Cited By
View all- Faenza YSegev DZhang L(2022)Approximation algorithms for the generalized incremental knapsack problemMathematical Programming: Series A and B10.1007/s10107-021-01755-7198:1(27-83)Online publication date: 30-Jan-2022
A Mazing 2+ε Approximation for Unsplittable Flow on a Path
Authors: 
Aris Anagnostopoulos, Fabrizio Grandoni, 
Stefano Leonardi, Andreas WieseAuthors Info & Claims
Aris Anagnostopoulos, Fabrizio Grandoni, Stefano Leonardi, Andreas WieseAuthors Info & ClaimsArticle No.: 55, Pages 1 - 23
Abstract
We study the problem of unsplittable flow on a path (UFP), which arises naturally in many applications such as bandwidth allocation, job scheduling, and caching. Here we are given a path with nonnegative edge capacities and a set of tasks, which are characterized by a subpath, a demand, and a profit. The goal is to find the most profitable subset of tasks whose total demand does not violate the edge capacities. Not surprisingly, this problem has received a lot of attention in the research community.
If the demand of each task is at most a small-enough fraction δ of the capacity along its subpath (δ-small tasks), then it has been known for a long time [Chekuri et al., ICALP 2003] how to compute a solution of value arbitrarily close to the optimum via LP rounding. However, much remains unknown for the complementary case, that is, when the demand of each task is at least some fraction δ > 0 of the smallest capacity of its subpath (δ-large tasks). For this setting, a constant factor approximation is known, improving on an earlier logarithmic approximation [Bonsma et al., FOCS 2011].
In this article, we present a polynomial-time approximation scheme (PTAS) for δ-large tasks, for any constant δ > 0. Key to this result is a complex geometrically inspired dynamic program. Each task is represented as a segment underneath the capacity curve, and we identify a proper maze-like structure so that each corridor of the maze is crossed by only O(1) tasks in the optimal solution. The maze has a tree topology, which guides our dynamic program. Our result implies a 2+ε approximation for UFP, for any constant ε > 0, improving on the previously best 7+ε approximation by Bonsma et al. We remark that our improved approximation algorithm matches the best known approximation ratio for the considerably easier special case of uniform edge capacities.
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Index Terms
- A Mazing 2+ε Approximation for Unsplittable Flow on a Path
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Publication History
Published: 17 September 2018
Accepted: 01 July 2018
Revised: 01 April 2018
Received: 01 May 2017
Published in TALG Volume 14, Issue 4
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View all- Faenza YSegev DZhang L(2022)Approximation algorithms for the generalized incremental knapsack problemMathematical Programming: Series A and B10.1007/s10107-021-01755-7198:1(27-83)Online publication date: 30-Jan-2022
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