南方科技大学知识苑(SUSTech KC): 一种基于GPU并行优化的进场动力学框架

题名	一种基于GPU并行优化的进场动力学框架
其他题名	A GPU-OPTIMIZED PARALLEL FRAMEWORK FOR PERIDYNAMICS
姓名	苏梓鑫
姓名拼音	SU Zixin
学号	12132416
学位类型	硕士
学位专业	0801 力学
学科门类/专业学位类别	08 工学
导师	刘轶军
导师单位	力学与航空航天工程系
论文答辩日期	2024-05-07
论文提交日期	2024-07-07
学位授予单位	南方科技大学
学位授予地点	深圳
摘要	近场动力学是一种新兴的基于非局部理论的力学分析框架，通过积分替代偏微分方程，在处理非连续性问题时避免了奇异性问题，特别适用于解决传统力学理论难以处理的非连续问题。然而，由于其计算过程离散成一系列带有一定体积的材料点或物质点，并分析材料邻域关系，因此计算量大大超过经典力学理论，而且需要大量内存容量。为解决上述问题，本文利用 GPU 并行的 CUDA 编程技术，对近场动力学的并行求解方法展开了研究，并设计了一个成本低、性能高的近场动力学模拟框架PD-General。本文的主要工作包括：（1）对邻域函数模块进行重构，重新设计获取实际邻域数量的方法，并据此分配内存和程序执行资源。同时，采用了高消耗指令替换和减少重复计算等策略，有效减少了计算量和计算指令的周期数，从而降低了全局内存的使用和线程的空置。（2）文章提出了两种优化访存效率的方法。一种是限制邻域数量，实现了高速计算效率；另一种是利用线程聚合和原子操作，解决了邻域数量的限制，虽然牺牲了轻量级的性能，但提高了访存效率。这些访存优化策略有效应用，使得优化后的程序相比未优化的程序加速了 5 到 30 倍。（3）基于以上优化，开发了一个基于 CUDA 的高性能近场动力学分析程序，实现了键基近场动力学、非常规态近场动力学以及支持键基近场动力学的裂纹模拟。该分析框架能够以高效的计算速率，准确地模拟常规近场动力学问题。相比串行程序和 OpenMP 并行程序，PD-General 分别取得了最大 800 倍和最大 100 倍的加速比。在常规百万级别的粒子模拟中，执行 4000 步迭代，单精度下可以在 5分钟内完成计算，双精度下可以在 20 分钟内完成模拟。在最大规模的探索上，程序实现了在单精度下，基于态基近场动力学解决 1000 步规模为 75,000,000 迭代的二维单轴拉伸问题的计算，仅需两分钟。
关键词	近场动力学 CUDA GPU并行计算访存优化
语种	中文
培养类别	独立培养
入学年份	2021
学位授予年份	2024-06
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所在学位评定分委会	力学
国内图书分类号	O39
来源库	人工提交
成果类型	学位论文
条目标识符	http://sustech.caswiz.com/handle/2SGJ60CL/779085
专题	工学院_力学与航空航天工程系
推荐引用方式 GB/T 7714	苏梓鑫. 一种基于GPU并行优化的进场动力学框架[D]. 深圳. 南方科技大学,2024.

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