Cisco ONS 15454 SDH Reference Manual Product and Documentation Release 7.0 Last Updated: October 2008 Corporate Headquarters Cisco Systems, Inc. 170 West Tasman Drive San Jose, CA 95134-1706 USA http://www.cisco.
THE SPECIFICATIONS AND INFORMATION REGARDING THE PRODUCTS IN THIS MANUAL ARE SUBJECT TO CHANGE WITHOUT NOTICE. ALL STATEMENTS, INFORMATION, AND RECOMMENDATIONS IN THIS MANUAL ARE BELIEVED TO BE ACCURATE BUT ARE PRESENTED WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED. USERS MUST TAKE FULL RESPONSIBILITY FOR THEIR APPLICATION OF ANY PRODUCTS.
CONTENTS About this Manual xxxv Revision History xxxv Document Objectives Audience xxxvi xxxvi Document Organization xxxvi Related Documentation xxxviii Document Conventions xxxix Obtaining Optical Networking Information xlv Where to Find Safety and Warning Information xlv Cisco Optical Networking Product Documentation CD-ROM Obtaining Documentation and Submitting a Service Request CHAPTER 1 Shelf and FMEC Hardware 1.1 Overview 1.2 Front Door xlv xlv 1-1 1-2 1-3 1.
Contents CHAPTER 2 Common Control Cards 2-1 2.1 Common Control Card Overview 2-1 2.1.1 Card Summary 2-1 2.1.2 Card Compatibility 2-2 2.1.3 Cross-Connect Card Compatibility 2-3 2.2 TCC2 Card 2-5 2.2.1 TCC2 Card Functionality 2-6 2.2.2 TCC2 Card-Level Indicators 2-8 2.2.3 Network-Level Indicators 2-8 2.2.4 Power-Level Indicators 2-9 2.3 TCC2P Card 2-9 2.3.1 TCC2P Functionality 2-10 2.3.2 TCC2P Card-Level Indicators 2-12 2.3.3 Network-Level Indicators 2-12 2.3.4 Power-Level Indicators 2-13 2.
Contents 3.2.1 E1-N-14 Card Functionality 3-5 3.2.2 E1-N-14 Card-Level Indicators 3-6 3.2.3 E1-N-14 Port-Level Indicators 3-6 3.3 E1-42 Card 3-6 3.3.1 E1-42 Card Functionality 3-7 3.3.2 E1-42 Card-Level Indicators 3-8 3.3.3 E1-42 Port-Level Indicators 3-8 3.4 E3-12 Card 3-8 3.4.1 E3-12 Card Functionality 3-9 3.4.2 E3-12 Card-Level Indicators 3-10 3.4.3 E3-12 Port-Level Indicators 3-10 3.5 DS3i-N-12 Card 3-10 3.5.1 DS3i-N-12 Card Functionality 3-11 3.5.2 DS3i-N-12 Card-Level Indicators 3-12 3.5.
Contents 4.2.1 OC3 IR 4/STM1 SH 1310 Functionality 4-6 4.2.2 OC3 IR 4/STM1 SH 1310 Card-Level Indicators 4-6 4.2.3 OC3 IR 4/STM1 SH 1310 Port-Level Indicators 4-6 4.3 OC3 IR/STM1 SH 1310-8 Card 4-7 4.3.1 OC3 IR/STM1 SH 1310-8 Card-Level Indicators 4-8 4.3.2 OC3 IR/STM1 SH 1310-8 Port-Level Indicators 4-8 4.4 OC12 IR/STM4 SH 1310 Card 4-8 4.4.1 OC12 IR/STM4 SH 1310 Card-Level Indicators 4-10 4.4.2 OC12 IR/STM4 SH 1310 Port-Level Indicators 4-10 4.5 OC12 LR/STM4 LH 1310 Card 4-10 4.5.
Contents 4.12.3 OC192 IR/STM64 SH 1550 Port-Level Indicators 4-26 4.13 OC192 LR/STM64 LH 1550 Card 4-26 4.13.1 OC192 LR/STM64 LH 1550 Card Functionality 4-29 4.13.2 OC192 LR/STM64 LH 1550 Card-Level Indicators 4-30 4.13.3 OC192 LR/STM64 LH 1550 Port-Level Indicators 4-30 4.14 OC192 LR/STM64 LH ITU 15xx.xx Card 4-30 4.14.1 OC192 LR/STM64 LH ITU 15xx.xx Card Functionality 4-32 4.14.2 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators 4-33 4.14.3 OC192 LR/STM64 LH ITU 15xx.xx Port-Level Indicators 4-33 4.
Contents 5.4.3 G1000-4 Port-Level Indicators 5.4.4 Slot Compatibility 5-11 5-10 5.5 G1K-4 Card 5-11 5.5.1 G1K-4 Card-Level Indicators 5-12 5.5.2 G1K-4 Port-Level Indicators 5-13 5.5.3 G1K-4 Compatibility 5-13 5.6 ML100T-12 Card 5-13 5.6.1 ML100T-12 Card-Level Indicators 5-15 5.6.2 ML100T-12 Port-Level Indicators 5-15 5.6.3 ML100T-12 Compatibility 5-15 5.7 ML100X-8 Card 5-15 5.7.1 ML100X-8 Card-Level Indicators 5-17 5.7.2 ML100X-8 Port-Level Indicators 5-17 5.7.3 ML100X-8 Compatibility 5-17 5.
Contents 6.2.2 Enhanced Card Mode 6-4 6.2.2.1 Mapping 6-4 6.2.2.2 SW-LCAS 6-4 6.2.2.3 Distance Extension 6-5 6.2.2.4 Differential Delay Features 6-5 6.2.2.5 Interoperability Features 6-6 6.2.3 Link Integrity 6-6 6.2.4 Link Recovery 6-6 6.3 FC_MR-4 Card Application 6.4 FC_MR-4 Card GBICs CHAPTER 7 Card Protection 6-6 6-7 7-1 7.1 Electrical Card Protection 7-1 7.1.1 1:1 Protection 7-1 7.1.2 1:N Protection 7-2 7.1.2.1 Revertive Switching 7-3 7.1.2.2 1:N Protection Guidelines 7.
Contents 8.5.2.4 Link Consolidation 8-14 8.5.3 Card View 8-14 8.5.4 Print or Export CTC Data 8-16 8.6 TCC2/TCC2P Card Reset 8-17 8.7 TCC2/TCC2P Card Database 8.8 Software Revert CHAPTER Security 9 8-17 8-17 9-1 9.1 User IDs and Security Levels 9-1 9.2 User Privileges and Policies 9-1 9.2.1 User Privileges by CTC Task 9-2 9.2.2 Security Policies 9-5 9.2.2.1 Superuser Privileges for Provisioning Users 9-6 9.2.2.2 Idle User Timeout 9-6 9.2.2.3 User Password, Login, and Access Policies 9-6 9.2.2.
Contents 11.4.1 Traditional DCC Tunnels 11.4.2 IP-Encapsulated Tunnels 11-12 11-13 11.5 Multiple Destinations for Unidirectional Circuits 11.6 Monitor Circuits 11-14 11-14 11.7 SNCP Circuits 11-14 11.7.1 Open-Ended SNCP Circuits 11-15 11.7.2 Go-and-Return SNCP Routing 11-15 11.8 MS-SPRing Protection Channel Access Circuits 11.9 MS-SPRing VC4 Squelch Table 11.10 Section and Path Trace 11-16 11-17 11-17 11.11 Path Signal Label, C2 Byte 11-18 11.12 Automatic Circuit Routing 11-19 11.12.
Contents 12.2.5 MS-SPRing Fiber Connections 12-12 12.2.6 Two-Fiber MS-SPRing to Four-Fiber MS-SPRing Conversion 12.3 Subnetwork Connection Protection 12-13 12.4 Dual Ring Interconnect 12-18 12.4.1 MS-SPRing DRI 12-18 12.4.2 SNCP Dual Ring Interconnect 12-21 12.4.3 SNCP/MS-SPRing DRI Handoff Configurations 12.5 Subtending Rings 12-13 12-24 12-25 12.6 Linear ADM Configurations 12-27 12.7 Extended SNCP Mesh Networks 12.8 Four Node Configurations 12-28 12-30 12.9 STM-N Speed Upgrades 12-30 12.9.
Contents 13.7.5 TARP 13-37 13.7.5.1 TARP Processing 13-38 13.7.5.2 TARP Loop Detection Buffer 13-39 13.7.5.3 Manual TARP Adjacencies 13-40 13.7.5.4 Manual TID to NSAP Provisioning 13-40 13.7.6 TCP/IP and OSI Mediation 13-40 13.7.7 OSI Virtual Routers 13-41 13.7.8 IP-over-CLNS Tunnels 13-42 13.7.8.1 Provisioning IP-over-CLNS Tunnels 13-43 13.7.8.2 IP-over-CLNS Tunnel Scenario 1: ONS Node to Other Vendor GNE 13-44 13.7.8.3 IP-over-CLNS Tunnel Scenario 2: ONS Node to Router 13-45 13.7.8.
Contents 14.3.7.2 Retrieving and Displaying Alarm and Condition History 14.3.8 Alarm History and Log Buffer Capacities 14-10 14.4 Alarm Severities 14-9 14-10 14.5 Alarm Profiles 14-10 14.5.1 Creating and Modifying Alarm Profiles 14.5.2 Alarm Profile Buttons 14-12 14.5.3 Alarm Profile Editing 14-12 14.5.4 Alarm Severity Options 14-12 14.5.5 Row Display Options 14-13 14.5.6 Applying Alarm Profiles 14-13 14-11 14.6 Alarm Suppression 14-14 14.6.1 Alarms Suppressed for Maintenance 14-14 14.6.
Contents 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters 15-26 15.6.4.1 CE-Series Ether Ports Statistics Parameters 15-26 15.6.4.2 CE-Series Card Ether Ports Utilization Parameters 15-30 15.6.4.3 CE-Series Card Ether Ports History Parameters 15-30 15.6.4.4 CE-Series POS Ports Statistics Parameters 15-30 15.6.4.5 CE-Series Card POS Ports Utilization Parameters 15-31 15.6.4.6 CE-Series Card Ether Ports History Parameters 15-31 15.7 Performance Monitoring for Optical Cards 15-31 15.7.
Contents 16.10.2 HC-RMON-MIB Support 16-18 16.10.3 Ethernet Statistics RMON Group 16-18 16.10.3.1 Row Creation in etherStatsTable 16-18 16.10.3.2 Get Requests and GetNext Requests 16-19 16.10.3.3 Row Deletion in etherStatsTable 16-19 16.10.3.4 64-Bit etherStatsHighCapacity Table 16-19 16.10.4 History Control RMON Group 16-19 16.10.4.1 History Control Table 16-19 16.10.4.2 Row Creation in historyControlTable 16-19 16.10.4.3 Get Requests and GetNext Requests 16-20 16.10.4.
Contents A.4.1 A.4.2 A.4.3 A.4.4 A.4.5 A.4.6 TCC2 Card Specifications A-10 TCC2P Card Specifications A-10 XC-VXL-10G Card Specifications A-11 XC-VXL-2.5G Card Specifications A-12 XC-XVC-10G Card Specifications A-12 AIC-I Specifications A-12 A.5 Electrical Card and FMEC Specifications A-14 A.5.1 E1-N-14 Card Specifications A-14 A.5.2 E1-42 Card Specifications A-15 A.5.3 E3-12 Card Specifications A-16 A.5.4 DS3i-N-12 Card Specifications A-17 A.5.5 STM1E-12 Card Specifications A-18 A.5.6 FILLER Card A-19 A.
Contents A.6.16 OC192/STM64 Any Reach Card Specifications A-43 A.7 Ethernet Card Specifications A-44 A.7.1 E100T-G Card Specifications A-44 A.7.2 E1000-2-G Card Specifications A-45 A.7.3 CE-1000-4 Card Specifications A-45 A.7.4 CE-100T-8 Card Specifications A-45 A.7.5 G1K-4 Card Specifications A-46 A.7.6 ML100T-12 Card Specifications A-46 A.7.7 ML1000-2 Card Specifications A-47 A.7.8 ML100X-8 Card Specifications A-47 A.8 Storage Access Networking Card Specifications A.8.
Contents C.2.3.14 MRC-12 Card Default Settings C-35 C.2.3.15 FC_MR-4 Card Default Settings C-45 C.3 Node Default Settings C-46 C.3.1 Time Zones C-55 C.4 CTC Default Settings C-58 INDEX Cisco ONS 15454 SDH Reference Manual, R7.
Contents Cisco ONS 15454 SDH Reference Manual, R7.
F I G U R E S Figure 1-1 ONS 15454 SDH Dimensions Figure 1-2 The ONS 15454 SDH Front Door Figure 1-3 Removing the ONS 15454 SDH Front Door Figure 1-4 Front-Door Erasable Label Figure 1-5 Laser Warning on the Front-Door Label Figure 1-6 Mounting the E1-75/120 Conversion Panel in a Rack Figure 1-7 100BaseT Connector Pins Figure 1-8 Straight-Through Cable Figure 1-9 Crossover Cable Figure 1-10 Managing Cables on the Front Panel Figure 1-11 Fiber Capacity Figure 1-12 Position of the Fan-
Figures Figure 3-9 FMEC E1-120NP Faceplate and Block Diagram Figure 3-10 FMEC E1-120PROA Faceplate and Block Diagram 3-21 Figure 3-11 FMEC E1-120PROB Faceplate and Block Diagram 3-24 Figure 3-12 E1-75/120 Impedance Conversion Panel Faceplate Figure 3-13 E1-75/120 with Optional Rackmount Brackets Figure 3-14 E1-75/120 Impedance Conversion Panel Block Diagram Figure 3-15 FMEC-E3/DS3 Faceplate and Block Diagram Figure 3-16 FMEC STM1E 1:1 Faceplate and Block Diagram Figure 3-17 BLANK-FMEC Fa
Figures Figure 5-3 G1000-4 Faceplate and Block Diagram Figure 5-4 G1K-4 Faceplate and Block Diagram Figure 5-5 ML100T-12 Faceplate and Block Diagram Figure 5-6 ML100X-8 Faceplate and Block Diagram 5-16 Figure 5-7 ML1000-2 Faceplate and Block Diagram 5-18 Figure 5-8 CE-100T-8 Faceplate and Block Diagram 5-20 Figure 5-9 CE-1000-4 Faceplate and Block Diagram 5-24 Figure 5-10 GBICs with Clips (left) and with a Handle (right) Figure 5-11 CWDM GBIC with Wavelength Appropriate for Fiber-Conne
Figures Figure 11-11 VCAT Common Fiber Routing Figure 11-12 VCAT Split Fiber Routing Figure 11-13 Rolls Window Figure 11-14 Single Source Roll Figure 11-15 Single Destination Roll Figure 11-16 Single Roll from One Circuit to Another Circuit (Destination Changes) Figure 11-17 Single Roll from One Circuit to Another Circuit (Source Changes) Figure 11-18 Dual Roll to Reroute a Link Figure 11-19 Dual Roll to Reroute to a Different Node Figure 12-1 Four-Node, Two-Fiber MS-SPRing Figure 12-2
Figures Figure 12-27 MS-SPRing Subtending from an MS-SPRing Figure 12-28 Linear (Point-to-Point) ADM Configuration Figure 12-29 Extended SNCP Mesh Network Figure 12-30 Extended SNCP Virtual Ring Figure 13-1 Scenario 1: CTC and ONS 15454 SDH Nodes on the Same Subnet 13-3 Figure 13-2 Scenario 2: CTC and ONS 15454 SDH Nodes Connected to Router 13-4 Figure 13-3 Scenario 3: Using Proxy ARP Figure 13-4 Scenario 3: Using Proxy ARP with Static Routing 13-6 Figure 13-5 Scenario 4: Default Gatewa
Figures Figure 13-32 OSI/IP Scenario 3 with OSI/IP-over-CLNS Tunnel Endpoint at the GNE Figure 13-33 OSI/IP Scenario 4: Multiple ONS DCC Areas Figure 13-34 OSI/IP Scenario 5: GNE Without an OSI DCC Connection Figure 13-35 OSI/IP Scenario 6: IP OSS, OSI DCN, ONS GNE, OSI DCC, and Other Vendor ENE Figure 13-36 OSI/IP Scenario 7: OSI OSS, OSI DCN, Other Vender GNE, OSI DCC, and ONS NEs 13-57 Figure 13-37 OSI/IP Scenario 8: OSI OSS, OSI DCN, ONS GNE, OSI DCC, and Other Vender NEs 13-59 Figure 14-
T A B L E S Table 1-1 Slot and FMEC Symbols Table 1-2 FMEC, Ports, Line Rates, and Connectors Table 1-3 E100-TX Connector Pinout Table 1-4 Fiber Channel Capacity (One Side of the Shelf) Table 1-5 Slot and Card Symbols Table 1-6 Card Ports, Line Rates, and Connectors Table 1-7 ONS 15454 SDH Software Release/Hardware Compatibility—XC-VXL-2.
Tables Table 3-3 E1-N-14 Card-Level Indicators Table 3-4 E1-42 Card-Level Indicators 3-8 Table 3-5 E3-12 Card-Level Indicators 3-10 Table 3-6 DS3i-N-12 Card-Level Indicators 3-12 Table 3-7 STM1E-12 Card-Level Indicators 3-14 Table 3-8 E-1 Interface Pinouts on the FMEC-DS1/E1 Card Ports 1 to 7 Table 3-9 E-1 Interface Pinouts on the FMEC-DS1/E1 Card Ports 8 to 14 Table 3-10 E-1 Interface Pinouts on the FMEC E1-120NP Card Ports 1 to 21 Table 3-11 E-1 Interface Pinouts on the FMEC E1-120NP
Tables Table 5-2 Ethernet Card Software Compatibility Table 5-3 E100T-G Card-Level Indicators 5-5 Table 5-4 E100T-G Port-Level Indicators 5-5 Table 5-5 E1000-2-G Card-Level Indicators 5-8 Table 5-6 E1000-2-G Port-Level Indicators 5-8 Table 5-7 G1000-4 Card-Level Indicators 5-10 Table 5-8 G1000-4 Port-Level Indicators 5-11 Table 5-9 G1K-4 Card-Level Indicators 5-13 Table 5-10 G1K-4 Port-Level Indicators 5-13 Table 5-11 ML100T-12 Card-Level Indicators 5-15 Table 5-12 ML100T-12 P
Tables Table 8-12 Link Icons Table 8-13 Card View Tabs and Subtabs Table 9-1 ONS 15454 SDH Security Levels—Node View Table 9-2 ONS 15454 SDH Security Levels—Network View Table 9-3 ONS 15454 SDH Default User Idle Times Table 9-4 Audit Trail Window Columns Table 9-5 Shared Secret Character Groups Table 10-1 SDH SSM Message Set 10-3 Table 11-1 VC4 Mapping Using CTC 11-4 Table 11-2 ONS 15454 SDH Circuit Status Table 11-3 Circuit Protection Types Table 11-4 Port State Color Indicators
Tables Table 13-10 TCP/IP and OSI Protocols Table 13-11 NSAP Fields Table 13-12 TARP PDU Fields 13-37 Table 13-13 TARP PDU Types 13-38 Table 13-14 TARP Timers Table 13-15 TARP Processing Flow Table 13-16 OSI Virtual Router Constraints Table 13-17 IP-over-CLNS Tunnel IOS Commands Table 13-18 OSI Actions from the CTC Provisioning Tab Table 13-19 OSI Actions from the CTC Maintenance Tab Table 14-1 Alarms Column Descriptions Table 14-2 Color Codes for Alarm and Condition Severities Ta
Tables Table 15-17 PM Parameters for the STM-1E Cards Table 15-18 PM Parameters for STM-4 Cards Table 15-19 PM Parameters for STM-16 and STM-64 Cards Table 15-20 Table of Border Error Rates Table 15-21 MRC-12 Card PMs Table 15-22 maxBaseRate for STS Circuits Table 15-23 FC_MR-4 History Statistics per Time Interval Table 16-1 ONS 15454 SDH SNMP Message Types Table 16-2 IETF Standard MIBs Implemented in the ONS 15454 SDH System Table 16-3 ONS 15454 SDH Proprietary MIBs Table 16-4 cerentG
Tables Table C-11 STM-16 Card Default Settings C-25 Table C-12 STM-64 Card Default Settings C-28 Table C-13 STM64-XFP Default Settings Table C-14 MRC-12 Card Default Settings Table C-15 FC_MR-4 Card Default Settings Table C-16 Node Default Settings Table C-17 Time Zones Table C-18 CTC Default Settings C-31 C-35 C-45 C-47 C-55 C-58 Cisco ONS 15454 SDH Reference Manual, R7.
Tables Cisco ONS 15454 SDH Reference Manual, R7.
About this Manual Note The terms "Unidirectional Path Switched Ring" and "UPSR" may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as "Path Protected Mesh Network" and "PPMN," refer generally to Cisco's path protection feature, which may be used in any topological network configuration.
About this Manual Date Notes April 2008 Added a note in the “User Password, Login, and Access Policies” section in the Security chapter. Updated note on protection switching in “Link Capacity Adjustment” section of Chapter 11, Circuits and Tunnels. May 2008 Added power-level LED information for TCC2 and TCC2P cards in Chapter 2, Common Control Cards.
About this Manual Table 1 Cisco ONS 15454 SDH Reference Manual Chapters Title Summary Chapter 1, “Shelf and FMEC Hardware” Includes descriptions of the rack, ferrites, power and ground, fan-tray assembly, air filter, card slots, cable, cable connectors, and cable routing. Chapter 2, “Common Control Cards” Includes descriptions of the TCC2P, XC10G, XC-VXL, and AIC-I cards.
About this Manual Table 1 Cisco ONS 15454 SDH Reference Manual Chapters (continued) Title Summary Chapter 13, “Management Network Connectivity” Provides an overview of ONS 15454 SDH data communications network (DCN) connectivity, scenarios showing Cisco ONS 15454 SDH nodes in common IP network configurations, and information about provisionable patchcords, the IP routing table, external firewalls, and open gateway network element (GNE) networks.
About this Manual Document Conventions This publication uses the following conventions: Convention Application boldface Commands and keywords in body text. italic Command input that is supplied by the user. [ Keywords or arguments that appear within square brackets are optional. ] {x|x|x} A choice of keywords (represented by x) appears in braces separated by vertical bars. The user must select one. Ctrl The control key.
About this Manual Warning IMPORTANT SAFETY INSTRUCTIONS This warning symbol means danger. You are in a situation that could cause bodily injury. Before you work on any equipment, be aware of the hazards involved with electrical circuitry and be familiar with standard practices for preventing accidents. Use the statement number provided at the end of each warning to locate its translation in the translated safety warnings that accompanied this device.
About this Manual Avvertenza IMPORTANTI ISTRUZIONI SULLA SICUREZZA Questo simbolo di avvertenza indica un pericolo. La situazione potrebbe causare infortuni alle persone. Prima di intervenire su qualsiasi apparecchiatura, occorre essere al corrente dei pericoli relativi ai circuiti elettrici e conoscere le procedure standard per la prevenzione di incidenti.
About this Manual Cisco ONS 15454 SDH Reference Manual, R7.
About this Manual Aviso INSTRUÇÕES IMPORTANTES DE SEGURANÇA Este símbolo de aviso significa perigo. Você se encontra em uma situação em que há risco de lesões corporais. Antes de trabalhar com qualquer equipamento, esteja ciente dos riscos que envolvem os circuitos elétricos e familiarize-se com as práticas padrão de prevenção de acidentes. Use o número da declaração fornecido ao final de cada aviso para localizar sua tradução nos avisos de segurança traduzidos que acompanham o dispositivo.
About this Manual Cisco ONS 15454 SDH Reference Manual, R7.
About this Manual Obtaining Optical Networking Information This section contains information that is specific to optical networking products. For information that pertains to all of Cisco, refer to the Obtaining Documentation and Submitting a Service Request section. Where to Find Safety and Warning Information For safety and warning information, refer to the Cisco Optical Transport Products Safety and Compliance Information document that accompanied the product.
About this Manual Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 1 Shelf and FMEC Hardware This chapter provides a description of Cisco ONS 15454 SDH shelf and backplane hardware. Card and cable descriptions are provided in Chapter 2, “Common Control Cards,” Chapter 3, “Electrical Cards,” Chapter 4, “Optical Cards,” Chapter 5, “Ethernet Cards,” and Chapter 6, “Storage Access Networking Cards.” To install equipment, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: Note Caution • 1.1 Overview, page 1-2 • 1.
Chapter 1 Shelf and FMEC Hardware 1.1 Overview 1.1 Overview When installed in an equipment rack, the ONS 15454 SDH assembly is typically connected to a fuse and alarm panel to provide centralized alarm connection points and distributed power for the ONS 15454 SDH. Fuse and alarm panels are third-party equipment and are not described in this documentation. If you are unsure about the requirements or specifications for a fuse and alarm panel, consult the user documentation for the related equipment.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door Figure 1-1 ONS 15454 SDH Dimensions Top View 535 mm (21.06 in.) total width 280 mm (11.02 in.) Side View 40 mm (1.57 in.) Front View 280 mm (11.02 in.) 535 mm (21.06 in.) total width 61213 616.5 mm (24.27 in.) 1.2 Front Door The Critical, Major, and Minor alarm LEDs visible through the front door indicate whether a critical, major, or minor alarm is present anywhere on the ONS 15454 SDH.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door Figure 1-2 The ONS 15454 SDH Front Door CISCO ONS 15454 Optical Network System Door lock Door button 33923 Viewholes for Critical, Major and Minor alarm LEDs You can remove the front door of the ONS 15454 SDH to provide unrestricted access to the front of the shelf assembly (Figure 1-3). Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door Removing the ONS 15454 SDH Front Door FAN 61237 Figure 1-3 FAIL CR IT MAJ MIN Translucent circles for LED viewing Door hinge Assembly hinge pin Assembly hinge An erasable label is pasted on the inside of the front door (Figure 1-4). You can use the label to record slot assignments, port assignments, card types, node ID, rack ID, and serial number for the ONS 15454 SDH. Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door Front-Door Erasable Label P/N 47-12460-01 124755 Figure 1-4 The front door label also includes the Class I and Class 1M laser warning (Figure 1-5). Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 1 Shelf and FMEC Hardware 1.3 Front Mount Electrical Connection Laser Warning on the Front-Door Label 78099 Figure 1-5 1.3 Front Mount Electrical Connection The positive and negative power terminals are located on FMEC cards in the Electrical Facility Connection Assembly (EFCA). The ground connection is the grounding receptacle on the side panel of the shelf. The ONS 15454 SDH EFCA at the top of the shelf has 12 FMEC slots numbered sequentially from left to right (18 to 29).
Chapter 1 Shelf and FMEC Hardware 1.3 Front Mount Electrical Connection • FMEC Slot 20 supports an electrical card in Slot 3. • FMEC Slot 21 supports an electrical card in Slot 4. • FMEC Slot 22 supports an electrical card in Slot 5. • FMEC Slot 23 hosts the MIC-A/P alarm and power FMEC. • FMEC Slot 24 supports the MIC-C/T/P timing, craft, and power FMEC. • FMEC Slot 25 supports an electrical card in Slot 13. • FMEC Slot 26 supports an electrical card in Slot 14.
Chapter 1 Shelf and FMEC Hardware 1.4 E1-75/120 Conversion Panel Table 1-2 FMEC, Ports, Line Rates, and Connectors (continued) FMEC Ports Line Rate per Port Connector Type Connector Location FMEC E1-120PROB 3 to 42 2.048 Mbps Molex 96-pin LFH connector EFCA, Slots 26 to 29 FMEC-E3/DS3 12 34.368 Mbps 1.0/2.3 miniature coax connector EFCA 1.0/2.3 miniature coax connector EFCA 44.736 Mbps FMEC STM1E 1:1 12 (protected) or 155.
Chapter 1 Shelf and FMEC Hardware 1.5 Coaxial Cable Figure 1-6 Mounting the E1-75/120 Conversion Panel in a Rack 83912 Equipment rack 1.5 Coaxial Cable Caution Always use the supplied ESD wristband when working with a powered ONS 15454 SDH. Plug the wristband cable into the ESD jack located on the lower-right outside edge of the shelf assembly. All interfaces that are listed in Table 1-2 on page 1-8 with 1.0/2.
Chapter 1 Shelf and FMEC Hardware 1.7 Ethernet Cables All E-1 interfaces that are listed in Table 1-2 on page 1-8 with DB-37 or with Molex 96-pin LFH connectors must be connected using a 120-ohm twisted-pair balanced cable. For the interfaces that use Molex 96-pin LFH connectors Cisco offers ready-made cables. 1.7 Ethernet Cables Ethernet cables use RJ-45 connectors, and are straight-through or crossover, depending on what is connected to them.
Chapter 1 Shelf and FMEC Hardware 1.8 Cable Routing and Management Figure 1-8 shows the straight-through Ethernet cable schematic. Use a straight-through cable when connecting to a router or a PC. Straight-Through Cable Switch Router or PC 3 TD+ 6 TD– 3 RD+ 6 RD– 1 RD+ 2 RD– 1 TD+ 2 TD– H5578 Figure 1-8 Figure 1-9 shows the crossover Ethernet cable schematic. Use a crossover cable when connecting to a switch or hub.
Chapter 1 Shelf and FMEC Hardware 1.9 Fiber Management Figure 1-10 Managing Cables on the Front Panel FAN FAIL CR IT MA J MIN 145262 Cable-routing channel posts Fold down front door 1.9 Fiber Management The jumper routing fins are designed to route fiber jumpers out of both sides of the shelf. Slots 1 to 6 exit to the left, and Slots 12 to 17 exit to the right. Figure 1-11 shows fibers routed from cards in the left slots, down through the fins, then exiting out the fiber channel to the left.
Chapter 1 Shelf and FMEC Hardware 1.10 Fan-Tray Assembly Table 1-4 provides the maximum capacity of the fiber channel for one side of a shelf, depending on fiber size and number of Ethernet cables running through that fiber channel. Table 1-4 Fiber Channel Capacity (One Side of the Shelf) Maximum Number of Fibers Exiting Each Side Fiber Diameter No Ethernet Cables One Ethernet Cable Two Ethernet Cables 1.6 mm (0.6 inch) 126 110 94 2 mm (0.7 inch) 80 70 60 3 mm (0.
Chapter 1 Shelf and FMEC Hardware 1.10.1 Fan Speed Position of the Fan-Tray Assembly 61236 Figure 1-12 FAN FAIL CR IT MAJ MIN LCD Fan tray assembly 1.10.1 Fan Speed If one or more fans fail on the fan-tray assembly, replace the entire assembly. You cannot replace individual fans. The red Fan Fail LED on the front of the fan tray illuminates when one or more fans fail. For fan tray replacement instructions, refer to the Cisco ONS 15454 SDH Troubleshooting Guide.
Chapter 1 Shelf and FMEC Hardware 1.11 Power and Ground Description Caution Do not operate an ONS 15454 SDH without a fan-tray air filter. A fan-tray air filter is mandatory. 1.11 Power and Ground Description Ground the equipment according to standards or local practices. The ONS 15454 SDH has redundant –48 VDC power connectors on the MIC-A/P and MIC-C/T/P faceplates. To install redundant power feeds, use the two power cables shipped with the ONS 15454 SDH and one ground cable. For details, see the “3.
Chapter 1 Shelf and FMEC Hardware 1.13.1 Card Slot Requirements Installing Cards in the ONS 15454 SDH FAN 61239 Figure 1-13 FAIL CR IT MAJ MIN Ejector Guide rail 1.13.1 Card Slot Requirements The ONS 15454 SDH shelf assembly has 17 card slots numbered sequentially from left to right. Slots 1 through 6 and 12 through 17 are for traffic-bearing cards. Slots 7 and 11 are dedicated to TCC2/TCC2P cards. Slots 8 and 10 are dedicated to cross-connect (XC-VXL-2.5G, XC-VXL-10G, XC-VXC-10G) cards.
Chapter 1 Shelf and FMEC Hardware 1.13.1 Card Slot Requirements Table 1-5 Symbol Color/Shape Slot and Card Symbols Definition Orange/Circle Slots 1 to 6 and 12 to 17. Only install ONS 15454 SDH cards with a circle symbol on the faceplate. Blue/Triangle Slots 5, 6, 12, and 13. Only install ONS 15454 SDH cards with circle or a triangle symbol on the faceplate. Purple/Square TCC2/TCC2P slot, Slots 7 and 11. Only install ONS 15454 SDH cards with a square symbol on the faceplate.
