TY - JOUR
T1 - 2-node-connectivity network design
AU - Nutov, Zeev
N1 - Publisher Copyright:
© 2023 Elsevier B.V.
PY - 2024/3/1
Y1 - 2024/3/1
N2 - We consider 2-connectivity network design problems in which we are given a graph and seek a min-size 2-connected subgraph that satisfies a prescribed property. • In the 1-CONNECTIVITY AUGMENTATION problem the goal is to augment a connected graph by a minimum size edge subset of a specified edge set such that the augmented graph is 2-connected. We breach the natural approximation ratio 2 for this problem, and also for the more general CROSSING FAMILY COVER problem. • In the 2-CONNECTED DOMINATING SET problem, we seek a minimum size 2-connected subgraph that dominates all nodes. We give the first non-trivial approximation algorithm with expected approximation ratio O(σ(n)⋅log3n), where σ(n)=O(logn⋅loglogn⋅(logloglogn)3). The unifying technique of both results is a reduction to the SUBSET STEINER CONNECTED DOMINATING SET problem. Such a reduction was known for edge-connectivity, and we extend it to 2-node connectivity problems. We show that the same method can be used to obtain easily polylogarithmic approximation ratios that are not too far from the best known ones for several other problems.
AB - We consider 2-connectivity network design problems in which we are given a graph and seek a min-size 2-connected subgraph that satisfies a prescribed property. • In the 1-CONNECTIVITY AUGMENTATION problem the goal is to augment a connected graph by a minimum size edge subset of a specified edge set such that the augmented graph is 2-connected. We breach the natural approximation ratio 2 for this problem, and also for the more general CROSSING FAMILY COVER problem. • In the 2-CONNECTED DOMINATING SET problem, we seek a minimum size 2-connected subgraph that dominates all nodes. We give the first non-trivial approximation algorithm with expected approximation ratio O(σ(n)⋅log3n), where σ(n)=O(logn⋅loglogn⋅(logloglogn)3). The unifying technique of both results is a reduction to the SUBSET STEINER CONNECTED DOMINATING SET problem. Such a reduction was known for edge-connectivity, and we extend it to 2-node connectivity problems. We show that the same method can be used to obtain easily polylogarithmic approximation ratios that are not too far from the best known ones for several other problems.
KW - 2-connectivity
KW - Approximation algorithm
KW - Dominating set
KW - Symmetric crossing family
UR - http://www.scopus.com/inward/record.url?scp=85181066497&partnerID=8YFLogxK
U2 - 10.1016/j.tcs.2023.114367
DO - 10.1016/j.tcs.2023.114367
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AN - SCOPUS:85181066497
SN - 0304-3975
VL - 987
JO - Theoretical Computer Science
JF - Theoretical Computer Science
M1 - 114367
ER -