Accelerating FDTD simulation of microwave pulse coupling into narrow slots on the Intel MIC architecture

2015 IEEE Pacific Rim Conference on Communications, Computers and Signal Processing (PACRIM) Pub Date : 2015-11-30 DOI:10.1109/PACRIM.2015.7334845

Qinglin Wang, Jie Liu, Xiantao Cui, Guitao Fu, Chunye Gong, Zuocheng Xing

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引用次数: 1

Abstract

The coupling of microwaves into apertures plays an important part in many electromagnetic physics and engineering fields. When the width of apertures is very small, Finite Difference Time Domain (FDTD) simulation of the coupling is very time-consuming. As a many-core architecture, the Intel's Many Integrated Core (MIC) architecture owns 512-bit vector units and more than 200 threads. In this paper, we parallelize FDTD simulation of microwave pulse coupling into narrow slots on the Intel MIC architecture. In the implementation, the parallel programming model OpenMP is used to exploit thread parallelism while loop unrolling and SIMD intrinsic functions are utilized to accomplish vectorization. Compared with the serial version on Intel Xeon E5-2670 CPU, the implementation on the MIC coprocessor including 57 cores obtains a speedup of 11.57 times. The experiment results also demonstrate that the parallelization has good scalability in performance. Additionally, how binding relationship between OpenMP threads and hardware threads in MIC influences performance is also reported.

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在Intel MIC架构上加速微波脉冲耦合的时域有限差分模拟

微波与孔径的耦合在许多电磁物理和工程领域中起着重要的作用。当孔径很小时，耦合的时域有限差分(FDTD)仿真非常耗时。作为一种多核架构，英特尔的多集成核心(MIC)架构拥有512位矢量单元和200多个线程。在本文中，我们在Intel MIC架构上并行化时域有限差分法模拟微波脉冲耦合的窄槽。在实现中，采用并行编程模型OpenMP开发线程并行性，利用循环展开和SIMD固有函数实现向量化。与在Intel至强E5-2670 CPU上的串行版本相比，在57核MIC协处理器上的实现速度提高了11.57倍。实验结果还表明，并行化在性能上具有良好的可扩展性。此外，还报告了MIC中OpenMP线程和硬件线程之间的绑定关系如何影响性能。

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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2015 IEEE Pacific Rim Conference on Communications, Computers and Signal Processing (PACRIM)

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