Persistent Homology of the Wiener Sausage II: A Central Limit Theorem for Drifted Planar Brownian Motion

Abstract

Let Xt = Bt + μ t, t ≥ 0, be planar Brownian motion with nonzero drift, and let Ktr = \x ∈ R2 : dist(x, X[0,t]) ≤ r\ be the radius-r Wiener sausage up to time t. For a bounded Borel function supported in a compact interval [r0, r1] ⊂ (0,∞), consider the smoothed Betti-curve functional (t) := ∫r0r1 β1t(r)\,(r)\,dr, where β1t(r) denotes the number of holes of Ktr. In a previous paper, a regeneration scheme along the drift direction was used to prove a law of large numbers for (t). In the present paper we prove the corresponding central limit theorem. More precisely, there exist a deterministic constant and a variance σ2 ≥ 0 such that ((t) - t)/t dt ∞ N(0, σ2). We also obtain the finite-dimensional Gaussian limit for finitely many test functions. The proof preserves the regenerative structure of the law of large numbers, but requires a new L2 analysis of the topological interface terms created at regeneration cuts. The key input is a finite-time polynomial moment bound for integrated hole counts of the Wiener sausage. This yields square-integrability of cycle increments, within-cycle oscillations, and the last incomplete-cycle remainder, which in turn allows one to combine a standard central limit theorem for stationary 1-dependent sequences with a renewal time-change argument.