Beyond Pointwise Submodularity: Non-Monotone Adaptive Submodular Maximization subject to Knapsack and $k$-System Constraints

TL;DR

This paper introduces the first constant approximation algorithms for non-monotone adaptive submodular maximization under knapsack and $k$-system constraints without assuming pointwise submodularity, advancing the theoretical understanding of these problems.

Contribution

It removes the pointwise submodularity assumption and provides the first constant approximation solutions for these complex constrained maximization problems.

Findings

Achieves a 1/10 approximation for knapsack constraints.

Achieves a 1/(2k+4) approximation for k-system constraints.

Develops a sampling-based randomized algorithm for non-monotone adaptive submodular maximization.

Abstract

In this paper, we study the non-monotone adaptive submodular maximization problem subject to a knapsack and a $k$-system constraints. The input of our problem is a set of items, where each item has a particular state drawn from a known prior distribution. However, the state of an item is initially unknown, one must select an item in order to reveal the state of that item. There is a utility function which is defined over items and states. Our objective is to sequentially select a group of items to maximize the expected utility. Although the cardinality-constrained non-monotone adaptive submodular maximization has been well studied in the literature, whether there exists a constant approximation solution for the knapsack-constrained or $k$-system constrained adaptive submodular maximization problem remains an open problem. It fact, it has only been settled given the additional assumption of pointwise submodularity. In this paper, we remove the common assumption on pointwise submodularity and propose the first constant approximation solutions for both cases. Inspired by two recent studies on non-monotone adaptive submodular maximization, we develop a sampling-based randomized algorithm that achieves a $\frac{1}{10}$ approximation for the case of a knapsack constraint and that achieves a $\frac{1}{2k+4}$ approximation ratio for the case of a $k$-system constraint.