On Convergence to Essential Singularities
Abstract
An iterative optimization method applied to a function on will produce a sequence of arguments ; this sequence is often constrained such that is monotonic. As part of the analysis of an iterative method, one may ask under what conditions the sequence converges. In 2005, Absil et al.\ employed the {\L}ojasiewicz gradient inequality in a proof of convergence; this requires that the objective function exist at a cluster point of the sequence. Here we provide a convergence result that does not require to be defined at the limit , should the limit exist. We show that a variant of the {\L}ojasiewicz gradient inequality holds on sets adjacent to singularities of bounded multivariate rational functions. We extend the results of Absil et al.\ to prove that if has a cluster point , if is a bounded multivariate rational function on , and if a technical condition holds, then even if is not in the domain of . We demonstrate how this may be employed to analyze divergent sequences by mapping them to projective space, and consider the implications this has for the study of low-rank tensor approximations.
Cite
@article{arxiv.1801.01610,
title = {On Convergence to Essential Singularities},
author = {Nathaniel J. McClatchey},
journal= {arXiv preprint arXiv:1801.01610},
year = {2018}
}
Comments
19 pages, 2 figures, preprint