English

Correlation based passive imaging with a white noise source

Analysis of PDEs 2016-11-07 v2 Probability

Abstract

Passive imaging refers to problems where waves generated by unknown sources are recorded and used to image the medium through which they travel. The sources are typically modelled as a random variable and it is assumed that some statistical information is available. In this paper we study the stochastic wave equation t2uΔgu=χW\partial_t^2 u - \Delta_g u = \chi W, where WW is a random variable with the white noise statistics on R1+n{\mathbb R}^{1+n}, n3n \ge 3, χ\chi is a smooth function vanishing for negative times and outside a compact set in space, and Δg\Delta_g is the Laplace-Beltrami operator associated to a smooth non-trapping Riemannian metric tensor gg on Rn{\mathbb R}^n. The metric tensor gg models the medium to be imaged, and we assume that it coincides with the Euclidean metric outside a compact set. We consider the empirical correlations on an open set XRn\mathcal X \subset {\mathbb R}^n, CT(t1,x1,t2,x2)=1T0Tu(t1+s,x1)u(t2+s,x2)ds,t1,t2>0, x1,x2X, C_T(t_1, x_1, t_2, x_2) = \frac 1 T \int_0^T u(t_1+s,x_1) u(t_2+s,x_2) ds, \quad t_1,t_2>0,\ x_1,x_2\in \mathcal X, for T>0T>0. Supposing that χ\chi is non-zero on X\mathcal X and constant in time after t>1t > 1, we show that in the limit TT \to \infty, the data CTC_T becomes statistically stable, that is, independent of the realization of WW. Our main result is that, with probability one, this limit determines the Riemannian manifold (Rn,g)({\mathbb R}^n,g) up to an isometry. To our knowledge, this is the first result showing that a medium can be determined in a passive imaging setting, without assuming a separation of scales.

Cite

@article{arxiv.1609.08022,
  title  = {Correlation based passive imaging with a white noise source},
  author = {Tapio Helin and Matti Lassas and Lauri Oksanen and Teemu Saksala},
  journal= {arXiv preprint arXiv:1609.08022},
  year   = {2016}
}
R2 v1 2026-06-22T16:01:35.666Z