MPLS local protection

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In MPLS Fast Reroute (also called MPLS local restoration or MPLS local protection) is a local restoration network resiliency mechanism. It is actually a feature of RSVP Traffic Engineering (RSVP-TE). In MPLS local protection each LSP passing through a facility [1] is protected by a backup path which originates at the node immediately upstream to that facility. [2] [3][4] [5] [6]

This node redirects the traffic onto preset backup path, is called the Point of Local Repair (PLR) and the node where backup LSP merges with primary LSP is called Merge Point (MP)[2][3]. This mechanism (local protection) provides faster recovery because the decision of recovery is strictly local. For comparison, when recovery mechanisms are employed at the IP layer, restoration may take several seconds which is unacceptable for real-time applications (such as VoIP). In contrast, MPLS local protection meets the requirements of real-time applications with recovery times comparable to those of SONET rings. [2][3][4]

Contents

[edit] Local protection approches

There are two distinct approaches to local protection: (1) one-to-one local protection (detour) (2) many-to-one local protection (facility backup). [2][3]

[edit] One-to-one local protection

In one-to-one backup approach, the PLRs maintain separate backup paths for each LSP passing through a facility. The backup path terminates by merging back with the primary path at a node called the Merge Point (MP). In one-to-one backup approach, the MP can be any node downstream from the protected facility. Maintaining state information for backup paths protecting individual LSPs, as in the one-to-one approach, is a significant resource burden for the PLR. Moreover, periodic refresh messages[7] sent by the PLR, in order to maintain each backup path, may become a network bottleneck.

[edit] Many-to-one local protection

In many-to-one approach, a PLR maintains a single backup path to protect a set of primary LSPs traversing the triplet (PLR, facility, MP). Thus, fewer states need to be maintained and refreshed which results in a scalable solution. The many-to-one backup approach is also called facility backup. Note that in this approach, the MP should be the node immediately downstream to the facility.

[edit] Example

Fig.1 Fast Reroute operation
Fig.1 Fast Reroute operation

In Fig.1 (right), there is a primary path (LSP-Label Switched Path) from A to E via B and D. The traffic of customers connected to A and E will take this path in the normal operation. There is also a secondary path (LSP) from A to E via C. This path can be either pre-signaled or not. For the primary LSP, FRR (Fast ReRoute) is enabled. Once enabled, the other network elements on the LSP will know that FRR is enabled. Let's assume there is a break between D and E. D will immediately know this and it will inform B and A. For A to know that there is a failure between D and E, it takes a while. Since D gets to know immediately about the failure and FRR is enabled on the LSP, it uses the detour path D-C-E to get rid of the failure immediately and traffic will continue to flow along that path. This takes less than 50ms. Once the secondary LSP is up, traffic is switched to the secondary LSP and detour path is no more.

[edit] Local protection fault-models

An illustration of MPLS local protection Faults Modes. Note that complete network is not shown only primary and backup paths are shown. Furthermore, nodes traversed by a backup path are not shown.
An illustration of MPLS local protection Faults Modes. Note that complete network is not shown only primary and backup paths are shown. Furthermore, nodes traversed by a backup path are not shown.

[edit] Link protection

In a link protection model each link (or subset links) used by an LSP is provided protection by pre-established [8] backup paths.

[edit] Node protection

In a node protection model each node (or subset of nodes) used by an LSP is provided protection by pre-established backup paths.

[edit] Element protection

In an element protection model provide protection against the failure of link as well as nodes along the LSP.

[edit] References

  1. ^ The term facility is usually refer to a link or node
  2. ^ a b c d Aslam et al. (2005-02-02). "NPP: A Facility Based Computation Framework for Restoration Routing Using Aggregate Link Usage Information". QoS-IP 2005 : quality of service in multiservice IP network. Retrieved on 2006-10-27.
  3. ^ a b c d Raza et al.. "Online routing of bandwidth guaranteed paths with local restoration using optimized aggregate usage information". IEEE-ICC 2005. Retrieved on 2006-10-27.
  4. ^ a b Li Li et al.. "Routing bandwidth guaranteed paths with local restoration in label switched networks". 
  5. ^ Pan et al.. "Fast Reroute Extensions to RSVP-TE for LSP Tunnels networks". RFC-4090. Retrieved on 2006-10-27.
  6. ^ Kodialam et al.. "Dynamic Routing of Locally Restorable Bandwidth Guaranteed Tunnels using Aggregated Link Usage Information". IEEE Infocom. pp. 376–385. 2001. Retrieved on 2006-10-27.
  7. ^ Local protection primarily uses RSVP-TE extensions, which is a soft-state protocol and requires periodic refresh messages to maintain its states.
  8. ^ backup paths are establish before the failure