变形为更快的计算与有限差分时域算法

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY EPJ Applied Metamaterials Pub Date : 2022-01-01 DOI:10.1051/epjam/2021011
Ronald Aznavourian, S. Guenneau, B. Ungureanu, J. Marot
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引用次数: 0

摘要

在波传播的框架下,时域有限差分(FDTD)算法计算时间长。我们建议使用变形算法来推导出它们与不同形状和不同尺寸的流固结构相互作用的一些近似波图,这些波图是从三角形、圆形和椭圆形三种给定形状的固体散射的FDTD计算中推导出来的。如果明智地选择控制点,则FDTD解与通过源图像和目标图像的变形推导出的近似解之间的L2范数误差通常小于1%。因此,我们建议使用一种变形算法来推导近似的波图:在中间时间步长,从该事件之前和之后的时间步长的波图的FDTD计算,以及在同一时间步长,但对于平均频率信号之间的FDTD计算具有两个不同信号频率的波图。我们强调,我们的方法可以大大加快时域有限差分计算,因为空间和时间的离散化是通过Courant-Friedrichs-Lewy稳定性条件固有地联系在一起的。我们的方法需要一些人为干预,因为变形的准确性高度依赖于控制点,但与直接计算方法相比,我们的方法更快,需要更少的资源。我们还将该方法与一些基于神经网络的图像变换方法——神经风格迁移(NST)算法进行了比较。我们的方法在L2范数、平均结构相似性、预期信号误差率方面优于NST。
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Morphing for faster computations with finite difference time domain algorithms
In the framework of wave propagation, finite difference time domain (FDTD) algorithms, yield high computational time. We propose to use morphing algorithms to deduce some approximate wave pictures of their interactions with fluid-solid structures of various shapes and different sizes deduced from FDTD computations of scattering by solids of three given shapes: triangular, circular and elliptic ones. The error in the L2 norm between the FDTD solution and approximate solution deduced via morphing from the source and destination images are typically less than 1% if control points are judiciously chosen. We thus propose to use a morphing algorithm to deduce approximate wave pictures: at intermediate time steps from the FDTD computation of wave pictures at a time step before and after this event, and at the same time step, but for an average frequency signal between FDTD computation of wave pictures with two different signal frequencies. We stress that our approach might greatly accelerate FDTD computations as discretizations in space and time are inherently linked via the Courant–Friedrichs–Lewy stability condition. Our approach requires some human intervention since the accuracy of morphing highly depends upon control points, but compared to the direct computational method our approach is much faster and requires fewer resources. We also compared our approach to some neural style transfer (NST) algorithm, which is an image transformation method based on a neural network. Our approach outperforms NST in terms of the L2 norm, Mean Structural SIMilarity, expected signal to error ratio.
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来源期刊
EPJ Applied Metamaterials
EPJ Applied Metamaterials MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
3.10
自引率
6.20%
发文量
16
审稿时长
8 weeks
期刊最新文献
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