New Results on a General Class of Minimum Norm Optimization Problems
Abstract
We study the general norm optimization for combinatorial problems, initiated by Chakrabarty and Swamy (STOC 2019). We propose a general formulation that captures a large class of combinatorial structures: we are given a set U of n weighted elements and a family of feasible subsets F. Each subset S∈ F is called a feasible solution/set of the problem. We denote the value vector by v=\vi\i∈ [n], where vi≥ 0 is the value of element i. For any subset S⊂eq U, we use v[S] to denote the n-dimensional vector \ve· 1[e∈ S]\e∈ U. Let f: Rn→R+ be a symmetric monotone norm function. Our goal is to minimize the norm objective f(v[S]) over feasible subset S∈ F. We present a general equivalent reduction of the norm minimization problem to a multi-criteria optimization problem with logarithmic budget constraints, up to a constant approximation factor. Leveraging this reduction, we obtain constant factor approximation algorithms for the norm minimization versions of several covering problems, such as interval cover, multi-dimensional knapsack cover, and logarithmic factor approximation for set cover. We also study the norm minimization versions for perfect matching, s-t path and s-t cut. We show the natural linear programming relaxations for these problems have a large integrality gap. To complement the negative result, we show that, for perfect matching, there is a bi-criteria result: for any constant ε,δ>0, we can find in polynomial time a nearly perfect matching (i.e., a matching that matches at least 1-ε proportion of vertices) and its cost is at most (8+δ) times of the optimum for perfect matching. Moreover, we establish the existence of a polynomial-time O( n)-approximation algorithm for the norm minimization variant of the s-t path problem.
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