Approximation algorithm for Directed Multicuts

Yana Kortsarts; Guy Kortsarz; Zeev Nutov

doi:10.1007/978-3-540-31833-0_7

Approximation algorithm for Directed Multicuts

Yana Kortsarts, Guy Kortsarz, Zeev Nutov

מדעי המחשב

פרסום מחקרי: פרסום בכתב עת › מאמר מכנס › ביקורת עמיתים

תקציר

The Directed Multicut (DM) problem is: given a simple directed graph G = (V, E) with positive capacities u_e on the edges, and a set K ⊆ V × V of ordered pairs of nodes of G, find a minimum capacity K-multicut; C ⊆ E is a K-multicut if in G-C there is no (s, t)-path for every (s, t) ∈ K. In the uncapacitated case (UDM) the goal is to find a minimum size K-multicut. The best approximation ratio known for DM is min{O(√n),opt} by Anupam Gupta [5], where n = |V|, and opt is the optimal solution value. All known non-trivial approximation algorithms for the problem solve large linear programs. We give the first combinatorial approximation algorithms for the problem. Our main result is a Ō(n^2/3/opt^1/3)- approximation algorithm for UDM, which improves the √n-approximation for opt = Ω(n^1/2+ε). Combined with the paper of Gupta [5], we get that UDM can be approximated within better than O(√n), unless opt = Θ̃(√n). We also give a simple and fast O(n^2/3)- approximation algorithm for DM.

שפה מקורית	אנגלית
עמודים (מ-עד)	61-67
מספר עמודים	7
כתב עת	Lecture Notes in Computer Science
כרך	3351
מזהי עצם דיגיטלי (DOIs)	https://doi.org/10.1007/978-3-540-31833-0_7
סטטוס פרסום	פורסם - 2005
אירוע	Second International Workshop on Approximation and Online Algorithms, WAOA 2004 - Bergen, נורווגיה משך הזמן: 14 ספט׳ 2004 → 16 ספט׳ 2004

גישה למסמך

10.1007/978-3-540-31833-0_7

קבצים וקישורים אחרים

Link to publication in Scopus

פורמט ציטוט ביבליוגרפי

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abstract = "The Directed Multicut (DM) problem is: given a simple directed graph G = (V, E) with positive capacities ue on the edges, and a set K ⊆ V × V of ordered pairs of nodes of G, find a minimum capacity K-multicut; C ⊆ E is a K-multicut if in G-C there is no (s, t)-path for every (s, t) ∈ K. In the uncapacitated case (UDM) the goal is to find a minimum size K-multicut. The best approximation ratio known for DM is min{O(√n),opt} by Anupam Gupta [5], where n = |V|, and opt is the optimal solution value. All known non-trivial approximation algorithms for the problem solve large linear programs. We give the first combinatorial approximation algorithms for the problem. Our main result is a Ō(n2/3/opt1/3)- approximation algorithm for UDM, which improves the √n-approximation for opt = Ω(n1/2+ε). Combined with the paper of Gupta [5], we get that UDM can be approximated within better than O(√n), unless opt = {\~Θ}(√n). We also give a simple and fast O(n2/3)- approximation algorithm for DM.",

author = "Yana Kortsarts and Guy Kortsarz and Zeev Nutov",

note = "Copyright: Copyright 2020 Elsevier B.V., All rights reserved.; Second International Workshop on Approximation and Online Algorithms, WAOA 2004 ; Conference date: 14-09-2004 Through 16-09-2004",

year = "2005",

doi = "10.1007/978-3-540-31833-0_7",

language = "אנגלית",

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pages = "61--67",

journal = "Lecture Notes in Computer Science",

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AU - Kortsarts, Yana

AU - Kortsarz, Guy

AU - Nutov, Zeev

PY - 2005

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AB - The Directed Multicut (DM) problem is: given a simple directed graph G = (V, E) with positive capacities ue on the edges, and a set K ⊆ V × V of ordered pairs of nodes of G, find a minimum capacity K-multicut; C ⊆ E is a K-multicut if in G-C there is no (s, t)-path for every (s, t) ∈ K. In the uncapacitated case (UDM) the goal is to find a minimum size K-multicut. The best approximation ratio known for DM is min{O(√n),opt} by Anupam Gupta [5], where n = |V|, and opt is the optimal solution value. All known non-trivial approximation algorithms for the problem solve large linear programs. We give the first combinatorial approximation algorithms for the problem. Our main result is a Ō(n2/3/opt1/3)- approximation algorithm for UDM, which improves the √n-approximation for opt = Ω(n1/2+ε). Combined with the paper of Gupta [5], we get that UDM can be approximated within better than O(√n), unless opt = Θ̃(√n). We also give a simple and fast O(n2/3)- approximation algorithm for DM.

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Approximation algorithm for Directed Multicuts

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