An optimal (ε,δ)-approximation scheme for the mean of random variables with bounded relative variance

Abstract

Randomized approximation algorithms for many #P-complete problems (such as the partition function of a Gibbs distribution, the volume of a convex body, the permanent of a \0,1\-matrix, and many others) reduce to creating random variables X1,X2,… with finite mean μ and standard deviationσ such that μ is the solution for the problem input, and the relative standard deviation |σ/μ| ≤ c for known c. Under these circumstances, it is known that the number of samples from the \Xi\ needed to form an (ε,δ)-approximation μ that satisfies P(| μ - μ| > ε μ) ≤ δ is at least (2-o(1))ε-2 c2(1/δ). We present here an easy to implement (ε,δ)-approximation μ that uses (2+o(1))c2ε-2(1/δ) samples. This achieves the same optimal running time as other estimators, but without the need for extra conditions such as bounds on third or fourth moments.