Log-concavity and lower bounds for arithmetic circuits

Abstract

One question that we investigate in this paper is, how can we build log-concave polynomials using sparse polynomials as building blocks? More precisely, let f = Σ\i = 0d a\i Xi ∈ R+[X] be a polynomial satisfying the log-concavity condition a\i2 τ a\i-1a\i+1 for every i ∈ \1,…,d-1\, where τ 0. Whenever f can be written under the form f = Σ\i = 1k Π\j = 1m f\i,j where the polynomials f\i,j have at most t monomials, it is clear that d ≤ k tm. Assuming that the f\i,j have only non-negative coefficients, we improve this degree bound to d = O(k m2/3 t2m/3 log2/3(kt)) if τ 1, and to d ≤ kmt if τ = d2d. This investigation has a complexity-theoretic motivation: we show that a suitable strengthening of the above results would imply a separation of the algebraic complexity classes VP and VNP. As they currently stand, these results are strong enough to provide a new example of a family of polynomials in VNP which cannot be computed by monotone arithmetic circuits of polynomial size.