High Availability Overview
Cisco High Availability (HA) enables network-wide protection by providing fast recovery from faults that may occur in any part of the network. With Cisco High Availability, network hardware and software work together and enable rapid recovery from disruptions to ensure fault transparency to users and network applications.
The unique hardware and software architecture of the Cisco ASR 903 Series Router is designed to maximize router uptime during any network event, and thereby provide maximum uptime and resilience within any network scenario.
This chapter covers the aspects of High Availability that are unique to the Cisco ASR 903 Series Router. It is not intended as a comprehensive guide to High Availability, nor is it intended to provide information on High Availability features that are available on other Cisco routers that are configured and implemented identically on the Cisco ASR 903 Series Router. The Cisco IOS feature documents and guides should be used in conjunction with this chapter to gather information about High Availability-related features that are available on multiple Cisco platforms and work identically on the Cisco ASR 903 Series Router.
This section discusses various aspects of High Availability on the Cisco ASR 903 Series Router and contains the following sections:
Hardware Redundancy Overview
The Cisco ASR 903 Series Router supports redundant Route Switch Processors (RSPs) and power supplies. Redundancy is not supported on interface modules.
Note Some interface modules require a reload during a software upgrade, briefly interrupting traffic.
Hardware redundancy provides the following benefits:
A failover option—If a processor fails, the standby processor immediately becomes the active processor with little or no delay. The failover happens completely within the same router, so a second standby router is not needed.
No downtime upgrades—Using features like ISSU, a software upgrade can be handled on the standby processor while the active processor continues normal operation.
provides a hardware redundancy overview.
Table 4-1 Hardware Redundancy Overview
Support for Dual Hardware Configuration
Route Switch Processor
If an active RSP experiences an event that makes it unable to forward traffic (such as a hardware failure, a software failure, an OIR, or a manual switch) and a standby RSP is configured, the standby RSP immediately becomes the active RSP.
No standby configurations are available for interface modules. If an interface module fails, it cannot forward traffic.
In the event of an interface module shutdown, all other interface modules remain fully operational.
The Stateful Switchover (SSO) feature takes advantage of processor redundancy by establishing one of the processors as the active processor while the other RSP is designated as the standby processor, and then synchronizing critical state information between them. Following an initial synchronization between the two processors, SSO dynamically maintains RSP state information between the dual processors.
Stateful Switchover is particularly useful in conjunction with Nonstop Forwarding. SSO allows the dual processors to maintain state at all times, and Nonstop Forwarding lets a switchover happen seamlessly when a switchover occurs.
It is important to note that in most cases, SSO requires less downtime for switchover and upgrades than RPR. RPR should only be used when there is a compelling reason to not use SSO.
For additional information on NSF/SSO, see the
Cisco Nonstop Forwarding
SSO-Aware Protocol and Applications
SSO-supported line protocols and applications must be SSO-aware. A feature or protocol is SSO-aware if it maintains, either partially or completely, undisturbed operation through an RSP switchover. State information for SSO-aware protocols and applications is synchronized from active to standby to achieve stateful switchover for those protocols and applications.
The dynamically created state of SSO-unaware protocols and applications is lost on switchover and must be reinitialized and restarted on switchover.
To see which protocols are SSO-aware on your router, use the
show redundancy client
show redundancy history
Bidirectional Forwarding Detection
Bidirectional Forwarding Detection (BFD) is a detection protocol designed to provide fast forwarding path failure detection times for all media types, encapsulations, topologies, and routing protocols. In addition to fast forwarding path failure detection, BFD provides a consistent failure detection method for network administrators. Because the network administrator can use BFD to detect forwarding path failures at a uniform rate rather than the variable rates for different routing protocol hello mechanisms, network profiling and planning is easier, and reconvergence time is consistent and predictable.
For more information on BFD, see the
IP Routing BFD Configuration Guide, Cisco IOS XE Release 3S.