Chapter 1 Shelf and FMEC Hardware 1.13.2 Card Replacement Table 1-6 Card Ports, Line Rates, and Connectors (continued) Card Ports Line Rate per Port Connector Types Connector Location ML100T-12 12 100 Mbps RJ-45 Faceplate ML100X-8 8 100 Mbps SC (SFP) Faceplate ML1000-2 2 1 Gbps LC (SFP) Faceplate OC3 IR 4/STM1 SH 1310 4 155.52 Mbps (STM-1) SC Faceplate OC3IR/STM1SH 1310-8 8 155.52 Mbps (STM-1) LC Faceplate OC12 IR/STM4 SH 1310 1 622.
Chapter 1 Shelf and FMEC Hardware 1.14 Software and Hardware Compatibility Caution Removing any active card from the ONS 15454 SDH can result in traffic interruption. Use caution when replacing cards and verify that only inactive or standby cards are being replaced. If the active card needs to be replaced, switch it to standby prior to removing the card from the node. For traffic switching procedures, refer to the Cisco ONS 15454 SDH Procedure Guide.
Chapter 1 Shelf and FMEC Hardware 1.14 Software and Hardware Compatibility Table 1-7 ONS 15454 SDH Software Release/Hardware Compatibility—XC-VXL-2.5G Configurations (continued) Hardware 4.0.0x (4.0) 4.1.0x (4.1) 4.6.0x (4.6) 5.0.0x (5.0) 6.0.0x (6.0) 7.0.0x (7.
Chapter 1 Shelf and FMEC Hardware 1.14 Software and Hardware Compatibility Table 1-8 ONS 15454 SDH Software Release/Hardware Compatibility—XC10G, XC-VXC-10G, and XC-VXL-10G Configuration Hardware 4.0.0x (4.0) 4.1.0x (4.
Chapter 1 Shelf and FMEC Hardware 1.14 Software and Hardware Compatibility Table 1-8 ONS 15454 SDH Software Release/Hardware Compatibility—XC10G, XC-VXC-10G, and XC-VXL-10G Configuration (continued) 4.0.0x (4.0) 4.1.0x (4.1) Hardware 4.6.0x (4.6) 5.0.0x (5.0) 6.0.0x (6.0) 7.0.0x (7.
Chapter 1 Shelf and FMEC Hardware 1.14 Software and Hardware Compatibility Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 2 Common Control Cards This chapter describes the Cisco ONS 15454 SDH common control card functions. It includes descriptions, hardware specifications, and block diagrams for each card. For installation and card turn-up procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 2.1 Common Control Card Overview, page 2-1 • 2.2 TCC2 Card, page 2-5 • 2.3 TCC2P Card, page 2-9 • 2.4 XC-VXL-10G Card, page 2-13 • 2.5 XC-VXL-2.5G Card, page 2-15 • 2.
Chapter 2 Common Control Cards 2.1.2 Card Compatibility Table 2-1 Common Control Cards for the ONS 15454 SDH For Additional Information... Card Description TCC2 The Advanced Timing, Communications, and Control See the “2.2 TCC2 Card” section on page 2-5. (TCC2) card is the main processing center of the ONS 15454 SDH and provides system initialization, provisioning, alarm reporting, maintenance, and diagnostics. TCC2P The Advanced Timing, Communications, and Control See the “2.
Chapter 2 Common Control Cards 2.1.3 Cross-Connect Card Compatibility Table 2-2 Common-Control Card Software Release Compatibility Card R4.0 R4.1 R4.5 R4.6 R4.7 R5.0 R6.0 R7.0 TCC2 Yes Yes Yes Yes Yes Yes Yes Yes TCC2P Yes Yes Yes Yes Yes Yes Yes Yes XC10G Yes Yes — Yes — Yes No No XC-VXL-10G Yes Yes — Yes — Yes Yes Yes XC-VXL-2.5G Yes Yes — Yes — Yes Yes Yes XC-VXC-10G — — — — — — Yes Yes AIC-I Yes Yes Yes Yes Yes Yes Yes Yes 2.1.
Chapter 2 Common Control Cards 2.1.3 Cross-Connect Card Compatibility Table 2-4 Electrical Card Cross-Connect Compatibility (continued) Electrical Card XC10G Card XC-VXL-2.5G Card XC-VXL-10G Card XC-VXC-10G Card DS3i-N-12 Yes Yes Yes Yes STM1E-12 — Yes Yes Yes Table 2-5 lists the cross-connect card compatibility for each optical card. “Yes” means that the optical card is compatible with the listed cross-connect card.
Chapter 2 Common Control Cards 2.2 TCC2 Card Table 2-6 Ethernet Card Cross-Connect Compatibility (continued) Ethernet Cards XC10G Card XC-VXL-2.5G Card XC-VXL-10G Card XC-VXC-10G Card ML1000-2 Yes Yes Yes Yes ML100X-8 Yes Yes Yes Yes CE-100T-8 — Yes Yes Yes CE-1000-4 Yes Yes Yes Yes Table 2-6 lists the cross-connect card compatibility for the FC_MR-4 card. “Yes” means that the storage area network (SAN) card is compatible with the listed cross-connect card.
Chapter 2 Common Control Cards 2.2.
Chapter 2 Common Control Cards 2.2.1 TCC2 Card Functionality The TCC2 card also originates and terminates a cell bus carried over the module. The cell bus supports links between any two cards in the node, which is essential for peer-to-peer communication. Peer-to-peer communication accelerates protection switching for redundant cards. The node database, IP address, and system software are stored in TCC2 card nonvolatile memory, which allows quick recovery in the event of a power or card failure.
Chapter 2 Common Control Cards 2.2.2 TCC2 Card-Level Indicators 2.2.2 TCC2 Card-Level Indicators Table 2-8 describes the two card-level LEDs on the TCC2 card faceplate. Table 2-8 TCC2 Card-Level Indicators Card-Level LEDs Definition Red FAIL LED The FAIL LED flashes during the boot and write process. Replace the card if the FAIL LED persists. ACT/STBY LED The ACT/STBY (Active/Standby) LED indicates the TCC2 card is active (green) or in standby (amber) mode.
Chapter 2 Common Control Cards 2.2.4 Power-Level Indicators 2.2.4 Power-Level Indicators Table 2-10 describes the two power-level LEDs on the TCC2 faceplate. Table 2-10 TCC2 Power-Level Indicators Power-Level LEDs Definition Green/Red PWR A LED The PWR A LED is green when the voltage on supply input A is between the extremely low battery voltage (ELWBATVG) and extremely high battery voltage (EHIBATVG) thresholds.
Chapter 2 Common Control Cards 2.3.1 TCC2P Functionality Figure 2-2 shows the faceplate and block diagram for the TCC2P card.
Chapter 2 Common Control Cards 2.3.1 TCC2P Functionality The TCC2P also originates and terminates a cell bus carried over the module. The cell bus supports links between any two cards in the node, which is essential for peer-to-peer communication. Peer-to-peer communication accelerates protection switching for redundant cards. The node database, IP address, and system software are stored in TCC2P nonvolatile memory, which allows quick recovery in the event of a power or card failure.
Chapter 2 Common Control Cards 2.3.2 TCC2P Card-Level Indicators Note When a second TCC2P card is inserted into a node, it synchronizes its software, its backup software, and its database with the active TCC2P. If the software version of the new TCC2P does not match the version on the active TCC2P, the newly inserted TCC2P copies from the active TCC2P, taking about 15 to 20 minutes to complete.
Chapter 2 Common Control Cards 2.3.4 Power-Level Indicators 2.3.4 Power-Level Indicators Table 2-14 describes the two power-level LEDs on the TCC2P faceplate. Table 2-14 TCC2P Power-Level Indicators Power-Level LEDs Definition Green/Red PWR A LED The PWR A LED is green when the voltage on supply input A is between the extremely low battery voltage (ELWBATVG) and extremely high battery voltage (EHIBATVG) thresholds.
Chapter 2 Common Control Cards 2.4 XC-VXL-10G Card Figure 2-3 shows the XC-VXL-10G faceplate and block diagram. Figure 2-3 XC-VXL-10G Faceplate and Block Diagram XCVXL Line 1 10G Line 2 Line 3 Line 4 FAIL uP Interface ACT/STBY Span 1 Span 2 Cross-Connect Matrix Span 3 Span 4 Line 5 Line 6 Line 7 Line 8 Ref Clk A Flash Ref Clk B B a c k p l a n e RAM uP Interface TCCA ASIC Protect SCL SCL link 110949 Main SCL uP Figure 2-4 shows the XC-VXL-10G cross-connect matrix.
Chapter 2 Common Control Cards 2.4.1 XC-VXL-10G Functionality 2.4.1 XC-VXL-10G Functionality The XC-VXL-10G card manages up to 192 bidirectional STM-1 cross-connects, 192 bidirectional E-3 or DS-3 cross-connects, or 1008 bidirectional E-1 cross-connects. The TCC2/TCC2P card assigns bandwidth to each slot on a per-STM-1 basis. The XC-VXL-10G card works with the TCC2/TCC2P card to maintain connections and set up cross-connects within the node.
Chapter 2 Common Control Cards 2.5 XC-VXL-2.5G Card Figure 2-5 shows the XC-VXL-2.5G card faceplate and block diagram. Figure 2-5 XC-VXL-2.5G Faceplate and Block Diagram XCVXL Line 1 2.5G Line 2 Line 3 Line 4 FAIL uP Interface ACT/STBY Span 1 Span 2 Cross-Connect Matrix Span 3 Span 4 Line 5 Line 6 Line 7 Line 8 Ref Clk A Flash Ref Clk B B a c k p l a n e RAM uP Interface TCCA ASIC Protect SCL SCL link 110950 Main SCL uP Figure 2-6 shows the XC-VXL-2.5G cross-connect matrix.
Chapter 2 Common Control Cards 2.5.1 XC-VXL-2.5G Card Functionality 2.5.1 XC-VXL-2.5G Card Functionality The XC-VXL-2.5G card manages up to 192 bidirectional STM-1 cross-connects, 192 bidirectional E-3 or DS-3 cross-connects, or 1008 bidirectional E-1 cross-connects. The TCC2/TCC2P card assigns bandwidth to each slot on a per-STM-1 basis. The XC-VXL-2.5G card works with the TCC2/TCC2P card to maintain connections and set up cross-connects within the node.
Chapter 2 Common Control Cards 2.6.1 XC-VXC-10G Functionality Figure 2-7 XC-VXC-10G Faceplate and Block Diagram XC-VXC10G XC-VXC-10G Backplane Connectors SCL Bus IBPIA (2) FAIL IBPIA (2) TCCA ACT/STBY Clock FPGA STM-1 Cross Connect ASIC 2 VT Ports 2 VT Ports 6 AUX Ports 6 AUX Ports FLASH EDVT TULA GDX2 TU Cross Connect ASIC EEPROM Serial Port 2 VT Ports 2 VT Ports CPU VT Cross Connect ASIC DDR SDRAM DETLEF DDR FPGA 134370 CPLD TARAN GDX1 2.6.
Chapter 2 Common Control Cards 2.6.
Chapter 2 Common Control Cards 2.6.2 XC-VXC-10G Card-Level Indicators Figure 2-8 XC-VXC-10G Cross-Connect Matrix XC-XVC-10G STM-1 Cross-connect ASIC (384x384 STM-1) Input Ports 8X STM-16 4X STM-64 Output Ports 1 1 2 2 . . . . . . . .
Chapter 2 Common Control Cards 2.7 AIC-I Card 2.7 AIC-I Card Note For AIC-I card specifications, see the “A.4.6 AIC-I Specifications” section on page A-12. The optional AIC-I card provides customer-defined alarm inputs and outputs, user data channels (UDCs), and supports local and express orderwire. It provides 16 customer-defined input contacts and 4 customer-defined input/output contacts. It requires the MIC-A/P for connection to the alarm contacts.
Chapter 2 Common Control Cards 2.7.2 External Alarms and Controls Table 2-18 AIC-I Card-Level Indicators Card-Level LEDs Description Red FAIL LED Indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the red FAIL LED persists. Green ACT LED Indicates that the AIC-I card is provisioned for operation.
Chapter 2 Common Control Cards 2.7.3 Orderwire • Local NE alarm severity: A hierarchy of Not Reported, Not Alarmed, Minor, Major, or Critical alarm severities that you set to cause output closure. For example, if the trigger is set to Minor, a Minor alarm or above is the trigger. • Remote NE alarm severity: Same as the local NE alarm severity but applies to remote alarms only.
Chapter 2 Common Control Cards 2.7.4 Power Monitoring The orderwire ports are standard RJ-11 receptacles. The pins on the orderwire ports correspond to the tip and ring orderwire assignments. Table 2-19 describes the orderwire pin assignments.
Chapter 2 Common Control Cards 2.7.6 Data Communications Channel Table 2-20 UDC Pin Assignments RJ-11 Pin Number Description 1 For future use 2 TXN 3 RXN 4 RXP 5 TXP 6 For future use 2.7.6 Data Communications Channel The DCC features a dedicated data channel of 576 kbps (D4 to D12 bytes) between two nodes in an ONS 15454 SDH network. Each AIC-I card provides two DCCs, DCC-A and DCC-B, through separate RJ-45 connectors on the front of the AIC-I.
Chapter 2 Common Control Cards 2.7.6 Data Communications Channel Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 3 Electrical Cards This chapter describes the Cisco ONS 15454 SDH electrical card features and functions. It includes descriptions, hardware specifications, and block diagrams for each card. For installation and card turn-up procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 3.1 Electrical Card Overview, page 3-1 • 3.2 E1-N-14 Card, page 3-4 • 3.3 E1-42 Card, page 3-6 • 3.4 E3-12 Card, page 3-8 • 3.5 DS3i-N-12 Card, page 3-10 • 3.
Chapter 3 Electrical Cards 3.1.1 Card Summary Note Each card is marked with a symbol that corresponds to a slot (or slots) on the ONS 15454 shelf assembly. The cards are then installed into slots displaying the same symbols. See the “1.13.1 Card Slot Requirements” section on page 1-17 for a list of slots and symbols. 3.1.1 Card Summary Table 3-1 shows available electrical cards for the ONS 15454 SDH. Table 3-1 Electrical Cards Card Description For Additional Information...
Chapter 3 Electrical Cards 3.1.1 Card Summary Table 3-1 Electrical Cards (continued) Card Description For Additional Information... FMEC E1-120PROA See the “3.11 FMEC Provides electrical connection into the system for 42 pairs of 120-ohm balanced E1-120PROA Card” section on page 3-21. E-1 ports from the E1-42 card. It provides 1:3 protection from the A side (left side of the shelf). It occupies four slots, Slots 18 to 21. It uses Molex 96-pin LFH connectors. FMEC E1-120PROB See the “3.
Chapter 3 Electrical Cards 3.1.2 Card Compatibility 3.1.2 Card Compatibility Table 3-2 lists the Cisco Transport Controller (CTC) software compatibility for each electrical card. See Table 2-4 on page 2-3 for a list of cross-connect cards that are compatible with each electrical card. Note "Yes" indicates that this card is fully or partially supported by the indicated software release. Refer to the individual card reference section for more information about software limitations for this card.
Chapter 3 Electrical Cards 3.2.1 E1-N-14 Card Functionality Figure 3-1 E1-N-14 Faceplate and Block Diagram E1-N 14 FAIL ACT/STBY SF Protection Relay Matrix 14 Line Interface Units AU-3 to 14 E1 Mapper AU-3 / STM-4 Mux/Demux FPGA BTC ASIC B a c k p l a n e DRAM FLASH 134371 uP 3.2.1 E1-N-14 Card Functionality Each E1-N-14 port features ITU-T G.703 compliant outputs and inputs supporting cable losses of up to 6 dB at 1024 kHz. The E1-N-14 card supports 1:N (N <= 4) protection.
Chapter 3 Electrical Cards 3.2.2 E1-N-14 Card-Level Indicators 3.2.2 E1-N-14 Card-Level Indicators Table 3-3 describes the three E1-N-14 card faceplate LEDs. Table 3-3 E1-N-14 Card-Level Indicators Card-Level LEDs Description Red FAIL LED Indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the FAIL LED persists in flashing.
Chapter 3 Electrical Cards 3.3.1 E1-42 Card Functionality Figure 3-2 E1-42 Faceplate and Block Diagram E1-42 FAIL ACT/STBY SF Protection Relay Matrix 6 * 7 Line Interface Units AU-4 to 2 * 21 E1 Mapper AU-4 / STM-4 BTC ASIC B a c k p l a n e DRAM FLASH 134377 uP 3.3.1 E1-42 Card Functionality Each E1-42 port features ITU-T G.703 compliant outputs and inputs supporting cable losses of up to 6 dB at 1024 kHz. The E1-42 card supports 1:3 protection.
Chapter 3 Electrical Cards 3.3.2 E1-42 Card-Level Indicators 3.3.2 E1-42 Card-Level Indicators Table 3-4 describes the three LEDs on the E1-42 card faceplate. Table 3-4 E1-42 Card-Level Indicators Card-Level LEDs Description Red FAIL LED Indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the FAIL LED persists in flashing.
Chapter 3 Electrical Cards 3.4.1 E3-12 Card Functionality Figure 3-3 E3-12 Card Faceplate and Block Diagram FAIL ACT/STBY Protection Relay Matrix SF 12 Line Interface Units E3 ASIC BTC ASIC B a c k p l a n e 134378 E3 12 3.4.1 E3-12 Card Functionality You can install the E3-12 card in Slots 1 to 5 and 14 to 17 of the ONS 15454 SDH. Each E3-12 port features ITU-T G.703 compliant outputs supporting cable losses of up to 12 dB at 17184 kHz. The E3-12 card supports 1:1 protection.
Chapter 3 Electrical Cards 3.4.2 E3-12 Card-Level Indicators 3.4.2 E3-12 Card-Level Indicators Table 3-5 describes the three LEDs on the E3-12 card faceplate. Table 3-5 E3-12 Card-Level Indicators Card-Level LEDs Description Red FAIL LED Indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the FAIL LED persists in flashing.
Chapter 3 Electrical Cards 3.5.1 DS3i-N-12 Card Functionality Figure 3-4 DS3i-N-12 Faceplate and Block Diagram DS3I- N 12 main DS3-m1 protect DS3-p1 Line Interface Unit #1 FAIL ACT/STBY SF DS3 ASIC BERT FPGA main DS3-m12 protect DS3-p12 Line Interface Unit #1 OHP FPGA BTC ASIC B a c k p l a n e Processor SDRAM Flash 134379 uP bus 3.5.1 DS3i-N-12 Card Functionality The DS3i-N-12 can detect several different errored logic bits within a DS-3 frame.
Chapter 3 Electrical Cards 3.5.2 DS3i-N-12 Card-Level Indicators • C-bit parity monitoring • X-bit monitoring • M-bit monitoring • F-bit monitoring • Far-end block error (FEBE) monitoring • Far-end alarm and control (FEAC) status and loop code detection • Path trace byte support with TIM-P alarm generation You can install the DS3i-N-12 card in Slots 1 to 5 and 13 to 17. Each DS3i-N-12 port features DS-N-level outputs supporting distances up to 137 m (450 feet).
Chapter 3 Electrical Cards 3.6.1 STM 1E-12 Card Functionality The 12-port ONS 15454 SDH STM1E-12 card provides 12 ITU-compliant, G.703 STM-1 ports per card. Each interface operates at 155.52 mbps for STM-1 over a 75-ohm coaxial cable (with the FMEC STM1E 1:1 card). The STM1E-12 card operates as a working or protect card in 1:1 protection schemes. Figure 3-5 shows the STM1E-12 faceplate and block diagram.
Chapter 3 Electrical Cards 3.6.2 STM1E-12 Card-Level Indicators Note When a protection switch moves traffic from the STM1E-12 working/active card to the STM1E-12 protect/standby card, ports on the now active/standby card cannot be taken out of service. Lost traffic can result if you take a port out of service, even if the STM1E-12 active/standby card no longer carries traffic. Note Use an external clock when doing service disruption time measurements on the STM1E-12. 3.6.
Chapter 3 Electrical Cards 3.8 FMEC-E1 Card FILLER Faceplate 33678 12931 61333 Figure 3-6 3.8 FMEC-E1 Card Note For FMEC-E1 specifications, see the “A.5.7 FMEC-E1 Specifications” section on page A-19. The ONS 15454 SDH FMEC-E1 card provides front mount electrical connection for 14 ITU-compliant, G.703 E-1 ports. With the FMEC-E1 card, each E1-N-14 port operates at 2.048 mbps over a 75-ohm unbalanced coaxial 1.0/2.3 miniature coax connector.
Chapter 3 Electrical Cards 3.
Chapter 3 Electrical Cards 3.9 FMEC-DS1/E1 Card Figure 3-8 FMEC-DS1/E1 Faceplate and Block Diagram Ch 1-7 In/Out DB Connector 14 Pairs of common mode chokes Ch 8 - 14 In/Out DB Connector 14 Pairs of Transient Suppr. 14 Pairs of Imped. Transf. Inventory Data (EEPROM) B a c k p l a n e 134382 FMEC DS1/E1 You can install the FMEC-DS1/E1 card in any EFCA slot from Slot 18 to 22 or Slot 25 to 29 of the ONS 15454 SDH.
Chapter 3 Electrical Cards 3.10 FMEC E1-120NP Card Table 3-8 E-1 Interface Pinouts on the FMEC-DS1/E1 Card Ports 1 to 7 (continued) Pin No. Signal Name Pin No. Signal Name 18 TX 1 N 37 GND 19 GND — — Use Table 3-9 to make the connection from the E-1 37-pin DB connector for Ports 8 to 14 to the external balanced 120-ohm E-1 interfaces. Table 3-9 E-1 Interface Pinouts on the FMEC-DS1/E1 Card Ports 8 to 14 Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.10 FMEC E1-120NP Card Caution This interface can only be connected to SELV circuits. The interface is not intended for connection to any Australian telecommunications network without the written consent of the network manager.
Chapter 3 Electrical Cards 3.10 FMEC E1-120NP Card Table 3-10 E-1 Interface Pinouts on the FMEC E1-120NP Card Ports 1 to 21 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.11 FMEC E1-120PROA Card Table 3-11 E-1 Interface Pinouts on the FMEC E1-120NP Card Ports 22 to 42 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 20 TX 23 P 44 RX 23 P 68 TX 33 P 92 RX 33 P 21 TX 22 N 45 RX 22 N 69 NC 93 NC 22 TX 22 P 46 RX 22 P 70 NC 94 NC 23 NC 47 NC 71 NC 95 NC 24 NC 48 NC 72 NC 96 NC 3.11 FMEC E1-120PROA Card Note For FMEC E1-120PROA specifications, see the “A.5.
Chapter 3 Electrical Cards 3.11 FMEC E1-120PROA Card Table 3-12 E-1 Interface Pinouts on the FMEC E1-120PROA Card Ports 1 to 21 Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.12 FMEC E1-120PROB Card Table 3-13 E-1 Interface Pinouts on the FMEC E1-120PROA Card Ports 22 to 42 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.12 FMEC E1-120PROB Card Figure 3-11 FMEC E1-120PROB Faceplate and Block Diagram PORT 1-21 PORT 1-21 PORT 1-21 6 Interface Connectors CLEI CODE Protect Switch Relay Matrix 4 x 42 Pairs of Transformers Inventory Data (EEPROM) BARCODE PORT 22-42 PORT 22-42 B a c k p l a n e PORT 22-42 134373 FMEC E1-120PROB You can install the FMEC E1-120PROB card in EFCA Slots 26 to 29 of the ONS 15454 SDH.
Chapter 3 Electrical Cards 3.12 FMEC E1-120PROB Card Table 3-14 E-1 Interface Pinouts on the FMEC E1-120PROB Card Ports 1 to 21 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.13 E1-75/120 Impedance Conversion Panel Table 3-15 E-1 Interface Pinouts on the FMEC E1-120PROB Card Ports 22 to 42 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 23 NC 47 NC 71 NC 95 NC 24 NC 48 NC 72 NC 96 NC 3.13 E1-75/120 Impedance Conversion Panel Note For specifications, see the “A.5.12 E1-75/120 Impedance Conversion Panel Specifications” section on page A-23.
Chapter 3 Electrical Cards 3.13 E1-75/120 Impedance Conversion Panel Figure 3-13 E1-75/120 with Optional Rackmount Brackets ETSI rackmount bracket 83636 19 to 23 in. rackmount bracket Figure 3-14 shows a block diagram of the impedance conversion panel. Figure 3-14 E1-75/120 Impedance Conversion Panel Block Diagram 42 Channels Transformer 1.26:1 75-Ohm Unsymmetrical Signals Transformer 1.26:1 42 Channels 83637 120-Ohm Symmetrical Signals Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 3 Electrical Cards 3.14 FMEC-E3/DS3 Card You can install the E1-75/120 conversion panel in the rack containing the ONS 15454 SDH shelf or in a nearby rack. If you install the E1-75/120 conversion panel in a place where a longer cable is required, make sure that the total cable loss of the balanced 120-ohm cable and the unbalanced 75-ohm cable does not exceed the maximum allowed value.
Chapter 3 Electrical Cards 3.15 FMEC STM1E 1:1 Card DS3 signals. One of the following: • – Up to 137 m (450 ft) 734A, RG59, or 728A – Up to 24 m (79 ft) RG179 3.15 FMEC STM1E 1:1 Card Note For FMEC STM1E 1:1 specifications, see the “A.5.14 FMEC STM1E 1:1 Specifications” section on page A-25. The ONS 15454 SDH FMEC STM1E 1:1 card provides front mount electrical connection for 2 x 12 ITU-compliant, G.703 STM1E ports. With the FMEC STM1E 1:1 card, each interface of an STM1E-12 card operates at 155.
Chapter 3 Electrical Cards 3.17 MIC-A/P FMEC The BLANK-FMEC sheet metal faceplate provides EMC emission control for empty FMEC slots. It also provides a way to close off the EFCA area, thus allowing air flow and convection to be maintained through the EFCA. You must install the BLANK-FMEC faceplate in every empty FMEC slot to maintain EMC requirements of the system and proper air flow. Figure 3-17 shows the BLANK-FMEC faceplate. BLANK-FMEC Faceplate 61318 Figure 3-17 3.
Chapter 3 Electrical Cards 3.
Chapter 3 Electrical Cards 3.17 MIC-A/P FMEC Table 3-16 Alarm Interface Pinouts on the MIC-A/P DB-62 Connector (continued) Pin No.
Chapter 3 Electrical Cards 3.18 MIC-C/T/P FMEC Table 3-16 Alarm Interface Pinouts on the MIC-A/P DB-62 Connector (continued) Pin No.
Chapter 3 Electrical Cards 3.18 MIC-C/T/P FMEC MIC-C/T/P Faceplate and Block Diagram CLEI CODE 3W3 connector Power RJ-45 connectors System management serial ports System management LAN M LINK BARCODE RJ-45 connectors 4 coaxial connectors Inventory Data (EEPROM) Timing 2 x in / 2 x out ACT B a c k p l a n e 134376 Figure 3-19 AUTION E FACEPLATE 1.
C H A P T E R 4 Optical Cards This chapter describes the Cisco ONS 15454 SDH optical, transponder, and muxponder card features and functions. It includes descriptions, hardware specifications, and block diagrams for each card. For installation and card turn-up procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 4.1 Optical Card Overview, page 4-1 • 4.2 OC3 IR 4/STM1 SH 1310 Card, page 4-5 • 4.3 OC3 IR/STM1 SH 1310-8 Card, page 4-7 • 4.
Chapter 4 Optical Cards 4.1.1 Card Summary 4.1.1 Card Summary Table 4-1 lists the ONS 15454 SDH optical cards. Table 4-1 Optical Cards for the ONS 15454 SDH Card Description OC3 IR 4/STM1 SH 1310 The OC3 IR 4/STM1 SH 1310 card provides four See the “4.2 OC3 IR intermediate- or short-range STM-1 ports and operates 4/STM1 SH 1310 Card” at 1310 nm. It operates in Slots 1 to 6 and 12 to 17. section on page 4-5. OC3 IR/STM1 SH 1310-8 The OC3 IR/STM1SH 1310-8 card provides eight See the “4.
Chapter 4 Optical Cards 4.1.2 Card Compatibility Table 4-1 Optical Cards for the ONS 15454 SDH (continued) Card Description For Additional Information... OC192 LR/STM64 LH 1550 The OC192 LR/STM64 LH 1550 card provides one long-range STM-64 port at 1550 nm and operates in Slots 5, 6, 12, or 13 with the XC-VXL-10G or XC-VXC-10G cross-connect card. See the “4.13 OC192 LR/STM64 LH 1550 Card” section on page 4-26. OC192 LR/STM64 LH ITU 15xx.xx The OC192 LR/STM64 LH ITU 15xx.
Chapter 4 Optical Cards 4.1.2 Card Compatibility Note Table 4-2 "Yes" indicates that this card is fully or partially supported by the indicated software release. Refer to the individual card reference section for more information about software limitations for this card. Optical Card Software Release Compatibility Optical Card R2.2.1 R2.2.2 R3.0.1 R3.1 R3.2 R3.3 R3.4 R4.0 R4.1 R4.5 R4.6 R4.7 R5.0 R6.0 R7.
Chapter 4 Optical Cards 4.2 OC3 IR 4/STM1 SH 1310 Card 4.2 OC3 IR 4/STM1 SH 1310 Card Note For specifications, see the “A.6.1 OC3 IR 4/STM1 SH 1310 Card Specifications” section on page A-28. The OC3 IR 4/STM1 SH 1310 card provides four intermediate or short range SDH STM-1 ports compliant with ITU-T G.707 and ITU-T G.957. Each port operates at 155.52 Mbps over a single-mode fiber span. The card supports VC-4 and nonconcatenated or concatenated payloads at the STM-1 signal level.
Chapter 4 Optical Cards 4.2.1 OC3 IR 4/STM1 SH 1310 Functionality 4.2.1 OC3 IR 4/STM1 SH 1310 Functionality You can install the OC3 IR 4/STM1 SH 1310 card in Slots 1 to 6 and 12 to 17. The card can be provisioned as part of a subnetwork connection protection (SNCP) ring or linear add-drop multiplexer (ADM) configuration. Each interface features a 1310-nm laser and contains a transmit and receive connector (labeled) on the card faceplate. The card uses SC connectors.
Chapter 4 Optical Cards 4.3 OC3 IR/STM1 SH 1310-8 Card 4.3 OC3 IR/STM1 SH 1310-8 Card Note For specifications, see the “A.6.2 OC3 IR/STM1 SH 1310-8 Card Specifications” section on page A-29. The OC3 IR/STM1 SH 1310-8 card provides eight intermediate or short range SDH STM-1 ports compliant with ITU-T G.707, and ITU-T G.957. Each port operates at 155.52 Mbps over a single-mode fiber span. The card supports VC-4 and nonconcatenated or concatenated payloads at the STM-1 signal level.
Chapter 4 Optical Cards 4.3.1 OC3 IR/STM1 SH 1310-8 Card-Level Indicators You can install the OC3IR/STM1 SH 1310-8 card in Slots 1 to 4 and 14 to 17. The card can be provisioned as part of an SNCP or in an (ADM) configuration. Each interface features a 1310-nm laser and contains a transmit and receive connector (labeled) on the card faceplate. The card uses LC connectors on the faceplate, angled downward 12.5 degrees.
Chapter 4 Optical Cards 4.4 OC12 IR/STM4 SH 1310 Card The OC12 IR/STM4 SH 1310 card provides one intermediate or short range SDH STM-4 port compliant with ITU-T G.707 and ITU-T G.957. The port operates at 622.08 Mbps over a single-mode fiber span. The card supports VC-4 and nonconcatenated or concatenated payloads at STM-1 and STM-4 signal levels. Warning The laser is on when the optical card is booted. The port does not have to be in service for the laser to be on.
Chapter 4 Optical Cards 4.4.1 OC12 IR/STM4 SH 1310 Card-Level Indicators You can install the OC12 IR/STM4 SH 1310 card in Slots 1 to 6 and 12 to 17 and provision the card as part of an MS-SPRing or subnetwork connection protection (SNCP) ring. In ADM configurations, you can provision the card as either an access tributary or a transport span (trunk) side interface.
Chapter 4 Optical Cards 4.5 OC12 LR/STM4 LH 1310 Card Warning The laser is on when the optical card is booted. The port does not have to be in service for the laser to be on. Figure 4-4 shows the OC12 LR/STM4 LH 1310 faceplate and block diagram.
Chapter 4 Optical Cards 4.5.1 OC12 LR/STM4 LH 1310 Card-Level Indicators 4.5.1 OC12 LR/STM4 LH 1310 Card-Level Indicators Table 4-6 describes the three card-level LED indicators on the OC12 LR/STM4 LH 1310 card. Table 4-6 OC12 LR/STM4 LH 1310 Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the red FAIL LED persists.
