Koopman analysis of quantum systems
- URL: http://arxiv.org/abs/2201.12062v2
- Date: Tue, 28 Jun 2022 14:16:53 GMT
- Title: Koopman analysis of quantum systems
- Authors: Stefan Klus, Feliks N\"uske, Sebastian Peitz
- Abstract summary: Koopman operator theory has been successfully applied to problems from various research areas.
In this paper, we show how data-driven methods for the approximation of the Koopman operator can be used to analyze quantum physics problems.
We exploit the relationship between Schr"odinger operators and control problems to show that modern data-driven methods for control can be used to solve the stationary or imaginary-time Schr"odinger equation.
- Score: 0.3093890460224435
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Koopman operator theory has been successfully applied to problems from
various research areas such as fluid dynamics, molecular dynamics, climate
science, engineering, and biology. Applications include detecting metastable or
coherent sets, coarse-graining, system identification, and control. There is an
intricate connection between dynamical systems driven by stochastic
differential equations and quantum mechanics. In this paper, we compare the
ground-state transformation and Nelson's stochastic mechanics and demonstrate
how data-driven methods developed for the approximation of the Koopman operator
can be used to analyze quantum physics problems. Moreover, we exploit the
relationship between Schr\"odinger operators and stochastic control problems to
show that modern data-driven methods for stochastic control can be used to
solve the stationary or imaginary-time Schr\"odinger equation. Our findings
open up a new avenue towards solving Schr\"odinger's equation using recently
developed tools from data science.
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