The Cisco® Carrier Packet Transport System (CPT) 200 and 600 sets the industry benchmark as a carrier-class converged access and aggregation platform for integrated packet transport architectures. Cisco CPT product family offers exceptional pay as you grow scalability, carrier-class reliability, incredible flexibility, and TDM like ease of packet service provisioning, OAM and protection capability.
The Cisco CPT 200 and 600 Packet Transport Module (PTM) Line Card is a 40G line rate packet that delivers economical, scalable, highly available, and Packet Transport services through a unified Multiprotocol Label Switching (MPLS) network layer. In addition, the PTM delivers four 10-Gigabit Ethernet ports that can be used for User-to-Network Interfaces (UNI), Network-to-Network Interfaces (NNI), and enables extension of GE interfaces through the CPT 50 satellite architecture. The PTM enables Cisco CPT 200 and 600 provide a robust MPLS-Transport Profile (TP) infrastructure to deliver scalable Private Line, Business, Residential, Mobile Backhaul, Data Center, and Video Services (Figure 1).
Figure 1. Cisco CPT Packet Transport Module (PTM) Line Card
Features and Benefits
Cisco CPT 200 and 600 PTM offers:
• 40 Gbps of line-rate fully redundant switching fabric
• Distributed forwarding and control planes for higher performance
• Modularized system components in both hardware and software, isolating failure and faults to subsystem and component
• Hardware-based signaling for the fabric: support for near zero packet loss on switchover
• Built-in redundancy in hardware components such as the control-plane chassis control bus, and power supplies, thereby avoiding a single point of failure
• 4 port of 10 Gbps Ethernet Interfaces that operate as UNI, NNI, and Satellite architecture extension
With integrated synchronization circuitry and dedicated backplane timing traces for accessing the shelf controllers Stratum-3 subsystem, the CPT 200 and 600 PTM Line Card provides standards-based line-interface functions for delivering and deriving transport-class network timing, enabling support of network-synchronized services and applications such as mobile backhaul and migration of TDM services.
Pluggable SFP+ Interfaces
SFP+ interfaces provide mix/match interface types across a single line card. For a complete list of supported interfaces, please see the Cisco CPT pluggable configuration guide.
Scalable and Integrated Multiservice Support
Layer 2 Transport
Carrier Ethernet, MPLS-Transport Profile (TP) and IP/MPLS-(TE)
Layer 2 and Layer 2+ services
Carrier Ethernet - EPL, EVPL, ELAN, EVPLAN
MPLS-TP - P2P Circuits (VPWS), Multipoint (VPLS), Hierarchy Multipoint (H-VPLS), Ring VPLS (Optimized for Video Broadcast applications)
IP/MPLS(TE) - P2P Circuits (VPWS), Multipoint (VPLS), Hierarchy Multipoint (H-VPLS), Ring VPLS (Optimized for Video Broadcast applications)
Point to Point Ethernet Virtual Circuit (EVC)
Point to Multi-Point Ethernet Virtual Circuit (EVC)
4K with 8K members
MPLS-TP LSP Un-Protected
MPLS-TP LSP Protected
8K Policers 2-rate 3-color (2R3C)
64K Queues (3-level H-QoS)
ITU Y.1731 (FM)
Same as CFM
ITU Y.1731 (DM)
# of Sessions
# of Sessions
High Availability features
Stateful Switchover (SSO)
In Service Software Upgrade (ISSU)
MPLS-TP 1:1 path protection
Link Aggregation (LAG)
Resilient Ethernet Protocol (REP)
IGMP snooping v1, v2, and v3
Multicast VLAN registration (MVR)
Table 2. Product Specifications
Carrier-class Operations, Administration, and Maintenance (OA&M)
Derive and provide synchronization from BITS and Ethernets interfaces on CPT 200 and 600
IEEE 1588v2 PTP
Derive, Provide, and Transparently passes timing and frequency information on all CPT 200 and 600 Ethernet interfaces
Product Functionality, Benefits and Specifications
• Cisco Transport Controller: End-to-End Network Point and Click Provisioning, Maintenance, & Alarm Correlation.
• Integrated Robust Command Line Interface (CLI)
MPLS-Transport Profile (TP)
• IETF Standard Based MPLS-Transport Profile:
• RFC 5317
• RFC 5654
• RFC 5921
• RFC 5880
• RFC 5960
• RFC 5586
• RFC 5951
• RFC 5950
Flexible Ethernet services
• Ethernet Virtual Connections (EVCs): Ethernet services are supported using individual EVCs to carry traffic belonging to a specific service type or end user through the network. EVC-based services can be used in conjunction with MPLS-based L2VPNs and native Ethernet switching deployments.
• Flexible VLAN classification: VLAN classification into Ethernet flow points (EFPs) includes single-tagged VLANs, double-tagged VLANs (QinQ and 802.1ad), contiguous VLAN ranges, and noncontiguous VLAN lists.
• IEEE Bridging: The line cards support native bridging based on IEEE 802.1Q, IEEE 802.1ad, and QinQ VLAN encapsulation mechanisms.