Chapter 4 Optical Cards 4.6.1 OC12 LR/STM4 LH 1550 Card Functionality Figure 4-5 shows the OC12 LR/STM4 LH 1550 faceplate and a block diagram of the card. Figure 4-5 OC12 LR/STM4 LH 1550 Faceplate and Block Diagram OC12LR STM4LH 1550 FAIL ACT SF STS-12 Tx 1 Rx OC12/STM-4 Mux/ Demux Optical Transceiver Flash B a c k Main SCI p l a Protect SCI n e STS-12 BTC ASIC RAM uP bus 110871 uP 4.6.
Chapter 4 Optical Cards 4.6.2 OC12 LR/STM4 LH 1550 Card-Level Indicators The OC12 LR/STM4 LH 1550 card uses long-reach optics centered at 1550 nm and contains a transmit and receive connector (labeled) on the card faceplate. The OC12 LR/STM4 LH 1550 card uses SC optical connections and supports 1+1 bidirectional or unidirectional protection switching. The OC12 LR/STM4 LH 1550 card detects LOS, LOF, LOP, MS-AIS, and MS-FERF conditions.
Chapter 4 Optical Cards 4.7.1 OC12 IR/STM4 SH 1310-4 Card Functionality Warning The laser is on when the optical card is booted. The port does not have to be in service for the laser to be on. Figure 4-6 shows the OC12 IR/STM4 SH 1310-4 faceplate and block diagram.
Chapter 4 Optical Cards 4.7.2 OC12 IR/STM4 SH 1310-4 Card-Level Indicators Each port is configurable to support all ONS 15454 SDH configurations and can be provisioned as part of an MS-SPRing or SNCP configuration. To enable an MS-SPRing, the OC12 IR/STM4 SH 1310-4 card extracts the K1 and K2 bytes from the SDH overhead and processes them to switch accordingly. The GCC bytes are forwarded to the TCC2 card, which terminates the GCC.
Chapter 4 Optical Cards 4.8.1 OC48 IR/STM16 SH AS 1310 Card Functionality The OC48 IR/STM16 SH AS 1310 card provides one intermediate-range, ITU-T G.707- and G.957-compliant, SDH STM-16 port per card. The interface operates at 2.488 Gbps over a single-mode fiber span. The card supports concatenated or nonconcatenated payloads at STM-1, STM-4, or STM-16 signal levels on a per VC-4 basis. Warning The laser is on when the optical card is booted.
Chapter 4 Optical Cards 4.8.2 OC48 IR/STM16 SH AS 1310 Card-Level Indicators The STM-16 port features a 1310-nm laser and contains a transmit and receive connector (labeled) on the card faceplate. The OC48 IR/STM16 SH AS 1310 card uses SC connectors. The card supports 1+1 unidirectional protection and provisionable bidirectional switching. The OC48 IR/STM16 SH AS 1310 card detects LOS, LOF, LOP, MS-AIS, and MS-FERF conditions.
Chapter 4 Optical Cards 4.9.1 OC48 LR/STM16 LH AS 1550 Card Functionality Warning The laser is on when the optical card is booted. The port does not have to be in service for the laser to be on. Figure 4-8 shows the OC48 LR/STM16 LH AS 1550 faceplate and block diagram.
Chapter 4 Optical Cards 4.9.2 OC48 LR/STM16 LH AS 1550 Card-Level Indicators The OC48 LR/STM16 LH AS 1550 detects LOS, LOF, LOP, MS-AIS, and MS-FERF conditions. Refer to the Cisco ONS 15454 SDH Troubleshooting Guide for a description of these conditions. The card also counts section and line BIP errors. 4.9.2 OC48 LR/STM16 LH AS 1550 Card-Level Indicators Table 4-10 describes the three card-level LED indicators on the OC48 LR/STM16 LH AS 1550 card.
Chapter 4 Optical Cards 4.10.1 OC48 ELR/STM16 EH 100 GHz Card Functionality Figure 4-9 shows the OC48 ELR/STM16 EH 100 GHz faceplate and block diagram. Figure 4-9 OC48 ELR/STM16 EH 100 GHz Faceplate and Block Diagram OC48ELR STM16EH 15XX.XX STM-16 FAIL Optical Transceiver Mux/ Demux BTC ASIC SF Flash RAM uP bus TX 1 RX B a c k Main SCI p l a Protect SCI n e STM-16 ACT/STBY 134386 uP 4.10.
Chapter 4 Optical Cards 4.10.2 OC48 ELR/STM16 EH 100 GHz Card-Level Indicators transmission distances are achieved through the use of inexpensive optical amplifiers (flat gain amplifiers) such as erbium-doped fiber amplifiers (EDFAs). Using collocated amplification, distances up to 200 km can be achieved for a single channel (160 km for 8 channels). Maximum system reach in filterless applications is 24 dB, or approximately 80 km, without the use of optical amplifiers or regenerators.
Chapter 4 Optical Cards 4.11 OC192 SR/STM64 IO 1310 Card 4.11 OC192 SR/STM64 IO 1310 Card Note For specifications, see the “A.6.10 OC192 SR/STM64 IO 1310 Card Specifications” section on page A-37. The OC192 SR/STM64 IO 1310 card provides one intra-office haul, ITU-T G.707- and G.957-compliant, SDH STM-64 port per card in the 1310-nm wavelength range. The port operates at 9.95328 Gbps over unamplified distances up to 2 km (1.24 miles).
Chapter 4 Optical Cards 4.11.1 OC192 SR/STM64 IO 1310 Card Functionality 4.11.1 OC192 SR/STM64 IO 1310 Card Functionality You can install OC192 SR/STM64 IO 1310 cards in Slot 5, 6, 12, or 13. You can provision this card as part of an MS-SPRing, a SNCP, a linear configuration, or a regenerator for longer span reaches. The OC192 SR/STM64 IO 1310 port features a 1310-nm laser and contains a transmit and receive connector (labeled) on the card faceplate.
Chapter 4 Optical Cards 4.12.1 OC192 IR/STM64 SH 1550 Card Functionality The OC192 IR/STM64 SH 1550 card provides one short-range, ITU-T G.707- and G.957-compliant, SDH STM-64 port per card. The port operates at 9.95328 Gbps over unamplified distances up to 40 km with SMF-28 fiber limited by loss and/or dispersion. The card supports concatenated or nonconcatenated payloads on a VC-4 basis, as well as VC-4, VC-3, and VC-12 payloads.
Chapter 4 Optical Cards 4.12.2 OC192 IR/STM64 SH 1550 Card-Level Indicators The OC192 IR/STM64 SH 1550 port features a 1550-nm laser and contains a transmit and receive connector (labeled) on the card faceplate. The card uses a dual SC connector for optical cable termination. The card supports 1+1 unidirectional and bidirectional facility protection. It also supports 1:1 protection in four-fiber bidirectional line switched ring applications where both span switching and ring switching might occur.
Chapter 4 Optical Cards 4.13 OC192 LR/STM64 LH 1550 Card The OC192 LR/STM64 LH 1550 card provides one long-range SDH STM-64 port per card, compliant with ITU-T G.707 and G.957, and Telcordia GR-253-CORE (except minimum and maximum transmit power, and minimum receive power). Also, the port is compliant to ITU-T G.691 (prepublished unedited version 10/2000) L-64.2, except for optical output power and receiver sensitivity.
Chapter 4 Optical Cards 4.13 OC192 LR/STM64 LH 1550 Card Figure 4-12 OC192 LR/STM64 LH 1550 Faceplate and Block Diagram 1550 FAIL ACT/STBY SF OC-192/STM-64 STS Optical transceiver Demux CDR Mux SCL BTC ASIC TX 1 OC-192/STM-64 RX Optical transceiver Mux CK Mpy STS Mux SCL RX ! B a c k p l a n e MAX INPUT POWER LEVEL -7 dBm SRAM Flash Processor 115222 ADC x 8 Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 4 Optical Cards 4.13.1 OC192 LR/STM64 LH 1550 Card Functionality Figure 4-13 Enlarged Section of the OC192 LR/STM64 LH 1550 Faceplate 1550 FAIL ACT/STBY SF RX ! MAX INPUT POWER LEVEL -7 dBm TX 1 RX RX ! DATED JULY 26, 2001 LASER NOTICE No.50, AND 1040.11 EXCEPT FOR DEVIATIONS PURSUANT TO 115226 DATED JULY 26, 2001 LASER NOTICE No.50, AND 1040.11 EXCEPT FOR DEVIATIONS PURSUANT TO COMPLIES WITH 21 CFR 1040.10 COMPLIES WITH 21 CFR 1040.10 MAX INPUT POWER LEVEL -7 dBm 4.13.
Chapter 4 Optical Cards 4.13.2 OC192 LR/STM64 LH 1550 Card-Level Indicators The OC192 LR/STM64 LH 1550 card detects SF, LOS, or LOF conditions on the optical facility. Refer to the Cisco ONS 15454 SDH Troubleshooting Guide for a description of these conditions. The card also counts section and line BIP errors from B1 and B2 byte registers in the section and line overhead. Caution You must use a 20-dB fiber attenuator (19 to 24 dB) when working with the OC192 LR/STM64 LH 1550 card in a loopback.
Chapter 4 Optical Cards 4.14 OC192 LR/STM64 LH ITU 15xx.xx Card Note Longer distances are possible in an amplified system using dispersion compensation. Note The optics thresholds for this card are not retained after it is reset. As a result, the optics thresholds must be configured every time this card is reset, or any time the TCC/TCC2 card is reset. See DLP-D109 in the Cisco ONS 15454 SDH Procedure Guide, R7.0 for instructions on setting the optics thresholds.
Chapter 4 Optical Cards 4.14.1 OC192 LR/STM64 LH ITU 15xx.xx Card Functionality Figure 4-15 OC192 LR/STM64 LH ITU 15xx.xx Block Diagram STM-64/ OC-192 STM-64 / OC192 Optical transceiver Demux CDR Demux SCL BTC ASIC STM-64 / OC192 Optical transceiver Mux CK Mpy SRAM Flash SCL B a c k p l a n e Processor 63121 ADC x 8 Mux STM-64/ OC-192 4.14.1 OC192 LR/STM64 LH ITU 15xx.xx Card Functionality You can install OC192 LR/STM64 LH ITU 15xx.xx cards in Slot 5, 6, 12, or 13.
Chapter 4 Optical Cards 4.14.2 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators 4.14.2 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators Table 4-15 describes the three card-level LED indicators on the OC192 LR/STM64 LH ITU 15xx.xx card. Table 4-15 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card processor is not ready. The FAIL LED is on during reset and flashes during the boot process.
Chapter 4 Optical Cards 4.15 15454_MRC-12 Multirate Card Note Longer distances are possible in an amplified system using dispersion compensation. Note Refer to Table 4-2 on page 4-4 for information on optical card compatibility. Figure 4-16 shows the 15454_MRC-12 faceplate and block diagram. 15454_MRC-12 Card Faceplate and Block Diagram OC-3/12/48 (STM-1/4/16) COMPLIES WITH 21 CFR 1040.10 AND 1040.11 EXCEPT FOR DEVIATIONS PURSUANT TO LASER NOTICE No.
Chapter 4 Optical Cards 4.15.1 Slot Compatibility by Cross-Connect Card 4.15.1 Slot Compatibility by Cross-Connect Card You can install 15454_MRC-12 cards in Slots 1 through 6 and 12 through 17 with XC-VXL-2.5G, XC-VXL-10G, or XC-VXC-10G cards. Note The 15454_MRC-12 card supports an errorless software-initiated cross-connect card switch when used in a shelf equipped with XC-VXC-10G and TCC2/TCC2P cards.
Chapter 4 Optical Cards 4.15.2 Ports and Line Rates – If Port 4 is used as an STM-1, Ports 2 and 3 can be used as an STM-1 or STM-4. – If Port 7 is used as an STM-1, Ports 5, 6, and 8 can be used as an STM-1 or STM-4. – If Port 10 is used as an STM-1, Ports 9, 11, and 12 can be used as an STM-1 or STM-4. – Any port can be used as an STM-4 or STM-1, as long as all of the above rules are followed.
Chapter 4 Optical Cards 4.15.
Chapter 4 Optical Cards 4.15.4 15454_MRC-12 Port-Level Indicators Table 4-18 15454_MRC-12 Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card processor is not ready. This LED is on during reset. The FAIL LED flashes during the boot process. Replace the card if the red FAIL LED persists. ACT/STBY LED If the ACT/STBY LED is green, the card is operational and ready to carry traffic.
Chapter 4 Optical Cards 4.16 OC192SR1/STM64IO Short Reach and OC192/STM64 Any Reach Cards The cards are used in Slots 5, 6, 12, and 13 and only with 10 Gbps cross-connect cards, such as the XC-VXL-10G and XC-VXC-10G. The cards also must be supported with the TCC2 or TCC2P cards. Figure 4-17 shows the faceplates and block diagram for the two cards.
Chapter 4 Optical Cards 4.16.1 OC192SR1/STM64IO Short Reach and OC192/STM64 Any Reach Card-Level Indicators • A card using the LR-2 XFP is intended to be used in applications requiring 10 Gbps transport with unregenerated spans of up to 80 km. 4.16.1 OC192SR1/STM64IO Short Reach and OC192/STM64 Any Reach Card-Level Indicators Table 4-19 describes the three card-level LEDs on the OC-192/STM-64 cards.
Chapter 4 Optical Cards 4.17.2 SFP Description Caution Only use SFPs certified for use in Cisco Optical Networking Systems. The qualified Cisco SFP and XFP pluggable module’s top assembly numbers (TANs) are provided in Table 4-20. Table 4-20 SFP and XFP Card Compatibility Card 15454_MRC-12 (ONS 15454 SONET/SDH) OC192SR1/STM64IO Short Reach Compatible SFPs and XFPs (Cisco Product ID) Cisco Top Assembly Number (TAN) ONS-SI-2G-S1 ONS-SI-2G-I1 ONS-SI-2G-L1 ONS-SI-2G-L2 ONS-SC-2G-30.
Chapter 4 Optical Cards 4.17.3 XFP Description • IND—industrial operating temperature range -40•C C to 85•C Mylar Tab SFP Figure 4-19 Actuator/Button SFP Figure 4-20 Bail Clasp SFP 63067 63066 63065 Figure 4-18 4.17.3 XFP Description The 10 Gbps 1310 nm and 1550 nm XFP transceivers are integrated fiber optic transceivers that provide high-speed serial links at the following signaling rates: 9.95 Gbps, 10.31 Gbps, and 10.51 Gbps. The XFP integrates the receiver and transmit path.
Chapter 4 Optical Cards 4.17.4 PPM Provisioning XFP temperature ranges are: • COM—commercial operating temperature range -5•C C to 70•C • EXT—extended operating temperature range -5•C C to 85•C • IND—industrial operating temperature range -40•C C to 85•C Bail Clasp XFP (Unlatched) Figure 4-22 Bail Clasp XFP (Latched) 115719 115720 Figure 4-21 4.17.4 PPM Provisioning SFPs and XFPs are known as pluggable-port modules (PPMs) in the ONS 15454 SDH graphical user interface (GUI), CTC.
Chapter 4 Optical Cards 4.17.4 PPM Provisioning Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 5 Ethernet Cards Note The terms "Unidirectional Path Switched Ring" and "UPSR" may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as "Path Protected Mesh Network" and "PPMN," refer generally to Cisco's path protection feature, which may be used in any topological network configuration.
Chapter 5 Ethernet Cards 5.1.1 Cards Summary Note Each card is marked with a symbol that corresponds to a slot (or slots) on the ONS 15454 SDH shelf assembly. The cards are then installed into slots displaying the same symbols. See the Cisco ONS 15454 SDH Procedures Guide for a list of slots and symbols. 5.1.1 Cards Summary Table 5-1 lists the Cisco ONS 15454 SDH Ethernet cards.
Chapter 5 Ethernet Cards 5.1.2 Card Compatibility Table 5-1 Ethernet Cards for the ONS 15454 SDH (continued) Card Port Description For Additional Information... CE-100T-8 The CE-100T-8 card provides eight IEEE-compliant, 10/100-Mbps ports and is compatible with the XC-VXL-2.5G, XC-VXL-10G, and XC-VXC-10G cards. See the “5.9 CE-100T-8 Card” section on page 5-19. CE-1000-4 The CE-1000-4 card provides four IEEE-compliant, 1000-Mbps ports.
Chapter 5 Ethernet Cards 5.2 E100T-G Card The ports autoconfigure to operate at either half or full duplex and determine whether to enable or disable flow control. You can also configure Ethernet ports manually. Figure 5-1 shows the faceplate and a block diagram of the card.
Chapter 5 Ethernet Cards 5.2.1 E100T-G Slot Compatibility 5.2.1 E100T-G Slot Compatibility You can install the E100T-G card in Slots 1 to 6 and 12 to 17. Multiple E-Series Ethernet cards installed in an ONS 15454 SDH can act independently or as a single Ethernet switch. You can create logical SDH ports by provisioning a number of SDH channels to the packet switch entity within the ONS 15454 SDH. Logical ports can be created with a bandwidth granularity of VC-4. 5.2.
Chapter 5 Ethernet Cards 5.3 E1000-2-G Card 5.3 E1000-2-G Card Note For specifications, see the “A.7.2 E1000-2-G Card Specifications” section on page A-45. The ONS 15454 SDH uses E1000-2-G cards for Gigabit Ethernet (1000 Mbps). The E1000-2-G card provides two IEEE-compliant, 1000-Mbps ports for high-capacity customer LAN interconnections. Each port supports full-duplex operation. The E1000-2-G card uses GBIC modular receptacles for the optical interfaces. For details, see the “5.
Chapter 5 Ethernet Cards 5.3 E1000-2-G Card Figure 5-2 shows the card faceplate and a block diagram of the card.
Chapter 5 Ethernet Cards 5.3.1 E1000-2-G Card-Level Indicators Multiple E-Series Ethernet cards installed in an ONS 15454 SDH can act together as a single switching entity or as independent single switches supporting a variety of SDH port configurations. You can create logical SDH ports by provisioning a number of SDH channels to the packet switch entity within the ONS 15454 SDH. Logical ports can be created with a bandwidth granularity of VC-4. 5.3.
Chapter 5 Ethernet Cards 5.4 G1000-4 Card 5.4 G1000-4 Card The G1000-4 card requires the XC10G card. The ONS 15454 uses G1000-4 cards for Gigabit Ethernet (1000 Mbps). The G1000-4 card provides four ports of IEEE-compliant, 1000-Mbps interfaces. Each port supports full-duplex operation for a maximum bandwidth of OC-48 on each card. The G1000-4 card uses GBIC modular receptacles for the optical interfaces. For details, see the “5.11 Ethernet Card GBICs and SFPs” section on page 5-25.
Chapter 5 Ethernet Cards 5.4.1 STS-24c Restriction switches (such as 1+1 automatic protection switching [APS], path protection, or bidirectional line switch ring [BLSR]). Full provisioning support is possible through Cisco Transport Controller (CTC), Transaction Language One (TL1), or Cisco Transport Manager (CTM). The circuit sizes supported are STS-1, STS-3c, STS-6c, STS-9c, STS-12c, STS-24c, and STS-48c. 5.4.
Chapter 5 Ethernet Cards 5.4.4 Slot Compatibility Table 5-8 G1000-4 Port-Level Indicators Port-Level LED Status Description Off No link exists to the Ethernet port. Steady amber A link exists to the Ethernet port, but traffic flow is inhibited. For example, an unconfigured circuit, an error on line, or a nonenabled port might inhibit traffic flow. Solid green A link exists to the Ethernet port, but no traffic is carried on the port.
Chapter 5 Ethernet Cards 5.5.
Chapter 5 Ethernet Cards 5.5.2 G1K-4 Port-Level Indicators Table 5-9 G1K-4 Card-Level Indicators Card-Level LEDs Description FAIL LED (red) The red FAIL LED indicates that the card processor is not ready or that a catastrophic software failure occurred on the G1K-4 card. As part of the boot sequence, the FAIL LED is turned on, and it goes off when the software is deemed operational. The red FAIL LED blinks when the card is loading software.
Chapter 5 Ethernet Cards 5.6 ML100T-12 Card determine whether to enable or disable flow control. For ML-Series configuration information, see the Ethernet Card Software Feature and Configuration Guide for the Cisco ONS 15454, Cisco ONS 15454 SDH, and Cisco ONS 15327. Figure 5-5 shows the card faceplate and block diagram. Caution Figure 5-5 Shielded twisted-pair cabling should be used for inter-building applications.
Chapter 5 Ethernet Cards 5.6.1 ML100T-12 Card-Level Indicators 5.6.1 ML100T-12 Card-Level Indicators The ML00T-12 card supports two card-level LED indicators, described in Table 5-11. Table 5-11 ML100T-12 Card-Level Indicators Card-Level LEDs Description Red SF LED The red SF LED indicates that the card processor is not ready or that a catastrophic software failure occurred on the ML100T-12 card. As part of the boot sequence, the FAIL LED is illuminated until the software deems the card operational.
Chapter 5 Ethernet Cards 5.7 ML100X-8 Card The 100 Mbps 802.3-compliant FX SFP operates over a pair of multimode optical fibers and includes LC connectors. For more information on SFPs, see the “5.11 Ethernet Card GBICs and SFPs” section on page 5-25. Each interface supports full-duplex operation for a maximum bandwidth of 200 Mbps per port and 2.488 Gbps per card.
Chapter 5 Ethernet Cards 5.7.1 ML100X-8 Card-Level Indicators be provisioned with two circuit members. An ML-Series card supports VC-3-2v, VC-4-2v and VC-4-4c-2v. To configure an ML-Series-card VCAT circuit, refer to the “Create Circuits and Low-Order Tunnels” chapter of the Cisco ONS 15454 SDH Procedure Guide. 5.7.1 ML100X-8 Card-Level Indicators The ML100X-8 card supports two card-level LED indicators. The card-level indicators are described in Table 5-13.
Chapter 5 Ethernet Cards 5.8 ML1000-2 Card The ML1000-2 card provides two ports of IEEE-compliant, 1000-Mbps interfaces. Each interface supports full-duplex operation for a maximum bandwidth of 2 Gbps per port and 4 Gbps per card. Each port autoconfigures for full duplex and IEEE 802.3x flow control. SFP modules are offered as separate orderable products for maximum customer flexibility. For details, see the “5.11 Ethernet Card GBICs and SFPs” section on page 5-25.
Chapter 5 Ethernet Cards 5.8.1 ML1000-2 Card-Level Indicators 5.8.1 ML1000-2 Card-Level Indicators The ML1000-2 card faceplate has two card-level LED indicators, described in Table 5-15. Table 5-15 ML1000-2 Card-Level Indicators Card-Level LEDs Description FAIL LED (Red) The red FAIL LED indicates that the card processor is not ready or that a catastrophic software failure occurred on the ML1000-2 card.
Chapter 5 Ethernet Cards 5.9 CE-100T-8 Card • Low order (LO) VCAT VC-3 circuit sizes of up to three members: VC-3-1v, VC-3-2v, or VC-3-3v • Low order (LO) VCAT VC-12 circuit sizes of up to 63 members: VC-12-Nv (where N=1 to 63) VC-3 VCAT circuits map administrative unit 4 (AU-4), and VC-12 VCAT circuits map tributary unit 12 (TU-12). In addition, the CE-100T-8 card supports Generic Framing Procedure (GFP-F) and point-to-point protocol/high-level data link control (PPP/HDLC) framing protocols.
Chapter 5 Ethernet Cards 5.9.1 CE-100T-8 Card-Level Indicators The following paragraphs describe the general functions of the CE-100T-8 card and relate to the block diagram. In the ingress direction, (Ethernet-to-SDH), the PHY, which performs all of the physical layer interface functions for 10/100 Mbps Ethernet, sends the frame to the network processor for queuing in the respective packet buffer memory. The network processor performs packet processing, packet switching, and classification.
Chapter 5 Ethernet Cards 5.9.3 CE-100T-8 Compatibility 5.9.3 CE-100T-8 Compatibility The CE-100T-8 card operates in Slots 1 to 6 or 12 to 17 and operates with the XC-VXL-2.5G, XC-VXL-10G, or XC-VXC-10G cards. 5.10 CE-1000-4 Card Note For hardware specifications, see the “A.7.3 CE-1000-4 Card Specifications” section on page A-45. The CE-1000-4 card uses pluggable Gigabit Interface Converters (GBICs) to transport Ethernet traffic over a SDH network. The CE-1000-4 provides four IEEE 802.
Chapter 5 Ethernet Cards 5.10 CE-1000-4 Card • Adding or removing cross connects from the VCG is not service affecting if the associated members are not in group. The CE-1000-4 card supports a non link capacity adjustment scheme (no-LCAS). This also makes it compatible with the ONS 15454 CE-100T-8 and ML-Series cards. The CE-1000-4 card supports VCAT groups (VCGs) that are fixed and not reconfigurable when no-LCAS is enabled (fixed VCGs).
Chapter 5 Ethernet Cards 5.10.1 CE-1000-4 Card-Level Indicators Figure 5-9 CE-1000-4 Faceplate and Block Diagram CE-1000-4 FAIL 8260 Processor, SDRAM Flash and DecodePLD ACT Protect RX BPIA SERDES GBIC Protect TX BPIA Rx 1 Tx SERDES GBIC ACT/LNK Rx 2 Malena FPGA Altera 4 ports: GigE Tx ACT/LNK TADM SERDES GBIC Main RX BPIA CDR Framer Rx 3 Tx ACT/LNK BUFFER MEMORY SERDES GBIC Rx 4 Tx CLOCK Generation 50MHz,100Mhz 125Mhz,155MHz Diff. Delay. Mem. POWER 5V, 3.3V, 2.5V, 1.8V, -1.
Chapter 5 Ethernet Cards 5.10.2 CE-1000-4 Port-Level Indicators 5.10.2 CE-1000-4 Port-Level Indicators The CE-1000-4 card provides a pair of LEDs for each Gigabit Ethernet port: an amber LED for activity (ACT) and a green LED for link status (LINK). Table Table 5-20 describes the status that each color represents. Table 5-20 CE-1000-4 Port-Level Indicators Port-Level Indicators Description Off No link exists to the Ethernet port.
Chapter 5 Ethernet Cards 5.11.2 GBIC Description Table 5-21 GBIC and SFP Card Compatibility Compatible GBIC or SFP (Cisco Product ID) Cisco Top Assembly Number (TAN) E1000-2-G (ONS 15454 SONET) E1000-2 (ONS 15454 SONET/SDH) 15454-GBIC-SX 15454E-GBIC-SX 15454-GBIC-LX/LH 15454E-GBIC-LX/LH 30-0759-01 800-06780-01 1 10-1743-01 30-0703-01 G1K-4 (ONS 15454 SONET/SDH) 15454-GBIC-SX 15454E-GBIC-SX 15454-GBIC-LX/LH 15454E-GBIC-LX/LH 15454-GBIC-ZX 15454E-GBIC-ZX 15454-GBIC-xx.x2 15454E-GBIC-xx.
Chapter 5 Ethernet Cards 5.11.3 DWDM and CWDM GBICs • Depth 2.56 in. (6.5 cm) GBIC temperature ranges are: • COM—commercial operating temperature range -5•C C to 70•C • EXT—extended operating temperature range 0•C C to 85•C • IND—industrial operating temperature range -40•C C to 85•C Figure 5-10 GBICs with Clips (left) and with a Handle (right) Clip Handle Receiver Transmitter 51178 Receiver Transmitter 5.11.3 DWDM and CWDM GBICs DWDM (15454-GBIC-xx.x, 15454E-GBIC-xx.
Chapter 5 Ethernet Cards 5.11.3 DWDM and CWDM GBICs The ONS 15454-supported DWDM GBICs reach up to 100 to 120 km over single-mode fiber and support 32 different wavelengths in the red and blue bands. Paired with optical amplifiers, such as the Cisco ONS 15216, the DWDM GBICs allow maximum unregenerated spans of approximately 300 km (Table 5-23). Table 5-23 Blue Band Supported Wavelengths for DWDM GBICs 1530.33 nm 1531.12 nm 1531.90 nm 1532.68 nm 1534.25 nm 1535.04 nm 1535.82 nm 1536.61 nm 1538.
Chapter 5 Ethernet Cards 5.11.4 SFP Description Figure 5-12 G-1K-4 with CWDM/DWDM GBICs in Cable Network Conventional GigE signals GigE / GigE / GigE over 's HFC CWDM/DWDM ONS Node Mux only with G-Series Cards with CWDM/DWDM GBICs QAM CWDM/DWDM Demux only 90954 VoD = Lambdas 5.11.4 SFP Description SFPs are integrated fiber-optic transceivers that provide high speed serial links from a port or slot to the network. Various latching mechanisms can be utilized on the SFP modules.
Chapter 5 Ethernet Cards 5.11.4 SFP Description Actuator/Button SFP Figure 5-15 Bail Clasp SFP 63067 63066 Figure 5-14 Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 6 Storage Access Networking Cards The Fibre Channel Multirate 4-Port (FC_MR-4) card is a 1.0625- or 2.125-Gbps Fibre Channel/fiber connectivity (FICON) card that integrates non-SDH framed protocols into an SDH time-division multiplexing (TDM) platform through virtually concatenated (VCAT) payloads. This chapter provides information about the FC_MR-4 card. For installation and step-by-step circuit configuration procedures, refer to the Cisco ONS 15454 SDH Procedure Guide.
Chapter 6 Storage Access Networking Cards 6.1.1 FC_MR-4 Card-Level Indicators SONET containers as small as STS1-1v (subrate) SDH containers as small as VC4-1v (subrate) SONET/SDH containers as small as STS-18c/VC4-6v (full rate) – Four 2.125 Gbps FC channels can be mapped into one of the following: SONET containers as small as STS1-1v (subrate) SDH containers as small as VC4-1v (subrate) SONET/SDH containers as small as STS36c/VC4-12v (full rate) • Frame encapsulation: ITU-T G.
Chapter 6 Storage Access Networking Cards 6.1.2 FC_MR-4 Port-Level Indicators Table 6-1 FC_MR-4 Card-Level Indicators Card-Level Indicators Description Red FAIL LED The red FAIL LED indicates that the card’s processor is not ready. Replace the card if the red FAIL LED persists. Green ACT LED If the ACTV/STBY LED is green, the card is operational and ready to carry traffic. Amber ACT LED If the ACTV/STBY LED is amber, the card is rebooting. 6.1.
Chapter 6 Storage Access Networking Cards 6.2.2 Enhanced Card Mode • 1-Gbps Fibre Channel/FICON is mapped into: – STS24c, STS48c – VC4-8c, VC4-16c – STS1-Xv where X is 19 to 24 – STS3c-Xv where X is 6 to 8 – VC4-Xv where X is 6 to 8 • 2-Gbps Fibre Channel/FICON is mapped into: – STS48c – VC4-16c – STS1-Xv where X is 37 to 48 – STS3c-Xv where X is 12 to 16 – VC4-Xv where X is 12 to 16 6.2.2 Enhanced Card Mode Features available in enhanced card mode are given in this section. 6.2.2.
Chapter 6 Storage Access Networking Cards 6.2.2 Enhanced Card Mode • VCG is flexible when SW-LCAS is enabled. (VCG can run traffic as soon as the first cross-connect is provisioned on both sides of the transport.) 6.2.2.
Chapter 6 Storage Access Networking Cards 6.2.3 Link Integrity 6.2.2.5 Interoperability Features The interoperability features are as follows: • Maximum frame size setting to prevent accumulation of oversized performance monitoring (PM) parameters for virtual SAN (VSAN) frames • Ingress filtering disabled for attachment to third-party GFP-over-SONET/SDH equipment 6.2.
Chapter 6 Storage Access Networking Cards 6.4 FC_MR-4 Card GBICs Hitless software upgrades are not possible with an activation from 5.0 to 6.0 in enhanced card mode. This is because the FPGA must be upgraded to support differential delay in enhanced mode. Upgrades are still hitless with the line rate mode.
Chapter 6 Storage Access Networking Cards 6.4 FC_MR-4 Card GBICs Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 7 Card Protection This chapter explains the Cisco ONS 15454 SDH card protection configurations. To provision card protection, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 7.1 Electrical Card Protection, page 7-1 • 7.2 STM-N Card Protection, page 7-4 • 7.3 Unprotected Cards, page 7-4 • 7.4 External Switching Commands, page 7-5 7.1 Electrical Card Protection The ONS 15454 SDH provides a variety of electrical card protection methods.
Chapter 7 Card Protection 7.1.2 1:N Protection Figure 7-1 ONS 15454 SDH Cards in a 1:1 Protection Configuration 26 28 29 Protect Working Protect Working (not electric) 12 27 Working Working Timing, Comm., and Control Cross Connect AIC-I (optional) Cross Connect Timing, Comm.
Chapter 7 Card Protection 7.1.2 1:N Protection Figure 7-2 ONS 15454 SDH Cards in a 1:N Protection Configuration 26 28 29 Working Working Working (not electric) 12 27 1:N Protection Working Working Timing, Comm., and Control Cross Connect AIC-I (optional) Cross Connect Timing, Comm.
