Proves Cov(f,g) ≥ 4 ∑_{∅≠S} |S| ˆf(S)^2 ˆg(S)^2 for increasing Boolean f,g on {0,1}^n, with the factor 4 sharp and all equality cases determined.
Talagrand-Type Correlation Inequalities for Submodular and Supermodular Functions on the Hypercube
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abstract
Talagran's correlation inequality provides quantitative lower bounds on the covariance of two increasing Boolean functions in terms of their coordinate influences, but, in general, a logarithmic loss is necessary. Motivated by a question of Kalai, Keller and Mossel, we identify a natural log-free regime. We prove that if two increasing Boolean functions on $\{0,1\}^n$ are either both submodular or both supermodular, then $$ \mathbb{E}[fg]-\mathbb{E}[f]\mathbb{E}[g]\ge \frac{1}{4}\cdot\sum\limits_{i=1}^n\mathrm{Inf}_i[f]\mathrm{Inf}_i[g], $$ where the constant $1/4$ is optimal. We also prove a real-valued extension: for two functions with the same second-difference sign, the covariance is bounded below by the sum of products of their Level-1 Fourier coefficients. As a consequence, we verify the Friedgut--Kahn--Kalai--Keller spectral conjecture in this structured setting. The proofs combine a heat-semigroup representation based on second-order discrete derivatives with an independent induction argument for the Boolean case.
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math.CO 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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The sharp diagonal spectral correlation inequality on the discrete cube
Proves Cov(f,g) ≥ 4 ∑_{∅≠S} |S| ˆf(S)^2 ˆg(S)^2 for increasing Boolean f,g on {0,1}^n, with the factor 4 sharp and all equality cases determined.