Acoustic Source Localization with the Angular Spectrum Approach in Continuously Stratified Media

TL;DR

This paper extends the angular spectrum approach (ASA) for acoustic source localization to continuously stratified media, providing an analytical correction that improves accuracy with minimal computational cost across biomedical, underwater, and atmospheric applications.

Contribution

The authors develop a first-order analytical solution for ASA in stratified media, enhancing localization accuracy while maintaining computational efficiency.

Findings

Stratified ASA reduces localization error from 1.2±0.3 to 0.49±0.3 wavelengths.

The method achieves localization in milliseconds on standard hardware.

Applicable to biomedical, underwater, and atmospheric acoustics.

Abstract

The angular spectrum approach (ASA)---a fast, frequency domain method for calculation of the acoustic field---enables passive source localization and modeling forward propagation in homogeneous media with high computational efficiency. Here we show that, if the medium is continuously stratified, a first-order analytical solution may be obtained for the field at arbitrary depth. Our simulations show that the stratified ASA solution enables accurate source localization as compared to the uncorrected ASA (error from 1.2$\pm$0.3 to 0.49$\pm$0.3 wavelengths) at scalings relevant to biomedical ($kL \sim$ 500, where $L$ is the length of the measurement aperture), underwater ($kL \sim$ 800), and atmospheric ($kL \sim$ 10) acoustic applications. Overall the total computation was on the order milliseconds on standard hardware (225$\pm$84 ms, compared with $78\pm63$ ms for the homogeneous ASA formulation over all cases). Collectively, the results suggest the proposed ASA phase correction enables efficient and accurate method for source localization in continuously stratified environments.