11 Power and Ground Description
- 1.12 Alarm, Timing, LAN, and Craft Pin Connections
- 1.13 Cards and Slots
- 1.14 Software and Hardware Compatibility
- Common Control Cards
- Electrical Cards
- 3.1 Electrical Card Overview
- 3.2 E1-N-14 Card
- 3.3 E1-42 Card
- 3.4 E3-12 Card
- 3.5 DS3i-N-12 Card
- 3.6 STM1E-12 Card
- 3.7 FILLER Card
- 3.8 FMEC-E1 Card
- 3.9 FMEC-DS1/E1 Card
- 3.10 FMEC E1-120NP Card
- 3.11 FMEC E1-120PROA Card
- 3.12 FMEC E1-120PROB Card
- 3.13 E1-75/120 Impedance Conversion Panel
- 3.14 FMEC-E3/DS3 Card
- 3.15 FMEC STM1E 1:1 Card
- 3.16 BLANK-FMEC Faceplate
- 3.17 MIC-A/P FMEC
- 3.18 MIC-C/T/P FMEC
- Optical Cards
- 4.1 Optical Card Overview
- 4.2 OC3 IR 4/STM1 SH 1310 Card
- 4.3 OC3 IR/STM1 SH 1310-8 Card
- 4.4 OC12 IR/STM4 SH 1310 Card
- 4.5 OC12 LR/STM4 LH 1310 Card
- 4.6 OC12 LR/STM4 LH 1550 Card
- 4.7 OC12 IR/STM4 SH 1310-4 Card
- 4.8 OC48 IR/STM16 SH AS 1310 Card
- 4.9 OC48 LR/STM16 LH AS 1550 Card
- 4.10 OC48 ELR/STM16 EH 100 GHz Cards
- 4.11 OC192 SR/STM64 IO 1310 Card
- 4.12 OC192 IR/STM64 SH 1550 Card
- 4.13 OC192 LR/STM64 LH 1550 Card
- 4.14 OC192 LR/STM64 LH ITU 15xx.xx Card
- 4.15 15454_MRC-12 Multirate Card
- 4.16 OC192SR1/STM64IO Short Reach and OC192/STM64 Any Reach Cards
- 4.17 SFPs and XFPs
- Ethernet Cards
- Storage Access Networking Cards
- Card Protection
- Cisco Transport Controller Operation
- Security
- Timing
- Circuits and Tunnels
- 11.1 Overview
- 11.2 Circuit Properties
- 11.3 Cross-Connect Card Bandwidth
- 11.4 DCC Tunnels
- 11.5 Multiple Destinations for Unidirectional Circuits
- 11.6 Monitor Circuits
- 11.7 SNCP Circuits
- 11.8 MS-SPRing Protection Channel Access Circuits
- 11.9 MS-SPRing VC4 Squelch Table
- 11.10 Section and Path Trace
- 11.11 Path Signal Label, C2 Byte
- 11.12 Automatic Circuit Routing
- 11.13 Manual Circuit Routing
- 11.14 Constraint-Based Circuit Routing
- 11.15 Virtual Concatenated Circuits
- 11.16 Bridge and Roll
- 11.17 Merged Circuits
- 11.18 Reconfigured Circuits
- 11.19 Server Trails
- SDH Topologies and Upgrades
- Management Network Connectivity
- 13.1 IP Networking Overview
- 13.2 IP Addressing Scenarios
- 13.2.1 Scenario 1: CTC and ONS 15454 SDH Nodes on Same Subnet
- 13.2.2 Scenario 2: CTC and ONS 15454 SDH Nodes Connected to a Router
- 13.2.3 Scenario 3: Using Proxy ARP to Enable an ONS 15454 SDH Gateway
- 13.2.4 Scenario 4: Default Gateway on CTC Computer
- 13.2.5 Scenario 5: Using Static Routes to Connect to LANs
- 13.2.6 Scenario 6: Using OSPF
- 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server
- 13.2.8 Scenario 8: Dual GNEs on a Subnet
- 13.2.9 Scenario 9: IP Addressing with Secure Mode Enabled
- 13.3 Provisionable Patchcords
- 13.4 Routing Table
- 13.5 External Firewalls
- 13.6 Open GNE
- 13.7 TCP/IP and OSI Networking
- 13.7.1 Point-to-Point Protocol
- 13.7.2 Link Access Protocol on the D Channel
- 13.7.3 OSI Connectionless Network Service
- 13.7.4 OSI Routing
- 13.7.5 TARP
- 13.7.6 TCP/IP and OSI Mediation
- 13.7.7 OSI Virtual Routers
- 13.7.8 IP-over-CLNS Tunnels
- 13.7.9 OSI/IP Networking Scenarios
- 13.7.9.1 OSI/IP Scenario 1: IP OSS, IP DCN, ONS GNE, IP DCC, and ONS ENE
- 13.7.9.2 OSI/IP Scenario 2: IP OSS, IP DCN, ONS GNE, OSI DCC, and Other Vendor ENE
- 13.7.9.3 OSI/IP Scenario 3: IP OSS, IP DCN, Other Vendor GNE, OSI DCC, and ONS ENE
- 13.7.9.4 OSI/IP Scenario 4: Multiple ONS DCC Areas
- 13.7.9.5 OSI/IP Scenario 5: GNE Without an OSI DCC Connection
- 13.7.9.6 OSI/IP Scenario 6: IP OSS, OSI DCN, ONS GNE, OSI DCC, and Other Vendor ENE
