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Autori principali: Hunstig, Anna, Peitz, Sebastian, Rose, Hendrik, Meier, Torsten
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2310.16578
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author Hunstig, Anna
Peitz, Sebastian
Rose, Hendrik
Meier, Torsten
author_facet Hunstig, Anna
Peitz, Sebastian
Rose, Hendrik
Meier, Torsten
contents The prediction of photon echoes is a crucial technique for understanding optical quantum systems. However, it typically requires numerous simulations with varying parameters and input pulses, rendering numerical studies computationally expensive. This article investigates the use of data-driven surrogate models based on the Koopman operator to accelerate this process while maintaining accuracy over many time steps. To this end, we employ a bilinear Koopman model using extended dynamic mode decomposition to simulate the optical Bloch equations for an ensemble of inhomogeneously broadened two-level systems. These systems are well suited to describe the excitation of excitonic resonances in semiconductor nanostructures, such as ensembles of semiconductor quantum dots. We conduct a detailed study to determine the number of system simulations required for the resulting data-driven Koopman model to achieve sufficient accuracy across a wide range of parameter settings. We analyze the L2 error and the relative error of the photon echo peak and investigate how the control positions relate to stabilization. After proper training, our methods can predict the dynamics of the quantum ensemble accurately and with numerical efficiency.
format Preprint
id arxiv_https___arxiv_org_abs_2310_16578
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Accelerating the analysis of optical quantum systems using the Koopman operator
Hunstig, Anna
Peitz, Sebastian
Rose, Hendrik
Meier, Torsten
Quantum Physics
Dynamical Systems
The prediction of photon echoes is a crucial technique for understanding optical quantum systems. However, it typically requires numerous simulations with varying parameters and input pulses, rendering numerical studies computationally expensive. This article investigates the use of data-driven surrogate models based on the Koopman operator to accelerate this process while maintaining accuracy over many time steps. To this end, we employ a bilinear Koopman model using extended dynamic mode decomposition to simulate the optical Bloch equations for an ensemble of inhomogeneously broadened two-level systems. These systems are well suited to describe the excitation of excitonic resonances in semiconductor nanostructures, such as ensembles of semiconductor quantum dots. We conduct a detailed study to determine the number of system simulations required for the resulting data-driven Koopman model to achieve sufficient accuracy across a wide range of parameter settings. We analyze the L2 error and the relative error of the photon echo peak and investigate how the control positions relate to stabilization. After proper training, our methods can predict the dynamics of the quantum ensemble accurately and with numerical efficiency.
title Accelerating the analysis of optical quantum systems using the Koopman operator
topic Quantum Physics
Dynamical Systems
url https://arxiv.org/abs/2310.16578