Inverse problems for Lorentzian manifolds and non-linear hyperbolic equations

Abstract

We study two inverse problems on a globally hyperbolic Lorentzian manifold (M,g). The problems are: 1. Passive observations in spacetime: Consider observations in a neighborhood V⊂ M of a time-like geodesic μ. Under natural causality conditions, we reconstruct the conformal type of the unknown open, relatively compact set W⊂ M, when we are given V, the conformal class of g|V, and the light observations sets PV(q) corresponding to all source points q in W. The light observation set PV(q) is the intersection of V and the light-cone emanating from the point q, i.e., the points in the set V where light from a point source at q is observed. 2. Active measurements in spacetime: We develop a new method for inverse problems for non-linear hyperbolic equations that utilizes the non-linearity as a tool. This enables us to solve inverse problems for non-linear equations for which the corresponding problems for linear equations are still unsolved. To illustrate this method, we solve an inverse problem for semilinear wave equations with quadratic non-linearities. We assume that we are given the neighborhood V of the time-like geodesic μ and the source-to-solution operator that maps the source supported on V to the restriction of the solution of the wave equation in V. When M is 4-dimensional, we show that these data determine the topological, differentiable, and conformal structures of the spacetime in the maximal set where waves can propagate from μ and return back to μ.