Lower Bounds on the Complexity of Mixed-Integer Programs for Stable Set and Knapsack

Abstract

Standard mixed-integer programming formulations for the stable set problem on n-node graphs require n integer variables. We prove that this is almost optimal: We give a family of n-node graphs for which every polynomial-size MIP formulation requires (n/2 n) integer variables. By a polyhedral reduction we obtain an analogous result for n-item knapsack problems. In both cases, this improves the previously known bounds of (n/ n) by Cevallos, Weltge & Zenklusen (SODA 2018). To this end, we show that there exists a family of n-node graphs whose stable set polytopes satisfy the following: any (1+/n)-approximate extended formulation for these polytopes, for some constant > 0, has size 2(n/ n). Our proof extends and simplifies the information-theoretic methods due to G\"o\"os, Jain & Watson (FOCS 2016, SIAM J. Comput. 2018) who showed the same result for the case of exact extended formulations (i.e. = 0).