Near log-convexity of measured heat in (discrete) time and consequences

Abstract

Let u,v ∈ R+ be positive unit vectors and S∈R×+ be a symmetric substochastic matrix. For an integer t 0, let mt = v,Stu, which we view as the heat measured by v after an initial heat configuration u is let to diffuse for t time steps according to S. Since S is entropy improving, one may intuit that mt should not change too rapidly over time. We give the following formalizations of this intuition. We prove that mt+2 mt1+2/t\!, an inequality studied earlier by Blakley and Dixon (also Erdos and Simonovits) for u=v and shown true under the restriction mt e-4t. Moreover we prove that for any ε>0, a stronger inequality mt+2 t1-ε· mt1+2/t holds unless mt+2mt-2 δ mt2 for some δ that depends on ε only. Phrased differently, ∀ ε> 0, ∃ δ> 0 such that ∀ S,u,v equation* mt+2mt1+2/t \t1-ε, δmt1-2/tmt-2\, ∀ t 2, equation* which can be viewed as a truncated log-convexity statement. Using this inequality, we answer two related open questions in complexity theory: Any property tester for k-linearity requires (k k) queries and the randomized communication complexity of the k-Hamming distance problem is (k k). Further we show that any randomized parity decision tree computing k-Hamming weight has size ((k k)).