Gradual time reversal in thermo- and photo- acoustic tomography within a resonant cavity

TL;DR

This paper introduces a gradual time reversal method for thermo- and photo-acoustic tomography in resonant cavities, enabling initial pressure reconstruction where traditional methods fail due to reflections.

Contribution

The paper proposes a novel gradual time reversal technique that effectively reconstructs initial pressure in resonant cavities, extending tomography capabilities beyond free space assumptions.

Findings

The method converges to the exact solution with sufficiently large T.

It handles boundary reflections where classical methods cannot.

Provides a practical approach for imaging in resonant environments.

Abstract

Thermo- and photo- acoustic tomography require reconstructing initial acoustic pressure in a body from time series of pressure measured on a surface surrounding the body. For the classical case of free space wave propagation, various reconstruction techniques are well known. However, some novel measurement schemes place the object of interest between reflecting walls that form a de facto resonant cavity. In this case, known methods (including the popular time reversal algorithm) cannot be used. The inverse problem involving reflecting walls can be solved by the $gradual$ $time$ $reversal$ method we propose here. It consists in solving back in time on the interval $[0,T]$ the initial/boundary value problem for the wave equation, with the Dirichlet boundary data multiplied by a smooth cut-off function. If $T$ is sufficiently large one obtains a good approximation to the initial pressure; in the limit of large $T$ such an approximation converges (under certain conditions) to the exact solution.