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Main Authors: Dawson, William, Ozaki, Katsuhisa, Domke, Jens, Nakajima, Takahito
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.13299
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author Dawson, William
Ozaki, Katsuhisa
Domke, Jens
Nakajima, Takahito
author_facet Dawson, William
Ozaki, Katsuhisa
Domke, Jens
Nakajima, Takahito
contents The abundant demand for deep learning compute resources has created a renaissance in low precision hardware. Going forward, it will be essential for simulation software to run on this new generation of machines without sacrificing scientific fidelity. In this paper, we examine the precision requirements of a representative kernel from quantum chemistry calculations: calculation of the single particle density matrix from a given mean field Hamiltonian (i.e. Hartree-Fock or Density Functional Theory) represented in an LCAO basis. We find that double precision affords an unnecessarily high level of precision, leading to optimization opportunities. We show how an approximation built from an error-free matrix multiplication transformation can be used to potentially accelerate this kernel on future hardware. Our results provide a road map for adapting quantum chemistry software for the next generation of High Performance Computing platforms.
format Preprint
id arxiv_https___arxiv_org_abs_2407_13299
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Reducing Numerical Precision Requirements in Quantum Chemistry Calculations
Dawson, William
Ozaki, Katsuhisa
Domke, Jens
Nakajima, Takahito
Chemical Physics
The abundant demand for deep learning compute resources has created a renaissance in low precision hardware. Going forward, it will be essential for simulation software to run on this new generation of machines without sacrificing scientific fidelity. In this paper, we examine the precision requirements of a representative kernel from quantum chemistry calculations: calculation of the single particle density matrix from a given mean field Hamiltonian (i.e. Hartree-Fock or Density Functional Theory) represented in an LCAO basis. We find that double precision affords an unnecessarily high level of precision, leading to optimization opportunities. We show how an approximation built from an error-free matrix multiplication transformation can be used to potentially accelerate this kernel on future hardware. Our results provide a road map for adapting quantum chemistry software for the next generation of High Performance Computing platforms.
title Reducing Numerical Precision Requirements in Quantum Chemistry Calculations
topic Chemical Physics
url https://arxiv.org/abs/2407.13299