Solution of the $k$-th eigenvalue problem in large-scale electronic structure calculations
Abstract
We consider computing the -th eigenvalue and its corresponding eigenvector of a generalized Hermitian eigenvalue problem of large sparse matrices. In electronic structure calculations, several properties of materials, such as those of optoelectronic device materials, are governed by the eigenpair with a material-specific index We present a three-stage algorithm for computing the -th eigenpair with validation of its index. In the first stage of the algorithm, we propose an efficient way of finding an interval containing the -th eigenvalue with a non-standard application of the Lanczos method. In the second stage, spectral bisection for large-scale problems is realized using a sparse direct linear solver to narrow down the interval of the -th eigenvalue. In the third stage, we switch to a modified shift-and-invert Lanczos method to reduce bisection iterations and compute the -th eigenpair with validation. Numerical results with problem sizes up to 1.5 million are reported, and the results demonstrate the accuracy and efficiency of the three-stage algorithm.
Keywords
Cite
@article{arxiv.1710.05134,
title = {Solution of the $k$-th eigenvalue problem in large-scale electronic structure calculations},
author = {Dongjin Lee and Takeo Hoshi and Tomohiro Sogabe and Yuto Miyatake and Shao-Liang Zhang},
journal= {arXiv preprint arXiv:1710.05134},
year = {2018}
}