Generalized budgeted submodular set function maximization

Abstract

In this paper we consider a generalization of the well-known budgeted maximum coverage problem. We are given a ground set of elements and a set of bins. The goal is to find a subset of elements along with an associated set of bins, such that the overall cost is at most a given budget, and the profit is maximized. Each bin has its own cost and the cost of each element depends on its associated bin. The profit is measured by a monotone submodular function over the elements. We first present an algorithm that guarantees an approximation factor of 12(1-1eα), where α ≤ 1 is the approximation factor of an algorithm for a sub-problem. We give two polynomial-time algorithms to solve this sub-problem. The first one gives us α=1- ε if the costs satisfies a specific condition, which is fulfilled in several relevant cases, including the unitary costs case and the problem of maximizing a monotone submodular function under a knapsack constraint. The second one guarantees α=1-1e-ε for the general case. The gap between our approximation guarantees and the known inapproximability bounds is 12. We extend our algorithm to a bi-criterion approximation algorithm in which we are allowed to spend an extra budget up to a factor β≥ 1 to guarantee a 12(1-1eαβ)-approximation. If we set β=1α (12ε), the algorithm achieves an approximation factor of 12-ε, for any arbitrarily small ε>0.