Approximation Algorithms for the Weighted Nash Social Welfare via Convex and Non-Convex Programs

Abstract

In an instance of the weighted Nash Social Welfare problem, we are given a set of m indivisible items, G, and n agents, A, where each agent i ∈ A has a valuation vij≥ 0 for each item j∈ G. In addition, every agent i has a non-negative weight wi such that the weights collectively sum up to 1. The goal is to find an assignment σ:G→ A that maximizes Πi∈ A (Σj∈ σ-1(i) vij)wi, the product of the weighted valuations of the players. When all the weights equal 1n, the problem reduces to the classical Nash Social Welfare problem, which has recently received much attention. In this work, we present a 5·(2· DKL(w\, ||\, 1n)) = 5·(2n + 2Σi=1n wi wi)-approximation algorithm for the weighted Nash Social Welfare problem, where DKL(w\, ||\, 1n) denotes the KL-divergence between the distribution induced by w and the uniform distribution on [n]. We show a novel connection between the convex programming relaxations for the unweighted variant of Nash Social Welfare presented in cole2017convex, anari2017nash, and generalize the programs to two different mathematical programs for the weighted case. The first program is convex and is necessary for computational efficiency, while the second program is a non-convex relaxation that can be rounded efficiently. The approximation factor derives from the difference in the objective values of the convex and non-convex relaxation.