A near-optimal Quadratic Goldreich-Levin algorithm

Abstract

In this paper, we give a quadratic Goldreich-Levin algorithm that is close to optimal in the following ways. Given a bounded function f on the Boolean hypercube F2n and any >0, the algorithm returns a quadratic polynomial q: F2n F2 so that the correlation of f with the function (-1)q is within an additive of the maximum possible correlation with a quadratic phase function. The algorithm runs in O(n3) time and makes O(n2 n) queries to f, which matches the information-theoretic lower bound of (n2) queries up to a logarithmic factor. As a result, we obtain a number of corollaries: - A near-optimal self-corrector of quadratic Reed-Muller codes, which makes O(n2 n) queries to a Boolean function f and returns a quadratic polynomial q whose relative Hamming distance to f is within of the minimum distance. - An algorithmic polynomial inverse theorem for the order-3 Gowers uniformity norm. - An algorithm that makes a polynomial number of queries to a bounded function f and decomposes f as a sum of poly(1/) quadratic phase functions and error terms of order . Our algorithm is obtained using ideas from recent work on quantum learning theory. Its construction deviates from previous approaches based on algorithmic proofs of the inverse theorem for the order-3 uniformity norm (and in particular does not rely on the recent resolution of the polynomial Freman-Ruzsa conjecture).