An asymptotically optimal bound for the concentration function of a sum of independent integer random variables
Abstract
For a random variable X define Q(X) = x ∈ R P(X=x). Let X1, …, Xn be independent integer random variables. Suppose Q(Xi) αi ∈ (0,1] for each i ∈ \1, …, n\. Juskevicius (2023) conjectured that Q(X1 + … +Xn) Q(Y1 + …+ Yn) where Y1, …, Yn are independent and Yi is a random integer variable with Q(Yi) =αi that has the smallest variance, i.e. the distribution of Yi has probabilities αi, …, αi, βi or probabilities βi, αi, …, αi on some interval of integers, where 0 βi < αi. We prove this conjecture asymptotically: i.e., we show that for each δ > 0 there is V0 = V0(δ) such that if Var (Σ Yi) V0 then Q(Σ Xi) (1+δ) Q(Σ Yi). This implies an analogous asymptotically optimal inequality for concentration at a point when X1, …, Xn take values in a separable Hilbert space. Our long and technical argument relies on several non-trivial previous results including an inverse Littlewood--Offord theorem and an approximation in total variation distance of sums of multivariate lattice random vectors by a discretized Gaussian distribution.
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