Chapter 7 Card Protection 7.2 STM-N Card Protection The ONS 15454 SDH automatically detects and identifies a 1:N protect card when the card is installed in Slot 3 or Slot 15. However, the slot containing the 1:N card in a protection group must be manually provisioned as a protect slot because by default, all cards are working cards. 7.2 STM-N Card Protection With 1+1 port-to-port protection, any number of ports on the protect card can be assigned to protect the corresponding ports on the working card.
Chapter 7 Card Protection 7.4 External Switching Commands Figure 7-3 ONS 15454 SDH Cards in an Unprotected Configuration FMEC FMEC FMEC FMEC 23 FMEC 22 MIC-T/C/P 21 MIC-A/P 20 FMEC 19 FMEC FMEC FMEC FMEC 18 24 25 26 27 28 29 Working Working Working Working Working Working (not electric) Timing, Comm., and Control Cross Connect AIC-I (optional) Cross Connect Timing, Comm.
Chapter 7 Card Protection 7.4 External Switching Commands Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 8 Cisco Transport Controller Operation This chapter describes Cisco Transport Controller (CTC), the Cisco software interface for the Cisco ONS 15454 SDH. For CTC set up and login information, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 8.1 CTC Software Delivery Methods, page 8-1 • 8.2 CTC Installation Overview, page 8-4 • 8.3 PC and UNIX Workstation Requirements, page 8-4 • 8.4 ONS 15454 SDH Connection, page 8-6 • 8.5 CTC Window, page 8-7 • 8.
Chapter 8 Cisco Transport Controller Operation 8.1.1 CTC Software Installed on the TCC2/TCC2P Card Figure 8-1 CTC Software Versions, Node View Select the Maintenance > Software tabs in network view to display the software versions installed on all the network nodes (Figure 8-2). Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 8 Cisco Transport Controller Operation 8.1.2 CTC Software Installed on the PC or UNIX Workstation Figure 8-2 CTC Software Versions, Network View 8.1.2 CTC Software Installed on the PC or UNIX Workstation CTC software is downloaded from the TCC2/TCC2P cards and installed on your computer automatically after you connect to the ONS 15454 SDH with a new software release for the first time.
Chapter 8 Cisco Transport Controller Operation 8.2 CTC Installation Overview 8.2 CTC Installation Overview To connect to an ONS 15454 SDH using CTC, you enter the ONS 15454 SDH IP address in the URL field of Netscape Communicator or Microsoft Internet Explorer. After connecting to an ONS 15454 SDH, the following occurs automatically: 1. A CTC launcher applet is downloaded from the TCC2/TCC2P card to your computer. 2.
Chapter 8 Cisco Transport Controller Operation 8.3 PC and UNIX Workstation Requirements Note To avoid network performance issues, Cisco recommends managing a maximum of 50 nodes concurrently with CTC. The 50 nodes can be on a single DCC or split across multiple DCCs. Cisco does not recommend running multiple CTC sessions when managing two or more large networks. To manage more than 50 nodes, Cisco recommends using Cisco Transport Manager (CTM).
Chapter 8 Cisco Transport Controller Operation 8.4 ONS 15454 SDH Connection Table 8-2 CTC Computer Requirements (continued) Area Requirements Java Runtime JRE 1.4.2 or JRE 5.0 Environment Notes JRE 1.4.2 is installed by the CTC Installation Wizard included on the Cisco ONS 15454 software CD. JRE 1.4.2 and JRE 5.0 provide enhancements to CTC performance, especially for large networks with numerous circuits. Cisco recommends that you use JRE 1.4.2 or JRE 5.0 for networks with Software R7.0 nodes.
Chapter 8 Cisco Transport Controller Operation 8.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View Figure 8-3 Node View (Default Login View) Lower card shelf Node view Upper FMEC shelf Menu Tool bar Status area Graphic area Tabs 102028 Subtabs Status bar 8.5.1 Node View Node view, shown in Figure 8-3, is the first view open after you log into an ONS 15454 SDH. The login node is the first node shown, and it is the “home view” for the session. Node view allows you to view and manage one ONS 15454 SDH node.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View Table 8-4 Node View Card Colors (continued) Card Color Status Orange Slot is provisioned; a Major alarm condition exists. Red Slot is provisioned; a Critical alarm exists. The colors of the Front Mount Electrical Connection (FMEC) cards reflect the real-time status of the physical FMEC cards. Table 8-5 lists the FMEC card colors. The FMEC ports shown in CTC do not change color. Note You cannot preprovision FMECs.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View Table 8-6 Node View Card Port Colors and Service States (continued) Port Color Service State Description Green Unlocked-enabled The port is fully operational and performing as provisioned. The port transmits a signal and displays alarms; loopbacks are not allowed. Violet Unlocked-disabled, automaticInService The port is out-of-service, but traffic is carried. Alarm reporting is suppressed.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View The graphics on a port in node view show the state of a port (diagonal lines or loop graphics). Table 8-8 lists the port graphic and their description. Table 8-8 Node View Port Graphics Lower Shelf Port Graphics Description Multiple diagonal lines on port Port is in service and card was reset. Loop graphic on port Port is in service and has a loopback provisioned in Card View > Maintenance > Loopback tabs. 8.5.1.
Chapter 8 Cisco Transport Controller Operation 8.5.2 Network View Table 8-9 Node View Tabs and Subtabs (continued) Tab Description Inventory Provides inventory information (part number, — serial number, CLEI codes) for cards installed in the node. Allows you to delete and reset cards. Maintenance Performs maintenance tasks for the node.
Chapter 8 Cisco Transport Controller Operation 8.5.2 Network View The graphic area displays a background image with colored ONS 15454 SDH icons. A Superuser can set up the logical network view feature, which enables each user to see the same network view. Selecting a node or span in the graphic area displays information about the node and span in the status area. 8.5.2.1 CTC Node Colors The color of a node in network view, shown in Table 8-10, indicates the node alarm status.
Chapter 8 Cisco Transport Controller Operation 8.5.3 Card View There are four possible combinations for the appearance of DCCs: green/solid, green/dashed, gray/solid, or gray/dashed. DCC appearance corresponds to the following states: active/routable, active/nonroutable, failed/routable, or failed/nonroutable. Circuit provisioning uses active/routable links. 8.5.2.
Chapter 8 Cisco Transport Controller Operation 8.5.3 Card View Figure 8-7 Note CTC Card View CTC provides a card view for all ONS 15454 SDH cards except the TCC2, TCC2P, XC10G, XC-VXL-10G, XC-VXL-2.5G, XC-VXC-2.5G, and SC-VSC-10G cards. Provisioning for these common control cards occurs at the node view; therefore, no card view is necessary. Use the card view tabs and subtabs, shown in Table 8-13, to provision and manage the ONS 15454 SDH.
Chapter 8 Cisco Transport Controller Operation 8.5.4 Print or Export CTC Data Table 8-13 Card View Tabs and Subtabs (continued) Tab Description Subtabs Circuits Creates, deletes, edits, and searches for circuits. Circuits Provisioning Provisions an ONS 15454 SDH card.
Chapter 8 Cisco Transport Controller Operation 8.6 TCC2/TCC2P Card Reset 8.6 TCC2/TCC2P Card Reset You can reset the ONS 15454 SDH TCC2/TCC2P card by using CTC (a soft reset) or by physically reseating a TCC2/TCC2P card (a hard reset). A soft reset reboots the TCC2/TCC2P card and reloads the operating system and the application software. Additionally, a hard reset temporarily removes power from the TCC2/TCC2P card and clears all buffer memory.
Chapter 8 Cisco Transport Controller Operation 8.8 Software Revert The revert feature is useful if a maintenance window closes while you are upgrading CTC software. You can revert to the protect software load without losing traffic. When the next maintenance window opens, complete the upgrade and activate the new software load. Circuits created and provisioning done after a software load is activated (upgraded to a higher software release) will be lost with a revert.
C H A P T E R 9 Security This chapter provides information about Cisco ONS 15454 SDH user security. To provision security, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 9.1 User IDs and Security Levels, page 9-1 • 9.2 User Privileges and Policies, page 9-1 • 9.3 Audit Trail, page 9-7 • 9.4 RADIUS Security, page 9-8 9.
Chapter 9 Security 9.2.1 User Privileges by CTC Task 9.2.1 User Privileges by CTC Task Table 9-1 shows the actions that each user privilege level can perform in node view.
Chapter 9 Security 9.2.
Chapter 9 Security 9.2.
Chapter 9 Security 9.2.2 Security Policies 2. The action buttons in the subtab are active for all users, but the actions can be completely performed only by the users assigned with the required security levels. Table 9-2 shows the actions that each user privilege level can perform in network view.
Chapter 9 Security 9.2.2 Security Policies 9.2.2.1 Superuser Privileges for Provisioning Users Superusers can grant permission to Provisioning users to retrieve audit logs, restore databases, clear performance monitoring (PM) parameters, activate software loads, and revert software loads. These privileges can only be set using CTC network element (NE) defaults, except the PM clearing privilege, which can be granted using the CTC Provisioning > Security > Access tabs.
Chapter 9 Security 9.3 Audit Trail For more information on how to enable EMS secure access, refer Cisco ONS 15454 SDH Procedure Guide for instructions. 9.3 Audit Trail The ONS 15454 SDH maintains an audit trail log that resides on the TCC2/TCC2P. This record shows who has accessed the system and what operations were performed during a given time period.
Chapter 9 Security 9.3.2 Audit Trail Capacities • Message Type—Denotes if the event is Success/Failure type • Message Details—A description of the change 9.3.2 Audit Trail Capacities The system is able to store 640 log entries.When this limit is reached, the oldest entries are overwritten with new events. When the log server is 80 percent full, an AUD-LOG-LOW condition is raised and logged (by way of CORBA/CTC).
Chapter 9 Security 9.4.2 Shared Secrets 9.4.2 Shared Secrets A shared secret is a text string that serves as a password between: • A RADIUS client and RADIUS server • A RADIUS client and a RADIUS proxy • A RADIUS proxy and a RADIUS server For a configuration that uses a RADIUS client, a RADIUS proxy, and a RADIUS server, the shared secret that is used between the RADIUS client and the RADIUS proxy can be different than the shared secret used between the RADIUS proxy and the RADIUS server.
Chapter 9 Security 9.4.2 Shared Secrets Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 10 Timing This chapter provides information about Cisco ONS 15454 SDH users and SDH timing. To provision security and timing, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 10.1 Timing Parameters, page 10-1 • 10.2 Network Timing, page 10-2 • 10.3 Synchronization Status Messaging, page 10-3 10.1 Timing Parameters SDH timing parameters must be set for each ONS 15454 SDH.
Chapter 10 Timing 10.2 Network Timing card. However, if you assign all three references to other timing sources, the internal clock is always available as a backup timing reference. The internal clock is a Stratum 3 (ST3), so if an ONS 15454 SDH node becomes isolated, timing is maintained at the ST3 level. The CTC Maintenance > Timing > Report tabs show current timing information for an ONS 15454 SDH, including the timing mode, clock state and status, switch type, and reference data.
Chapter 10 Timing 10.
Chapter 10 Timing 10.3 Synchronization Status Messaging Table 10-1 SDH SSM Message Set (continued) Message Quality Description G812T 3 Transit node clock traceable G812L 4 Local node clock traceable SETS 5 Synchronous equipment DUS 6 Do not use for timing synchronization Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 11 Circuits and Tunnels Note The terms "Unidirectional Path Switched Ring" and "UPSR" may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as "Path Protected Mesh Network" and "PPMN," refer generally to Cisco's path protection feature, which may be used in any topological network configuration.
Chapter 11 Circuits and Tunnels 11.1 Overview 11.1 Overview You can create circuits across and within ONS 15454 SDH nodes and assign different attributes to circuits. For example, you can: • Create one-way, two-way (bidirectional), or broadcast circuits. VC low-order path tunnels (VC_LO_PATH_TUNNEL) are automatically set to bidirectional and do not use multiple drops. • Assign user-defined names to circuits. • Assign different circuit sizes. • Enable port grouping on low-order path tunnels.
Chapter 11 Circuits and Tunnels 11.2 Circuit Properties • Type—Circuit types are HOP (high-order circuit), LOP (low-order circuit), VCT (VC low-order tunnel), VCA (VC low-order aggregation point), OCHNC (dense wavelength division multiplexing [DWDM] optical channel network connection, HOP_v (high-order virtual concatenated [VCAT] circuit), and LOP_v (low-order VCAT circuit). Note For OCHNC information, refer to the Cisco ONS 15454 DWDM Procedure Guide. • Size—The circuit size.
Chapter 11 Circuits and Tunnels 11.2.1 Concatenated VC4 Time Slot Assignments Figure 11-1 ONS 15454 SDH Circuit Window in Network View 11.2.1 Concatenated VC4 Time Slot Assignments Table 11-1 shows the available time slot assignments for concatenated VC4s when using CTC to provision circuits.
Chapter 11 Circuits and Tunnels 11.2.
Chapter 11 Circuits and Tunnels 11.2.
Chapter 11 Circuits and Tunnels 11.2.3 Circuit States Table 11-2 ONS 15454 SDH Circuit Status (continued) Status Definition/Activity PARTIAL A CTC-created circuit is missing a cross-connect or network span, a complete path from source to destination(s) does not exist, or an alarm interface panel (AIP) change occurred on one of the circuit nodes and the circuit is in need of repair. (AIPs store the node MAC address.) In CTC, circuits are represented using cross-connects and network spans.
Chapter 11 Circuits and Tunnels 11.2.4 Circuit Protection Types • Partial is appended to the Locked circuit service state when circuit cross-connects state are mixed and not all in the Unlocked-enabled service state. The Locked-partial state can occur during automatic or manual transitions between states. The Locked-partial service state can appear during a manual transition caused by an abnormal event such as a CTC crash or communication error, or if one of the cross-connects could not be changed.
Chapter 11 Circuits and Tunnels 11.2.5 Circuit Information in the Edit Circuit Window Table 11-3 Circuit Protection Types Protection Type Description 1+1 The circuit is protected by a 1+1 protection group. 2F MS-SPRing The circuit is protected by a two-fiber MS-SPRing. 4F MS-SPRing The circuit is protected by a four-fiber MS-SPRing. 2F-PCA The circuit is routed on a protection channel access (PCA) path on a two-fiber MS-SPRing; PCA circuits are unprotected.
Chapter 11 Circuits and Tunnels 11.2.5 Circuit Information in the Edit Circuit Window • UPSR Switch Counts—Allows you to change path protection switch protection paths. For more information, see the “11.7 SNCP Circuits” section on page 11-14. • State—Allows you to edit cross-connect service states. • Merge—Allows you to merge aligned circuits. For more information, see the “11.17 Merged Circuits” section on page 11-33.
Chapter 11 Circuits and Tunnels 11.3 Cross-Connect Card Bandwidth A notation within or by the squares or selector pentagons on each node indicates switches and loopbacks, including: • F = Force switch • M = Manual switch • L = Lockout switch • Arrow = Facility (outward) or terminal (inward) loopback Figure 11-2 shows an example of a 2F-PCA circuit with a card in terminal loopback in the Edit Circuits window.
Chapter 11 Circuits and Tunnels 11.4 DCC Tunnels or DS-3 cross-connects, or 1008 bidirectional E-1 cross-connects. The XC-VXC-10G card manages up to 576 bidirectional STM-1 cross-connects, 576 bidirectional E-3 or DS-3 cross-connects, or 1344 bidirectional E-1 cross-connects. The XC-VXL-10G, XC-VXL-2.5G, and XC-VXC-10G cards work with the TCC2/TCC2P card to maintain connections and set up cross-connects within the node. You can create circuits using CTC.
Chapter 11 Circuits and Tunnels 11.4.2 IP-Encapsulated Tunnels Note A DCC does not function on a mixed network of ONS 15454 SDH nodes and ONS 15454 nodes. DCC tunneling is required for ONS 15454 SDH nodes transporting data through ONS 15454 nodes.
Chapter 11 Circuits and Tunnels 11.5 Multiple Destinations for Unidirectional Circuits 11.5 Multiple Destinations for Unidirectional Circuits Unidirectional circuits can have multiple destinations for use in broadcast circuit schemes. In broadcast scenarios, one source transmits traffic to multiple destinations, but traffic is not returned back to the source.
Chapter 11 Circuits and Tunnels 11.7.1 Open-Ended SNCP Circuits On the SNCP Switch Counts subtab, you can: • Perform maintenance switches on the circuit selector. • View switch counts for the selectors. 11.7.1 Open-Ended SNCP Circuits If ONS 15454 SDH nodes are connected to a third-party network, you can create an open-ended SNCP circuit to route a circuit through it. To do this, you create three circuits. One circuit is created on the source ONS 15454 SDH network.
Chapter 11 Circuits and Tunnels 11.8 MS-SPRing Protection Channel Access Circuits Figure 11-5 SNCP Go-and-Return Routing Node A Any network Any network Go and Return working connection Go and Return protecting connection 96953 Node B 11.8 MS-SPRing Protection Channel Access Circuits You can provision circuits to carry traffic on MS-SPRing protection channels when conditions are fault free.
Chapter 11 Circuits and Tunnels 11.9 MS-SPRing VC4 Squelch Table 11.9 MS-SPRing VC4 Squelch Table MS-SPRing VC4 squelch tables show VC4s that will be squelched for every isolated node. The MS-SPRing Squelch Table window displays the following information: Note • VC4 Number—Shows the MS-SPRing VC4 numbers. For two-fiber MS-SPRings, the number of VC4s is half the MS-SPRing OC-N, for example, an STM-16 MS-SPRing squelch table will show 8 VC4s.
Chapter 11 Circuits and Tunnels 11.11 Path Signal Label, C2 Byte Table 11-7 ONS 15454 SDH Cards Capable of J2 Path Trace J2 Function Cards Transmit and Receive E1-42 Receive Only STM1E-12 If the string received at a circuit drop port does not match the string the port expects to receive, an alarm is raised. Two path trace modes are available: • Automatic—The receiving port assumes that the first string it receives is the baseline string.
Chapter 11 Circuits and Tunnels 11.12 Automatic Circuit Routing 11.12 Automatic Circuit Routing If you select automatic routing during circuit creation, CTC routes the circuit by dividing the entire circuit route into segments based on protection domains. For unprotected segments of circuits provisioned as fully protected, CTC finds an alternate route to protect the segment, creating a virtual SNCP. Each segment of a circuit path is a separate protection domain.
Chapter 11 Circuits and Tunnels 11.13 Manual Circuit Routing Figure 11-6 Secondary Sources and Destinations Primary source Primary destination Vendor A network Vendor B network Secondary source ONS network 83948 Secondary destination Several rules apply to secondary sources and destinations: • CTC does not allow a secondary destination for unidirectional circuits, because you can always specify additional destinations after you create the circuit.
Chapter 11 Circuits and Tunnels 11.13 Manual Circuit Routing CTC imposes the following rules on manual routes: • All circuits, except multicard EtherSwitch circuits in a shared packet ring, should have links with a direction that flows from source to destination. This is true for multicard EtherSwitch circuits that are not in a shared packet ring. • If you enabled Fully Path Protected, choose a diverse protect (alternate) path for every unprotected segment (Figure 11-7).
Chapter 11 Circuits and Tunnels 11.13 Manual Circuit Routing • Choose the links of multicard EtherSwitch circuits in a shared packet ring to route the circuit from source to destination back to source (Figure 11-9). Otherwise, a route (set of links) chosen with loops is invalid.
Chapter 11 Circuits and Tunnels 11.
Chapter 11 Circuits and Tunnels 11.
Chapter 11 Circuits and Tunnels 11.15 Virtual Concatenated Circuits 11.15 Virtual Concatenated Circuits Virtual concatenated (VCAT) circuits, also called VCAT groups (VCGs), transport traffic using noncontiguous time division multiplexing (TDM) time slots, avoiding the bandwidth fragmentation problem that exists with contiguous concatenated circuits. The cards that support VCAT circuits are the CE-Series, FC_MR-4 (both enhanced and line rate mode), and ML-Series cards.
Chapter 11 Circuits and Tunnels 11.15.
Chapter 11 Circuits and Tunnels 11.15.4 VCAT Circuit Size autonomously remove members that have defects in the H4/Z7 byte. SW-LCAS is only available for legacy SONET defects such as AIS-P, LOP-P, etc. SW-LCAS is optional. You can select SW-LCAS during VCAT circuit creation. The FC_MR-4 card in line rate mode does not support SW-LCAS. SW-LCAS allows circuit pairing for ML-Series cards over two-fiber MS-SPRing.
Chapter 11 Circuits and Tunnels 11.16 Bridge and Roll • FC_MR-4 (enhanced mode) card—You can add or delete SW-LCAS VCAT members, although it might affect service. Before deleting a member, Cisco recommends that you put the member in the Locked-enabled,outOfGroup service state. You cannot add or delete members from VCAT circuits without SW-LCAS. • FC_MR-4 (line rate mode) card—All VCAT circuits using FC_MR-4 (line rate mode) cards have a fixed number of members; you cannot add or delete members.
Chapter 11 Circuits and Tunnels 11.16.1 Rolls Window 11.16.1 Rolls Window The Rolls window lists information about a rolled circuit before the roll process is complete. You can access the Rolls window by clicking the Circuits > Rolls tabs in either network or node view. Figure 11-13 shows the Rolls window. Figure 11-13 Rolls Window The Rolls window information includes: • Roll From Circuit—The circuit with connections that will no longer be used when the roll process is complete.
Chapter 11 Circuits and Tunnels 11.16.2 Roll Status • Force Valid Signal—Forces a roll onto the Roll To Circuit destination without a valid signal. If you choose Force Valid Signal, traffic on the circuit that is involved in the roll will be dropped when the roll is completed. • Finish—Completes the circuit processing of both manual and automatic rolls and changes the circuit status from ROLL_PENDING to DISCOVERED.
Chapter 11 Circuits and Tunnels 11.16.3 Single and Dual Rolls S1 Single Source Roll Node 2 Node 1 S2 D Original leg New leg 83267 Figure 11-14 In Figure 11-15, you can select any available VC4 on Node 2 for a new destination. S Single Destination Roll Node 1 Node 2 D1 Original leg New leg D2 83266 Figure 11-15 Figure 11-16 shows one circuit rolling onto another circuit at the destination. The new circuit has cross-connects on Node 1, Node 3, and Node 4.
Chapter 11 Circuits and Tunnels 11.16.4 Two Circuit Bridge and Roll Note Create a Roll To Circuit before rolling a circuit with the source on Node 3 and the destination on Node 4. A dual roll involves two cross-connects. It allows you to reroute intermediate segments of a circuit, but keep the original source and destination. If the new segments require new cross-connects, use the Bridge and Roll wizard or create a new circuit and then perform a roll.
Chapter 11 Circuits and Tunnels 11.16.5 Protected Circuits • A maximum of two rolls can exist between any two circuits. • If two rolls are involved between two circuits, both rolls must be on the original circuit. The second circuit should not carry live traffic. The two rolls loop from the second circuit back to the original circuit. The roll mode of the two rolls must be identical (either automatic or manual).
Chapter 11 Circuits and Tunnels 11.18 Reconfigured Circuits 11.18 Reconfigured Circuits You can reconfigure multiple circuits, which is typically necessary when a large number of circuits are in the PARTIAL state. When reconfiguring multiple circuits, the selected circuits can be any combination of DISCOVERED, PARTIAL, DISCOVERED_TL1, or PARTIAL_TL1 circuits. You can reconfigure VCTs, VCA circuits, VLAN-assigned circuits, VCAT circuits, CTC-created circuits, and TL1-created circuits.
C H A P T E R 12 SDH Topologies and Upgrades This chapter explains Cisco ONS 15454 SDH topologies and upgrades. To provision topologies, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 12.1 SDH Rings and TCC2/TCC2P Cards, page 12-1 • 12.2 Multiplex Section-Shared Protection Rings, page 12-2 • 12.3 Subnetwork Connection Protection, page 12-13 • 12.4 Dual Ring Interconnect, page 12-18 • 12.5 Subtending Rings, page 12-25 • 12.
Chapter 12 SDH Topologies and Upgrades 12.2 Multiplex Section-Shared Protection Rings 4. Total MS-DCC usage must be equal to or less than 28 MS-DCCs. 5. See the “12.3 Subnetwork Connection Protection” section on page 12-13. 6. Total MS-DCC and RS-DCC usage must be equal to or less than 84. When MS-DCC is provisioned, an RS-DCC termination is allowed on the same port, but is not recommended.
Chapter 12 SDH Topologies and Upgrades 12.2.1 Two-Fiber MS-SPRings Figure 12-1 Four-Node, Two-Fiber MS-SPRing VC4s 1-8 (working) VC4s 9-16 (protect) Node 0 VC4s 1-8 (working) VC4s 9-16 (protect) STM-16 Ring Node 1 = Fiber 1 Node 2 = Fiber 2 71491 Node 3 The SDH K1, K2, and K3 bytes carry the information that governs MS-SPRing protection switches. Each MS-SPRing node monitors the K bytes to determine when to switch the SDH signal to an alternate physical path.
Chapter 12 SDH Topologies and Upgrades 12.2.1 Two-Fiber MS-SPRings Figure 12-2 Four-Node, Two-Fiber MS-SPRing Traffic Pattern Node 0 Node 3 STM-16 Ring Node 1 Fiber 1 Node 2 Fiber 2 71276 Traffic flow Figure 12-3 shows how traffic is rerouted after a line break between Node 0 and Node 3. • All circuits originating on Node 0 and carried to Node 2 on Fiber 2 are switched to the protect bandwidth of Fiber 1. For example, a circuit carried on VC4-1 on Fiber 2 is switched to VC4-9 on Fiber 1.
Chapter 12 SDH Topologies and Upgrades 12.2.2 Four-Fiber MS-SPRings Figure 12-3 Four-Node, Two-Fiber MS-SPRing Traffic Pattern After Line Break Node 0 Node 3 STM-16 Ring Node 1 Fiber 1 Node 2 Fiber 2 71277 Traffic flow 12.2.2 Four-Fiber MS-SPRings Four-fiber MS-SPRings double the bandwidth of two-fiber MS-SPRings. Because they allow span switching as well as ring switching, four-fiber MS-SPRings increase the reliability and flexibility of traffic protection.
Chapter 12 SDH Topologies and Upgrades 12.2.2 Four-Fiber MS-SPRings Figure 12-4 Four-Node, Four-Fiber MS-SPRing Node 0 Span 4 Span 1 Span 5 Span 8 STM-16 Ring Span 6 Node 1 Span 7 Span 3 Span 2 = Working fibers Node 2 = Protect fibers 71275 Node 3 Four-fiber MS-SPRings provide span and ring switching. Span switching occurs when a working span fails (Figure 12-5).
Chapter 12 SDH Topologies and Upgrades 12.2.2 Four-Fiber MS-SPRings Figure 12-5 Four-Fiber MS-SPRing Span Switch Node 0 Span 4 Span 1 Span 5 Span 8 STM-16 Ring Span 6 Node 1 Span 7 Span 3 Span 2 = Working fibers Node 2 = Protect fibers 71278 Node 3 Ring switching occurs when a span switch cannot recover traffic (Figure 12-6), such as when both the working and protect fibers fail on the same span. In a ring switch, traffic is routed to the protect fibers throughout the full ring.
Chapter 12 SDH Topologies and Upgrades 12.2.3 MS-SPRing Bandwidth Figure 12-6 Four-Fiber MS-SPRing Switch Node 0 Span 4 Span 1 Span 5 Span 8 STM-16 Ring Span 6 Node 1 Span 7 Span 3 Span 2 = Working fibers Node 2 = Protect fibers 71279 Node 3 12.2.3 MS-SPRing Bandwidth An MS-SPRing node can terminate traffic it receives from either side of the ring. Therefore, MS-SPRings are suited for distributed node-to-node traffic applications such as interoffice networks and access networks.
Chapter 12 SDH Topologies and Upgrades 12.2.4 MS-SPRing Application Sample Table 12-3 shows the bidirectional bandwidth capacities of four-fiber MS-SPRings. Table 12-3 Four-Fiber MS-SPRing Capacity STM Rate Working Bandwidth Protection Bandwidth Ring Capacity STM-16 VC4 1-16 (Fiber 1) VC4 1-16 (Fiber 2) 16 x N – PT STM-64 VC4 1-64 (Fiber 1) VC4 1-64 (Fiber 2) 64 x N – PT Figure 12-7 shows an example of MS-SPRing bandwidth reuse.
Chapter 12 SDH Topologies and Upgrades 12.2.4 MS-SPRing Application Sample Figure 12-8 Five-Node, Two-Fiber MS-SPRing Carrier 1 2 STM-1s 56 local Carrier 2 E-1s 12 E-3s 4 E-3s 14 E-1s Node 1 Node 0 14 E-1s 2 E-3s Node 4 Node 2 14 E-1s 8 E-3s = Fiber 1 4 E-3s 14 E-1s = Fiber 2 71263 Node 3 Figure 12-9 shows the shelf assembly layout for Node 0, which has one free slot. Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 12 SDH Topologies and Upgrades 12.2.4 MS-SPRing Application Sample Figure 12-9 Shelf Assembly Layout for Node 0 in Figure 12-8 Lower Shelf 134604 E3-12 E3-12 OC3/STM1 OC3/STM1 OC48/STM16 OC48/STM16 TCC2/TCC2P Cross Connect Free Slot Cross Connect TCC2/TCC2P Free Slot E1-N-14 E1-N-14 E1-N-14 E1-N-14 E1-N-14 Figure 12-10 shows the shelf assembly layout for the remaining sites in the ring. In this MS-SPRing configuration, an additional eight E-3s at Node IDs 1 and 3 can be activated.
Chapter 12 SDH Topologies and Upgrades 12.2.5 MS-SPRing Fiber Connections 12.2.5 MS-SPRing Fiber Connections Plan your fiber connections and use the same plan for all MS-SPRing nodes. For example, make the east port the farthest slot to the right and the west port the farthest slot to the left. Plug fiber connected to an east port at one node into the west port on an adjacent node. Figure 12-11 shows fiber connections for a two-fiber MS-SPRing with trunk cards in Slot 5 (west) and Slot 12 (east).
Chapter 12 SDH Topologies and Upgrades 12.2.6 Two-Fiber MS-SPRing to Four-Fiber MS-SPRing Conversion Connecting Fiber to a Four-Node, Four-Fiber MS-SPRing West Node 1 Node 2 Tx Rx Tx Rx East West Slot Slot 12 13 Slot Slot 6 5 Tx Rx West East Slot Slot 12 13 Slot Slot 5 6 Node 4 Slot Slot 12 13 Slot Slot 6 5 Tx Rx East West East Slot Slot 12 13 Slot Slot 5 6 Node 3 Working fibers Protect fibers 61958 Figure 12-12 12.2.
Chapter 12 SDH Topologies and Upgrades 12.3 Subnetwork Connection Protection CTC automates ring configuration. SNCP ring network traffic is defined within the ONS 15454 SDH on a circuit-by-circuit basis. If an extended SNCP ring mesh network circuit is not defined within a 1+1 or MS-SPRing line protection scheme and path protection is available and specified, CTC uses an SNCP ring as the default protection mechanism. An SNCP ring circuit requires two DCC-provisioned optical spans per node.
Chapter 12 SDH Topologies and Upgrades 12.
Chapter 12 SDH Topologies and Upgrades 12.3 Subnetwork Connection Protection Figure 12-15 STM-1 SNCP Ring V5.x Switch ONS 15454 SDH Node A 8 E-1s ONS 15454 SDH Node D ONS 15454 SDH Node B 8 E-1s = Fiber 1 8 E-1s = Fiber 2 71268 ONS 15454 SDH Node C Node A has four E1-14 cards to provide 42 active E-1 ports. The other sites only require two E1-14 cards to carry the eight E-1s to and from the remote switch.
Chapter 12 SDH Topologies and Upgrades 12.3 Subnetwork Connection Protection Figure 12-16 Card Setup of Node A in the STM-1 SNCP Ring Example Lower Shelf 134602 Free Slot Free Slot Free Slot Free Slot Free Slot Free Slot TCC2/TCC2P Cross Connect Free Slot Cross Connect TCC2/TCC2P OC3/STM1 OC3/STM1 E1-N-14 E1-N-14 E1-N-14 E1-N-14 In Figure 12-15 on page 12-16, Nodes B through D each contain two E1-14 cards and two STM-1 cards.
Chapter 12 SDH Topologies and Upgrades 12.4 Dual Ring Interconnect 12.4 Dual Ring Interconnect Dual ring interconnect (DRI) topology provides an extra level of path protection for circuits on interconnected rings. DRI allows users to interconnect MS-SPRings, SNCPs, or an SNCP with an MS-SPRing, with additional protection provided at the transition nodes. In a DRI topology, ring interconnections occur at two or four nodes. The drop-and-continue DRI method is used for all ONS 15454 SDH DRIs.
