Improved quantum lower and upper bounds for matrix scaling
Abstract
Matrix scaling is a simple to state, yet widely applicable linear-algebraic problem: the goal is to scale the rows and columns of a given non-negative matrix such that the rescaled matrix has prescribed row and column sums. Motivated by recent results on first-order quantum algorithms for matrix scaling, we investigate the possibilities for quantum speedups for classical second-order algorithms, which comprise the state-of-the-art in the classical setting. We first show that there can be essentially no quantum speedup in terms of the input size in the high-precision regime: any quantum algorithm that solves the matrix scaling problem for matrices with at most non-zero entries and with -error must make queries to the matrix, even when the success probability is exponentially small in . Additionally, we show that for , any quantum algorithm capable of producing --approximations of the row-sum vector of a (dense) normalized matrix uses queries, and that there exists a constant for which this problem takes queries. To complement these results we give improved quantum algorithms in the low-precision regime: with quantum graph sparsification and amplitude estimation, a box-constrained Newton method can be sped up in the large- regime, and outperforms previous quantum algorithms. For entrywise-positive matrices, we find an --scaling in time , whereas the best previously known bounds were (classical) and (quantum).
Cite
@article{arxiv.2109.15282,
title = {Improved quantum lower and upper bounds for matrix scaling},
author = {Sander Gribling and Harold Nieuwboer},
journal= {arXiv preprint arXiv:2109.15282},
year = {2021}
}
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30 pages