Strongly polynomial algorithm for a class of minimum-cost flow problems with separable convex objectives
Abstract
A well-studied nonlinear extension of the minimum-cost flow problem is to minimize the objective over feasible flows , where on every arc of the network, is a convex function. We give a strongly polynomial algorithm for the case when all 's are convex quadratic functions, settling an open problem raised e.g. by Hochbaum [1994]. We also give strongly polynomial algorithms for computing market equilibria in Fisher markets with linear utilities and with spending constraint utilities, that can be formulated in this framework (see Shmyrev [2009], Devanur et al. [2011]). For the latter class this resolves an open question raised by Vazirani [2010]. The running time is for quadratic costs, for Fisher's markets with linear utilities and for spending constraint utilities. All these algorithms are presented in a common framework that addresses the general problem setting. Whereas it is impossible to give a strongly polynomial algorithm for the general problem even in an approximate sense (see Hochbaum [1994]), we show that assuming the existence of certain black-box oracles, one can give an algorithm using a strongly polynomial number of arithmetic operations and oracle calls only. The particular algorithms can be derived by implementing these oracles in the respective settings.
Cite
@article{arxiv.1110.4882,
title = {Strongly polynomial algorithm for a class of minimum-cost flow problems with separable convex objectives},
author = {Laszlo A. Vegh},
journal= {arXiv preprint arXiv:1110.4882},
year = {2016}
}