• Resilient Ethernet protocol (REP): The REP provides a resilient, fast-convergence mechanism for aggregating and connecting to Ethernet-based access rings.
• MPLS-TP Circuit with Ethernet over MPLS-TP (EoMPLS-TP): EoMPLS-TP transports Ethernet frames across an MPLS-TP LSPs using pseudowires. Individual EFPs or traffic from an entire port can be transported over an MPLS-TP network using pseudowires to an egress interface or sub-interface.
• Virtual Private LAN Services (VPLS): These services are included in a class of VPN that supports the connection of multiple sites in a single bridged domain over a MPLS-TP network. VPLS presents an Ethernet interface to customers, simplifying the LAN and WAN boundary for service providers and customers, and enabling rapid and flexible service provisioning, because the service bandwidth is not tied to the physical interface. All services in a VPLS appear to be on the same LAN, regardless of location.
• Pseudowire redundancy: Pseudowire redundancy supports the definition of a backup pseudowire to protect a primary pseudowire in case of failure.
• Multi-segment pseudowire stitching: Multi-segment pseudowire stitching is a method for interworking two pseudowires together to form a cross-connect relationship.
Span is a technique of replicating the ingress or egress frames in a specific port to a specified list of destination ports. It is a monitoring feature used to monitor the traffic that is coming out of a port or an EFP. The monitored traffic can be used to debug the network and can also be used by law enforcement agencies.
• MPLS-TP: 1:1 MPLS TP LSP delivers protection switching for networks with sub-50ms APS switching for link, node, path failures.
• Bidirectional Forwarding Detection (BFD): BFD is a detection protocol that is designed to provide fast forwarding path-failure detection times for all media types, encapsulations, topologies, and routing protocols
• 802.3ad Link Aggregation Bundles: The line cards support a bundle of multiple links to provide added resiliency and the ability to load balance traffic over multiple member links.
• IGMP v2 and v3 snooping: This Layer 2 mechanism efficiently tracks multicast membership on an L2VPN network. Individual IGMP joins are snooped at the VLAN level or pseudowire level. In residential broadband deployments, this scenario enables the network to send only channels that are being watched to downstream users.
• Multicast VLAN Registration (MVR): MVR optimizes the control plane (IGMP) load between the router and switch. MVR feature enables switch to aggregate different JOINs received on different VLANs (from the receivers) into one JOIN (on a single VLAN, which could be the same as or different from the VLANs of the receiving ports) towards the router. The switch then distributes (replicate) the received content into the relevant ports.
• Connectivity Fault Management (CFM) Ethernet layer OAM protocol provides end-to-end provider edge (PE to PE) and/or customer edge to customer edge (CE to CE) fault management. CFM includes proactive connectivity monitoring, fault verification, and fault isolation for large Ethernet metropolitan-area networks (MANs) and WANs. CFM is defined by IEEE 802.1ag standard.
• Ethernet Link OAM is a protocol for installing, monitoring, and troubleshooting Ethernet metropolitan-area networks (MANs) and Ethernet WANs. It relies on an optional sublayer in the data link layer of the Open Systems Interconnection (OSI) model. Ethernet Link OAM is defined by IEEE 802.3ah standard.
• Remote Ethernet Port Shutdown. The Remote Ethernet Port Shutdown replicates a local link failure over an EoMPLS pseudowire to a remote link shutdown the remote Ethernet port down. Bot UNI interfaces connected to the EoMPLS pseudowire will shutdown in the event of a pseudowire failure.
• ITU Y.1731 Fault Management and Delay Management. The ITU-T Y.1731 feature provides OAM functions for fault management and performance monitoring functionality for service providers in a large network. ITY Y.1731 includes Ethernet Alarm Indication Signal (ETH-AIS), Ethernet Remote Defect Indication (ETH-RDI), Ethernet Locked Signal (ETH-LCK) functionality for fault detection and isolation. ITU Y.1731 Delay Management (DM) provides a standard Ethernet PM function that includes measurement of Ethernet frame delay and frame delay variation.
• IP/MPLS OA&M: LSP Ping & LSP Trace Route
• Pseudo-Wire: Virtual Circuit Connectivity Verification (VCCV), Ping, Traceroute, Static Status Message to LDP Status Message Translation
• MPLS-TP OA&M: GACH/GAL and MPLS-TP LSP BFD OAM
4x10-Gbps 802.3 Ethernet SFP+ Ports
2 GB DRAM
Environmental and Compliance Standardization
(H x W x D); Weight
13.035 x 0.975 x 10.085 in., 2.30 pounds (US)
513.1990 x 2.4765 x 25.6159 cm, 1.04 kg
Max Power 128 Watts
Nominal Power 89 Watts
Network Equipment Building Standards (NEBS)
GR-1089 Issue 5, GR-63 Issue 3
Operating temperature (nominal)
50°C to 55°C
Operating humidity (nominal) (relative humidity)
5-85% noncondensing, operation is guaranteed up to 95% noncondensing
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For More Information
For more information about the Cisco CPT Packet Transport Module (PTM), contact your local account representative or visit Cisco at: www.cisco.com/go/CPT.