A Lower Bound for the Fourier Entropy of Boolean Functions on the Biased Hypercube
Abstract
We study Boolean functions on the p-biased hypercube (\0,1\n,μpn) through the lens of Fourier (spectral) entropy, i.e. the Shannon entropy of the squared p-biased Fourier coefficients. Motivated by recent restriction-based advances on upper bounds toward the Fourier-Entropy-Influence (FEI) conjecture, we prove a complementary, sharp lower bound that decomposes the entropy into coordinate-wise contributions. Let q:=4p(1-p) and define :[0,12][0, 2] by (t):=h(1+1-4t22), where h(u):=-u u-(1-u)(1-u). We show that for every Boolean f:(\0,1\n,μpn)\1\, Entp(f) Σk=1n (q(1-q)·Infk(p)[f]). When p≠ 12, this bound is tight and equality holds if and only if f is a parity function. Our proof adapts the restriction-moment framework to the biased cube.
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