Chapter 12 SDH Topologies and Upgrades 12.4.1 MS-SPRing DRI Figure 12-18 shows ONS 15454 SDH nodes in a traditional MS-SPRing DRI topology with same-side routing. In Ring 1, Nodes 3 and 4 are the interconnect nodes, and in Ring 2, Nodes 8 and 9 are the interconnect nodes. Duplicate signals are sent between Node 4 (Ring 1) and Node 9 (Ring 2), and between Node 3 (Ring 1) and Node 8 (Ring 2).
Chapter 12 SDH Topologies and Upgrades 12.4.1 MS-SPRing DRI Figure 12-19 shows ONS 15454 SDH nodes in a traditional MS-SPRing DRI topology with opposite-side routing. In Ring 1, Nodes 3 and 4 are the interconnect nodes, and in Ring 2, Nodes 8 and 9 are the interconnect nodes. Duplicate signals are sent from Node 4 (Ring 1) to Node 8 (Ring 2), and between Node 3 (Ring 1) and Node 9 (Ring 2). In Ring 1, traffic at Node 4 is dropped (to Node 9) and continued (to Node 8).
Chapter 12 SDH Topologies and Upgrades 12.4.2 SNCP Dual Ring Interconnect Figure 12-20 ONS 15454 SDH Integrated MS-SPRing Dual Ring Interconnect Node 1 Node 2 MS-SPRing 1 Primary Node 3 Node 4 Node 8 Secondary Node 5 MS-SPRing 2 Node 7 Node 6 Primary Path (working) Secondary Path (protection) 115739 Service Selector 12.4.2 SNCP Dual Ring Interconnect The SNCP dual ring interconnect topology (SNCP DRI) provides an extra level of path protection between interconnected SNCP rings.
Chapter 12 SDH Topologies and Upgrades 12.4.2 SNCP Dual Ring Interconnect Figure 12-21 ONS 15454 Traditional SDH Dual Ring Interconnect E1/E3/DS3I/GigE Node #1 SNCP Ring 1 Node #3 Node #4 Node #2 Node #5 Duplicate Signals Node #6 Node #7 SNCP Ring 2 Bridge Pass-through Node E1/E3/DS3I/GigE Path Selector Primary Path - Primary Return Path - Primary Return Path - Secondary 90392 Primary Path - Secondary Figure 12-22 shows ONS 15454 SDH nodes in an integrated DRI topology.
Chapter 12 SDH Topologies and Upgrades 12.4.
Chapter 12 SDH Topologies and Upgrades 12.4.3 SNCP/MS-SPRing DRI Handoff Configurations 12.4.3 SNCP/MS-SPRing DRI Handoff Configurations SNCPs and MS-SPRings can also be interconnected. In SNCP/MS-SPRing DRI handoff configurations, primary and secondary nodes can be the circuit source or destination, which is useful when non-DCC optical interconnecting links are present. Figure 12-23 shows an example of an SNCP to MS-SPRing traditional DRI handoff.
Chapter 12 SDH Topologies and Upgrades 12.5 Subtending Rings Figure 12-24 ONS 15454 SDH SNCP to MS-SPRing Integrated DRI Handoff Node 5 Node 1 Node 2 SNCP Node 4 Node 3 MS-SPRing Node 7 Node 8 Node 6 Bridge 115741 Path Selector 12.5 Subtending Rings The ONS 15454 SDH supports up to 84 SDH regenerator RS-DCCs or 28 MS-DCCs with TCC2/TCC2P cards. See Table 12-1 on page 12-1 for ring and regenerator RS-DCC and MS-DCC information.
Chapter 12 SDH Topologies and Upgrades 12.5 Subtending Rings Figure 12-25 ONS 15454 SDH with Multiple Subtending Rings SNCP SNCP SNCP or MS-SPRing SNCP 71273 SNCP or MS-SPRing Figure 12-26 shows an SNCP ring subtending from an MS-SPRing. In this example, Node 3 is the only node serving both the MS-SPRing and SNCP ring. STM-N cards in Slots 5 and 12 serve the MS-SPRing, and STM-N cards in Slots 6 and 13 serve the SNCP ring.
Chapter 12 SDH Topologies and Upgrades 12.6 Linear ADM Configurations Figure 12-27 shows two MS-SPRings shared by one ONS 15454 SDH. Ring 1 runs on Nodes 1, 2, 3, and 4. Ring 2 runs on Nodes 4, 5, 6, and 7. Two MS-SPRing, Ring 1 and Ring 2, are provisioned on Node 4. Ring 1 uses cards in Slots 5 and 12, and Ring 2 uses cards in Slots 6 and 13. Nodes in different MS-SPRings can have the same or different node IDs.
Chapter 12 SDH Topologies and Upgrades 12.7 Extended SNCP Mesh Networks Linear (Point-to-Point) ADM Configuration Slot 5 to Slot 5 Slot 12 to Slot 12 Slot 6 to Slot 6 Slot 13 to Slot 13 Node 1 Node 2 34284 Figure 12-28 Node 3 Protect Path Working Path 12.7 Extended SNCP Mesh Networks In addition to single MS-SPRings, SNCP rings, and ADMs, you can extend ONS 15454 SDH traffic protection by creating extended SNCP mesh networks.
Chapter 12 SDH Topologies and Upgrades 12.7 Extended SNCP Mesh Networks Figure 12-29 Extended SNCP Mesh Network Source Node Node 3 Node 5 Node 2 Node 4 Node 1 Node 10 Node 8 Node 6 Node 7 Node 11 Node 9 c raffi ng t ki Wor Destination Node = Primary path = Secondary path 32136 Protect traffic Extended SNCP rings also allow spans with different SDH speeds to be mixed together in “virtual rings.” Figure 12-30 shows Nodes 1, 2, 3, and 4 in a standard STM-16 ring.
Chapter 12 SDH Topologies and Upgrades 12.8 Four Node Configurations 12.8 Four Node Configurations You can link multiple ONS 15454 SDH nodes using their STM-N cards (that is, create a fiber-optic bus) to accommodate more access traffic than a single ONS 15454 SDH can support. Refer to the Cisco ONS 15454 SDH Procedure Guide for more information. You can link nodes with STM-4 or STM-16 fiber spans as you would link any other two network nodes.
Chapter 12 SDH Topologies and Upgrades 12.9.1 Span Upgrade Wizard technicians (one at each end of the span) who can communicate with each other during the upgrade. Upgrading a span is non-service affecting and causes no more than three switches, each of which is less than 50 ms in duration. Note Span upgrades do not upgrade SDH topologies, for example, a 1+1 group to a two-fiber MS-SPRing. Refer to the Cisco ONS 15454 SDH Procedure Guide for topology upgrade procedures. 12.9.
Chapter 12 SDH Topologies and Upgrades 12.9.2 Manual Span Upgrades Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 13 Management Network Connectivity This chapter provides an overview of ONS 15454 SDH data communications network (DCN) connectivity. Cisco Optical Networking System (ONS) network communication is based on IP, including communication between Cisco Transport Controller (CTC) computers and ONS 15454 SDH nodes and communication among networked ONS 15454 SDH nodes.
Chapter 13 Management Network Connectivity 13.1 IP Networking Overview 13.1 IP Networking Overview ONS 15454 SDH nodes can be connected in many different ways within an IP environment: • They can be connected to LANs through direct connections or a router. • IP subnetting subnetting can create multiple logical ONS 15454 networks within a single Class A, B, or C IP network. If you do not subnet, you will only be able to use one network from your Class A, B, or C network.
Chapter 13 Management Network Connectivity 13.2.1 Scenario 1: CTC and ONS 15454 SDH Nodes on Same Subnet Note The ONS 15454 secure mode option is available when TCC2P cards are installed. Secure mode allows two IP addresses to be provisioned for the node, one for the MIC-C/T/P LAN port and one for the TCC2P DCC interfaces. Secure mode IP addressing is described in the “13.2.9 Scenario 9: IP Addressing with Secure Mode Enabled” section on page 13-20.
Chapter 13 Management Network Connectivity 13.2.3 Scenario 3: Using Proxy ARP to Enable an ONS 15454 SDH Gateway On the CTC computer, the default gateway is set to router interface A. If the LAN uses Dynamic Host Configuration Protocol (DHCP), the default gateway and IP address are assigned automatically. In the example shown in Figure 13-2, a DHCP server is not available. Figure 13-2 Scenario 2: CTC and ONS 15454 SDH Nodes Connected to Router LAN A Int "A" CTC Workstation IP Address 192.168.1.
Chapter 13 Management Network Connectivity 13.2.3 Scenario 3: Using Proxy ARP to Enable an ONS 15454 SDH Gateway a LAN device sends an ARP request to an ONS 15454 SDH that is not connected to the LAN, the gateway ONS 15454 SDH returns its MAC address to the LAN device. The LAN device then sends the datagram for the remote ONS 15454 SDH to the MAC address of the proxy ONS 15454 SDH. The proxy ONS 15454 SDH uses its routing table to forward the datagram to the non-LAN ONS 15454 SDH.
Chapter 13 Management Network Connectivity 13.2.4 Scenario 4: Default Gateway on CTC Computer • A node cannot be the proxy ARP server for a host connected to its Ethernet port. In Figure 13-4, ONS 15454 SDH #1 announces to ONS 15454 SDH #2 and #3 that it can reach the CTC host. Similarly, ONS 15454 SDH #3 announces that it can reach the ONS 152xx. The ONS 152xx is shown as an example; any network element can be set up as an additional host.
Chapter 13 Management Network Connectivity 13.2.5 Scenario 5: Using Static Routes to Connect to LANs Figure 13-5 Scenario 4: Default Gateway on a CTC Computer CTC Workstation IP Address 192.168.1.100 Subnet Mask at CTC Workstation 255.255.255.0 Default Gateway = 192.168.1.10 Host Routes = N/A LAN A ONS 15454 SDH #1 IP Address 192.168.1.10 Subnet Mask 255.255.255.0 Default Router = N/A Static Routes = N/A SDH RING ONS 15454 SDH #3 IP Address 192.168.3.30 Subnet Mask 255.255.255.
Chapter 13 Management Network Connectivity 13.2.5 Scenario 5: Using Static Routes to Connect to LANs Figure 13-6 Scenario 5: Static Route With One CTC Computer Used as a Destination Router IP Address of interface ”A” to LAN “A” 192.168.1.1 IP Address of interface “B” to LAN “B” 192.168.2.1 Subnet Mask 255.255.255.0 Static Routes: Destination = 192.168.0.0 Destination = 192.168.4.0 Mask = 255.255.255.0 Mask = 255.255.255.0 Next Hop = 192.168.5.1 Next Hop = 192.168.5.
Chapter 13 Management Network Connectivity 13.2.5 Scenario 5: Using Static Routes to Connect to LANs Figure 13-7 Scenario 5: Static Route With Multiple LAN Destinations LAN D Router #3: IP Address of the interface connected to LAN-C = 192.168.5.10 IP Address of the interface connected to LAN-D = 192.168.6.1 Subnet Mask = 255.255.255.0 Static Routes: Destination = 192.168.0.0 Destination = 192.168.4.0 Mask = 255.255.255.0 Mask = 255.255.255.0 Next Hop = 192.168.5.1 Next Hop = 192.168.5.
Chapter 13 Management Network Connectivity 13.2.6 Scenario 6: Using OSPF 13.2.6 Scenario 6: Using OSPF Open Shortest Path First (OSPF) is a link state Internet routing protocol. Link state protocols use a “hello protocol” to monitor their links with adjacent routers and to test the status of their links to their neighbors. Link state protocols advertise their directly connected networks and their active links.
Chapter 13 Management Network Connectivity 13.2.6 Scenario 6: Using OSPF Figure 13-8 Scenario 6: OSPF Enabled Router IP Address of interface “A” to LAN A 192.168.1.1 IP Address of interface “B” to LAN B 192.168.2.1 Subnet Mask 255.255.255.0 LAN A Int "A" CTC Workstation IP Address 192.168.1.100 Subnet Mask 255.255.255.0 Default Gateway = 192.168.1.1 Host Routes = N/A Int "B" LAN B ONS 15454 SDH #1 IP Address 192.168.2.10 Subnet Mask 255.255.255.0 Default Router = 192.168.2.
Chapter 13 Management Network Connectivity 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 13-9 Scenario 6: OSPF Not Enabled LAN A Int "A" CTC Workstation IP Address 192.168.1.100 Subnet Mask 255.255.255.0 Default Gateway = 192.168.1.1 Host Routes = N/A Router IP Address of interface “A” to LAN A 192.168.1.1 IP Address of interface “B” to LAN B 192.168.2.1 Subnet Mask 255.255.255.0 Static Routes = Destination 192.168.3.20 Next Hop 192.168.2.10 Destination 192.168.4.
Chapter 13 Management Network Connectivity 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server The ONS 15454 SDH proxy server performs the following tasks: • Isolates DCC IP traffic from Ethernet (craft port) traffic and accepts packets based on filtering rules. The filtering rules (see Table 13-3 on page 13-17 and Table 13-4 on page 13-18) depend on whether the packet arrives at the ONS 15454 SDH DCC or TCC2/TCC2P Ethernet interface.
Chapter 13 Management Network Connectivity 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 13-10 Proxy Server Gateway Settings Figure 13-11 shows an ONS 15454 SDH proxy server implementation. A GNE ONS 15454 SDH is connected to a central office LAN and to ENE ONS 15454 SDH nodes. The central office LAN is connected to a NOC LAN, which has CTC computers. The NOC CTC computer and craft technicians must be able to access the ONS 15454 SDH ENEs.
Chapter 13 Management Network Connectivity 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 13-11 Scenario 7: SDH Proxy Server with GNE and ENEs on the Same Subnet Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH GNE 10.10.10.100/24 ONS 15454 SDH ENE 10.10.10.150/24 ONS 15454 SDH ENE 10.10.10.250/24 ONS 15454 SDH ENE 10.10.10.200/24 SDH 78236 Ethernet Local/Craft CTC 192.168.20.
Chapter 13 Management Network Connectivity 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 13-12 Scenario 7: ONS 15454 SDH Proxy Server with GNE and ENEs on Different Subnets Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH GNE 10.10.10.100/24 ONS 15454 SDH ENE 192.168.10.150/24 ONS 15454 SDH ENE 192.168.10.250/24 ONS 15454 SDH ENE 192.168.10.200/24 SDH 78237 Ethernet Local/Craft CTC 192.168.20.
Chapter 13 Management Network Connectivity 13.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 13-13 Scenario 7: ONS 15454 SDH Proxy Server With ENEs on Multiple Rings Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH GNE 10.10.10.100/24 ONS 15454 SDH ENE 192.168.10.150/24 ONS 15454 SDH GNE 10.10.10.200/24 ONS 15454 SDH ENE 192.168.10.250/24 ONS 15454 SDH ENE 192.168.60.150/24 ONS 15454 SDH ENE 192.168.10.
Chapter 13 Management Network Connectivity 13.2.
Chapter 13 Management Network Connectivity 13.2.8 Scenario 8: Dual GNEs on a Subnet Figure 13-14 Scenario 8: Dual GNEs on the Same Subnet Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 ONS 15454 SDH 10.10.10.100/24 ONS 15454 SDH 10.10.10.150/24 ONS 15454 SDH 10.10.10.250/24 ONS 15454 SDH 10.10.10.200/24 Ethernet Local/Craft CTC 192.168.20.20 SDH 115275 10.10.10.0/24 Figure 13-15 shows a network with dual GNEs on different subnets.
Chapter 13 Management Network Connectivity 13.2.9 Scenario 9: IP Addressing with Secure Mode Enabled Figure 13-15 Scenario 8: Dual GNEs on Different Subnets Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/2 10.20.10.1 10.10.10.0/24 10.20.10.0/24 ONS 15454 SDH 10.20.10.100/24 ONS 15454 SDH 10.10.10.100/24 ONS 15454 SDH 192.168.10.200/24 ONS 15454 SDH 192.168.10.250/24 Ethernet Local/Craft CTC 192.168.20.20 SDH 115277 Interface 0/1 10.10.10.1 13.2.
Chapter 13 Management Network Connectivity 13.2.9 Scenario 9: IP Addressing with Secure Mode Enabled Figure 13-16 shows an example of ONS 15454 SDH nodes on the same subnet with secure mode enabled.In the example, TCC2P port addresses are on a different subnet from the node MIC-C/T/P IP addresses. Note Secure mode is not available if TCC2 cards are installed. If one TCC2 and one TCC2P card are installed, secure mode will appear in CTC but cannot be modified.
Chapter 13 Management Network Connectivity 13.3 Provisionable Patchcords Figure 13-17 Scenario 9: ONS 15454 SDH GNE and ENEs on Different Subnets with Secure Mode Enabled Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH Gateway NE MIC-C/T/P - 10.10.10.100/24 TCC2P - 176.20.20.40/24 ONS 15454 SDH External NE 192.168.10.150/24 - MIC-C/T/P 176.20.20.10/24 - TCC2P ONS 15454 SDH External NE MIC-C/T/P - 192.168.10.
Chapter 13 Management Network Connectivity 13.3 Provisionable Patchcords Table 13-5 Client-to-Trunk Card Combinations for Provisionable Patchcords Client Cards MXP_2.5G_10G/ TXP_MR_10G TXP(P)_MR_ MXP_2.5G_10E/ 2.5G TXP_MR_10E 32MUX-O 32DMX-O 32-WSS/ 32-DMX ADxC 4MD MXP_2.5G_10G/ TXP_MR_10G — — — Yes Yes Yes Yes TXPP_MR_2.5G — — — Yes Yes Yes Yes MXP_2.5G_10E/ TXP_MR_10E — — — Yes Yes Yes Yes MXPP_MR_2.
Chapter 13 Management Network Connectivity 13.4 Routing Table Optical ports have the following requirements when used in a provisionable patchcord: • An optical port connected to transponder/muxponder port or add/drop multiplexer or multiplexer/demultiplexer port requires an RS-DCC/MS-DCC termination. • If the optical port is the protection port in a 1+1 group, the working port must have an RS-DCC/MS-DCC termination provisioned.
Chapter 13 Management Network Connectivity 13.4 Routing Table Table 13-8 Sample Routing Table Entries (continued) Entry Destination Mask Gateway Interface 4 172.20.214.93 255.255.255.255 0.0.0.0 pdcc0 5 172.20.214.94 255.255.255.255 172.20.214.93 pdcc0 Entry 1 shows the following: • Destination (0.0.0.0) is the default route entry. All undefined destination network or host entries on this routing table are mapped to the default route entry. • Mask (0.0.0.
Chapter 13 Management Network Connectivity 13.5 External Firewalls 13.5 External Firewalls This section provides sample access control lists for external firewalls. Table 13-9 lists the ports that are used by the TCC2/TCC2P card.
Chapter 13 Management Network Connectivity 13.6 Open GNE access-list access-list access-list access-list access-list *** access-list access-list access-list access-list workstation access-list access-list access-list 100 100 100 100 100 permit remark remark permit remark 101 remark 101 remark 101 permit 101 remark (port 683) 100 remark 101 permit 101 remark tcp host 192.168.10.10 any host 10.10.10.100 eq www *** allows initial contact with ONS 15454 SDH using http (port 80) tcp host 192.168.10.
Chapter 13 Management Network Connectivity 13.6 Open GNE To configure an open GNE network, you can provision RS-DCC, MS-DCC, and GCC terminations to include a far-end, non-ONS node using either the default IP address of 0.0.0.0 or a specified IP address. You provision a far-end, non-ONS node by checking the “Far End is Foreign” check box during RS-DCC, MS-DCC, and GCC creation. The default 0.0.0.
Chapter 13 Management Network Connectivity 13.6 Open GNE Figure 13-18 Proxy and Firewall Tunnels for Foreign Terminations Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 ONS 15454 SDH Gateway NE 10.10.10.100/24 ONS 15454 SDH External NE 10.10.10.150/24 ONS 15454 SDH External NE 10.10.10.250/24 ONS 15454 SDH External NE 10.10.10.200/24 Non-ONS node Foreign NE 130.94.122.199/28 Ethernet Local/Craft CTC 192.168.20.20 SDH 115759 10.10.10.
Chapter 13 Management Network Connectivity 13.7 TCP/IP and OSI Networking Figure 13-19 Foreign Node Connection to an ENE Ethernet Port Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 ONS 15454 SDH Gateway NE 10.10.10.100/24 ONS 15454 SDH External NE 10.10.10.150/24 ONS 15454 SDH External NE 10.10.10.250/24 ONS 15454 SDH External NE 10.10.10.200/24 Non-ONS node Foreign NE 130.94.122.199/28 Ethernet Local/Craft CTC 192.168.20.20 SDH 115760 10.10.
Chapter 13 Management Network Connectivity 13.7.
Chapter 13 Management Network Connectivity 13.7.2 Link Access Protocol on the D Channel 13.7.2 Link Access Protocol on the D Channel LAP-D is a data link protocol used in the OSI protocol stack. LAP-D is assigned when you provision an ONS 15454 SDH RS-DCC as OSI-only.
Chapter 13 Management Network Connectivity 13.7.3 OSI Connectionless Network Service CLNP uses network service access points (NSAPs) to identify network devices. The CLNP source and destination addresses are NSAPs. In addition, CLNP uses a network element title (NET) to identify a network-entity in an end system (ES) or intermediate system (IS). NETs are allocated from the same name space as NSAP addresses. Whether an address is an NSAP address or a NET depends on the network selector value in the NSAP.
Chapter 13 Management Network Connectivity 13.7.3 OSI Connectionless Network Service Table 13-11 NSAP Fields (continued) Field Definition Description System System identifier The ONS 15454 SDH system identifier is set to its IEEE 802.3 MAC address. Each ONS 15454 SDH supports three OSI virtual routers. Each router NSAP system identifier is the ONS 15454 SDH IEEE 802.3 MAC address + n, where n = 0 to 2. For the primary virtual router, n = 0.
Chapter 13 Management Network Connectivity 13.7.4 OSI Routing The ONS 15454 SDH main NSAP address is shown on the node view Provisioning > OSI > Main Setup subtab. This address is also the Router 1 primary manual area address, which is viewed and edited on Provisioning > OSI > Routers subtab. See the “13.7.7 OSI Virtual Routers” section on page 13-41 for information about the OSI router and manual area addresses in CTC. 13.7.4 OSI Routing OSI architecture includes ESs and ISs.
Chapter 13 Management Network Connectivity 13.7.
Chapter 13 Management Network Connectivity 13.7.5 TARP route between Level 1 areas and form an intradomain routing backbone. Level 1 ISs need to know only how to get to the nearest Level 2 IS. The backbone routing protocol can change without impacting the intra-area routing protocol. OSI routing begins when the ESs discover the nearest IS by listening to ISH packets. When an ES wants to send a packet to another ES, it sends the packet to one of the ISs on its directly attached network.
Chapter 13 Management Network Connectivity 13.7.5 TARP Table 13-12 TARP PDU Fields (continued) Field Abbreviation Size (bytes) Description TID Target Length tar-tln 1 The number of octets in the tar-ttg field. TID Originator Length tar-oln 1 The number of octets in the tar-tor field. Protocol Address Length tar-pln 1 The number of octets in the tar-por field. TID of Target tar-ttg n = 0, 1, 2... TID value for the target NE. TID of Originator tar-tor n = 0, 1, 2...
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.
Chapter 13 Management Network Connectivity 13.7.6 TCP/IP and OSI Mediation and the tar-seq field in the LDB entry is updated with the new value. The Cisco ONS 15454 SDH LDB holds approximately 500 entries. The LDB is flushed periodically based on the time set in the LDB Flush timer on the node view OSI > TARP > Config tab. 13.7.5.
Chapter 13 Management Network Connectivity 13.7.7 OSI Virtual Routers Figure 13-23 T–TD Protocol Flow OSS GNE ENE TL1 TL1 Gateway TL1 Gateway ACSE ACSE Presentation Presentation Session Session TP4 TP4 TL1 UDP • TCP UDP TCP TL1 IPv4 ISIS / CLNS ISIS / CLNS LLC1 LAPD LAPD LAN LAN DCC DCC 131954 IPv4 LLC1 FT–TD—Performs an FTP conversion between FTAM and FTP.
Chapter 13 Management Network Connectivity 13.7.8 IP-over-CLNS Tunnels • FTAM • FT-TD • T-TD • LAN subnet OSI virtual router constraints depend on the routing mode provisioned for the node. Table 13-16 shows the number of IS L1s, IS L1/L2s, and DCCs that are supported by each router. An IS L1 and IS L1/L2 support one ES per DCC subnet and up to 100 ESs per LAN subnet.
Chapter 13 Management Network Connectivity 13.7.8 IP-over-CLNS Tunnels IP-over-CLNS Tunnel Flow NE-D NE-C NE-B NE-A (GNE) EMS SNMP RMON HTTP FTP Telnet SNMP RMON HTTP FTP Telnet UDP TCP UDP TCP IPv4 GRE Tunnel CLNP CLNP CLNP CLNP LLC1 LAPD LAPD LAPD LAN DCC DCC DCC GRE Tunnel IPv4 IPv4 LAPD LLC1 LLC1 DCC LAN LAN 131956 Figure 13-25 13.7.8.
Chapter 13 Management Network Connectivity 13.7.8 IP-over-CLNS Tunnels Table 13-17 IP-over-CLNS Tunnel IOS Commands Step Step Purpose 1 Router (config) # interface ctunnel interface-number Creates a virtual interface to transport IP over a CLNS tunnel and enters interface configuration mode. The interface number must be unique for each CTunnel interface. 2 Router (config-if # ctunnel destination remote-nsap-address Configures the destination parameter for the CTunnel.
Chapter 13 Management Network Connectivity 13.7.8 IP-over-CLNS Tunnels Figure 13-26 IP-over-CLNS Tunnel Scenario 1: ONS NE to Other Vender GNE CTC 1 10.10.10.100/24 Router 2 Interface 0/0: 10.10.10.10/24 Interface 0/1: 10.10.20.10/24 39.840F.80.111111.0000.1111.1111.aaaaaaaaaaaa.00 IP DCN Router 1 Interface 0/0: 10.10.20.20/24 Interface 0/1: 10.10.30.10/24 39.840F.80. 111111.0000.1111.1111.bbbbbbbbbbbb.00 IP/OSI Vendor GNE 10.10.30.20/24 39.840F.80. 111111.0000.1111.1111.cccccccccccc.
Chapter 13 Management Network Connectivity 13.7.8 IP-over-CLNS Tunnels CTunnel (IP-over-CLNS) provisioning on Router 1: ip routing clns routing interface ctunnel 102 ip address 10.10.30.30 255.255.255.0 ctunnel destination 39.840F.80.1111.0000.1111.1111.dddddddddddd.00 interface Ethernet0/1 clns router isis router isis net 39.840F.80.1111.0000.1111.1111.bbbbbbbbbbbb.00 Figure 13-27 IP-over-CLNS Tunnel Scenario 2: ONS Node to Router CTC 1 10.10.10.100/24 Router 2 Interface 0/0: 10.10.10.
Chapter 13 Management Network Connectivity 13.7.8 IP-over-CLNS Tunnels 13.7.8.4 IP-over-CLNS Tunnel Scenario 3: ONS Node to Router Across an OSI DCN Figure 13-28 shows an IP-over-CLNS tunnel from an ONS node to a router across an OSI DCN. The other vendor NE has an OSI connection to an IP DCN to which a CTC computer is attached. An OSI-only (LAP-D) RS-DCC is created between the ONS NE 1 and the other vender GNE.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-28 IP-over-CLNS Tunnel Scenario 3: ONS Node to Router Across an OSI DCN CTC 1 10.10.10.100/24 IP Router 2 Interface 0/0: 10.10.10.10/24 Interface 0/1: 10.10.20.10/24 39.840F.80.111111.0000.1111.1111.aaaaaaaaaaaa.00 OSI DCN Router 1 Interface 0/0: 10.10.20.20/24 Interface 0/1: 10.10.30.10/24 39.840F.80. 111111.0000.1111.1111.bbbbbbbbbbbb.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios • All ONS 15454 SDH NEs participating in an OSI network run OSI over PPP between themselves. This is needed so that other vendor GNEs can route TL1 commands to all ONS 15454 SDH NEs participating in the OSI network. 13.7.9.1 OSI/IP Scenario 1: IP OSS, IP DCN, ONS GNE, IP DCC, and ONS ENE Figure 13-29 shows OSI/IP Scenario 1, the current ONS 15454 SDH IP-based implementation, with an IP DCN, IP-over-PPP DCC, and OSPF routing.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-30 OSI/IP Scenario 2: IP OSS, IP DCN, ONS GNE, OSI DCC, and Other Vendor ENE 1 CTC/CTM IP OSS IP IP IP DCN IP ONS GNE 2 3 4 IP and OSI/PPP/DCC OSI/LAP-D/DCC IP/OSPF ONS NE OSI/IS-IS Other vendor NE 5 ONS NE OSI/LAP-D/DCC Other vendor NE 131932 IP and OSI/PPP/DCC 1 The IP OSS manages ONS 15454 SDH and other vendor NEs using TL1 and FTP.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios OSS-initiated software downloads consist of two parts: the OSS to destination NE TL1 download request and the file transfer. The TL1 request is handled the same as described in the previous paragraph. The ONS 15454 SDH NEs use FTP for file transfers. OSI-only NEs use FTAM to perform file transfers. The FTAM protocol is carried over OSI between the OSI NE and the ONS 15454 SDH GNE.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-31 OSI/IP Scenario 3: IP OSS, IP DCN, Other Vendor GNE, OSI DCC, and ONS ENE 1 CTC/CTM IP OSS IP IP IP DCN IP OSI 2 3 Other vendor GNE OSI/LAP-D/DCC OSI/LAPD/DCC 4 IP and OSI/PPP/DCC ONS NE 2 Other vendor NE OSI/LAP-D/DCC Other vendor NE 131933 ONS NE 1 1 The IP OSS manages the ONS 15454 SDH and other vendor NEs using TL1 and FTP.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-32 OSI/IP Scenario 3 with OSI/IP-over-CLNS Tunnel Endpoint at the GNE 1 CTC/CTM IP OSS IP IP IP DCN 2 IP Other vendor GNE 4 3 OSI/LAP-D/DCC OSI/LAPD/DCC 5 IP and OSI/PPP/DCC ONS NE 2 Other vendor NE OSI/LAP-D/DCC Other vendor NE 131931 ONS NE 1 1 The IP OSS manages ONS and other vendor NEs using TL1 and FTP.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-33 OSI/IP Scenario 4: Multiple ONS DCC Areas 1 CTC/CTM IP OSS IP IP IP DCN IP IP 2 2 OSI 2 Other vendor GNE OSI/ LAP-D/ DCC OSI/ LAP-D/ DCC OSI/ LAP-D/ DCC ONS NE ONS NE IP and OSI/PPP/DCC IP and OSI/PPP/DCC IP and OSI/PPP/DCC ONS NE ONS NE ONS NE 131934 ONS NE 1 The IP OSS manages ONS 15454 SDH and other vendor NEs using TL1 and FTP.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-34 OSI/IP Scenario 5: GNE Without an OSI DCC Connection 1 CTC/CTM IP OSS IP IP IP DCN IP IP 3 2 Other vendor GNE OSI/ LAP-D/ DCC ONS NE Other vendor NE IP and OSI/PPP/DCC OSI/LAP-D/DCC ONS NE Other vendor NE 131935 4 OSI/ LAP-D/ DCC 1 The IP OSS manages ONS 15454 SDH and other vendor NEs using TL1 and FTP. 2 The other vendor GNE performs mediation on TL1 and FTP, so DCCs are OSI-only.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-35 OSI/IP Scenario 6: IP OSS, OSI DCN, ONS GNE, OSI DCC, and Other Vendor ENE 1 CTC/CTM IP OSS IP IP OSI OSI OSI DCN 3 2 OSI IP 4 ONS GNE OSI/ LAP-D/ DCC IP and OSI/PPP/DCC ONS GNE Other vendor NE OSI/LAP-D/DCC Other vendor NE 131936 ONS GNE OSI/ LAP-D/ DCC 1 The IP OSS manages ONS 15454 SDH and other vendor NEs using TL1 and FTP.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-36 OSI/IP Scenario 7: OSI OSS, OSI DCN, Other Vender GNE, OSI DCC, and ONS NEs 1 2 CTC/CTM IP OSS IP OSI OSI OSI DCN OSI 3 Other vendor GNE OSI/ LAP-D/ DCC ONS NE 1 Other vendor NE 1 IP and OSI/PPP/DCC ONS NE 2 OSI/ LAP-D/ DCC OSI/LAP-D/DCC Other vendor NE 2 IP and OSI/PPP/DCC 131937 ONS NE 3 1 ONS 15454 SDH NEs are managed by CTC/CTM only (TL1/FTP is not used).
