An SoS Entropy Dichotomy via Windowed Hypercontractivity

Abstract

We prove an entropy versus degree dichotomy for low-degree tests and the Sum-of-Squares (SoS) hierarchy on a calibrated window after a gadget layer. For a target distribution \(μ\) and a product-like proxy \(u\), we study the low-degree discrepancy \(k(μ,u)\), defined as the optimal distinguishing advantage of degree \( k\) polynomial tests. Using a bias-orthonormal Walsh basis and a test-moment equivalence on the window, we relate \(k\) (up to constants) to the squared \(2\) mass of signed low-degree moments. Calibrated pseudoexpectations match \(u\) on all moments of degree \( k\), hence test discrepancy equals SoS pseudoexpectation deviation. Under bias, product, and width assumptions along a switching path, a windowed Bonami--Beckner inequality yields hypercontractive tail bounds. Combining these with moment matching, we obtain a discrepancy-to-degree theorem: if \(k(μ,u) n-β\), then any polynomial-calculus or SoS refutation separating \(μ\) from \(u\) requires degree \((k)\). Instantiating \(k = c n\) gives an explicit \(( n)\) SoS degree lower bound whenever \(k n-η\). All constants are explicit and depend only on calibrated window parameters. This work provides the SoS/low-degree core and complements a prior calibration blueprint; a companion paper lifts the windowed statements to full distribution families.