Quantum SDP-Solvers: Better upper and lower bounds
Abstract
Brand\~ao and Svore very recently gave quantum algorithms for approximately solving semidefinite programs, which in some regimes are faster than the best-possible classical algorithms in terms of the dimension of the problem and the number of constraints, but worse in terms of various other parameters. In this paper we improve their algorithms in several ways, getting better dependence on those other parameters. To this end we develop new techniques for quantum algorithms, for instance a general way to efficiently implement smooth functions of sparse Hamiltonians, and a generalized minimum-finding procedure. We also show limits on this approach to quantum SDP-solvers, for instance for combinatorial optimizations problems that have a lot of symmetry. Finally, we prove some general lower bounds showing that in the worst case, the complexity of every quantum LP-solver (and hence also SDP-solver) has to scale linearly with when , which is the same as classical.
Cite
@article{arxiv.1705.01843,
title = {Quantum SDP-Solvers: Better upper and lower bounds},
author = {Joran van Apeldoorn and András Gilyén and Sander Gribling and Ronald de Wolf},
journal= {arXiv preprint arXiv:1705.01843},
year = {2020}
}
Comments
v4: 69 pages, small corrections and clarifications. This version will appear in Quantum