Hardness and Approximation of Submodular Minimum Linear Ordering Problems

Abstract

The minimum linear ordering problem (MLOP) generalizes well-known combinatorial optimization problems such as minimum linear arrangement and minimum sum set cover. MLOP seeks to minimize an aggregated cost f(·) due to an ordering σ of the items (say [n]), i.e., σ Σi∈ [n] f(Ei,σ), where Ei,σ is the set of items mapped by σ to indices [i]. Despite an extensive literature on MLOP variants and approximations for these, it was unclear whether the graphic matroid MLOP was NP-hard. We settle this question through non-trivial reductions from mininimum latency vertex cover and minimum sum vertex cover problems. We further propose a new combinatorial algorithm for approximating monotone submodular MLOP, using the theory of principal partitions. This is in contrast to the rounding algorithm by Iwata, Tetali, and Tripathi [ITT2012], using Lov\'asz extension of submodular functions. We show a (2-1+f1+|E|)-approximation for monotone submodular MLOP where f=f(E)x∈ Ef(\x\) satisfies 1 ≤ f ≤ |E|. Our theory provides new approximation bounds for special cases of the problem, in particular a (2-1+r(E)1+|E|)-approximation for the matroid MLOP, where f = r is the rank function of a matroid. We further show that minimum latency vertex cover (MLVC) is 43-approximable, by which we also lower bound the integrality gap of its natural LP relaxation, which might be of independent interest.