Quantum Speedups for Bayesian Network Structure Learning

Abstract

The Bayesian network structure learning (BNSL) problem asks for a directed acyclic graph that maximizes a given score function. For networks with n nodes, the fastest known algorithms run in time O(2n n2) in the worst case, with no improvement in the asymptotic bound for two decades. Inspired by recent advances in quantum computing, we ask whether BNSL admits a polynomial quantum speedup, that is, whether the problem can be solved by a quantum algorithm in time O(cn) for some constant c less than 2. We answer the question in the affirmative by giving two algorithms achieving c 1.817 and c 1.982 assuming the number of potential parent sets is, respectively, subexponential and O(1.453n). Both algorithms assume the availability of a quantum random access memory. We also prove that one presumably cannot lower the base 2 for any classical algorithm, as that would refute the strong exponential time hypothesis.