A Direct Method for Photoacoustic Tomography with Inhomogeneous Sound Speed

TL;DR

This paper introduces a direct Landweber regularization method for photoacoustic tomography with inhomogeneous sound speed, providing convergence guarantees even in trapping conditions and offering a numerical approach based on coupled boundary and interior equations.

Contribution

It develops a novel direct method for photoacoustic imaging that works on the whole Euclidean space and compares favorably to traditional time reversal techniques.

Findings

The method converges under trapping sound speed conditions.

Numerical implementation uses a BEM-FEM coupled scheme.

The approach is validated through numerical tests and analysis.

Abstract

The standard approach for photoacoustic imaging with variable speed of sound is time reversal, which consists in solving a well-posed final-boundary value problem for the wave equation backwards in time. This paper investigates the iterative Landweber regularization algorithm, where convergence is guaranteed by standard regularization theory, notably also in cases of trapping sound speed or for short measurement times. We formulate and solve the direct and inverse problem on the whole Euclidean space, what is common in standard photoacoustic imaging, but not for time-reversal algorithms, where the problems are considered on a domain enclosed by the measurement devices. We formulate both the direct and adjoint photoacoustic operator as the solution of an interior and an exterior differential equation which are coupled by transmission conditions. The prior is solved numerically using a Galerkin scheme in space and finite difference discretization in time, while the latter consists in solving a boundary integral equation. We therefore use a BEM-FEM approach for numerical solution of the forward operators. We analyze this method, prove convergence, and provide numerical tests. Moreover, we compare the approach to time reversal.