Dimension Reduction for Polynomials over Gaussian Space and Applications
Abstract
We introduce a new technique for reducing the dimension of the ambient space of low-degree polynomials in the Gaussian space while preserving their relative correlation structure, analogous to the Johnson-Lindenstrauss lemma. As applications, we address the following problems: 1. Computability of Approximately Optimal Noise Stable function over Gaussian space: The goal is to find a partition of into parts, that maximizes the noise stability. An -optimal partition is one which is within additive of the optimal noise stability. De, Mossel & Neeman (CCC 2017) raised the question of proving a computable bound on the dimension in which we can find an -optimal partition. While De et al. provide such a bound, using our new technique, we obtain improved explicit bounds on the dimension . 2. Decidability of Non-Interactive Simulation of Joint Distributions: A "non-interactive simulation" problem is specified by two distributions and : The goal is to determine if two players that observe sequences and respectively where are drawn i.i.d. from can generate pairs and respectively (without communicating with each other) with a joint distribution that is arbitrarily close in total variation to . Even when and are extremely simple, it is open in several cases if can simulate . In the special where is a joint distribution over , Ghazi, Kamath and Sudan (FOCS 2016) proved a computable bound on the number of samples that can be drawn from to get -close to (if it is possible at all). Recently De, Mossel & Neeman obtained such bounds when is a distribution over for any . We recover this result with improved explicit bounds on .
Cite
@article{arxiv.1708.03808,
title = {Dimension Reduction for Polynomials over Gaussian Space and Applications},
author = {Badih Ghazi and Pritish Kamath and Prasad Raghavendra},
journal= {arXiv preprint arXiv:1708.03808},
year = {2017}
}