对称自洽特征值计算中并行移反频谱切片的移位选择策略

David B. Williams-Young, Paul G. Beckman, Chao Yang
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引用次数: 5

摘要

大规模特征值问题在科学计算中的核心重要性要求开发大规模并行算法来解决这些问题。密集数值线性代数的最新进展使得在世界上最大的超级计算机上能够常规地处理数十万维数的特征值问题。在密集处理不可行的情况下,Krylov子空间方法提供了一个有吸引力的替代方案,因为它们不需要存储问题矩阵。然而,由于通信需求和串行瓶颈,这两类特征值算法在能够表达大规模并行性的计算架构上的可扩展性的演示是非平凡的。在这项工作中,我们介绍了SISLICE方法:一种求解对称自洽场(SCF)特征值问题的并行移位-逆变算法。SISLICE方法分别通过基于状态密度估计和k-means聚类的各种移位选择和迁移技术,极大地降低了当前并行移位-反特征值算法的通信需求。这项工作证明了SISLICE方法在SCF特征值问题的代表性集上的鲁棒性和并行性能,并概述了未来工作将探索的研究方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Shift Selection Strategy for Parallel Shift-invert Spectrum Slicing in Symmetric Self-consistent Eigenvalue Computation
The central importance of large-scale eigenvalue problems in scientific computation necessitates the development of massively parallel algorithms for their solution. Recent advances in dense numerical linear algebra have enabled the routine treatment of eigenvalue problems with dimensions on the order of hundreds of thousands on the world’s largest supercomputers. In cases where dense treatments are not feasible, Krylov subspace methods offer an attractive alternative due to the fact that they do not require storage of the problem matrices. However, demonstration of scalability of either of these classes of eigenvalue algorithms on computing architectures capable of expressing massive parallelism is non-trivial due to communication requirements and serial bottlenecks, respectively. In this work, we introduce the SISLICE method: a parallel shift-invert algorithm for the solution of the symmetric self-consistent field (SCF) eigenvalue problem. The SISLICE method drastically reduces the communication requirement of current parallel shift-invert eigenvalue algorithms through various shift selection and migration techniques based on density of states estimation and k-means clustering, respectively. This work demonstrates the robustness and parallel performance of the SISLICE method on a representative set of SCF eigenvalue problems and outlines research directions that will be explored in future work.
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