Related papers: Resolution enhancement of one-dimensional molecular wavefunctions in plane-wave basis via quantum machine learning

Resolution enhancement of one-dimensional molecular wavefunctions in plane-wave basis via quantum machine learning

URL: http://arxiv.org/abs/2211.04336v1
Date: Tue, 8 Nov 2022 15:54:49 GMT
Title: Resolution enhancement of one-dimensional molecular wavefunctions in plane-wave basis via quantum machine learning
Authors: Rei Sakuma, Yutaro Iiyama, Lento Nagano, Ryu Sawada, Koji Terashi
Abstract summary: Super-resolution is a machinelearning technique in image processing which generates high-resolution images from low-resolution images. Inspired by this approach, we perform a numerical experiment of quantum machine learning, which takes low-resolution (low plane-wave energy cutoff) one-particle molecular wavefunctions in plane-wave basis as input. We show that the trained models can generate wavefunctions having higher fidelity values with respect to the ground-truth wave-functions, and the results can be improved both qualitatively and quantitatively by including data-dependent information in the ansatz.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Super-resolution is a machine-learning technique in image processing which generates high-resolution images from low-resolution images. Inspired by this approach, we perform a numerical experiment of quantum machine learning, which takes low-resolution (low plane-wave energy cutoff) one-particle molecular wavefunctions in plane-wave basis as input and generates high-resolution (high plane-wave energy cutoff) wavefunctions in fictitious one-dimensional systems, and study the performance of different learning models. We show that the trained models can generate wavefunctions having higher fidelity values with respect to the ground-truth wavefunctions than a simple linear interpolation, and the results can be improved both qualitatively and quantitatively by including data-dependent information in the ansatz. On the other hand, the accuracy of the current approach deteriorates for wavefunctions calculated in electronic configurations not included in the training dataset. We also discuss the generalization of this approach to many-body electron wavefunctions.

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