Abstract: In a network having working and protection paths, extra traffic is put on the protection paths when they are not being used by working traffic. In the event of a fault in a working path, the working traffic is switched to a respective protection path using a span switch operation. The extra traffic is displaced, but at least some of it is protected by switching it to an alternative path using a ring switch operation.

Abstract: The working fibre and protection fibre between pairs of nodes are shared between adjacent rings in a network, such that working traffic on the working fibre between the pair of nodes can be protected by the ring architecture of either of adjacent rings. A network management system routes signals across the network and dictates which rings within the network provide protection for the signal route. The ring structure enables protection for signal traffic on a ring to be protected by the ring protocols, providing rapid protection switching. It is also possible to select the location of protection bandwidth for a signal path across the network. In this way, protection bandwidth is shares and can also be configured to optimise the use of the total available protection bandwidth.

Abstract: An important feature of communications networks is resilience in the event of failure. Conventional ring-configured networks use 100% bandwidth over provisioning so that in the event of failure of a fiber, a span which may be used to use the spare capacity on the same span and in the event of a total failure in a particular span of both working and protection capacity, it is possible to ring switch the data around the far side of the ring in order to provide total protection. However, 100% over provisioning of bandwidth in the network is expensive. By using up to half the protection bandwidth for working date and using span and ring switching together, it is possible to use some of the bandwidth capacity on the protection path and still retain a robust network configuration.

Abstract: A method of restoring data transport following a network resource failure in a communication network includes searching for protection bandwidth in a data transport ring where the transport resource failure occurred, and the search is extended to protection bandwidth on adjacent data transport rings, as required, until protection bandwidth for restoring data transport are located or all adjacent rings have been searched. Thus the ratio of working:protection bandwidth is improved by elimination of protection bandwidth between matched pair nodes interconnecting adjoining BLSRs of the network. However, high reliability which is characteristic of a BLSR network is preserved by providing a recovery algorithm that promptly allocates protection bandwidth of one or more rings, as required, in order to circumvent a failed network resource.

Abstract: A method and apparatus for redirecting data communications traffic in a mesh network via an alternate path. When operating in a SONET environment, the method makes use of bi-directional line switching ring (BLSR) principles in addition to a dynamically invoked flexible ring formation mechanism. The network comprises a plurality of computing nodes, where the plurality of computing node are interconnected to one another by a plurality of communication links and exchange traffic with one another over the communication links. The method includes detecting a failure on a certain communication link, the certain communication link interconnecting a first computing node and a second computing node. Upon detecting a failure on the certain communication link, at least one ring protection path is generated between the first computing node and the second computing node, where the ring protection path excludes the certain communication link.