Log-rank and lifting for AND-functions

Abstract

Let f: \0,1\n \0, 1\ be a boolean function, and let f (x, y) = f(x y) denote the AND-function of f, where x y denotes bit-wise AND. We study the deterministic communication complexity of f and show that, up to a n factor, it is bounded by a polynomial in the logarithm of the real rank of the communication matrix of f. This comes within a n factor of establishing the log-rank conjecturefor AND-functions with no assumptions on f. Our result stands in contrast with previous results on special cases of the log-rank conjecture, which needed significant restrictions on f such as monotonicity or low F2-degree. Our techniques can also be used to prove (within a n factor) a lifting theorem for AND-functions, stating that the deterministic communication complexity of f is polynomially-related to the AND-decision tree complexity of f. The results rely on a new structural result regarding boolean functions f:\0, 1\n \0, 1\ with a sparse polynomial representation, which may be of independent interest. We show that if the polynomial computing f has few monomials then the set system of the monomials has a small hitting set, of size poly-logarithmic in its sparsity. We also establish extensions of this result to multi-linear polynomials f:\0,1\n R with a larger range.