Quantum complexity of minimum cut
Abstract
The minimum cut problem in an undirected and weighted graph is to find the minimum total weight of a set of edges whose removal disconnects . We completely characterize the quantum query and time complexity of the minimum cut problem in the adjacency matrix model. If has vertices and edge weights at least and at most , we give a quantum algorithm to solve the minimum cut problem using queries and time. Moreover, for every integer we give an example of a graph with edge weights and such that solving the minimum cut problem on requires many queries to the adjacency matrix of . These results contrast with the classical randomized case where queries to the adjacency matrix are needed in the worst case even to decide if an unweighted graph is connected or not. In the adjacency array model, when has edges the classical randomized complexity of the minimum cut problem is . We show that the quantum query and time complexity are and , respectively, where again the edge weights are between and . For dense graphs we give lower bounds on the quantum query complexity of for and for any . Our query algorithm uses a quantum algorithm for graph sparsification by Apers and de Wolf (FOCS 2020) and results on the structure of near-minimum cuts by Kawarabayashi and Thorup (STOC 2015) and Rubinstein, Schramm and Weinberg (ITCS 2018). Our time efficient implementation builds on Karger's tree packing technique (STOC 1996).
Cite
@article{arxiv.2011.09823,
title = {Quantum complexity of minimum cut},
author = {Simon Apers and Troy Lee},
journal= {arXiv preprint arXiv:2011.09823},
year = {2021}
}
Comments
15 pages; v2: improved bounds on query and time complexity; v3: fixes typos, accepted to CCC 2021