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引用次数: 0
摘要
我们提出了一个简单且易于实现的图形处理单元(GPU)加速程序,用于数值模拟超短强激光脉冲与介质相互作用时的传播。该例程基于麦克斯韦波动方程的频域解,采用扩展的Crank-Nicolson算法,在Nvidia CUDA c++编程语言中实现。我们的方法的主要优点是其显著的加速因子和易于实现,只需要CUDA和c++的基本知识。在本文中,我们回顾了需要求解的强场波动方程及其离散化,并演示了如何在Nvidia GPU上实现它们的数值求解器。我们展示了近红外激光脉冲在部分电离原子气体中传播的模拟结果,并讨论了我们的gpu加速方案的性能。与实现相同例程的naïve中央处理单元相比,我们的gpu加速版本在标准机制下的速度高达198倍。
A simple graphics processing unit-accelerated propagation routine for laser pulses in the strong-field regime.
We present a simple and easy-to-implement Graphics Processing Unit (GPU)-accelerated routine to numerically simulate the propagation of ultrashort and intense laser pulses as they interact with a medium. The routine is based on the solution of Maxwell's wave equation in the frequency domain with an extended Crank-Nicolson algorithm implemented in the Nvidia CUDA C++ programming language. The main advantages of our method are its significant speed-up factor and its ease of implementation, requiring only basic knowledge of CUDA and C++. In this article, we review the strong-field wave equations to be solved and their discretization and demonstrate how to implement a numerical solver for them on an Nvidia GPU. We show the results of the simulation of a near-infrared laser pulse propagating through a partially ionized atomic gas and discuss the performance of our GPU-accelerated scheme. Compared to a naïve central processing unit implementation of the same routine, our GPU-accelerated version is up to 198 times faster in standard regimes.
期刊介绍:
Review of Scientific Instruments, is committed to the publication of advances in scientific instruments, apparatuses, and techniques. RSI seeks to meet the needs of engineers and scientists in physics, chemistry, and the life sciences.
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