Related papers: Symmetric and antisymmetric kernels for machine learning problems in quantum physics and chemistry

Symmetric and antisymmetric kernels for machine learning problems in quantum physics and chemistry

URL: http://arxiv.org/abs/2103.17233v1
Date: Wed, 31 Mar 2021 17:32:27 GMT
Title: Symmetric and antisymmetric kernels for machine learning problems in quantum physics and chemistry
Authors: Stefan Klus, Patrick Gel{\ss}, Feliks N\"uske, Frank No\'e
Abstract summary: We derive symmetric and antisymmetric kernels by symmetrizing and antisymmetrizing conventional kernels. We show that by exploiting symmetries or antisymmetries the size of the training data set can be significantly reduced.
Score: 0.3441021278275805
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We derive symmetric and antisymmetric kernels by symmetrizing and antisymmetrizing conventional kernels and analyze their properties. In particular, we compute the feature space dimensions of the resulting polynomial kernels, prove that the reproducing kernel Hilbert spaces induced by symmetric and antisymmetric Gaussian kernels are dense in the space of symmetric and antisymmetric functions, and propose a Slater determinant representation of the antisymmetric Gaussian kernel, which allows for an efficient evaluation even if the state space is high-dimensional. Furthermore, we show that by exploiting symmetries or antisymmetries the size of the training data set can be significantly reduced. The results are illustrated with guiding examples and simple quantum physics and chemistry applications.

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