A generalized approximation framework for fractional network flow and packing problems

We generalize the fractional packing framework of Garg and Koenemann (SIAM J Comput 37(2):630–652, 2007 ) to the case of linear fractional packing problems over polyhedral cones. More precisely, we provide approximation algorithms for problems of the form  max { c T x : A x ≤ b , x ∈ C } , where the...

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Bibliographic Details
Published in:Mathematical methods of operations research (Heidelberg, Germany) Germany), 2018-02, Vol.87 (1), p.19-50
Main Authors: Holzhauser, Michael, Krumke, Sven O.
Format: Article
Language:English
Subjects:
Algorithms
Approximation
Business and Management
Calculus of Variations and Optimal Control
Optimization
Cones
Functions (mathematics)
Mathematical analysis
Mathematics
Mathematics and Statistics
Operations research
Operations Research/Decision Theory
Original Article
Packing problem
Topological manifolds
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Summary:We generalize the fractional packing framework of Garg and Koenemann (SIAM J Comput 37(2):630–652, 2007 ) to the case of linear fractional packing problems over polyhedral cones. More precisely, we provide approximation algorithms for problems of the form  max { c T x : A x ≤ b , x ∈ C } , where the matrix  A contains no negative entries and C is a cone that is generated by a finite set  S of non-negative vectors. While the cone is allowed to require an exponential-sized representation, we assume that we can access it via one of three types of oracles. For each of these oracles, we present positive results for the approximability of the packing problem. In contrast to other frameworks, the presented one allows the use of arbitrary linear objective functions and can be applied to a large class of packing problems without much effort. In particular, our framework instantly allows to derive fast and simple fully polynomial-time approximation algorithms (FPTASs) for a large set of network flow problems, such as budget-constrained versions of traditional network flows, multicommodity flows, or generalized flows. Some of these FPTASs represent the first ones of their kind, while others match existing results but offer a much simpler proof.
ISSN:1432-2994
1432-5217
DOI:10.1007/s00186-017-0604-2