2002
DOI: 10.1109/49.974661
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Design of a meta-mesh of chain subnetworks: enhancing the attractiveness of mesh-restorable WDM networking on low connectivity graphs

Abstract: We have developed a design refinement to increase the capacity efficiency of span-restorable mesh networks on sparse facility graphs. The new approach views the network as a "meta-mesh of chain subnetworks." This makes the prospect of WDM mesh networking more economically viable than with previous mesh-based designs where the average nodal degree is low. The meta-mesh graph is a homeomorphism of the complete network in which edges are either direct spans or chains of degree-2 nodes. The main advantage is that … Show more

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Cited by 33 publications
(21 citation statements)
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“…Although this seems counter-intuitive at first, [14] explains that each bypass creates a specific form of dispersal of the end nodes involved in logical span restoration, resulting in more efficient spare capacity use. This is ultimately the same reason for the reduction of spare capacity obtained with the special forms of chain sub-network bypass considered in the meta-mesh design concept of [9]. But it bears explaining how a dual-span SRLG and a nodal bypass differ because at first glance they can seem to be almost identical arrangements that cause one physical failure to escalate into two logical failures.…”
Section: Outlinementioning
confidence: 95%
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“…Although this seems counter-intuitive at first, [14] explains that each bypass creates a specific form of dispersal of the end nodes involved in logical span restoration, resulting in more efficient spare capacity use. This is ultimately the same reason for the reduction of spare capacity obtained with the special forms of chain sub-network bypass considered in the meta-mesh design concept of [9]. But it bears explaining how a dual-span SRLG and a nodal bypass differ because at first glance they can seem to be almost identical arrangements that cause one physical failure to escalate into two logical failures.…”
Section: Outlinementioning
confidence: 95%
“…Pre-processing steps to enumerate the sets of eligible restoration routes are discussed in Section 3. A variation on the SCA model for span-restorable network design is joint capacity assignment (JCA), where working routes and capacity are jointly designed optimally with restoration routing and spare capacity [8,9]. This study is, however, based solely on non-joint models for capacity planning in which all demands are first shortest-path routed before solving optimally for the spare capacity assignment.…”
Section: Basic Span-restorable Spare Capacity Design Modelmentioning
confidence: 99%
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“…In work on sparser topologies we have seen threshold hop limits of up to 12, although this is almost always a result of many degree-two nodes in chain-like subnetworks. (In the meta-mesh abstraction [10] of those networks, the effective threshold hop limit can more often be expected to again be in the five to seven hop range, say.) Advantages to restricting the hop limit as much as possible in survivable design are numerous and obvious and include increased availability (fewer network elements involved in restoration), reduced regenerator cost associated with protection paths, and depending on signalling protocols, possibly increased restoration speed from fewer nodes having to react.…”
Section: Path Length Issues In Survivable Network Designsmentioning
confidence: 99%
“…Equations (7), (8), and (9) ensure that the number of copies of p-cycle p in the solution is the maximum of the number forced by any single span failure. Equations (10) and (11) are "backup" constraints to ensure that, if cycle p is not eligible to restore span i using either the L or R side, then it will not be considered for protection of that span. While not strictly required, (10) and (11) are "added valid knowledge" constraints that provide extra information and may thus hasten the solution process.…”
Section: P-cycle Model With Direct Path Length Constraintsmentioning
confidence: 99%