Finding Best Swap Edges Minimizing the Routing Cost of a Spanning Tree

Given an n -node, undirected and 2-edge-connected graph G =( V , E ) with positive real weights on its m edges, given a set of k source nodes S ⊆ V , and given a spanning tree T of G , the routing cost from S of T is the sum of the distances in T from every source s ∈ S to all the other nodes of G ....

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Bibliographic Details
Published in:Algorithmica Vol. 68; no. 2; pp. 337 - 357
Main Authors: Bilò, Davide, Gualà, Luciano, Proietti, Guido
Format: Journal Article
Language:English
Published: Boston Springer US 01.02.2014
Springer
Subjects:
Access methods and protocols, osi model
Algorithm Analysis and Problem Complexity
Algorithmics. Computability. Computer arithmetics
Algorithms
Applied sciences
Computer Science
Computer science; control theory; systems
Computer Systems Organization and Communication Networks
Data Structures and Information Theory
Exact sciences and technology
Information retrieval. Graph
Mathematics of Computing
Telecommunications
Telecommunications and information theory
Teleprocessing networks. Isdn
Theoretical computing
Theory of Computation
All-best swap edges problems
Transient edge failures
Graph algorithms
Minimum routing-cost spanning tree
Transient response
Edge(graph)
Connected graph
Routing
Linear time
Replacement
Graph theory
Modeling
Fault tolerance
Graph connectivity
Spanning tree
Center of mass
Subgraph
ISSN:0178-4617, 1432-0541
Online Access:Get full text
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Summary:Given an n -node, undirected and 2-edge-connected graph G =( V , E ) with positive real weights on its m edges, given a set of k source nodes S ⊆ V , and given a spanning tree T of G , the routing cost from S of T is the sum of the distances in T from every source s ∈ S to all the other nodes of G . If an edge e of T undergoes a transient failure, and one needs to promptly reestablish the connectivity, then to reduce set-up and rerouting costs it makes sense to temporarily replace e by means of a swap edge , i.e., an edge in G reconnecting the two subtrees of T induced by the removal of e . Then, a best swap edge for e is a swap edge which minimizes the routing cost from S of the tree obtained after the swapping. As a natural extension, the all-best swap edges problem is that of finding a best swap edge for every edge of T , and this has been recently solved in O ( mn ) time and linear space. In this paper, we focus our attention on the relevant cases in which k = O (1) and k = n , which model realistic communication paradigms. For these cases, we improve the above result by presenting an time and linear space algorithm. Moreover, for the case k = n , we also provide an accurate analysis showing that the obtained swap tree is effective in terms of routing cost. Indeed, if the input tree T has a routing cost from V which is a constant-factor away from that of a minimum routing-cost spanning tree (whose computation is a problem known to be in APX), and if in addition nodes in T enjoys a suitable distance stretching property from a tree centroid (which can be constructively induced, as we show), then the tree obtained after the swapping has a routing cost from V which is still a constant-ratio approximation of that of a new (i.e., in the graph deprived of the failed edge) minimum routing-cost spanning tree.
ISSN:0178-4617
1432-0541
DOI:10.1007/s00453-012-9674-y