Toward accurate polynomial evaluation in rounded arithmetic
Abstract
Given a multivariate real (or complex) polynomial and a domain , we would like to decide whether an algorithm exists to evaluate accurately for all using rounded real (or complex) arithmetic. Here ``accurately'' means with relative error less than 1, i.e., with some correct leading digits. The answer depends on the model of rounded arithmetic: We assume that for any arithmetic operator , for example or , its computed value is , where is bounded by some constant where , but is otherwise arbitrary. This model is the traditional one used to analyze the accuracy of floating point algorithms.Our ultimate goal is to establish a decision procedure that, for any and , either exhibits an accurate algorithm or proves that none exists. In contrast to the case where numbers are stored and manipulated as finite bit strings (e.g., as floating point numbers or rational numbers) we show that some polynomials are impossible to evaluate accurately. The existence of an accurate algorithm will depend not just on and , but on which arithmetic operators and which constants are are available and whether branching is permitted. Toward this goal, we present necessary conditions on for it to be accurately evaluable on open real or complex domains . We also give sufficient conditions, and describe progress toward a complete decision procedure. We do present a complete decision procedure for homogeneous polynomials with integer coefficients, , and using only the arithmetic operations , and .
Cite
@article{arxiv.math/0508350,
title = {Toward accurate polynomial evaluation in rounded arithmetic},
author = {James Demmel and Ioana Dumitriu and Olga Holtz},
journal= {arXiv preprint arXiv:math/0508350},
year = {2007}
}
Comments
54 pages, 6 figures; refereed version; to appear in Foundations of Computational Mathematics: Santander 2005, Cambridge University Press, March 2006