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Main Authors: Liu, Yu-Hong, Zeng, Yexiong, Tan, Qing-Shou, Dong, Daoyi, Nori, Franco, Liao, Jie-Qiao
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.05597
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author Liu, Yu-Hong
Zeng, Yexiong
Tan, Qing-Shou
Dong, Daoyi
Nori, Franco
Liao, Jie-Qiao
author_facet Liu, Yu-Hong
Zeng, Yexiong
Tan, Qing-Shou
Dong, Daoyi
Nori, Franco
Liao, Jie-Qiao
contents Efficiently controlling linear Gaussian quantum (LGQ) systems is a significant task in both the study of fundamental quantum theory and the development of modern quantum technology. Here, we propose a general quantum-learning-control method for optimally controlling LGQ systems based on the gradient-descent algorithm. Our approach flexibly designs the loss function for diverse tasks by utilizing first- and second-order moments that completely describe the quantum state of LGQ systems. We demonstrate both deep optomechanical cooling and large optomechanical entanglement using this approach. Our approach enables the fast and deep ground-state cooling of a mechanical resonator within a short time, surpassing the limitations of sideband cooling in the continuous-wave driven strong-coupling regime. Furthermore, optomechanical entanglement could be generated remarkably fast and surpass several times the corresponding steady-state entanglement, even when the thermal phonon occupation reaches one hundred. This work will not only broaden the application of quantum learning control, but also open an avenue for optimal control of LGQ systems.
format Preprint
id arxiv_https___arxiv_org_abs_2406_05597
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimal control of linear Gaussian quantum systems via quantum learning control
Liu, Yu-Hong
Zeng, Yexiong
Tan, Qing-Shou
Dong, Daoyi
Nori, Franco
Liao, Jie-Qiao
Quantum Physics
Efficiently controlling linear Gaussian quantum (LGQ) systems is a significant task in both the study of fundamental quantum theory and the development of modern quantum technology. Here, we propose a general quantum-learning-control method for optimally controlling LGQ systems based on the gradient-descent algorithm. Our approach flexibly designs the loss function for diverse tasks by utilizing first- and second-order moments that completely describe the quantum state of LGQ systems. We demonstrate both deep optomechanical cooling and large optomechanical entanglement using this approach. Our approach enables the fast and deep ground-state cooling of a mechanical resonator within a short time, surpassing the limitations of sideband cooling in the continuous-wave driven strong-coupling regime. Furthermore, optomechanical entanglement could be generated remarkably fast and surpass several times the corresponding steady-state entanglement, even when the thermal phonon occupation reaches one hundred. This work will not only broaden the application of quantum learning control, but also open an avenue for optimal control of LGQ systems.
title Optimal control of linear Gaussian quantum systems via quantum learning control
topic Quantum Physics
url https://arxiv.org/abs/2406.05597