Path protection

Path protection in telecommunications is an end-to-end protection scheme used in connection oriented circuits in different network architectures to protect against inevitable failures on service providers’ network that might affect the services offered to end customers. Any failure occurred at any point along the path of a circuit will cause the end nodes to move/pick the traffic to/from a new route. Finding paths with protection, especially in elastic optical networks, was considered a difficult problem, but an efficient and optimal algorithm was proposed . Path protection in telecommunications is an end-to-end protection scheme used in connection oriented circuits in different network architectures to protect against inevitable failures on service providers’ network that might affect the services offered to end customers. Any failure occurred at any point along the path of a circuit will cause the end nodes to move/pick the traffic to/from a new route. Finding paths with protection, especially in elastic optical networks, was considered a difficult problem, but an efficient and optimal algorithm was proposed . Other techniques to protect telecommunications networks against failures are: Channel Protection, Link Protection, Segment-Protection, and P-cycle Protection In ring-based networks topology where the setup is to form a closed loop among the Add Drop Multiplexers, there is basically one path related ring protection scheme available in Unidirectional Path-Switched Ring architecture. In SDH networks, the equivalent of UPSR is Sub-Network Connection Protection (SNCP). Note that SNCP does not assume a ring topology, and can also be used in mesh topologies. In UPSR, the data is transmitted in both directions, clock and counter clock wise, at the source ADM. At the destination then, both signals are compared and the best one of the two is selected. If a failure occurs then the destination just needs to switch to the unaffected path. Circuits in optical mesh networks can be unprotected, protected to a single failure, and protected to multiple failures. The end optical switches in protected circuits are in charge of detecting the failure, in some cases requesting digital cross connects or optical cross-connects in intermediate devices, and switching the traffic to/from the backup path. When the primary and backup paths are calculated, it is important that they are at least link diverse so that a single link failure does not affect both of them at the same time. They can also be node diverse, which offers more protection in case a node failure occurs; depending on the network sometimes the primary and backup path cannot be provisioned to be node diverse at the edges, ingress and egress, node. There are two types of path protection in Optical Mesh Networks: Dedicated Backup Path Protection and Shared Backup Path Protection In DBPP, both the primary and backup path carry the traffic end to end, then it is up to the receiver to decide which of the two incoming traffic it is going to pick; this is exactly the same concept as in Ring Based Path Protection. Since the optics along both paths are already active, DBPP is the fastest protection scheme available, usually in the order of a few tens of milliseconds, because there is no signaling involved in between ingress and egress nodes thus only needing the egress node to detect the failure and switch the traffic over to the unaffected path. Being the fastest protection scheme also makes it the most expensive; normally using more than double of the provisioned capacity for the primary because the backup path is usually longer due to the link and/or node diversity rule of thumb. The concept behind this protection scheme is to share a backup channel among different, link/node diverse, primary paths. In other words, one backup channel can be used to protect various primary paths as shown on the figure below where the link between S and T is used to protect both AB and CD primaries. Under normal operations, assuming no failure on the network, the traffic is carried on the primary paths only; the shared backup path is only used when there is a failure in one of those primary paths. There are two approaches to provision or reserve backups channels. First, there is the failure dependent assignment or approach also known as restoration in which the backup path is calculated in real time after the failure occurs. This technique is found in early versions of Mesh networks. However, in today’s Optical Mesh Network it can be used as a re-provisioning technique to help recover a second failure when the backup resources are already in use. The down side to restoration as a protection technique is that the recovery time is not fast enough.