Sharp inequalities for symmetric polynomials, Hunter's conjecture, and moments of exponential random variables
Abstract
We prove Hunter's conjecture on complete homogeneous symmetric polynomials. For even n and every integer k≥ 1, we show that under the constraint Σi=1n ai2=1 the global minimum of the even-degree polynomial h2k(a1,…,an) is attained precisely at the half-plus/half-minus vector and we compute the optimal value in closed form. The proof combines algebraic properties of h2k with the probabilistic representation k!\,hk(a)=E(Σi=1n aiXi)k, where X1,…,Xn are i.i.d. standard exponential random variables with density e-x1x>0 and a combinatorial identity. This viewpoint further yields sharp upper and lower bounds for E|Σi=1n aiXi|q under natural constraints on the coefficients, including the spherical constraint Σ ai2=1 combined with the non-negative regime ai0, or the centred regime Σ ai=0. Moreover, we determine the exact minimum of h2k on the ∞-sphere S∞ = \a ∈ Rn : \|a\|∞ = 1\, which yields sharp norm comparison inequalities between the matrix norms induced by complete homogeneous symmetric polynomials and the classical operator and Schatten norms.
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