Distribution of the least-squares estimators of a single Brownian trajectory diffusion coefficient

Abstract

In this paper we study the distribution function P(uα) of the estimators uα T-1 ∫T0 \, ω(t) \, B2t \, dt, which optimise the least-squares fitting of the diffusion coefficient Df of a single d-dimensional Brownian trajectory Bt. We pursue here the optimisation further by considering a family of weight functions of the form ω(t) = (t0 + t)-α, where t0 is a time lag and α is an arbitrary real number, and seeking such values of α for which the estimators most efficiently filter out the fluctuations. We calculate P(uα) exactly for arbitrary α and arbitrary spatial dimension d, and show that only for α = 2 the distribution P(uα) converges, as ε = t0/T 0, to the Dirac delta-function centered at the ensemble average value of the estimator. This allows us to conclude that only the estimators with α = 2 possess an ergodic property, so that the ensemble averaged diffusion coefficient can be obtained with any necessary precision from a single trajectory data, but at the expense of a progressively higher experimental resolution. For any α ≠ 2 the distribution attains, as ε 0, a certain limiting form with a finite variance, which signifies that such estimators are not ergodic.