用时域有限差分法有效模拟波浪在粗糙板中的传播

Stefanos Bakirtzis, Xingqi Zhang, C. Sarris
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引用次数: 1

摘要

随着5G通信系统以及几种采用毫米波的雷达和成像技术的发展,在这些频率下准确地模拟波的传播与以往一样重要。在这些频率下,波导组件的表面粗糙度(标准制造和3d打印的副作用)具有明显的作用。然而,在时域有限差分中,这种效应仍然是通过耗时的蒙特卡罗方法来建模的。本文提出了一种新的方法,与现有方法相比具有明显的优势。利用时域有限差分法和粗糙表面及其周围统计场的有效多项式混沌展开,对粗糙板的反射和透射进行了建模。我们证明了该技术的计算效率和准确性,它可以模拟由于小尺度粗糙度和漫射散射效应引起的通常的过量衰减。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Efficient Modeling of Wave Propagation Through Rough Slabs with FDTD
With 5G communication systems along with several radar and imaging technologies employing millimeter waves, accurately modeling wave propagation at these frequencies is as important as ever. At these frequencies, surface roughness of waveguide components (a side effect of both standard fabrication and 3-D printing) has a pronounced role. Yet, in FDTD, this effect is still modeled through the time-consuming Monte-Carlo method. This paper presents a new approach with distinct advantages over the state of the art. Reflection and transmission through rough slabs is modeled with FDTD and an efficient polynomial chaos expansion of the statistical fields in and around the rough surface. We demonstrate the computational efficiency and accuracy of this technique, which can model both the usual excess attenuation due to small-scale roughness and diffuse scattering effects.
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