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Bibliographic Details
Main Authors: Kallullathil, Sangeeth Das, Carrington, Tucker
Format: Preprint
Published: 2021
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Online Access:https://arxiv.org/abs/2110.07970
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author Kallullathil, Sangeeth Das
Carrington, Tucker
author_facet Kallullathil, Sangeeth Das
Carrington, Tucker
contents Present day computers do not have enough memory to store the high-dimensional tensors required when using a direct product basis to compute vibrational energy levels of a polyatomic molecule with more than about 5 atoms. One way to deal with this problem is to represent tensors using a tensor format. In this paper, we use CP format. Energy levels are computed by building a basis from vectors obtained by solving linear equations. The method can be thought of as a CP realization of a block inverse iteration method with multiple shifts. The CP rank of the tensors is fixed and the linear equations are solved with an Alternating Least Squares method. There is no need for rank reduction, no need for orthogonalization, and tensors with rank larger than the fixed rank used to solve the linear equations are never generated. The ideas are tested by computing vibrational energy levels of a 64-D bilinearly coupled model Hamiltonian and of acetonitrile(12-D).
format Preprint
id arxiv_https___arxiv_org_abs_2110_07970
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Computing vibrational energy levels by solving linear equations using a tensor method with an imposed rank
Kallullathil, Sangeeth Das
Carrington, Tucker
Computational Physics
Present day computers do not have enough memory to store the high-dimensional tensors required when using a direct product basis to compute vibrational energy levels of a polyatomic molecule with more than about 5 atoms. One way to deal with this problem is to represent tensors using a tensor format. In this paper, we use CP format. Energy levels are computed by building a basis from vectors obtained by solving linear equations. The method can be thought of as a CP realization of a block inverse iteration method with multiple shifts. The CP rank of the tensors is fixed and the linear equations are solved with an Alternating Least Squares method. There is no need for rank reduction, no need for orthogonalization, and tensors with rank larger than the fixed rank used to solve the linear equations are never generated. The ideas are tested by computing vibrational energy levels of a 64-D bilinearly coupled model Hamiltonian and of acetonitrile(12-D).
title Computing vibrational energy levels by solving linear equations using a tensor method with an imposed rank
topic Computational Physics
url https://arxiv.org/abs/2110.07970