利用商用电话的CAD文件和并行FDTD代码计算两种人体头部解剖模型的SAR分布

IEEE Antennas and Propagation Society International Symposium 1997. Digest Pub Date : 1997-07-13 DOI:10.1109/8.686769

A. Tinniswood, C. Furse, O. Gandhi

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引用次数: 112

摘要

时域有限差分法(FDTD)非常适合生物电磁效应的计算，已成为该领域研究人员的首选方法。然而，它的使用仍然存在一些限制。首先，时域有限差分法需要大量的内存和计算能力。模型的大小取决于模型的物理大小及其分辨率。更高的工作频率需要更高的分辨率。这可能会将一些问题的解决方案置于技术能力之外。其次，问题的表现(即头部和电话)会造成一些困难。通常，电话必须用一系列近似实际设备形状的盒子来表示。本文解决了这两个问题。通过使用FDTD方法的并行化版本来适应问题的大小，该方法在大型并行处理机器(如IBM SP-2)上运行。此外，还开发了一种从电话的计算机辅助设计(CAD)文件中输入数据的方法。这两种技术与两个头部模型结合使用，这两个模型是从两个人类受试者的MRI图像中开发出来的。讨论了所开发的技术的有用性，并比较了两种模型的比吸收率。

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Computations of SAR distributions for two anatomically-based models of the human head using CAD files of commercial telephones and the parallelized FDTD code

The finite difference time domain (FDTD) method is well suited for the computation of bio-electromagnetic effects and has become the method of choice for most researchers in this area. There does however remain some limitations on its use. Firstly the FDTD method requires large amounts of memory and computational power. The size of the model is dependent upon both the physical size of the model and its resolution. Higher frequencies of operation require higher resolutions. This can place the solution of some problems outside the capabilities of the technique. Secondly the representation of the problem (i.e. the head and the telephone) can cause some difficulties. Often the telephone has to be represented by a series of boxes which approximate the shape of the actual device. The paper addresses these two problems. The problem size is accommodated by the use of a parallelized version of the FDTD method, which is run on large parallel processing machines such as the IBM SP-2. Additionally a method of inputting data from the computer aided design (CAD) files of the telephone has been developed. These two techniques are used in combination with two head models which have been developed from MRI images of two human subjects. The usefulness of the techniques developed and comparisons of the specific absorption rates (SARs) in the two models is discussed.

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IEEE Antennas and Propagation Society International Symposium 1997. Digest

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