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios • TL1 management is not required. • FTP file transfer is not required. • TL1 and FTAM to FTP mediation is not required. Management traffic between CTC/CTM and ONS 15454 SDH NEs is carried over an IP-over-CLNS tunnel. A static route is configured on the ONS 15454 SDH that terminates the tunnel (ONS 15454 SDH NE 1) so that downstream ONS 15454 SDH NEs (ONS 15454 SDH NE 2 and 3) know how to reach CTC/CTM. 13.7.9.
Chapter 13 Management Network Connectivity 13.7.9 OSI/IP Networking Scenarios Figure 13-37 OSI/IP Scenario 8: OSI OSS, OSI DCN, ONS GNE, OSI DCC, and Other Vender NEs 1 2 CTC/CTM IP OSS IP OSI OSI OSI DCN 3 OSI ONS GNE 4 IP and OSI/LAP-D/ DCC ONS NE 1 IP and OSI/PPP/DCC ONS NE 2 OSI/ LAP-D/ DCC Other vendor NE 1 OSI/LAP-D/DCC Other vendor NE 2 Other vendor NE 3 131938 OSI/PPP/DCC 1 The ONS NEs are managed by CTC/CTM only (TL1/FTP is not used).
Chapter 13 Management Network Connectivity 13.7.10 Provisioning OSI in CTC 13.7.10 Provisioning OSI in CTC Table 13-18 shows the OSI actions that are performed from the node view Provisioning tab. Refer to the Cisco ONS 15454 SDH Procedure Guide for OSI procedures and tasks. Table 13-18 OSI Actions from the CTC Provisioning Tab Tab Actions OSI > Main Setup OSI > TARP > Config • View and edit Primary Area Address. • Change OSI routing mode. • Change LSP buffers.
C H A P T E R 14 Alarm Monitoring and Management This chapter explains how to manage alarms with Cisco Transport Controller (CTC). To troubleshoot specific alarms, refer to the Cisco ONS 15454 SDH Troubleshooting Guide. Chapter topics include: • 14.1 Overview, page 14-1 • 14.2 LCD Alarm Counts, page 14-1 • 14.3 Alarm Information, page 14-2 • 14.4 Alarm Severities, page 14-10 • 14.5 Alarm Profiles, page 14-10 • 14.6 Alarm Suppression, page 14-14 • 14.
Chapter 14 Alarm Monitoring and Management 14.3 Alarm Information The ONS 15454 SDH has a one-button update for some commonly viewed alarm counts. If you press the Slot button once and then wait eight seconds, the display automatically changes from a slot alarm count to a slot alarm summary. If you press the Port button to toggle to port-level display, you can use the Port button to toggle to a specific slot and to view each port’s port-level alarm count. Figure 14-1 shows the LCD panel layout.
Chapter 14 Alarm Monitoring and Management 14.3 Alarm Information Table 14-1 Note Alarms Column Descriptions (continued) Column Information Recorded Path Width Indicates how many VC-4s are contained in an alarmed path. (For any non-VC-4 object, such as a VC-3, the column is blank.) This information complements the alarm object notation, which is explained in Table 14-3. Sev Severity level: CR (Critical), MJ (Major), MN (Minor), NA (Not Alarmed), NR (Not Reported).
Chapter 14 Alarm Monitoring and Management 14.3.1 Viewing Alarms With Each Node’s Time Zone Note Major and Minor alarms may appear yellow in CTC under certain circumstances. This is not due to a CTC problem but to a workstation memory and color utilization problem. For example, a workstation might run out of colors if many color-intensive applications are running.
Chapter 14 Alarm Monitoring and Management 14.3.3 Filtering Alarms Table 14-4 Alarm Display (continued) Button/Check Box/Tool Action AutoDelete Cleared Alarms check box If checked, CTC automatically deletes cleared alarms. Filter tool Enables or disables alarm filtering in the card, node, or network view. When enabled or disabled, this state applies to other views for that node and for all other nodes in the network.
Chapter 14 Alarm Monitoring and Management 14.3.5 Conditions Tab Figure 14-2 Select Affected Circuits Option When the user selects the Select Affected Circuits option, the Circuits window opens to show the circuits that are affected by the alarm. 14.3.5 Conditions Tab The Conditions window displays retrieved fault conditions. A condition is a fault or status detected by ONS 15454 SDH hardware or software.
Chapter 14 Alarm Monitoring and Management 14.3.6 Controlling the Conditions Display Table 14-5 Conditions Display Button Action Retrieve Retrieves the current set of all existing fault conditions, as maintained by the alarm manager, from the ONS 15454 SDH. Filter Allows you to change the Conditions window display to only show the conditions that meet a certain severity level or occur in a specified time. For example, you can set the filter so that only Critical conditions display on the window.
Chapter 14 Alarm Monitoring and Management 14.3.7 Viewing History Table 14-6 Column Sev 1 Conditions Column Description (continued) Information Recorded Severity level: CR (Critical), MJ (Major), MN (Minor), NA (Not Alarmed), NR (Not Reported). SA1 Indicates a service-affecting alarm (when checked). Cond The error message/alarm name; these names are alphabetically defined in the “Alarm Troubleshooting” chapter of the Cisco ONS 15454 SDH Troubleshooting Guide.
Chapter 14 Alarm Monitoring and Management 14.3.7 Viewing History If you check the History window Alarms check box, you display the node history of alarms. If you check the Events check box, you display the node history of Not Alarmed and transient events (conditions). If you check both check boxes, you retrieve node history for both. 14.3.7.1 History Column Descriptions Table 14-7 lists the History window column headings and the information recorded in each column.
Chapter 14 Alarm Monitoring and Management 14.3.8 Alarm History and Log Buffer Capacities on the card in the History > Card window, or a history of alarms, conditions, and transients that have occurred during your login session in the History > Session window. You can also filter the severities and occurrence period in these history windows. 14.3.8 Alarm History and Log Buffer Capacities The ONS 15454 SDH alarm history log, stored in the TCC2/TCC2P RSA memory, contains four categories of alarms.
Chapter 14 Alarm Monitoring and Management 14.5.1 Creating and Modifying Alarm Profiles CTC can store up to ten active alarm profiles at any time to apply to the node. Custom profiles can take eight of these active profile positions. Two other profiles, Default profile and Inherited profile, are reserved by the NE, and cannot be edited.The reserved Default profile contains ITU-T G.733 severities.
Chapter 14 Alarm Monitoring and Management 14.5.2 Alarm Profile Buttons 14.5.2 Alarm Profile Buttons The Alarm Profiles window displays six buttons at the bottom. Table 14-8 lists and describes each of the alarm profile buttons and their functions. Table 14-8 Alarm Profile Buttons Button Description New Adds a new alarm profile. Load Loads a profile to a node or a file. Store Saves profiles on a node (or nodes) or in a file. Delete Deletes profiles from a node.
Chapter 14 Alarm Monitoring and Management 14.5.5 Row Display Options • Use Default • Transient (T) Transient and Use Default severity alarms only appear in alarm profiles. They do not appear when you view alarms, history, or conditions. 14.5.
Chapter 14 Alarm Monitoring and Management 14.6 Alarm Suppression Figure 14-3 Alarm Profile for an STM-1 Card 14.6 Alarm Suppression The following sections explain alarm suppression features for the ONS 15454 SDH. 14.6.1 Alarms Suppressed for Maintenance When you place a port in Locked,maintenance administrative state, this raises the alarm suppressed for maintenance (AS-MT) alarm in the Conditions and History windows1 and causes subsequently raised alarms for that port to be suppressed.
Chapter 14 Alarm Monitoring and Management 14.6.2 Alarms Suppressed by User Command 14.6.2 Alarms Suppressed by User Command In the Provisioning > Alarm Profiles > Alarm Behavior tabs, the ONS 15454 SDH has an alarm suppression option that clears raised alarm messages for the node, chassis, one or more slots (cards), or one or more ports. Using this option raises the alarms suppressed by user command, or AS-CMD alarm. The AS-CMD alarm, like the AS-MT alarm, appears in the Conditions, and History1 windows.
Chapter 14 Alarm Monitoring and Management 14.7.2 External Control Output Note When you provision an external alarm, the alarm object is ENV-IN-nn. The variable nn refers to the external alarm’s number, regardless of the name you assign. 14.7.2 External Control Output You can provision each alarm output separately. Provisionable characteristics of alarm outputs include: • Control type • Trigger type (alarm or virtual wire) • Description for CTC display • Closure setting (manually or by trigger).
C H A P T E R 15 Performance Monitoring Performance monitoring (PM) parameters are used by service providers to gather, store, set thresholds, and report performance data for early detection of problems. In this chapter, PM parameters and concepts are defined for electrical cards, Ethernet cards, and optical cards in the Cisco ONS 15454 SDH. For information about enabling and viewing PM values, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 15.
Chapter 15 Performance Monitoring 15.1 Threshold Performance Monitoring During the accumulation cycle, if the current value of a performance monitoring parameter reaches or exceeds its corresponding threshold value, a threshold crossing alert (TCA) is generated by the node and displayed by CTC. TCAs provide early detection of performance degradation. When a threshold is crossed, the node continues to count the errors during a given accumulation period.
Chapter 15 Performance Monitoring 15.2 Intermediate-Path Performance Monitoring Note Due to limitations of memory and the number of TCAs generated by different platforms, you can manually add or modify the following two properties to their property file (CTC.INI for Windows and .ctcrc for UNIX) to fit the need: ctc.15xxx.node.tr.lowater=yyy (where xxx is the platform and yyy is the number of the lowater mark. The default lowater mark is 25.) ctc.15xxx.node.tr.
Chapter 15 Performance Monitoring 15.3 Pointer Justification Count Performance Monitoring Note The E1 card and STM-1 card can monitor far-end IPPM. For all other cards listed in Table 15-2, far-end IPPM is not supported. However, SDH path PM parameters can be monitored by logging into the far-end node directly. The ONS 15454 SDH performs IPPM by examining the overhead in the monitored path and by reading all of the near-end path PM values in the incoming direction of transmission.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters Parameter Definition AISS-P AIS Seconds Path (AISS-P) is a count of one-second intervals containing one or more alarm indication signal (AIS) defects. BBE Path Background Block Error (BBE) is an errored block not occurring as part of a severely errored second (SES).
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition ESCP-P Errored Second Path (ESCP-P) is a count of seconds containing one or more CP-bit parity errors, one or more severely errored framing (SEF) defects, or one or more AIS defects. ESCP-P is defined for the C-bit parity application.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition HP-NPJC-Pdet High-Order Path Negative Pointer Justification Count, Path Detected (HP-NPJC-Pdet) is a count of the negative pointer justifications detected on a particular path on an incoming SDH signal.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition LOSS-L Line Loss of Signal Seconds (LOSS-L) is a count of one-second intervals containing one or more LOS defects. LP-BBE Low-Order Path Background Block Error (LP-BBE) is an errored block not occurring as part of an SES.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition MS-PSC (1+1 protection) In a 1+1 protection scheme for a working card, Multiplex Section Protection Switching Count (MS-PSC) is a count of the number of times service switches from a working card to a protection card plus the number of times service switches back to the working card.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition MS-PSD-R In a four-fiber MS-SPRing, Multiplex Section Protection Switching Duration-Ring (MS-PSD-R) is a count of the seconds that the protection line was used to carry service. A count is only incremented if ring switching is used.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition RS-EB Regenerator Section Errored Block (RS-EB) indicates that one or more bits are in error within a block. RS-ES Regenerator Section Errored Second (RS-ES) is a one-second period with one or more errored blocks or at least one defect.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition SASCP-P SEF/AIS Second (SASCP-P) is a count of one-second intervals containing one or more near-end SEF/AIS defects. SASP-P SEF/AIS Seconds Path (SASP-P) is a count of one-second intervals containing one or more SEFs or one or more AIS defects on the path.
Chapter 15 Performance Monitoring 15.4 Performance Monitoring Parameter Definitions Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition Tx SES-P Transmit Path Severely Errored Seconds (SES-P) is a one-second period containing 30 percent or more errored blocks or at least one defect; SES is a subset of ES. Tx SESR-P Transmit Path Severely Errored Second Ratio (SESR-P) is the ratio of SES to total seconds in available time during a fixed measurement interval.
Chapter 15 Performance Monitoring 15.5 Performance Monitoring for Electrical Cards Table 15-3 Performance Monitoring Parameters (continued) Parameter Definition UASP-P Unavailable Second Path (UASP-P) is a count of one-second intervals when the DS-3 path is unavailable. A DS3 path becomes unavailable when ten consecutive SESP-Ps occur. The ten SESP-Ps are included in unavailable time. After the DS-3 path becomes unavailable, it becomes available when ten consecutive seconds with no SESP-Ps occur.
Chapter 15 Performance Monitoring 15.5.1 E1-N-14 Card and E1-42 Card Performance Monitoring Parameters Note The E1-42 card uses the same PM read points. The only difference from Figure 15-3 is that the number of ports on the E1-42 equal 42.
Chapter 15 Performance Monitoring 15.5.2 E3-12 Card Performance Monitoring Parameters 15.5.2 E3-12 Card Performance Monitoring Parameters Figure 15-4 shows the signal types that support near-end and far-end PM parameters for the E3-12 card. Figure 15-5 shows where overhead bytes detected on the ASICs produce performance monitoring parameters for the E3-12 card.
Chapter 15 Performance Monitoring 15.5.3 DS3i-N-12 Card Performance Monitoring Parameters Table 15-5 PM Parameters for the E3-12 Card Line (NE) Path (NE) VC3 Low-End Path (NE/FE) VC4 HP Path (NE/FE) CV-L ES-L SES-L LOSS-L ES-P ESR-P SES-P SESR-P UAS-P LP-BBE LP-BBER LP-EB LP-ES LP-ESR LP-SES LP-SESR LP-UAS HP-BBE HP-BBER HP-EB HP-ES HP-ESR HP-SES HP-SESR HP-UAS 15.5.
Chapter 15 Performance Monitoring 15.5.
Chapter 15 Performance Monitoring 15.6 Performance Monitoring for Ethernet Cards 15.6 Performance Monitoring for Ethernet Cards The following sections define performance monitoring parameters and definitions for the E-Series, G-Series, and ML-Series Ethernet cards. 15.6.1 E-Series Ethernet Card Performance Monitoring Parameters CTC provides Ethernet performance information, including line-level parameters, port bandwidth consumption, and historical Ethernet statistics.
Chapter 15 Performance Monitoring 15.6.1 E-Series Ethernet Card Performance Monitoring Parameters Table 15-7 E-Series Ethernet Statistics Parameters (continued) Parameter Meaning Tx Excessive Collisions Number of consecutive collisions. Tx Deferred Number of packets deferred. 15.6.1.2 E-Series Ethernet Utilization Window The Utilization window shows the percentage of transmit (Tx) and receive (Rx) line bandwidth used by the Ethernet ports during consecutive time segments.
Chapter 15 Performance Monitoring 15.6.2 G-Series Ethernet Card Performance Monitoring Parameters Table 15-9 Ethernet Statistics History per Time Interval Time Interval Number of Intervals Displayed 1 minute 60 previous time intervals 15 minutes 32 previous time intervals 1 hour 24 previous time intervals 1 day (24 hours) 7 previous time intervals 15.6.
Chapter 15 Performance Monitoring 15.6.2 G-Series Ethernet Card Performance Monitoring Parameters Table 15-10 G-Series Ethernet Statistics Parameters (continued) Parameter Meaning Rx Giants Number of packets received that are greater than 1530 bytes in length. Rx Pause Frames Number of received Ethernet IEEE 802.3z pause frames. Tx Pause Frames Number of transmitted IEEE 802.3z pause frames.
Chapter 15 Performance Monitoring 15.6.3 ML-Series Ethernet Card Performance Monitoring Parameters Note Unlike E-Series cards, G-Series cards do not have a display of Trunk Utilization statistics, because G-Series cards are not Layer 2 devices. 15.6.2.3 G-Series Ethernet History Window The Ethernet History window lists past Ethernet statistics for the previous time intervals.
Chapter 15 Performance Monitoring 15.6.3 ML-Series Ethernet Card Performance Monitoring Parameters Table 15-11 ML-Series Ether Ports PM Parameters (continued) Parameter Meaning ifOutUcast Pkts Indicates the number of unicast packets transmitted. ifOutMulticast Pkts Indicates the number of multicast packets transmitted. ifOutBroadcast Pkts Indicates the number or broadcast packets transmitted.
Chapter 15 Performance Monitoring 15.6.3 ML-Series Ethernet Card Performance Monitoring Parameters Table 15-12 ML-Series POS Ports Parameters for HDLC Mode Parameter Meaning ifInOctets Indicates the number of bytes received since the last counter reset. rxTotalPkts Indicates the number of packets received. ifOutOctets Indicates the number of bytes transmitted since the last counter reset. tx TotalPkts Indicates the number of transmitted packets.
Chapter 15 Performance Monitoring 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters Table 15-13 ML-Series POS Ports Parameters for GFP-F Mode (continued) Parameter Meaning gfpStatsRxTypeInvalid Indicates the number of receive packets dropped due to Client Data Frame user payload identifier (UPI) error. gfpStatsRxCRCErrors Indicates the number of packets received with a payload FCS error. gfpStatsLFDRaised Indicates the count of core HEC CRC multiple bit errors.
Chapter 15 Performance Monitoring 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters Table 15-14 CE-Series Ether Ports PM Parameters Parameter Meaning Time Last Cleared Specifies a time stamp indicating the last time statistics were reset. Link Status Indicates whether the Ethernet link is receiving a valid Ethernet signal (carrier) from the attached Ethernet device. Up denotes present, and Down denotes not present.
Chapter 15 Performance Monitoring 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters Table 15-14 CE-Series Ether Ports PM Parameters (continued) Parameter Meaning dot3StatsFrameTooLong Indicates the count of frames received on a particular interface that exceed the maximum permitted frame size. etherStatsUndersizePkts Indicates the total number of packets received that were less than 64 octets long (excluding framing bits, but including FCS octets) and were otherwise well formed.
Chapter 15 Performance Monitoring 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters Table 15-14 CE-Series Ether Ports PM Parameters (continued) Parameter Meaning etherStatsJabbers Indicates the total number of packets received that were longer than 1518 octets (excluding framing bits, but including FCS octets), and had either a bad FCS with an integral number of octets (FCS error) or a bad FCS with a nonintegral number of octets (alignment error).
Chapter 15 Performance Monitoring 15.6.4 CE-Series Ethernet Card Performance Monitoring Parameters 15.6.4.2 CE-Series Card Ether Ports Utilization Parameters The Ether Ports Utilization window shows the percentage of Tx and Rx line bandwidth used by the Ethernet ports during consecutive time segments. The Utilization window provides an Interval menu that enables you to set time intervals of 1 minute, 15 minutes, 1 hour, and 1 day.
Chapter 15 Performance Monitoring 15.7 Performance Monitoring for Optical Cards Table 15-15 CE-Series POS Ports Statistics Parameters Parameter gfpStatsTxOctets Definition 2 Number of GFP bytes transmitted. gfpStatsRxSBitErrors Sum of all the single bit errors. In the GFP CORE HDR at the GFP-T receiver, these are correctable. gfpStatsRxMBitErrors Sum of all the multiple bit errors. In the GFP CORE HDR at the GFP-T receiver, these are uncorrectable.
Chapter 15 Performance Monitoring 15.7.1 STM-1 Card Performance Monitoring Parameters 100 GHz card, the OC192 SR/STM64 IO 1310 card, the OC192 IR/STM64 SH 1550 card, OC192 LR/STM 64 LH 1550 card, the OC192 LR/STM64 LH ITU 15xx.xx, OC192 SR1/STM64IO Short Reach card, and the OC192/STM64 Any Reach card. On all STM-N optical cards, errors are calculated in bits instead of blocks for B1 and B3. This means there could possibly be a slight difference between what is inserted and what is reported on CTC.
Chapter 15 Performance Monitoring 15.7.1 STM-1 Card Performance Monitoring Parameters Table 15-16 PM Parameters for the STM-1 and STM1 SH 1310-8 Cards RS (NE) MS (NE/FE) 1+1 LMSP (NE)1, 2 PJC (NE)3 VC4 and VC4-Xc HP Path (NE/FE4)5 RS-BBE RS-EB RS-ES RS-SES MS-BBE MS-EB MS-ES MS-SES MS-UAS MS-PSC (1+1) MS-PSD HP-PPJC-Pdet HP-NPJC-Pdet HP-PPJC-Pgen HP-NPJC-Pgen HP-PJCS-Pdet HP-PJCS-Pgen HP-PJCDiff HP-BBE HP-BBER HP-EB HP-ES HP-ESR HP-SES HP-SESR HP-UAS 1.
Chapter 15 Performance Monitoring 15.7.2 STM-1E Card Performance Monitoring Parameters 15.7.2 STM-1E Card Performance Monitoring Parameters Figure 15-9 shows where overhead bytes detected on the ASICs produce performance monitoring parameters for the STM-1E card.
Chapter 15 Performance Monitoring 15.7.2 STM-1E Card Performance Monitoring Parameters Figure 15-10 PM Read Points on the STM-1E Cards in E4 Mode ONS 15454 SDH STM-1E Card in E4 Mode Cross-Connect Card STM-1E Pointer Processors OCEAN ASIC ES ESR SES SESR BBE BBER UAS EB Path Level in E4 Mode 110403 PMs read on OCEAN ASIC The PM parameters for the STM-1E cards are listed in Table 15-17. The parameters are defined in Table 15-3 on page 15-5.
Chapter 15 Performance Monitoring 15.7.3 STM-4 Card Performance Monitoring Parameters 15.7.3 STM-4 Card Performance Monitoring Parameters Figure 15-11 shows the signal types that support near-end and far-end PM parameters for the OC12 IR/STM4 SH 1310, OC12 LR/STM4 LH 1310 card, the OC12 LR/STM4 LH 1550 card, and the OC12 IR/STM4 SH 1310-4 card.
Chapter 15 Performance Monitoring 15.7.4 STM-16 and STM-64 Card Performance Monitoring Parameters Table 15-18 PM Parameters for STM-4 Cards RS (NE/FE) MS (NE/FE) PSC (NE)1 RS-BBE RS-EB RS-ES RS-SES MS-BBE MS-EB MS-ES MS-SES MS-UAS MS-PSC (1+1) MS-PSC (MS-SPRing) MS-PSD MS-PSC-W MS-PSD-W MS-PSC-S MS-PSD-S MS-PSC-R MS-PSD-R PJC (NE)2 VC4 and VC4-Xc HP Path (NE)3 HP-PPJC-Pdet HP-NPJC-Pdet HP-PPJC-Pgen HP-NPJC-Pgen HP-BBE HP-BBER HP-EB HP-ES HP-ESR HP-SES HP-SESR HP-UAS 1.
Chapter 15 Performance Monitoring 15.7.4 STM-16 and STM-64 Card Performance Monitoring Parameters Figure 15-14 PM Read Points on STM-16 and STM-64 Cards ONS 15454 SDH STM-16 and STM-64 Cards BTC ASIC Cross-Connect Card E1 RS-EB RS-BBE RS-ES RS-SES MS-EB MS-BBE MS-ES MS-SES MS-UAS HP-PPJC-Pdet HP-NPJC-Pdet HP-PPJC-Pgen HP-NPJC-Pgen Note: The STM-16 and STM-64 have 1 port per card.
Chapter 15 Performance Monitoring 15.7.5 MRC-12 Card Performance Monitoring Parameters Note If the MS-EB(NE and FE) falls in a specific range, then, the user might see discrepancy in the MS-SES and the MS-UAS values. However, MS-ES will be in the nearest accuracy.
Chapter 15 Performance Monitoring 15.8 Performance Monitoring for the Fiber Channel Card Figure 15-15 PM Read Points for the MRC-12 Card ONS 15454 SDH XC Card MRC-12/MRC-2.
Chapter 15 Performance Monitoring 15.8.1 FC_MR-4 Card Performance Monitoring Parameters 15.8.1.1 FC_MR-4 Statistics Window The Statistics window lists parameters at the line level. The Statistics window provides buttons to change the statistical values shown. The Baseline button resets the displayed statistics values to zero. The Refresh button manually refreshes statistics. Auto-Refresh sets a time interval at which automatic refresh occurs. The Statistics window also has a Clear button.
Chapter 15 Performance Monitoring 15.8.1 FC_MR-4 Card Performance Monitoring Parameters Parameter Definition mediaIndStatsRxFramesTooLong Number of Fibre Channel frames received with frame size higher than the provisioned maximum frame size. mediaIndStatsRxFramesBadCRC Number of Fibre Channel frames received with bad CRC. mediaIndStatsTxFramesBadCRC Number of Fibre Channel frames transmitted with bad CRC. fcStatsLinkRecoveries Number of link recoveries.
Chapter 15 Performance Monitoring 15.8.1 FC_MR-4 Card Performance Monitoring Parameters Table 15-23 FC_MR-4 History Statistics per Time Interval Time Interval Number of Intervals Displayed 1 minute 60 previous time intervals 15 minutes 32 previous time intervals 1 hour 24 previous time intervals 1 day (24 hours) 7 previous time intervals Cisco ONS 15454 SDH Reference Manual, R7.
Chapter 15 Performance Monitoring 15.8.1 FC_MR-4 Card Performance Monitoring Parameters Cisco ONS 15454 SDH Reference Manual, R7.
C H A P T E R 16 SNMP This chapter explains Simple Network Management Protocol (SNMP) as implemented by the Cisco ONS 15454 SDH. For SNMP setup information, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 16.1 SNMP Overview, page 16-1 • 16.2 Basic SNMP Components, page 16-2 • 16.3 SNMP External Interface Requirement, page 16-4 • 16.4 SNMP Version Support, page 16-4 • 16.5 SNMP Message Types, page 16-4 • 16.6 SNMP Management Information Bases, page 16-5 • 16.
Chapter 16 SNMP 16.2 Basic SNMP Components Note The CERENT-MSDWDM-MIB.mib, CERENT-FC-MIB.mib, and CERENT-GENERIC-PM-MIB.mib in the CiscoV2 directory support 64-bit performance monitoring counters. The SNMPv1 MIB in the CiscoV1 directory does not contain 64-bit performance monitoring counters, but supports the lower and higher word values of the corresponding 64-bit counter. The other MIB files in the CiscoV1 and CiscoV2 directories are identical in content and differ only in format.
Chapter 16 SNMP 16.2 Basic SNMP Components Figure 16-2 Example of the Primary SNMP Components Management Entity NMS Agent Agent Management Database Management Database Management Database 33930 Agent Managed Devices An agent (such as SNMP) residing on each managed device translates local management information data, such as performance information or event and error information caught in software traps, into a readable form for the management system.
Chapter 16 SNMP 16.3 SNMP External Interface Requirement 16.3 SNMP External Interface Requirement Since all SNMP requests come from a third-party application, the only external interface requirement is that a third-party SNMP client application can upload RFC 3273 SNMP MIB variables in the etherStatsHighCapacityTable, etherHistoryHighCapacityTable, or mediaIndependentTable. 16.4 SNMP Version Support The ONS 15454 SDH supports SNMPv1 and SNMPv2c traps and get requests.
Chapter 16 SNMP 16.6 SNMP Management Information Bases 16.6 SNMP Management Information Bases Section 16.6.1 lists IETF-standard MIBs that are implemented in the ONS 15454 SDH and shows their compilation order. Section 16.6.2 lists proprietary MIBs for the ONS 15454 SDH and shows their compilation order. Section 16.6.3 contains information about the generic threshold and performance monitoring MIBs that can be used to monitor any network element (NE) contained in the network. 16.6.
Chapter 16 SNMP 16.6.2 Proprietary ONS 15454 SDH MIBS Table 16-2 IETF Standard MIBs Implemented in the ONS 15454 SDH System (continued) RFC1 Number Module Name Title/Comments 2674 P-BRIDGE-MIB-rfc2674.mib Q-BRIDGE-MIB-rfc2674.
Chapter 16 SNMP 16.6.3 Generic Threshold and Performance Monitoring MIBs 16.6.3 Generic Threshold and Performance Monitoring MIBs In Release 7.0, a MIB called CERENT-GENERIC-PM-MIB allows network management stations (NMS) to use a single, generic MIB for accessing threshold and performance monitoring data of different interface types. The MIB is generic in the sense that it is not tied to any particular kind of interface.
Chapter 16 SNMP 16.7 SNMP Trap Content The cerentGenericPmStatsCurrentTable validates the current PM value using the cerentGenericPmStatsCurrentValid object and registers the number of valid intervals with historical PM statistics in the cerentGenericPmStatsCurrentValidIntervals object. PM values are provided in 64-bit and 32-bit formats. The 64-bit values in cerentGenericPmStatsCurrentHCValue can be used with agents that support SNMPv2.
Chapter 16 SNMP 16.7.1 Generic and IETF Traps • Object IDs that uniquely identify each event with information about the generating entity (the slot or port; synchronous transport signal [STS] and Virtual Tributary [VT]; bidirectional line switched ring [BLSR], Spanning Tree Protocol [STP], etc.). • Severity and service effect of the alarm (critical, major, minor, or event; service-affecting or non-service affecting). • Date and time stamp showing when the alarm occurred. 16.7.
Chapter 16 SNMP 16.7.2 Variable Trap Bindings 16.7.2 Variable Trap Bindings Each SNMP trap contains variable bindings that are used to create the MIB tables. ONS 15454 SDH traps and variable bindings are listed in Table 16-8. For each group (such as Group A), all traps within the group are associated with all of its variable bindings.
Chapter 16 SNMP 16.7.2 Variable Trap Bindings Table 16-8 Group ONS 15454 SDH SNMPv2 Trap Variable Bindings (continued) Variable Trap Name(s) Associated Binding with Number SNMPv2 Variable Bindings Description (4) cerent454AlarmState The alarm severity and service-affecting status. Severities are Minor, Major, and Critical. Service-affecting statuses are Service-Affecting and Non-Service Affecting. (5) snmpTrapAddress The address of the SNMP trap.
Chapter 16 SNMP 16.7.2 Variable Trap Bindings Table 16-8 Group D1 (cont.) D2 ONS 15454 SDH SNMPv2 Trap Variable Bindings (continued) Variable Trap Name(s) Associated Binding with Number SNMPv2 Variable Bindings Description (5) alarmRisingThreshold When the current sampled value is greater than or equal to this threshold, and the value at the last sampling interval was less than this threshold, a single event is generated.
Chapter 16 SNMP 16.7.2 Variable Trap Bindings Table 16-8 Group ONS 15454 SDH SNMPv2 Trap Variable Bindings (continued) Variable Trap Name(s) Associated Binding with Number D2 (cont.) E failureDetectedExternal ToTheNE (from CERENT-454-mib) SNMPv2 Variable Bindings Description (7) cerent454AlarmState The alarm severity and service-affecting status. Severities are Minor, Major, and Critical. Service-affecting statuses are Service-Affecting and Non-Service Affecting.
Chapter 16 SNMP 16.7.2 Variable Trap Bindings Table 16-8 Group E (cont.) F ONS 15454 SDH SNMPv2 Trap Variable Bindings (continued) Variable Trap Name(s) Associated Binding with Number SNMPv2 Variable Bindings Description (9) cerent454AlarmAdditionalInfo Additional information for the alarm object. In the current version of the MIB, this object contains provisioned description for alarms that are external to the NE. If there is no additional information, the value is zero.
Chapter 16 SNMP 16.7.2 Variable Trap Bindings Table 16-8 Group ONS 15454 SDH SNMPv2 Trap Variable Bindings (continued) Variable Trap Name(s) Associated Binding with Number F (cont.) G All other traps (from CERENT-454-MIB) not listed above SNMPv2 Variable Bindings Description (10) cerent454ThresholdLocation Indicates whether the event occurred at the near- or far end. (11) cerent454ThresholdPeriod Indicates the sampling interval period.
Chapter 16 SNMP 16.8 SNMP Community Names Table 16-8 Group G (cont.) ONS 15454 SDH SNMPv2 Trap Variable Bindings (continued) Variable Trap Name(s) Associated Binding with Number SNMPv2 Variable Bindings Description (8) cerent454AlarmObjectName The TL1-style user-visible name that uniquely identifies an object in the system. (9) snmpTrapAddress The address of the SNMP trap. 16.8 SNMP Community Names Community names are used to group SNMP trap destinations.
Chapter 16 SNMP 16.10.1 64-Bit RMON Monitoring over DCC Certain statistics measured on the ML card are mapped to standard MIB if one exists else mapped to a non standard MIB variable. The naming convention used by the standarad/non-standard MIB is not the same as the statistics variable used by the card. Hence when these statistics are obtained via get-reques/get-next-request/SNMP Trap they don’t match the name used on the card or as seen by CTC/TL1.
