Local Optimality of Dictator Functions with Applications to Courtade--Kumar and Li--M\'edard Conjectures
Abstract
Given a convex function :[0,1], the -stability of a Boolean function f is defined as E[(Tf(X))], where X is a random vector uniformly distributed on the discrete cube \1\n and T is the Bonami-Beckner operator. In this paper, we prove that dictator functions are locally optimal in maximizing the -stability of f over all balanced Boolean functions. When focusing on the symmetric q-stability, combining this result with our previous bound, we use computer-assisted methods to prove that dictator functions maximize the symmetric q-stability for q=1 and ∈[0,0.914] or for q∈[1.36,2) and all ∈[0,1]. In other words, we confirm the (balanced) Courtade--Kumar conjecture with the correlation coefficient ∈[0,0.914] and the (symmetrized) Li--M\'edard conjecture with q∈[1.36,2). We conjecture that dictator functions maximize both the symmetric and asymmetric 12-stability over all balanced Boolean functions. Our proofs are based on majorization of noise operators and hypercontractivity inequalities.
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