A direction preserving discretization for computing phase-space densities

TL;DR

This paper introduces a Petrov-Galerkin discretization method for phase-space boundary integral equations that preserves wave propagation directions, improving the accuracy of energy transport simulations in complex multi-component domains.

Contribution

It presents a novel discretization approach that maintains directional information in phase-space density computations for wave energy transport.

Findings

Method effectively preserves propagation directions across domain components.

Applicable to acoustic and elastic wave problems in complex geometries.

Demonstrated on real-world structures like a car shock tower.

Abstract

Ray flow methods are an efficient tool to estimate vibro-acoustic or electromagnetic energy transport in complex domains at high-frequencies. Here, a Petrov-Galerkin discretization of a phase-space boundary integral equation for transporting wave energy densities on two-dimensional surfaces is proposed. The directional dependence of the energy density is approximated at each point on the boundary in terms of a finite local set of directions propagating into the domain. The direction of propagation can be preserved for transport across multi-component domains when the directions within the local set are inherited from a global direction set. The range of applicability and computational cost of the method will be explored through a series of numerical experiments, including wave problems from both acoustics and elasticity in both single and multi-component domains. The domain geometries considered range from both regular and irregular polygons to curved surfaces, including a cast aluminium shock tower from a Range Rover car.