Revised: May 14, 2013
Published: June 11, 2013
Abstract: [Plain Text Version]
A basic question in any model of computation is how to reliably compute a given function when its inputs are subject to noise. Buhrman, Newman, Röhrig, and de Wolf (2003) posed the noisy computation problem for real polynomials. We give a complete solution to this problem. For any $\delta>0$ and any polynomial $p\colon\zoon\to[-1,1],$ we construct a corresponding polynomial $p_\robust\colon\R^n\to\R$ of degree $O(\deg p+\log1/\delta)$ that is robust to noise in the inputs: $|p(x)-p_\robust(x+\epsilon)|<\delta$ for all $x\in\zoon$ and all $\epsilon\in[-1/3,1/3]^n$. This result is optimal with respect to all parameters. We construct $p_\robust$ explicitly for each $p$. Previously, it was open to give such a construction even for $p=x_1\oplus x_2\oplus \cdots\oplus x_n$ (Buhrman et al., 2003). The proof contributes a technique of independent interest, which allows one to force partial cancellation of error terms in a polynomial.
An extended abstract of this article appeared in the Proceedings of the Forty-Fourth Annual ACM Symposium on Theory of Computing (STOC'12), pages 747--758, 2012.