Contribution
Outdoor sound propagation simulations using the Discontinuous Galerkin method: Preliminary results
* Presenting author
Abstract:
Simulation of noise propagation outdoors is commonly performed using geometry-based methods. However, as these methods often do not adequately model wave effects (e.g., diffraction), they yield invalid results especially in the low-frequency regime. In this contribution, the Discontinuous Galerkin method – a wave-based method – is used to simulate acoustic wave propagation in time domain in a large real-world geometry. The Discontinuous Galerkin method allows for computations employing high-order ansatz functions both in time and space. Due to the matrix-free approach, the algorithm can be highly parallelized. The acoustic source term implementation allows for moving sources with arbitrary waveforms, such that traffic noise propagation can be efficiently modeled. In this contribution, preliminary results of Discontinuous Galerkin simulations in a geometrically complex outdoor scenario will be presented, highlighting the capabilities of the method.