An improvement of the Berry--Esseen inequality with applications to Poisson and mixed Poisson random sums

Abstract

By a modification of the method that was applied in (Korolev and Shevtsova, 2009), here the inequalities (Fn,)0.335789(β3+0.425)n and (Fn,) 0.3051(β3+1)n are proved for the uniform distance (Fn,) between the standard normal distribution function and the distribution function Fn of the normalized sum of an arbitrary number n1 of independent identically distributed random variables with zero mean, unit variance and finite third absolute moment β3. The first of these inequalities sharpens the best known version of the classical Berry--Esseen inequality since 0.335789(β3+0.425)0.335789(1+0.425)β3<0.4785β3 by virtue of the condition β31, and 0.4785 is the best known upper estimate of the absolute constant in the classical Berry--Esseen inequality. The second inequality is applied to lowering the upper estimate of the absolute constant in the analog of the Berry--Esseen inequality for Poisson random sums to 0.3051 which is strictly less than the least possible value of the absolute constant in the classical Berry--Esseen inequality. As a corollary, the estimates of the rate of convergence in limit theorems for compound mixed Poisson distributions are refined.