Finite Element–Boundary Element Acoustic Backscattering with Model Reduction of Surface Pressure Based on Coherent Clusters

IF 1.3 Q3 ACOUSTICS Acoustics (Basel, Switzerland) Pub Date : 2023-10-31 DOI:10.3390/acoustics5040058

Petr Krysl, Ahmad T. Abawi

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Abstract

Computing backscattering of harmonic acoustic waves from underwater elastic targets of arbitrary shape is a problem of considerable practical significance. The finite element method is commonly applied to the discretization of the target; on the other hand, the boundary element method naturally incorporates the radiation boundary condition at infinity. The coupled model tends to be expensive, primarily due to the need to manipulate large, dense, and complex matrices and to repeatedly solve systems of complex linear algebraic equations of significant size for each frequency of interest. In this article, we develop a model reduction transformation based on the notion of coherence applied to the surface pressures, which considerably reduces the size of the systems to be solved. We found that the proposed model reduction approach delivers acceptably accurate results at a fraction of the cost of the full model. A typical speedup of an order of magnitude was realized in our numerical experiments. Our approach enables backscattering computations with considerably larger models than have been feasible to date.

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基于相干簇表面压力模型降低的有限元-边界元声后向散射

计算任意形状水下弹性目标的谐波后向散射是一个具有重要实际意义的问题。有限元法通常用于目标的离散化;另一方面，边界元法自然地包含了无穷远处的辐射边界条件。耦合模型往往是昂贵的，主要是因为需要处理大型、密集和复杂的矩阵，并且需要对每个感兴趣的频率重复求解复杂的线性代数方程系统。在本文中，我们开发了一种基于应用于表面压力的相干概念的模型缩减转换，这大大减少了待解决系统的大小。我们发现，所提出的模型简化方法以完整模型的一小部分成本提供了可接受的精确结果。在我们的数值实验中实现了典型的一个数量级的加速。我们的方法使后向散射计算能够使用比迄今为止可行的大得多的模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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