- 13.7.9.7 OSI/IP Scenario 7: OSI OSS, OSI DCN, Other Vendor GNE, OSI DCC, and ONS NEs
- 13.7.9.8 OSI/IP Scenario 8: OSI OSS, OSI DCN, ONS GNE, OSI DCC, and Other Vendor NEs
- 13.7.10 Provisioning OSI in CTC
- Alarm Monitoring and Management
- 14.1 Overview
- 14.2 LCD Alarm Counts
- 14.3 Alarm Information
- 14.4 Alarm Severities
- 14.5 Alarm Profiles
- 14.6 Alarm Suppression
- 14.7 External Alarms and Controls
- Performance Monitoring
- 15.1 Threshold Performance Monitoring
- 15.2 Intermediate-Path Performance Monitoring
- 15.3 Pointer Justification Count Performance Monitoring
- 15.4 Performance Monitoring Parameter Definitions
- 15.5 Performance Monitoring for Electrical Cards
- 15.6 Performance Monitoring for Ethernet Cards
- 15.6.1 E-Series Ethernet Card Performance Monitoring Parameters
- 15.6.2 G-Series Ethernet Card Performance Monitoring Parameters
- 15.6.3 ML-Series Ethernet Card Performance Monitoring Parameters
- 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters
- 15.6.4.1 CE-Series Ether Ports Statistics Parameters
- 15.6.4.2 CE-Series Card Ether Ports Utilization Parameters
- 15.6.4.3 CE-Series Card Ether Ports History Parameters
- 15.6.4.4 CE-Series POS Ports Statistics Parameters
- 15.6.4.5 CE-Series Card POS Ports Utilization Parameters
- 15.6.4.6 CE-Series Card Ether Ports History Parameters
- 15.7 Performance Monitoring for Optical Cards
- 15.8 Performance Monitoring for the Fiber Channel Card
- SNMP
- 16.1 SNMP Overview
- 16.2 Basic SNMP Components
- 16.3 SNMP External Interface Requirement
- 16.4 SNMP Version Support
- 16.5 SNMP Message Types
- 16.6 SNMP Management Information Bases
- 16.7 SNMP Trap Content
- 16.8 SNMP Community Names
- 16.9 Proxy Over Firewalls
- 16.10 Remote Monitoring
- Hardware Specifications
- A.1 Shelf Specifications
- A.2 SFP and XFP Specifications
- A.3 General Card Specifications
- A.4 Common Control Card Specifications
- A.5 Electrical Card and FMEC Specifications
- A.5.1 E1-N-14 Card Specifications
- A.5.2 E1-42 Card Specifications
- A.5.3 E3-12 Card Specifications
- A.5.4 DS3i-N-12 Card Specifications
- A.5.5 STM1E-12 Card Specifications
- A.5.6 FILLER Card
- A.5.7 FMEC-E1 Specifications
- A.5.8 FMEC-DS1/E1 Specifications
- A.5.9 FMEC E1-120NP Specifications
- A.5.10 FMEC E1-120PROA Specifications
- A.5.11 FMEC E1-120PROB Specifications
- A.5.12 E1-75/120 Impedance Conversion Panel Specifications
- A.5.13 FMEC-E3/DS3 Specifications
- A.5.14 FMEC STM1E 1:1 Specifications
- A.5.15 BLANK-FMEC Specifications
- A.5.16 MIC-A/P Specifications
- A.5.17 MIC-C/T/P Specifications
- A.6 Optical Card Specifications
- A.6.1 OC3 IR 4/STM1 SH 1310 Card Specifications
- A.6.2 OC3 IR/STM1 SH 1310-8 Card Specifications
- A.6.3 OC12 IR/STM4 SH 1310 Card Specifications
- A.6.4 OC12 LR/STM4 LH 1310 Card Specifications
- A.6.5 OC12 LR/STM4 LH 1550 Card Specifications
- A.6.6 OC12 IR/STM4 SH 1310-4 Card Specifications
- A.6.7 OC48 IR/STM16 SH AS 1310 Card Specifications
- A.6.8 OC48 LR/STM16 LH AS 1550 Card Specifications
- A.6.9 OC48 ELR/STM16 EH 100 GHz Card Specifications
- A.6.10 OC192 SR/STM64 IO 1310 Card Specifications
- A.6.11 OC192 IR/STM64 SH 1550 Card Specifications
- A.6.12 OC192 LR/STM64 LH 1550 Card Specifications
- A.6.13 OC192 LR/STM64 LH ITU 15xx.xx Card Specifications
- A.6.14 15454_MRC-12 Card Specifications
- A.6.15 OC192SR1/STM64IO Short Reach Card Specifications
- A.6.16 OC192/STM64 Any Reach Card Specifications
- A.7 Ethernet Card Specifications
- A.8 Storage Access Networking Card Specifications
