Strictly Balancing Matrices in Polynomial Time Using Osborne's Iteration
Abstract
Osborne's iteration is a method for balancing matrices which is widely used in linear algebra packages, as balancing preserves eigenvalues and stabilizes their numeral computation. The iteration can be implemented in any norm over , but it is normally used in the norm. The choice of norm not only affects the desired balance condition, but also defines the iterated balancing step itself. In this paper we focus on Osborne's iteration in any norm, where . We design a specific implementation of Osborne's iteration in any norm that converges to a strictly -balanced matrix in iterations, where measures, roughly, the {\em number of bits} required to represent the entries of the input matrix. This is the first result that proves that Osborne's iteration in the norm (or any norm, ) strictly balances matrices in polynomial time. This is a substantial improvement over our recent result (in SODA 2017) that showed weak balancing in norms. Previously, Schulman and Sinclair (STOC 2015) showed strong balancing of Osborne's iteration in the norm. Their result does not imply any bounds on strict balancing in other norms.
Cite
@article{arxiv.1704.07406,
title = {Strictly Balancing Matrices in Polynomial Time Using Osborne's Iteration},
author = {Rafail Ostrovsky and Yuval Rabani and Arman Yousefi},
journal= {arXiv preprint arXiv:1704.07406},
year = {2017}
}
Comments
12 pages