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Main Authors: Wang, Zhao-Wei, Wang, Zhao-Ming
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.16368
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author Wang, Zhao-Wei
Wang, Zhao-Ming
author_facet Wang, Zhao-Wei
Wang, Zhao-Ming
contents The preparation of quantum states is essential in the realm of quantum information processing, and the development of efficient methodologies can significantly alleviate the strain on quantum resources. Within the framework of deep reinforcement learning (DRL), we integrate the initial and the target state information within the state preparation task together, so as to realize the control trajectory design between two arbitrary quantum states. Utilizing a semiconductor double quantum dots (DQDs) model, our results demonstrate that the resulting control trajectories can effectively achieve arbitrary quantum state preparation (AQSP) for both single-qubit and two-qubit systems, with average fidelities of 0.9868 and 0.9556 for the test sets, respectively. Furthermore, we consider the noise around the system and the control trajectories exhibit commendable robustness against charge and nuclear noise. Our study not only substantiates the efficacy of DRL in QSP, but also provides a new solution for quantum control tasks of multi-initial and multi-objective states, and is expected to be extended to a wider range of quantum control problems.
format Preprint
id arxiv_https___arxiv_org_abs_2407_16368
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Arbitrary quantum states preparation aided by deep reinforcement learning
Wang, Zhao-Wei
Wang, Zhao-Ming
Quantum Physics
The preparation of quantum states is essential in the realm of quantum information processing, and the development of efficient methodologies can significantly alleviate the strain on quantum resources. Within the framework of deep reinforcement learning (DRL), we integrate the initial and the target state information within the state preparation task together, so as to realize the control trajectory design between two arbitrary quantum states. Utilizing a semiconductor double quantum dots (DQDs) model, our results demonstrate that the resulting control trajectories can effectively achieve arbitrary quantum state preparation (AQSP) for both single-qubit and two-qubit systems, with average fidelities of 0.9868 and 0.9556 for the test sets, respectively. Furthermore, we consider the noise around the system and the control trajectories exhibit commendable robustness against charge and nuclear noise. Our study not only substantiates the efficacy of DRL in QSP, but also provides a new solution for quantum control tasks of multi-initial and multi-objective states, and is expected to be extended to a wider range of quantum control problems.
title Arbitrary quantum states preparation aided by deep reinforcement learning
topic Quantum Physics
url https://arxiv.org/abs/2407.16368