Chapter 16 SNMP 16.10.2 HC-RMON-MIB Support 16.10.1.2 Row Creation in cMediaIndependentHistoryControlTable SNMP row creation and deletion for the cMediaIndependentHistoryControlTable follows the same processes as for the MediaIndependentTable; only the variables differ.
Chapter 16 SNMP 16.10.4 History Control RMON Group 16.10.3.2 Get Requests and GetNext Requests Get requests and getNext requests for the etherStatsMulticastPkts and etherStatsBroadcastPkts columns return a value of zero because the variables are not supported by ONS 15454 SDH Ethernet cards. 16.10.3.3 Row Deletion in etherStatsTable To delete a row in the etherStatsTable, the SetRequest PDU should contain an etherStatsStatus “invalid” value (4). The OID marks the row for deletion.
Chapter 16 SNMP 16.10.
Chapter 16 SNMP 16.10.6 Alarm RMON Group 16.10.6.2 Row Creation in alarmTable To create a row in the alarmTable, the SetRequest PDU must be able to create the row in one single-set operation. All OIDs in the SetRequest PDU should be type OID.0 type for entry creation. The table has a maximum number of 256 rows.
Chapter 16 SNMP 16.10.7 Event RMON Group Table 16-10 OIDs Supported in the Alarm Table (continued) No. Column Name OID Status 16 Dot3StatsDeferredTransmissions {1.3.6.1.2.1.10.7.2.1.7} — 17 Dot3StatsLateCollisions {1.3.6.1.2.1.10.7.2.1.8} — 18 Dot3StatsExcessiveCollisions {13.6.1.2.1.10.7.2.1.9} — 19 Dot3StatsFrameTooLong {1.3.6.1.2.1.10.7.2.1.13} — 20 Dot3StatsCarrierSenseErrors {1.3.6.1.2.1.10.7.2.1.11} Unsupported in E100/E1000 21 Dot3StatsSQETestErrors {1.3.6.1.2.1.10.7.2.
Chapter 16 SNMP 16.10.7 Event RMON Group 16.10.7.1 Event Table The eventTable is read-only and unprovisionable. The table contains one row for rising alarms and another for falling ones. This table has the following restrictions: • The eventType is always log-and-trap (4). • The eventCommunity value is always a zero-length string, indicating that this event causes the trap to be despatched to all provisioned destinations. • The eventOwner column value is always “monitor.
Chapter 16 SNMP 16.10.7 Event RMON Group Cisco ONS 15454 SDH Reference Manual, R7.
A P P E N D I X A Hardware Specifications This appendix contains hardware and software specifications for the ONS 15454 SDH. A.1 Shelf Specifications This section provides specifications for shelf bandwidth; a list of topologies; Cisco Transport Controller (CTC) specifications; LAN, TL1, modem, alarm, and electrical interface assembly (EIA) interface specifications; database, timing, power, and environmental specifications; and shelf dimensions. A.1.
Appendix A Hardware Specifications A.1.3 Cisco Transport Controller • Wavelength multiplexer A.1.3 Cisco Transport Controller CTC, the ONS 15454 SDH craft interface software, has the following specifications: • 10BaseT • TCC2/TCC2P access: RJ-45 connector • Front Mount Electrical Connection (FMEC) access: LAN connector on MIC-C/T/P faceplate A.1.
Appendix A Hardware Specifications A.1.8 System Timing A.1.8 System Timing The ONS 15454 SDH has the following system timing specifications: • Stratum 3E, per ITU-T G.813 • Free running accuracy: +/– 4.6 ppm • Holdover stability: 3.7 exp –7/day, including temperature (< 255 slips in first 24 hours) • Reference: External building integrated timing supply (BITS), line, internal A.1.
Appendix A Hardware Specifications A.2 SFP and XFP Specifications • GE = Gigabit Ethernet • FC = Fibre Channel • HDTV = high definition television • DWDM = dense wavelength division multiplexing • CWDM = coarse wavelength division multiplexing Table A-1 SFP and XFP Specifications SFP/XFP Product ID Interface Transmitter Output Receiver Input Power Power Min/Max (dBm) Min/Max (dBm) 15454-SFP-LC-SX/ 15454E-SFP-LC-SX GE –9.5 to –4 –17 to 0 15454-SFP-LC-LX/ 15454E-SFP-LC-LX GE –9.
Appendix A Hardware Specifications A.3 General Card Specifications Table A-1 SFP and XFP Specifications (continued) SFP/XFP Product ID Interface Transmitter Output Receiver Input Power Power Min/Max (dBm) Min/Max (dBm) ONS-SC-2G-30.3 through ONS-SC-2G-60.
Appendix A Hardware Specifications A.3.1 Power Consumption Table A-2 Individual Card Power Requirements Card Type Card Name Watts Amperes BTU/Hr Control Cards TCC2 18.72 0.39 (0.213 at –60 V) 63.88 TCC2P 27.00 0.56 92.2 XC-VXL-10G 54.24 1.13 185.07 XC-VXL-2.5G 81.30 1.69 277.6 XC-VXC-10G 67 1.4 228.62 AIC-I 4.80 0.10 16.38 Fan Tray –48 VDC 129.60 2.7 442.21 E1-N-14 13.44 0.28 45.86 E1-42 43.2 0.90 147.40 E3-12 38.20 0.92 130.35 DS3i-N-12 19.0 0.80 64.
Appendix A Hardware Specifications A.3.2 Temperature Ranges Table A-2 Individual Card Power Requirements (continued) Card Type Card Name Watts Amperes BTU/Hr Optical Cards OC3 IR 4/STM1 SH 1310 19.20 0.40 65.6 OC3IR/STM1SH 1310-8 23.00 0.48 78.5 OC12 IR/STM4 SH 1310 9.28 0.19 31.7 OC12 LR/STM4 LH 1310 9.28 0.19 31.7 OC12 LR/STM4 LH 1550 9.28 0.19 31.7 OC12 LR/STM4 SH 1310-4 35.60 0.74 121.6 OC48 IR/STM16 SH AS 1310 37.20 0.78 127.0 OC48 LR/STM16 LH AS 1550 37.20 0.
Appendix A Hardware Specifications A.3.2 Temperature Ranges Table A-3 Card Temperature Ranges and Product Names I-Temp Product Name (–40 to +65 degrees Celsius, –40 to 149 degrees Fahrenheit) Card Type Card Name C-Temp Product Name (0 to +55 degrees Celsius, 32 to 131 degrees Fahrenheit) Control Cards TCC2 — 15454-TCC2 TCC2P — 15454-TCC2P XC-VXL-10G 15454E-XC-VXL10G — XC-VXL-2.5G 15454E-XC-VXL-2.
Appendix A Hardware Specifications A.4 Common Control Card Specifications Table A-3 Card Temperature Ranges and Product Names (continued) Card Type Card Name C-Temp Product Name (0 to +55 degrees Celsius, 32 to 131 degrees Fahrenheit) Optical OC3 IR 4/STM1 SH 1310 15454E-S1.1-4 — OC3 IR/STM1 SH 1310-8 15454E-S1.1-8 — OC12 IR/STM4 SH 1310 15454E-S4.1-1 — OC12 LR/STM4 LH 1310 15454E-L4.1-1 — OC12 LR/STM4 LH 1550 15454E-L4.2-1 — OC12 LR/STM4 SH 1310-4 15454E-L4.
Appendix A Hardware Specifications A.4.1 TCC2 Card Specifications A.4.1 TCC2 Card Specifications The TCC2 card has the following specifications: • CTC software – Interface: EIA/TIA-232 (local craft access, on TCC2 faceplate) – Interface: 10BaseT LAN (on TCC2 faceplate) – Interface: 10BaseT LAN (through backplane, access on the MIC-A/P card) • Synchronization – Stratum 3, per ITU-T G.812 – Free running access: Accuracy +/– 4.6 ppm – Holdover stability: 3.
Appendix A Hardware Specifications A.4.3 XC-VXL-10G Card Specifications • Synchronization – Stratum 3, per ITU-T G.812 – Free running access: Accuracy +/– 4.6 ppm – Holdover stability: 3.7 * 10 exp – 7 per day including temperature (< 255 slips in first 24 hours) – Reference: External BITS, line, internal • Supply voltage monitoring – Both supply voltage inputs are monitored – Normal operation: –40.5 to –56.7 V (in –48 VDC systems) –50.0 to –72.
Appendix A Hardware Specifications A.4.4 XC-VXL-2.5G Card Specifications A.4.4 XC-VXL-2.5G Card Specifications The XC-VXL-2.5G card has the following specifications: • Environmental – Operating temperature: –5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) – Operating humidity: 5 to 85 percent, noncondensing – Power consumption: 81.30 W, 1.69 A at –48 V, 277.6 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.
Appendix A Hardware Specifications A.4.6 AIC-I Specifications • Alarm outputs – Number of outputs: 4 (user configurable as inputs) – Switched by opto-MOS (metal oxide semiconductor) – Triggered by definable alarm condition – Maximum allowed open circuit voltage: 60 VDC – Maximum allowed closed circuit current: 100 mA – Termination through MIC-A/P • EOW/LOW – ITU-T G.711, ITU-T G.
Appendix A Hardware Specifications A.5 Electrical Card and FMEC Specifications A.5 Electrical Card and FMEC Specifications This section provides specifications for the electrical and Front Mount Electrical Connection (FMEC) cards. For compliance information, refer to the Cisco Optical Transport Products Safety and Compliance Information document. A.5.1 E1-N-14 Card Specifications The E1-N-14 card has the following specifications: • E1-N-14 input – Bit rate: 2.
Appendix A Hardware Specifications A.5.2 E1-42 Card Specifications – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 0.8 kg (1.9 lb) A.5.2 E1-42 Card Specifications The E1-42 card has the following specifications: • E1-42 input – Bit rate: 2.048 Mbps +/–50 ppm – Frame format: Unframed, ITU-T G.
Appendix A Hardware Specifications A.5.3 E3-12 Card Specifications A.5.3 E3-12 Card Specifications The E3-12 card has the following specifications: • E3-12 input – Bit rate: 34.368 Mbps +/–20 ppm – Line code: HDB-3 – Termination: Unbalanced coaxial cable – Input impedance: 75 ohms +/–5 percent – Cable loss: Up to 12 dB at 17184 kHz (for cable length, see the specification of the cable that you are using) – AIS: ITU-T G.704 compliant • E3-12 output – Bit rate: 34.
Appendix A Hardware Specifications A.5.4 DS3i-N-12 Card Specifications A.5.4 DS3i-N-12 Card Specifications The DS3i-N-12 card has the following specifications: • DS3i-N-12 input – Bit rate: 44.736 Mbps +/–20 ppm – Frame format: ITU-T G.704, ITU-T G.752/DS-3 ANSI T1.107-1988 – Line code: B3ZS – Termination: Unbalanced coaxial cable – Input impedance: 75 ohms +/– 5 percent – Cable loss: Maximum 137 m (450 ft): 734A, RG59, 728A Maximum 24 m (79 ft): RG179 – AIS: ITU-T G.
Appendix A Hardware Specifications A.5.5 STM1E-12 Card Specifications – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 0.8 kg (1.9 lb) A.5.5 STM1E-12 Card Specifications The STM1E-12 card has the following specifications: • STM1E-12 input – Bit rate: 155.52 Mbps +/–5 ppm for STM-1 or 139.
Appendix A Hardware Specifications A.5.6 FILLER Card – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 0.7 kg (1.7 lb) A.5.6 FILLER Card The FILLER card has the following specifications: • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: Not applicable • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.
Appendix A Hardware Specifications A.5.8 FMEC-DS1/E1 Specifications • Dimensions – Height: 182 mm (7.165 in.) – Width: 32 mm (1.25 in.) – Depth: 92 mm (3.62 in.) – Depth with backplane connector: 98 mm (3.87 in.) – Weight (not including clam shell): 0.3 kg (0.7 lb) A.5.8 FMEC-DS1/E1 Specifications The FMEC-DS1/E1 has the following specifications: • FMEC-DS1/E1 input – Bit rate: 2.
Appendix A Hardware Specifications A.5.9 FMEC E1-120NP Specifications A.5.9 FMEC E1-120NP Specifications The FMEC E1-120NP has the following specifications: • FMEC E1-120NP input – Bit rate: 2.048 Mbps +/–50 ppm – Line code: HDB-3 – Termination: Balanced twisted-pair cable – Input impedance: 120 ohms +/–5 percent – Cable loss: Up to 6 dB at 1024 kHz • FMEC E1-120NP output – Bit rate: 2.
Appendix A Hardware Specifications A.5.11 FMEC E1-120PROB Specifications – Cable loss: Up to 6 dB at 1024 kHz • FMEC E1-120PROA output – Bit rate: 2.048 Mbps +/–50 ppm – Line code: HDB-3 – Termination: Balanced twisted-pair cable – Input impedance: 120 ohms +/–5 percent – Pulse shape: conforms to ITU-T Recommendation G.703 (1991), Section 6.2, Figure 15 and Table 7 – Pulse amplitude: conforms to ITU-T Recommendation G.703 (1991), Section 6.
Appendix A Hardware Specifications A.5.12 E1-75/120 Impedance Conversion Panel Specifications – Pulse amplitude: conforms to ITU-T Recommendation G.703 (1991), Section 6.2, Figure 15 and Table 7 • FMEC E1-120PROB electrical interface – Connectors: Molex 96-pin LFH connectors (21 ports per connector) • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 0.
Appendix A Hardware Specifications A.5.13 FMEC-E3/DS3 Specifications A.5.13 FMEC-E3/DS3 Specifications The FMEC-E3/DS3 has the following specifications: • FMEC-E3/DS3 input (for E3 signals) – Bit rate: 34.368 Mbps +/–20 ppm – Line code: HDB-3 – Termination: Unbalanced coaxial cable – Input impedance: 75 ohms +/–5 percent – Cable loss: Up to 12 dB at 17184 kHz • FMEC-E3/DS3 output (for E3 signals) – Bit rate: 34.
Appendix A Hardware Specifications A.5.14 FMEC STM1E 1:1 Specifications – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 0.00 W, 0.00 A at –48 V, 0.0 BTU/hr • Dimensions – Height: 182 mm (7.165 in.) – Width: 32 mm (1.25 in.) – Depth: 92 mm (3.62 in.) – Depth with backplane connector: 98 mm (3.87 in.) – Weight (not including clam shell): 0.3 kg (0.7 lb) A.5.
Appendix A Hardware Specifications A.5.15 BLANK-FMEC Specifications • FMEC STM1E 1:1 electrical interface – Connectors: 1.0/2.3 miniature coax connectors • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 8.8 W (provided by the STM1E-12 card), 30.0 BTU/hr • Dimensions – Height: 182 mm (7.165 in.) – Width: 32 mm (1.25 in.) – Depth: 92 mm (3.62 in.
Appendix A Hardware Specifications A.5.17 MIC-C/T/P Specifications • Alarm inputs – Voltage (open contact): Maximum 60 VDC – Current (closed contact): Maximum 2 mA – Connector: 62-pin DB connector (common for inputs/outputs) • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 0.13 W (provided by +5 V from the TCC2/TCC2P card), 0.44 BTU/hr • Dimensions – Height: 182 mm (7.165 in.
Appendix A Hardware Specifications A.6 Optical Card Specifications – Connectors: 8-pin RJ-45 • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 0.38 W (provided by +5 V from the TCC2/TCC2P card), 1.37 BTU/hr • Dimensions – Height: 182 mm (7.165 in.) – Width: 32 mm (1.25 in.) – Depth: 92 mm (3.62 in.) – Depth with backplane connector: 98 mm (3.87 in.
Appendix A Hardware Specifications A.6.2 OC3 IR/STM1 SH 1310-8 Card Specifications – Minimum receiver level: –28 dBm at BER 1 * 10 exp – 12 – Receiver: InGaAs/InP photodetector – Link loss budget: 13 dB – Receiver input wavelength range: 1261 to 1360 nm – Jitter tolerance: Telcordia GR-253/ITU-T G.823 compliant • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 19.20 W, 0.
Appendix A Hardware Specifications A.6.3 OC12 IR/STM4 SH 1310 Card Specifications – Link loss budget: 13 dB – Receiver input wavelength range: 1274 to 1356 nm – Jitter tolerance: Telcordia GR-253/ITU-T G.823 compliant • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 23.00 W, 0.48 A at –48 V, 78.5 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.
Appendix A Hardware Specifications A.6.4 OC12 LR/STM4 LH 1310 Card Specifications – Jitter tolerance: Telcordia GR-253/ITU-T G.823 compliant • Environmental – Operating temperature: –5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 10.90 W, 0.23 A at –48 V, 37.2 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.
Appendix A Hardware Specifications A.6.5 OC12 LR/STM4 LH 1550 Card Specifications • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 0.6 kg (1.4 lb) A.6.5 OC12 LR/STM4 LH 1550 Card Specifications The OC12 LR/STM4 LH 1550 card has the following specifications: • Line – Bit rate: 622.
Appendix A Hardware Specifications A.6.6 OC12 IR/STM4 SH 1310-4 Card Specifications – Weight (not including clam shell): 0.6 kg (1.4 lb) A.6.6 OC12 IR/STM4 SH 1310-4 Card Specifications The OC12 IR/STM4 SH 1310-4 card has the following specifications: • Line – Bit rate: 622.
Appendix A Hardware Specifications A.6.7 OC48 IR/STM16 SH AS 1310 Card Specifications A.6.7 OC48 IR/STM16 SH AS 1310 Card Specifications The OC48 IR/STM16 SH AS 1310 card has the following specifications: • Line – Bit rate: 2488.320 Mbps – Code: Scrambled NRZ – Fiber: 1310-nm single-mode – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.9 OC48 ELR/STM16 EH 100 GHz Card Specifications – Code: Scrambled NRZ – Fiber: 1550-nm single-mode – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.9 OC48 ELR/STM16 EH 100 GHz Card Specifications – Compliance: ITU-T G.692, ITU-T G.707, ITU-T G.957, ITU-T G.958 • Transmitter – Maximum transmitter output power: 0 dBm – Minimum transmitter output power: –2 dBm – Center wavelength: +/– 0.
Appendix A Hardware Specifications A.6.10 OC192 SR/STM64 IO 1310 Card Specifications – 1554.13 +/– 0.25 nm, STM-16HS-LH 1554.13 (DWDM) – 1555.75 +/– 0.25 nm, STM-16HS-LH 1555.75 (DWDM) – 1557.36 +/– 0.25 nm, STM-16HS-LH 1557.36 (DWDM) – 1558.98 +/– 0.25 nm, STM-16HS-LH 1558.98 (DWDM) – 1560.61 +/– 0.25 nm, STM-16HS-LH 1560.61 (DWDM) A.6.10 OC192 SR/STM64 IO 1310 Card Specifications The OC192 SR/STM64 IO 1310 card has the following specifications: • Line – Bit rate: 9.
Appendix A Hardware Specifications A.6.11 OC192 IR/STM64 SH 1550 Card Specifications – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 1.3 kg (3.1 lb) A.6.11 OC192 IR/STM64 SH 1550 Card Specifications The OC192 IR/STM64 SH 1550 card has the following specifications: • Line – Bit rate: 9.
Appendix A Hardware Specifications A.6.12 OC192 LR/STM64 LH 1550 Card Specifications – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 1.3 kg (3.1 lb) A.6.12 OC192 LR/STM64 LH 1550 Card Specifications The OC192 LR/STM64 LH 1550 card has the following specifications: • Line – Bit rate: 9.
Appendix A Hardware Specifications A.6.13 OC192 LR/STM64 LH ITU 15xx.xx Card Specifications – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 1.3 kg (3.1 lb) A.6.13 OC192 LR/STM64 LH ITU 15xx.xx Card Specifications The OC192 LR/STM64 LH ITU 15xx.xx card has the following specifications: • Line – Bit rate: 9.
Appendix A Hardware Specifications A.6.14 15454_MRC-12 Card Specifications – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 52.00 W, 1.08 A at –48 V, 177.6 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 1.3 kg (3.1 lb) • Currently available wavelengths and versions of OC192 LR/STM64 LH ITU 15xx.
Appendix A Hardware Specifications A.6.15 OC192SR1/STM64IO Short Reach Card Specifications – Fiber: 1550-nm single-mode – Connectors: LC duplex connector for each SFP – Compliance: ITU-T G.957 and Telcordia GR-253 • Transmitter – Maximum transmitter output power: Depends on SFP (see A.2 SFP and XFP Specifications, page A-3) – Minimum transmitter output power: Depends on SFP (see A.
Appendix A Hardware Specifications A.6.16 OC192/STM64 Any Reach Card Specifications • Line – Bit rate: STM-64 (9.9520 Gbps) – Fiber: 1310-nm single-mode – Connectors: LC duplex connector for the XFP – Compliance: ITU G.
Appendix A Hardware Specifications A.7 Ethernet Card Specifications – Minimum transmitter output power: Depends on SFP (see the “A.2 SFP and XFP Specifications” section on page A-3) • Receiver – Maximum receiver level: Depends on SFP (see the “A.2 SFP and XFP Specifications” section on page A-3) – Minimum receiver level: Depends on SFP (see the “A.
Appendix A Hardware Specifications A.7.2 E1000-2-G Card Specifications – ONS 15454 SDH cards, when installed in a system, comply with these safety standards: UL 1950, CSA C22.2 No. 950, EN 60950, IEC 60950 A.7.2 E1000-2-G Card Specifications The E1000-2-G card has the following specifications: • Environmental – Operating temperature: C-Temp (15454-E1000-2-G): 0 to +55 degrees Celsius (32 to 131 degrees Fahrenheit) – Operating humidity: 5 to 95 percent, noncondensing – Power consumption: 53.50 W, 1.
Appendix A Hardware Specifications A.7.5 G1K-4 Card Specifications – Operating temperature: C-Temp (15454-CE100T): 0 to +55 degrees Celsius (32 to 131 degrees Fahrenheit) – Operating humidity: 0 to 95 percent, noncondensing – Power consumption: 53 W, 1.1 A, 181.3 BTU/hr • Dimensions – Height: 12.650 in. (321.3 mm) – Width: 0.913 in. (23.19 mm) – Depth: 9.073 in. (230.45 mm) – Weight (not including clam shell): 1.8 lb (0.82 kg) A.7.
Appendix A Hardware Specifications A.7.7 ML1000-2 Card Specifications – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight (not including clam shell): 2.3 lb (1.0 kg) • Compliance. ONS 15454 SDH cards, when installed in a system, comply with these standards: – Safety: IEC 60950, EN 60950, UL 60950, CSA C22.2 No. 60950, TS 001, and AS/NZS 3260 A.7.
Appendix A Hardware Specifications A.8 Storage Access Networking Card Specifications A.8 Storage Access Networking Card Specifications This section provides specifications for the FC_MR-4 (Fibre Channel) card. For compliance information, refer to the Cisco Optical Transport Products Safety and Compliance Information document. A.8.
A P P E N D I X B Administrative and Service States This appendix describes the administrative and service states for Cisco ONS 15454 SDH cards, ports, and cross-connects. For circuit state information, see Chapter 11, “Circuits and Tunnels.” Software Release 5.0 and later states are based on the generic state model defined in Telcordia GR-1093-CORE, Issue 2 and ITU-T X.731. B.
Appendix B Administrative and Service States B.2 Administrative States Table B-2 ONS 15454 SDH Secondary States Secondary State Definition automaticInService The entity is delayed before transitioning to the Unlocked-enabled service state. The transition to the Unlocked-enabled state depends on the correction of conditions, or on a soak timer. Alarm reporting is suppressed, but traffic is carried.
Appendix B Administrative and Service States B.3 Service State Transitions Note When an entity is put in the Locked,maintenance administrative state, the ONS 15454 SDH suppresses all standing alarms on that entity. All alarms and events appear on the Conditions tab. You can change this behavior for the LPBKFACILITY and LPBKTERMINAL alarms. To display these alarms on the Alarms tab, set the NODE.general.ReportLoopbackConditionsOnUnlocked,MaintenancePorts to TRUE on the NE Defaults tab.
Appendix B Administrative and Service States B.3.1 Card Service State Transitions Table B-4 ONS 15454 SDH Card Service State Transitions (continued) Current Service State Action Next Service State Unlocked-disabled,automaticInService and mismatchOfEquipment Pull the card. Unlocked-disabled,automaticInService & notInstalled Delete the card.
Appendix B Administrative and Service States B.3.1 Card Service State Transitions Table B-4 ONS 15454 SDH Card Service State Transitions (continued) Current Service State Action Next Service State Locked-disabled,mismatchOfEquipment & maintenance Change the administrative state to Unlocked. Unlocked-disabled,mismatchOfEquipment Pull the card. Locked-disabled,maintenance & notInstalled Delete the card.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-4 ONS 15454 SDH Card Service State Transitions (continued) Current Service State Action Next Service State Locked-enabled,maintenance Change the administrative state to Unlocked. Unlocked-enabled Delete the card. Locked-disabled,unassigned Pull the card. Locked-disabled,maintenance & notInstalled Reset the card.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions Current Service State Action Next Service State Unlocked-enabled Put the port or cross-connect in the Locked,maintenance administrative state. Locked-enabled,maintenance Put the port or cross-connect in the Locked,disabled administrative state.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions (continued) Current Service State Action Next Service State Unlocked-disabled,automaticInService & failed & outOfGroup Alarm/condition is cleared.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions (continued) Current Service State Action Next Service State Unlocked-disabled,failed and outOfGroup Alarm/condition is cleared. Unlocked-enabled or Locked-enabled,maintenance • If an In Group member is Unlocked-enabled or Unlocked-disabled,automaticInService, the member transitions to Unlocked-enabled.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions (continued) Current Service State Action Next Service State Locked-disabled,failed & maintenance & outOfGroup Alarm/condition is cleared. Locked-enabled,maintenance & outOfGroup Put the VCAT member in the Unlocked administrative state.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions (continued) Current Service State Action Next Service State Locked-enabled,maintenance Locked-enabled,loopback & maintenance Release the loopback.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Cisco ONS 15454 SDH Reference Manual, R7.
A P P E N D I X C Network Element Defaults This appendix describes the factory-configured (default) network element (NE) settings for the Cisco ONS 15454 SDH. It includes descriptions of card, node, and Cisco Transport Controller (CTC) default settings. To import, export, or edit the settings, refer to the “Maintain the Node” chapter of the Cisco ONS 15454 SDH Procedure Guide. Cards supported by this platform that are not listed in this appendix are not supported by user-configurable NE defaults settings.
Appendix C Network Element Defaults C.2 Card Default Settings Note Changing some node-level provisioning via NE defaults can cause CTC disconnection or a reboot of the node in order for the provisioning to take effect. Before you change a default, check in the Side Effects column of the Defaults editor (right-click a column header and select Show Column > Side Effects) and be prepared for the occurrence of any side effects listed for that default. C.
Appendix C Network Element Defaults C.2.2 Threshold Defaults • ALS (card-level Maintenance > ALS tab)—(STM1-8, STM16, STM64, STM64-XFP, and MRC-12 cards) ALS configuration defaults. • IOS (card-level IOS tab)—(ML-series cards) Console port and RADIUS server access settings. • Ether Ports—(CE-series cards) Line configuration settings (including 802 class of service [IEEE 802.1p CoS] and IP type of service [ToS]). • POS Ports—(CE-series cards) Line configuration settings.
Appendix C Network Element Defaults C.2.3 Defaults by Card C.2.3 Defaults by Card In the tables that follow, card defaults are defined by the default name, its factory-configured value, and the domain of allowable values that you can assign to it. Note Some default values, such as certain thresholds, are interdependent. Before changing a value, review the domain for that default and any other related defaults for potential dependencies. C.2.3.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-1 E1-N-14 Card Default Settings (continued) Default Name Default Value Default Domain E1.pmthresholds.path.nearend.15min.EB 9 (count) 0 - 450000 E1.pmthresholds.path.nearend.15min.ES 65 (seconds) 0 - 900 E1.pmthresholds.path.nearend.15min.SES 10 (seconds) 0 - 900 E1.pmthresholds.path.nearend.15min.UAS 10 (seconds) 0 - 900 E1.pmthresholds.path.nearend.1day.AISS 10 (seconds) 0 - 86400 E1.pmthresholds.path.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card C.2.3.2 E1-42 Card Default Settings Table C-2 lists the E1-42 card default settings. Table C-2 E1-42 Card Default Settings Default Name Default Value Default Domain E1_42.config.AINSSoakTime 08:00 (hours:mins) 00:00, 00:15, 00:30 .. 48:00 E1_42.config.LineCoding HDB3 HDB3 E1_42.config.LineType E1_MF E1_MF, E1_CRCMF, E1_UNFRAMED E1_42.config.SDBER 1.00E-07 1E-5, 1E-6, 1E-7, 1E-8, 1E-9 E1_42.config.SFBER 1.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-2 E1-42 Card Default Settings (continued) Default Name Default Value Default Domain E1_42.pmthresholds.vc4.farend.1day.SES 7 (seconds) 0 - 86400 E1_42.pmthresholds.vc4.farend.1day.UAS 10 (seconds) 0 - 86400 E1_42.pmthresholds.vc4.nearend.15min.BBE 25 (count) 0 - 2159100 E1_42.pmthresholds.vc4.nearend.15min.EB 15 (count) 0 - 7200000 E1_42.pmthresholds.vc4.nearend.15min.ES 12 (seconds) 0 - 900 E1_42.pmthresholds.vc4.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-3 E3-12 Card Default Settings Default Name Default Value Default Domain E3.config.AINSSoakTime 08:00 (hours:mins) 00:00, 00:15, 00:30 .. 48:00 E3.config.SDBER 1.00E-07 1E-5, 1E-6, 1E-7, 1E-8, 1E-9 E3.config.SFBER 1.00E-04 1E-3, 1E-4, 1E-5 E3.config.State unlocked, unlocked, locked, disabled, locked, maintenance, automaticInService unlocked, automaticInService E3.pmthresholds.line.nearend.15min.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-3 E3-12 Card Default Settings (continued) Default Name Default Value Default Domain E3.pmthresholds.vc4.nearend.1day.ES 100 (seconds) 0 - 86400 E3.pmthresholds.vc4.nearend.1day.SES 7 (seconds) 0 - 86400 E3.pmthresholds.vc4.nearend.1day.UAS 10 (seconds) 0 - 86400 E3.pmthresholds.vclo.farend.15min.BBE 15 (count) 0 - 2159100 E3.pmthresholds.vclo.farend.15min.EB 15 (count) 0 - 7200000 E3.pmthresholds.vclo.farend.15min.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-4 DS3i-N-12 Card Default Settings (continued) Default Name Default Value Default Domain DS3I.config.State unlocked, unlocked, locked, disabled, locked, automaticInService maintenance, unlocked, automaticInService DS3I.pmthresholds.cpbitpath.farend.15min.CV 382 (count) 0 - 287100 DS3I.pmthresholds.cpbitpath.farend.15min.ES 25 (seconds) 0 - 900 DS3I.pmthresholds.cpbitpath.farend.15min.SAS 2 (seconds) 0 - 900 DS3I.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-4 DS3i-N-12 Card Default Settings (continued) Default Name Default Value Default Domain DS3I.pmthresholds.pbitpath.nearend.1day.ES 250 (seconds) 0 - 86400 DS3I.pmthresholds.pbitpath.nearend.1day.SAS 8 (seconds) 0 - 86400 DS3I.pmthresholds.pbitpath.nearend.1day.SES 40 (seconds) 0 - 86400 DS3I.pmthresholds.pbitpath.nearend.1day.UAS 10 (seconds) 0 - 86400 DS3I.pmthresholds.vc4.farend.15min.BBE 25 (count) 0 - 2159100 DS3I.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-4 DS3i-N-12 Card Default Settings (continued) Default Name Default Value Default Domain DS3I.pmthresholds.vclo.nearend.15min.ES 12 (seconds) 0 - 900 DS3I.pmthresholds.vclo.nearend.15min.SES 3 (seconds) 0 - 900 DS3I.pmthresholds.vclo.nearend.15min.UAS 10 (seconds) 0 - 900 DS3I.pmthresholds.vclo.nearend.1day.BBE 150 (count) 0 - 207273600 DS3I.pmthresholds.vclo.nearend.1day.EB 125 (count) 0 - 691200000 DS3I.pmthresholds.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-5 STM1E-12 Card Default Settings (continued) Default Name Default Value Default Domain STM1E-12.pmthresholds.ms.farend.1day.UAS 10 (seconds) 0 - 86400 STM1E-12.pmthresholds.ms.nearend.15min.BBE 1312 (count) 0 - 137700 STM1E-12.pmthresholds.ms.nearend.15min.EB 1312 (count) 0 - 137700 STM1E-12.pmthresholds.ms.nearend.15min.ES 87 (seconds) 0 - 900 STM1E-12.pmthresholds.ms.nearend.15min.SES 1 (seconds) 0 - 900 STM1E-12.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-5 STM1E-12 Card Default Settings (continued) Default Name Default Value Default Domain STM1E-12.pmthresholds.rs.nearend.15min.EB 10000 (count) 0 - 138600 STM1E-12.pmthresholds.rs.nearend.15min.ES 500 (seconds) 0 - 900 STM1E-12.pmthresholds.rs.nearend.15min.SEFS 500 (seconds) 0 - 900 STM1E-12.pmthresholds.rs.nearend.15min.SES 500 (seconds) 0 - 900 STM1E-12.pmthresholds.rs.nearend.15min.UAS 3 (seconds) 0 - 900 STM1E-12.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-6 Ethernet Card Default Settings (continued) Default Name Default Value Default Domain ML100T.ios.consolePortAccess TRUE TRUE, FALSE ML100T.ios.radiusServerAccess FALSE TRUE, FALSE ML100X-8.config.card.Mode HDLC HDLC, GFP-F ML100X-8.ios.consolePortAccess TRUE TRUE, FALSE ML100X-8.ios.radiusServerAccess FALSE TRUE, FALSE C.2.3.7 STM-1 Card Default Settings Table C-7 lists the STM-1 card default settings.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-7 STM-1 Card Default Settings (continued) Default Name Default Value Default Domain STM1.pmthresholds.ms.nearend.15min.PSC 1 (count) 0 - 600 STM1.pmthresholds.ms.nearend.15min.PSD 300 (seconds) 0 - 900 STM1.pmthresholds.ms.nearend.15min.SES 1 (seconds) 0 - 900 STM1.pmthresholds.ms.nearend.15min.UAS 3 (seconds) 0 - 900 STM1.pmthresholds.ms.nearend.1day.BBE 13120 (count) 0 - 13219200 STM1.pmthresholds.ms.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-7 STM-1 Card Default Settings (continued) Default Name Default Value Default Domain STM1.pmthresholds.path.nearend.1day.NPJC-PDET 5760 (count) 0 - 691200000 STM1.pmthresholds.path.nearend.1day.NPJC-PGEN 5760 (count) 0 - 691200000 STM1.pmthresholds.path.nearend.1day.PJCDIFF 5760 (count) 0 - 1382400000 STM1.pmthresholds.path.nearend.1day.PJCS-PDET 9600 (seconds) 0 - 86400 STM1.pmthresholds.path.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-8 STM1-8 Card Default Settings (continued) Default Name Default Value Default Domain STM1-8.config.line.SDBER 1.00E-07 1E-5, 1E-6, 1E-7, 1E-8, 1E-9 STM1-8.config.line.SendDoNotUse FALSE FALSE when SendDoNotUse TRUE; FALSE, TRUE when SendDoNotUse FALSE STM1-8.config.line.SendDoNotUse FALSE FALSE, TRUE STM1-8.config.line.SFBER 1.00E-04 1E-3, 1E-4, 1E-5 STM1-8.config.line.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-8 STM1-8 Card Default Settings (continued) Default Name Default Value Default Domain STM1-8.pmthresholds.ms.farend.15min.ES 87 (seconds) 0 - 900 STM1-8.pmthresholds.ms.farend.15min.SES 1 (seconds) 0 - 900 STM1-8.pmthresholds.ms.farend.15min.UAS 3 (seconds) 0 - 900 STM1-8.pmthresholds.ms.farend.1day.BBE 13120 (count) 0 - 13219200 STM1-8.pmthresholds.ms.farend.1day.EB 13120 (count) 0 - 13219200 STM1-8.pmthresholds.ms.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-8 STM1-8 Card Default Settings (continued) Default Name Default Value Default Domain STM1-8.pmthresholds.path.nearend.15min.NPJC-PGEN 60 (count) 0 - 7200000 STM1-8.pmthresholds.path.nearend.15min.PJCDIFF 60 (count) 0 - 14400000 STM1-8.pmthresholds.path.nearend.15min.PJCS-PDET 100 (seconds) 0 - 900 STM1-8.pmthresholds.path.nearend.15min.PJCS-PGEN 100 (seconds) 0 - 900 STM1-8.pmthresholds.path.nearend.15min.