- Administrative and Service States
- Network Element Defaults
- C.1 Network Element Defaults Description
- C.2 Card Default Settings
- C.2.1 Configuration Defaults
- C.2.2 Threshold Defaults
- C.2.3 Defaults by Card
- C.2.3.1 E1-N-14 Card Default Settings
- C.2.3.2 E1-42 Card Default Settings
- C.2.3.3 E3-12 Card Default Settings
- C.2.3.4 DS3i-N-12 Card Default Settings
- C.2.3.5 STM1E-12 Card Default Settings
- C.2.3.6 Ethernet Card Default Settings
- C.2.3.7 STM-1 Card Default Settings
- C.2.3.8 STM1-8 Card Default Settings
- C.2.3.9 STM-4 Card Default Settings
- C.2.3.10 STM4-4 Card Default Settings
- C.2.3.11 STM-16 Card Default Settings
- C.2.3.12 STM-64 Card Default Settings
- C.2.3.13 STM64-XFP Default Settings
- C.2.3.14 MRC-12 Card Default Settings
- C.2.3.15 FC_MR-4 Card Default Settings
- C.3 Node Default Settings
- C.4 CTC Default Settings
- Index
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Cisco ONS 15454 SDH Reference Manual, R7.0
October 2008
Chapter 13 Management Network Connectivity
13.7.5 TARP
• NSAP—NSAP of the originating NE.
• Type— Indicates whether the TARP PDU was created through the TARP propagation process
(dynamic) or manually created (static).
Provisionable timers, shown in Table 13-14, control TARP processing.
Table 13-15 shows the main TARP processes and the general sequence of events that occurs in each
process.
13.7.5.2 TARP Loop Detection Buffer
The TARP loop detection buffer (LDB) can be enabled to prevent duplicate TARP PDUs from entering
the TDC. When a TARP Type 1, 2, or 4 PDU arrives, TARP checks its LDB for a NET address (tar-por)
of the PDU originator match. If no match is found, TARP processes the PDU and assigns a tar-por,
tar-seq (sequence) entry for the PDU to the LDB. If the tar-seq is zero, a timer associated with the LDB
entry is started using the provisionable LDB entry timer on the node view OSI > TARP > Config tab. If
a match exists, the tar-seq is compared to the LDB entry. If the tar-seq is not zero and is less than or equal
to the LDB entry, the PDU is discarded. If the tar-seq is greater than the LDB entry, the PDU is processed
Table 13-14 TARP Timers
Timer Description
Default
(seconds)
Range
(seconds)
T1 Waiting for response to TARP Type 1 Request PDU 15 0–3600
T2 Waiting for response to TARP Type 2 Request PDU 25 0–3600
T3 Waiting for response to address resolution request 40 0–3600
T4 Timer starts when T2 expires (used during error recovery) 20 0–3600
Table 13-15 TARP Processing Flow
Process General TARP Flow
Find a NET that
matches a TID
1. TARP checks its TDC for a match. If a match is found, TARP returns the
result to the requesting application.
2. If no match is found, a TARP Type 1 PDU is generated and Timer T1 is
started.
3. If Timer T1 expires before a match if found, a Type 2 PDU is generated and
Timer T2 is started.
4. If Timer T2 expires before a match is found, Timer T4 is started.
5. If Timer T4 expires before a match is found, a Type 2 PDU is generated and
Timer T2 is started.
Find a TID that
matches a NET
A Type 5 PDU is generated. Timer T3 is used. However, if the timer expires, no
error recovery procedure occurs, and a status message is provided to indicate
that the TID cannot be found.
Send a notification
of TID or protocol
address change
TARP generates a Type 4 PDU in which the tar-ttg field contains the NE’s TID
value that existed prior to the change of TID or protocol address. Confirmation
that other NEs successfully received the address change is not sent.