A Nearly Optimal Lower Bound on the Approximate Degree of AC0

Abstract

The approximate degree of a Boolean function f \-1, 1\n → \-1, 1\ is the least degree of a real polynomial that approximates f pointwise to error at most 1/3. We introduce a generic method for increasing the approximate degree of a given function, while preserving its computability by constant-depth circuits. Specifically, we show how to transform any Boolean function f with approximate degree d into a function F on O(n · polylog(n)) variables with approximate degree at least D = (n1/3 · d2/3). In particular, if d= n1-(1), then D is polynomially larger than d. Moreover, if f is computed by a polynomial-size Boolean circuit of constant depth, then so is F. By recursively applying our transformation, for any constant δ > 0 we exhibit an AC0 function of approximate degree (n1-δ). This improves over the best previous lower bound of (n2/3) due to Aaronson and Shi (J. ACM 2004), and nearly matches the trivial upper bound of n that holds for any function. Our lower bounds also apply to (quasipolynomial-size) DNFs of polylogarithmic width. We describe several applications of these results. We give: * For any constant δ > 0, an (n1-δ) lower bound on the quantum communication complexity of a function in AC0. * A Boolean function f with approximate degree at least C(f)2-o(1), where C(f) is the certificate complexity of f. This separation is optimal up to the o(1) term in the exponent. * Improved secret sharing schemes with reconstruction procedures in AC0.