Appendix C Network Element Defaults C.2.3 Defaults by Card C.2.3.9 STM-4 Card Default Settings Table C-9 lists the STM-4 card default settings. Table C-9 STM-4 Card Default Settings Default Name Default Value Default Domain STM4.config.line.AdminSSMIn STU G811, STU, G812T, G812L, SETS, DUS STM4.config.line.AINSSoakTime 08:00 (hours:mins) 00:00, 00:15, 00:30 .. 48:00 STM4.config.line.PJVC4Mon# 0 (VC4 #) 0-4 STM4.config.line.SDBER 1.00E-07 1E-5, 1E-6, 1E-7, 1E-8, 1E-9 STM4.config.line.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-9 STM-4 Card Default Settings (continued) Default Name Default Value Default Domain STM4.pmthresholds.ms.nearend.1day.ES 864 (seconds) 0 - 86400 STM4.pmthresholds.ms.nearend.1day.PSC 5 (count) 0 - 57600 STM4.pmthresholds.ms.nearend.1day.PSC-W 5 (count) 0 - 57600 STM4.pmthresholds.ms.nearend.1day.PSD 600 (seconds) 0 - 86400 STM4.pmthresholds.ms.nearend.1day.PSD-W 600 (seconds) 0 - 86400 STM4.pmthresholds.ms.nearend.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-9 STM-4 Card Default Settings (continued) Default Name Default Value Default Domain STM4.pmthresholds.rs.nearend.15min.UAS 3 (seconds) 0 - 900 STM4.pmthresholds.rs.nearend.1day.BBE 100000 (count) 0 - 53136000 STM4.pmthresholds.rs.nearend.1day.EB 100000 (count) 0 - 53136000 STM4.pmthresholds.rs.nearend.1day.ES 5000 (seconds) 0 - 86400 STM4.pmthresholds.rs.nearend.1day.SEFS 5000 (seconds) 0 - 86400 STM4.pmthresholds.rs.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-10 STM4-4 Card Default Settings (continued) Default Name Default Value Default Domain STM4-4.pmthresholds.ms.nearend.15min.BBE 5315 (count) 0 - 552600 STM4-4.pmthresholds.ms.nearend.15min.EB 5315 (count) 0 - 552600 STM4-4.pmthresholds.ms.nearend.15min.ES 87 (seconds) 0 - 900 STM4-4.pmthresholds.ms.nearend.15min.PSC 1 (count) 0 - 600 STM4-4.pmthresholds.ms.nearend.15min.PSC-W 1 (count) 0 - 600 STM4-4.pmthresholds.ms.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-10 STM4-4 Card Default Settings (continued) Default Name Default Value Default Domain STM4-4.pmthresholds.path.nearend.1day.PJCS-PDET 9600 (seconds) 0 - 86400 STM4-4.pmthresholds.path.nearend.1day.PJCS-PGEN 9600 (seconds) 0 - 86400 STM4-4.pmthresholds.path.nearend.1day.PPJC-PDET 5760 (count) 0 - 691200000 STM4-4.pmthresholds.path.nearend.1day.PPJC-PGEN 5760 (count) 0 - 691200000 STM4-4.pmthresholds.path.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-11 STM-16 Card Default Settings (continued) Default Name Default Value Default Domain STM16.config.line.SendDoNotUse FALSE FALSE, TRUE STM16.config.line.SFBER 1.00E-04 1E-3, 1E-4, 1E-5 STM16.config.line.State unlocked, unlocked, locked, disabled, locked, automaticInService maintenance, unlocked, automaticInService STM16.config.line.SyncMsgIn TRUE FALSE, TRUE STM16.config.vc4.IPPMEnabled FALSE TRUE, FALSE STM16.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-11 STM-16 Card Default Settings (continued) Default Name Default Value Default Domain STM16.pmthresholds.ms.nearend.1day.PSD 600 (seconds) 0 - 86400 STM16.pmthresholds.ms.nearend.1day.PSD-R 600 (seconds) 0 - 86400 STM16.pmthresholds.ms.nearend.1day.PSD-S 600 (seconds) 0 - 86400 STM16.pmthresholds.ms.nearend.1day.PSD-W 600 (seconds) 0 - 86400 STM16.pmthresholds.ms.nearend.1day.SES 4 (seconds) 0 - 86400 STM16.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-11 STM-16 Card Default Settings (continued) Default Name Default Value Default Domain STM16.pmthresholds.rs.nearend.1day.BBE 100000 (count) 0 - 206582400 STM16.pmthresholds.rs.nearend.1day.EB 100000 (count) 0 - 206582400 STM16.pmthresholds.rs.nearend.1day.ES 5000 (seconds) 0 - 86400 STM16.pmthresholds.rs.nearend.1day.SEFS 5000 (seconds) 0 - 86400 STM16.pmthresholds.rs.nearend.1day.SES 5000 (seconds) 0 - 86400 STM16.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-12 STM-64 Card Default Settings (continued) Default Name Default Value Default Domain STM64.physicalthresholds.alarm.OPT-HIGH 120 (%) OPT-LOW, OPT-LOW + 1.0, OPT-LOW + 2.0 .. 255.0 STM64.physicalthresholds.alarm.OPT-LOW 80 (%) 0.0, 1.0, 2.0 .. OPT-HIGH STM64.physicalthresholds.warning.15min.LBC-HIGH 200 (%) LBC-LOW, LBC-LOW + 1.0, LBC-LOW + 2.0 .. 255.0 STM64.physicalthresholds.warning.15min.LBC-LOW 20 (%) 0.0, 1.0, 2.0 ..
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-12 STM-64 Card Default Settings (continued) Default Name Default Value Default Domain STM64.pmthresholds.ms.nearend.15min.PSD 300 (seconds) 0 - 900 STM64.pmthresholds.ms.nearend.15min.PSD-R 300 (seconds) 0 - 900 STM64.pmthresholds.ms.nearend.15min.PSD-S 300 (seconds) 0 - 900 STM64.pmthresholds.ms.nearend.15min.PSD-W 300 (seconds) 0 - 900 STM64.pmthresholds.ms.nearend.15min.SES 1 (seconds) 0 - 900 STM64.pmthresholds.ms.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-12 STM-64 Card Default Settings (continued) Default Name Default Value Default Domain STM64.pmthresholds.path.nearend.1day.PJCDIFF 5760 (count) 0 - 1382400000 STM64.pmthresholds.path.nearend.1day.PJCS-PDET 9600 (seconds) 0 - 86400 STM64.pmthresholds.path.nearend.1day.PJCS-PGEN 9600 (seconds) 0 - 86400 STM64.pmthresholds.path.nearend.1day.PPJC-PDET 5760 (count) 0 - 691200000 STM64.pmthresholds.path.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-13 STM64-XFP Default Settings (continued) Default Name Default Value Default Domain STM64-XFP.config.line.SendDoNotUse FALSE FALSE, TRUE STM64-XFP.config.line.SFBER 1.00E-04 1E-3, 1E-4, 1E-5 STM64-XFP.config.line.State unlocked, unlocked, locked, disabled, locked, automaticInService maintenance, unlocked, automaticInService STM64-XFP.config.line.SyncMsgIn TRUE FALSE, TRUE STM64-XFP.config.vc4.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-13 STM64-XFP Default Settings (continued) Default Name Default Value Default Domain STM64-XFP.pmthresholds.ms.farend.1day.BBE 850400 (count) 0 - 849657600 STM64-XFP.pmthresholds.ms.farend.1day.EB 850400 (count) 0 - 849657600 STM64-XFP.pmthresholds.ms.farend.1day.ES 864 (seconds) 0 - 86400 STM64-XFP.pmthresholds.ms.farend.1day.SES 4 (seconds) 0 - 86400 STM64-XFP.pmthresholds.ms.farend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-13 STM64-XFP Default Settings (continued) Default Name Default Value Default Domain STM64-XFP.pmthresholds.path.farend.1day.BBE 250 (count) 0 - 207273600 STM64-XFP.pmthresholds.path.farend.1day.EB 125 (count) 0 - 691200000 STM64-XFP.pmthresholds.path.farend.1day.ES 100 (seconds) 0 - 86400 STM64-XFP.pmthresholds.path.farend.1day.SES 7 (seconds) 0 - 86400 STM64-XFP.pmthresholds.path.farend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-13 STM64-XFP Default Settings (continued) Default Name Default Value Default Domain STM64-XFP.pmthresholds.rs.nearend.1day.EB 100000 (count) 0 - 764899200 STM64-XFP.pmthresholds.rs.nearend.1day.ES 5000 (seconds) 0 - 86400 STM64-XFP.pmthresholds.rs.nearend.1day.SEFS 5000 (seconds) 0 - 86400 STM64-XFP.pmthresholds.rs.nearend.1day.SES 5000 (seconds) 0 - 86400 STM64-XFP.pmthresholds.rs.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.config.stm16.line.AlsRecoveryPulseInterval 100 (seconds) 60 - 300 MRC-12.config.stm16.line.PJVC4Mon# 0 (VC4 #) 0 - 16 MRC-12.config.stm16.line.SDBER 1.00E-07 1E-5, 1E-6, 1E-7, 1E-8, 1E-9 MRC-12.config.stm16.line.SendDoNotUse FALSE FALSE when SendDoNotUse TRUE; FALSE, TRUE when SendDoNotUse FALSE MRC-12.config.stm16.line.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.physicalthresholds.stm1.alarm.OPT-HIGH 120 (%) OPT-LOW, OPT-LOW + 1.0, OPT-LOW + 2.0 .. 255.0 MRC-12.physicalthresholds.stm1.alarm.OPT-LOW 80 (%) 0.0, 1.0, 2.0 .. OPT-HIGH MRC-12.physicalthresholds.stm1.warning.15min.LBC-HIGH 200 (%) LBC-LOW, LBC-LOW + 1.0, LBC-LOW + 2.0 .. 255.0 MRC-12.physicalthresholds.stm1.warning.15min.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.physicalthresholds.stm16.warning.1day.LBC-HIGH 200 (%) LBC-LOW, LBC-LOW + 1.0, LBC-LOW + 2.0 .. 255.0 MRC-12.physicalthresholds.stm16.warning.1day.LBC-LOW 20 (%) 0.0, 1.0, 2.0 .. LBC-HIGH MRC-12.physicalthresholds.stm16.warning.1day.OPR-HIGH 200 (%) OPR-LOW, OPR-LOW + 1.0, OPR-LOW + 2.0 .. 255.0 MRC-12.physicalthresholds.stm16.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm1.ms.farend.15min.SES 1 (seconds) 0 - 900 MRC-12.pmthresholds.stm1.ms.farend.15min.UAS 3 (seconds) 0 - 900 MRC-12.pmthresholds.stm1.ms.farend.1day.BBE 13120 (count) 0 - 13219200 MRC-12.pmthresholds.stm1.ms.farend.1day.EB 13120 (count) 0 - 13219200 MRC-12.pmthresholds.stm1.ms.farend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm1.path.nearend.15min.PJCDIFF 60 (count) 0 - 1200 MRC-12.pmthresholds.stm1.path.nearend.15min.PJCS-PDET 100 (seconds) 0 - 7200000 MRC-12.pmthresholds.stm1.path.nearend.15min.PJCS-PGEN 100 (seconds) 0 - 7200000 MRC-12.pmthresholds.stm1.path.nearend.15min.PPJC-PDET 60 (count) 0 - 7200000 MRC-12.pmthresholds.stm1.path.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm16.ms.farend.1day.BBE 212600 (count) 0 - 212371200 MRC-12.pmthresholds.stm16.ms.farend.1day.EB 212600 (count) 0 - 212371200 MRC-12.pmthresholds.stm16.ms.farend.1day.ES 864 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.ms.farend.1day.SES 4 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.ms.farend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm16.path.farend.1day.BBE 250 (count) 0 - 207273600 MRC-12.pmthresholds.stm16.path.farend.1day.EB 125 (count) 0 - 691200000 MRC-12.pmthresholds.stm16.path.farend.1day.ES 100 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.path.farend.1day.SES 7 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.path.farend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm16.rs.nearend.1day.EB 100000 (count) 0 - 206582400 MRC-12.pmthresholds.stm16.rs.nearend.1day.ES 5000 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.rs.nearend.1day.SEFS 5000 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.rs.nearend.1day.SES 5000 (seconds) 0 - 86400 MRC-12.pmthresholds.stm16.rs.nearend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm4.path.farend.15min.SES 3 (seconds) 0 - 900 MRC-12.pmthresholds.stm4.path.farend.15min.UAS 10 (seconds) 0 - 900 MRC-12.pmthresholds.stm4.path.farend.1day.BBE 250 (count) 0 - 207273600 MRC-12.pmthresholds.stm4.path.farend.1day.EB 125 (count) 0 - 691200000 MRC-12.pmthresholds.stm4.path.farend.1day.
Appendix C Network Element Defaults C.2.3 Defaults by Card Table C-14 MRC-12 Card Default Settings (continued) Default Name Default Value Default Domain MRC-12.pmthresholds.stm4.rs.nearend.15min.UAS 3 (seconds) 0 - 900 MRC-12.pmthresholds.stm4.rs.nearend.1day.BBE 100000 (count) 0 - 53136000 MRC-12.pmthresholds.stm4.rs.nearend.1day.EB 100000 (count) 0 - 53136000 MRC-12.pmthresholds.stm4.rs.nearend.1day.ES 5000 (seconds) 0 - 86400 MRC-12.pmthresholds.stm4.rs.nearend.1day.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-15 FC_MR-4 Card Default Settings (continued) Default Name Default Value Default Domain FC-MR.config.port.enhancedFibreChannelFicon.IngressIdleFiltering TRUE TRUE, FALSE FC-MR.config.port.enhancedFibreChannelFicon.MaxFrameSize 2148 2148, 2152, 2156, 2160, 2164, 2168, 2172 FC-MR.config.port.MediaType Undefined Fibre Channel - 1 Gbps ISL, Fibre Channel - 2 Gbps ISL, FICON - 1 Gbps ISL, FICON - 2 Gbps ISL, Undefined FC-MR.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 • Security Access settings—Set default security settings for LAN access, shell access, serial craft access, element management system (EMS) access (including Internet Inter-Object Request Broker Protocol [IIOP] listener port number), TL1 access, and SNMP access.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.general.NtpSntpServer 0.0.0.0 IP Address NODE.general.ReportLoopbackConditionsOnUnlocked,MaintenancePorts FALSE FALSE, TRUE NODE.general.TimeZone (GMT-08:00 ) Pacific Time (US & Canada), Tijuana (For applicable time zones, see Table C-17 on page C-55.) NODE.general.UseDST TRUE TRUE, FALSE NODE.network.general.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.osi.tarp.L1DataCache TRUE FALSE, TRUE NODE.osi.tarp.L2DataCache FALSE FALSE, TRUE NODE.osi.tarp.LANStormSuppression TRUE FALSE, TRUE NODE.osi.tarp.LDB TRUE FALSE, TRUE NODE.osi.tarp.LDBEntry 5 (min) 1 - 10 NODE.osi.tarp.LDBFlush 5 (min) 0 - 1440 NODE.osi.tarp.PDUsL1Propagation TRUE FALSE, TRUE NODE.osi.tarp.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.security.dataComm.CtcBackplaneIpDisplaySuppression TRUE FALSE, TRUE when isSecureModeSuppor tedOnControlCard TRUE; (NOT SUPPORTED) when isSecureModeSuppor tedOnControlCard FALSE NODE.security.dataComm.DefaultTCCEthernetIP 10.0.0.1 IP Address NODE.security.dataComm.DefaultTCCEthernetIPNetmask 24 (bits) 8, 9, 10 .. 32 NODE.security.dataComm.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.security.grantPermission.RestoreDB Superuser Provisioning, Superuser NODE.security.grantPermission.RetrieveAuditLog Superuser Provisioning, Superuser NODE.security.idleUserTimeout.Maintenance 01:00 00:00, 00:01, 00:02 .. (hours:mins) 16:39 NODE.security.idleUserTimeout.Provisioning 00:30 00:00, 00:01, 00:02 .. (hours:mins) 16:39 NODE.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.security.other.InactiveDuration 45 (days) 1, 2, 3 .. 99 when DisableInactiveUser TRUE; 45 when DisableInactiveUser FALSE NODE.security.other.SingleSessionPerUser FALSE TRUE, FALSE NODE.security.passwordAging.EnforcePasswordAging FALSE TRUE, FALSE NODE.security.passwordAging.maintenance.AgingPeriod 45 (days) 20 - 90 NODE.security.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.timing.bits-1.AISThreshold DUS G811, STU, G812T, G812L, SETS, DUS NODE.timing.bits-1.Coding HDB3 HDB3, AMI when FacilityType E1; N/A when FacilityType 2MHz; AMI when FacilityType 64kHz+8kHz NODE.timing.bits-1.CodingOut HDB3 HDB3, AMI when FacilityTypeOut E1; N/A when FacilityTypeOut 2MHz; AMI when FacilityTypeOut 6MHz NODE.timing.bits-1.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.timing.bits-1.Sa bit 4 4, 5, 6, 7, 8 when FacilityType E1; N/A when FacilityType 2MHz; N/A when FacilityType 64kHz+8kHz NODE.timing.bits-1.State unlocked unlocked, locked, disabled NODE.timing.bits-1.StateOut unlocked unlocked, locked, disabled NODE.timing.bits-2.AdminSSMIn STU G811, STU, G812T, G812L, SETS, DUS NODE.timing.bits-2.
Appendix C Network Element Defaults C.3.1 Time Zones Table C-16 Node Default Settings (continued) Default Name Default Value Default Domain NODE.timing.bits-2.FramingOut FAS+CAS+ CRC FAS+CRC, FAS+CAS, FAS+CAS+CRC, FAS, Unframed when FacilityTypeOut E1; when FacilityTypeOut 2MHz; FAS+CRC, FAS+CAS, FAS+CAS+CRC, FAS, Unframed, Unframed - 2Mhz when FacilityTypeOut 6MHz NODE.timing.bits-2.Sa bit 4 4, 5, 6, 7, 8 when FacilityType E1; N/A when FacilityType 2MHz; N/A when FacilityType 64kHz+8kHz NODE.
Appendix C Network Element Defaults C.3.
Appendix C Network Element Defaults C.3.1 Time Zones Table C-17 Time Zones (continued) Time Zone (GMT +/– Hours) Default Value GMT+03:00 (GMT+03:00) Aden, Antananarivo, Khartoum, Nairobi GMT+03:00 (GMT+03:00) Baghdad GMT+03:00 (GMT+03:00) Kuwait, Riyadh GMT+03:00 (GMT+03:00) Moscow, St.
Appendix C Network Element Defaults C.
I N D EX Numerics 1+1 optical card protection 12-27 7-1 block diagram description See also STM-N cards card-level LEDs 4-37 compatible SFPs 4-41 faceplate LEDs performance monitoring 2-22 2-21 input/output (external) alarm contacts 4-33 specifications 2-22 external controls 4-35 15-39 2-23 power monitoring 4-38, 1-1 2-24 software compatibility 4-4 specifications A-41 16-19 2-22 2-21 orderwire 4-35 64-bit etherStatsHighCapacityTable 2-3 2-21 external alarms cross-connect com
Index listing all capacities 14-12 listing by node loading 14-12 14-12 modifying 9-7 log entries 9-7 11-19 14-13 14-12 severity options description automatic circuit routing 14-11 row display options saving 9-8 B 14-12 alarms bandwidth change default severities. See alarm profiles allocation and routing create profiles. See alarm profiles cross-connect card traps.
Index coaxial port-level LEDs 1-8, 1-10 routing and management twisted-pair balanced 1-12 1-10 card compatibility electrical cards 11-26 5-21 cross-connect compatibility description 4-3 card mode (FC_MR-4) port-level LEDs card protection 1:0 electrical.
Index secondary circuit source for shared packet ring locations on card 11-2 1-18 miniature coax 11-23 1-18 states 11-7 Molex 96-pin LFH status 11-6 RJ-45 unidirectional SC 11-23 unidirectional with multiple drops user-defined names for 1-19 SC (SFP) 11-2 Cisco Transport Controller. See CTC CLNS 1-18 SC (GBIC) 11-14 1-18 1-19 types on cards corporate LAN 13-32 CMS. See CTC cost coaxial.
Index window documentation 8-7 C-Temp ranges audience A-8 CVCP-PFE parameter definition CVCP-P parameter definition CV-L parameter definition conventions 15-5 v-xxxix objectives 15-5 v-xxxvi organization 15-5 CVP-P parameter definition v-xxxvi v-xxxvi to v-xxxviii related to this book 15-5 v-xxxviii DRI description D 12-18, 12-21 integrated 12-18 integrated (figure) database revert traditional 8-17 storage specifications version 12-18 traditional (figure) A-2 creating mult
Index description faceplate LEDs E1-N-14 card 5-6 block diagram 5-7 cross-connect compatibility 5-8 port status description 5-8 software compatibility specifications faceplate 5-3 LEDs block diagram cross-connect compatibility description LEDs 3-6 port status 5-3 description 5-5 software compatibility E100-TX connector pinout 5-5 faceplate LEDs 3-9 11-17 performance monitoring 3-7 2-3 port status specifications 3-7 performance monitoring 15-14 software compatibility 3-4
Index ENE card performance monitoring description in a proxy server GNE load balancing cards 13-13 5-1 to 5-30 circuits 13-18 provisioning the proxy server proxy tunnel and firewall tunnel requirement remote nodes connected to ENE Ethernet ports 11-22 connector pinout 13-12 13-28 13-29 1-11 cross-connect card compatibility EtherSwitch circuits history RMON group 16-20 settings point-to-point circuits 11-22 enhanced card mode router aggregation 6-4 differential delay features distance
Index external timing setting up 10-1 13-28 FMEC F connectors 1-8 description 1-7 fan-tray air filter. See air filter electrical card assignments fan-tray assembly hardware 1-1 line rates 1-8 overview 1-7 description fan failure 1-14 1-15 fan speed ports 1-15 1-8 far-end block error.
Index specifications port status A-19 temperature range software compatibility A-8 FMEC-E3/DS3 card specifications block diagram description faceplate default block diagram 13-5 13-2 gateway network element. See proxy server GBIC 3-29 card compatibility A-25 13-30 four-fiber MS-SPRing.
Index go-and-return SNCP routing GRE tunnel grounding 11-15 13-42, 13-43 HP-NPJC-Pdet parameter definition 15-6 HP-NPJC-Pgen parameter definition 15-7 HP-PJCDIFF parameter definition 1-16 H HC-RMON-MIB support 16-18 15-7 HP-PJCS-Pdet parameter definition 15-7 HP-PJCS-Pgen parameter definition 15-7 HP-PPJC-Pdet parameter definition 15-7 HP-PPJC-Pgen parameter definition 15-7 HP-SES parameter high-order path background block error background block error ratio errored block definition
Index fixed values IP addressing scenarios CTC and nodes connected to router CTC and nodes on same subnet 13-3 13-3 default gateway on CTC workstation dual GNEs on a subnet OSPF 13-6 proxy server IPC parameter definition 13-20 13-7 13-32 connecting an ONS node to a router 13-45 connecting an ONS node to a router across an OSI DCN 13-47 13-32 1-6, 1-7 LBC-AVG parameter definition 15-7 LBC-MAX parameter definition 15-7 LCAS 11-26 LCD description 1-14 viewing alarm counts on line timing
Index LP-ESR parameter definition 15-8 cross-connect compatibility LP-SES parameter definition 15-8 description LP-SESR parameter definition LP-UAS parameter definition LR 15-8 15-8 faceplate LEDs 5-13 5-14 5-15 port status 4-10 5-15 slot compatibility 5-15 software compatibility M specifications clear table 9-4 proxy ARP 13-5 retrieve table merge circuits card-level LEDs 5-17 compatible SFPs 5-26 description 1-13 port status 11-33 block diagram 5-17 description specifica
Index MS-SES parameter definition E1-42 card 15-10 MS-SESR parameter definition E1-N-14 card 15-10 MS-SPRing E3-12 card bandwidth capacity 12-13 12-18 DRI with opposite-side routing (figure) DRI with same-side routing (figure) fiber configuration example fiber connections 12-20 12-19 C-45 MRC-12 card C-35 node defaults C-46 STM-16 card C-25 STM1-8 card C-17 C-15 STM1E-12 card STM4-4 card 12-10 four-fiber description C-14 STM-1 card 12-12 12-12 five-node, two-fiber C-7, C-8 F
Index address fields description 13-34 4-12 faceplate (figure) 13-33 location in CTC functionality 13-35 manual TID to NSAP provisioning 13-40 network service access points in CLNP TID-to-NSAP translation 13-33 13-37 LEDs 4-13 4-13 4-14 port status 4-14 software compatibility specifications 4-4 A-32 OC192/STM64 Any Reach card O See also STM-N cards OAM&P access See also XFP 8-7 OC12 IR/STM4 SH 1310-4 card card-level LEDs See also STM-N cards compatible XFPs description des
Index functionality LEDs specifications 4-32 OC48 ELR/STM16 EH 100 GHz cards 4-33, 4-37 port status See also STM-N cards 4-33, 4-38 software compatibility specifications topologies A-28 description 4-4 faceplate A-40 4-20 4-21 functionality 4-33 OC192 SR/STM64 IO 1310 card LEDs 4-21 4-22 See also STM-N cards port status description software compatibility faceplate 4-23 LEDs specifications 4-23 functionality A-35 See also STM-N cards description 4-24 software compatibility
Index orderwire PC.
Index connectionless network protocol (CLNP) ES-IS Q 13-36 HDLC IP 13-32 QoS 13-31 13-37 13-1 IS-IS 13-36 LAP-D R 13-32 LCP 13-31 rack size OSI 13-31 RADIUS point-to-point 1-2 security 13-31 Proxy ARP. See Proxy ARP 9-8 shared secrets 9-9 SNMP. See SNMP reconfigure circuits SSM remote network monitoring.
Index path topologies 11-29 protected circuits secondary sources 11-33 restrictions on two-circuit rolls roll cancelled roll pending 11-32 section trace 11-19 11-17 secure mode, IP addressing 11-30 roll completed 12-1 secure shell 11-30 13-20 9-6 security 11-30 single 11-30 see also superuser status 11-30 assign superuser privileges to provisioning users TL1 roll idle user timeout 11-30 two cross-connections unprotected circuits policies 11-30 9-6 9-5 RADIUS 11-33 9-8
Index SES parameter definition basic four-node ring (figure) 15-12 SES-PFE parameter definition 15-12 SES-PM parameter definition SES-P parameter definition 15-12 15-12 SESR-PM parameter definition 15-12 11-14 connecting with MS-SPRing description 15-12 SESP-P parameter definition circuit editing DRI 12-21 go-and-return routing 11-15 15-12 increasing the traffic speed SES-SM parameter definition 15-12 ring with fiber break (figure) STM-1 ring (figure) card compatibility description
Index general card A-6 CTC and nodes on same subnet 13-3 optical card A-28 multiple subnets on the network 13-6 power consumption using static routes A-5 storage access networking card temperature ranges with Proxy ARP A-48 9-6 24-bit 13-25 SSM 10-3 32-bit 13-25 access to nodes B-1 ST3 clock subtending rings STM1E-12 card description block diagram assign superuser privileges to provisioning users 3-13 cross-connect compatibility LEDs 12-25 superuser 3-12 change idle times
Index timers temperature range 13-39 TCA TCP/IP definition See also OSI 15-2 electrical cards that report RX and TX direction IPPM paths 15-2 mediation with OSI protocols 15-3 TCC2 card 13-40 13-31 TCP/IP and OSI networking card-level LEDs card view TDC 2-8 database description 2-6 fan speed control 1-15 13-27 secondary circuit sources 11-2 network-level LEDs 11-34 SNMP external interface 8-1 TIDs 13-26 11-4 timing 2-3 software installation overview 8-4 BITS.
Index two-fiber MS-SPRing. See MS-SPRing circuit sizes Tx AISS-P parameter definition circuit states Tx BBE-P parameter 15-12 11-27 11-25 common fiber routing 15-12 Tx BBER-P parameter definition link capacity adjustment scheme (LCAS) 15-13 Tx EB-P parameter definition 15-13 ML-Series support Tx ES-P parameter definition 15-12 server trail constraints Tx ESR-P parameter definition 15-12 split routing Tx SES-P parameter definition 15-13 views.
Index software compatibility specifications 2-3 A-12 temperature range A-8 XC-VXL-10G card card view 8-15 cross-connect compatibility cross-connect matrix described 2-13, 11-11 faceplate 2-14 functionality LEDs 2-3 2-14 2-15 2-15 software compatibility specifications 2-3 A-11 temperature ranges A-8 XC-VXL-2.
Index Cisco ONS 15454 SDH Reference Manual, R7.
