Optical quantum sensing for agnostic environments via deep learning
Optical quantum sensing promises measurement precision beyond classical sensors termed the Heisenberg limit (HL). However, conventional methodologies often rely on prior knowledge of the target system to achieve HL, presenting challenges in practical applications. Addressing this limitation, we intr...
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sg-ntu-dr.10356-1821232025-01-08T08:01:13Z Optical quantum sensing for agnostic environments via deep learning Zhou, Zeqiao Du, Yuxuan Yin, Xu-Fei Zhao, Shanshan Tian, Xinmei Tao, Dacheng College of Computing and Data Science Computer and Information Science Fisher information Graph neural networks Optical quantum sensing promises measurement precision beyond classical sensors termed the Heisenberg limit (HL). However, conventional methodologies often rely on prior knowledge of the target system to achieve HL, presenting challenges in practical applications. Addressing this limitation, we introduce an innovative deep-learning-based quantum sensing scheme (DQS), enabling optical quantum sensors to attain HL in agnostic environments. DQS incorporates two essential components: a graph neural network (GNN) predictor and a trigonometric interpolation algorithm. Operating within a data-driven paradigm, DQS utilizes the GNN predictor, trained on offline data, to unveil the intrinsic relationships between the optical setups employed in preparing the probe state and the resulting quantum Fisher information (QFI) after interaction with the agnostic environment. This distilled knowledge facilitates the identification of optimal optical setups associated with maximal QFI. Subsequently, DQS employs a trigonometric interpolation algorithm to recover the unknown parameter estimates for the identified optical setups. Extensive experiments are conducted to investigate the performance of DQS under different settings up to eight photons. Our findings not only offer a different lens through which to accelerate optical quantum sensing tasks but also catalyze future research integrating deep learning and quantum mechanics. Nanyang Technological University Published version This work was supported in part by NSFC Grant No. 62222117. X.-F.Y. acknowledges support from the China Postdoctoral Science Foundation (Grant No. 2023M733418). Dr. Tao’s research is partially supported by NTU RSR and Start Up Grants. 2025-01-08T08:01:12Z 2025-01-08T08:01:12Z 2024 Journal Article Zhou, Z., Du, Y., Yin, X., Zhao, S., Tian, X. & Tao, D. (2024). Optical quantum sensing for agnostic environments via deep learning. Physical Review Research, 6(4), 043267-. https://dx.doi.org/10.1103/PhysRevResearch.6.043267 2643-1564 https://hdl.handle.net/10356/182123 10.1103/PhysRevResearch.6.043267 2-s2.0-85212537029 4 6 043267 en NTU RSR NTU SUG Physical Review Research © The Authors. Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI. application/pdf |
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Computer and Information Science Fisher information Graph neural networks Zhou, Zeqiao Du, Yuxuan Yin, Xu-Fei Zhao, Shanshan Tian, Xinmei Tao, Dacheng Optical quantum sensing for agnostic environments via deep learning |
| description |
Optical quantum sensing promises measurement precision beyond classical sensors termed the Heisenberg limit (HL). However, conventional methodologies often rely on prior knowledge of the target system to achieve HL, presenting challenges in practical applications. Addressing this limitation, we introduce an innovative deep-learning-based quantum sensing scheme (DQS), enabling optical quantum sensors to attain HL in agnostic environments. DQS incorporates two essential components: a graph neural network (GNN) predictor and a trigonometric interpolation algorithm. Operating within a data-driven paradigm, DQS utilizes the GNN predictor, trained on offline data, to unveil the intrinsic relationships between the optical setups employed in preparing the probe state and the resulting quantum Fisher information (QFI) after interaction with the agnostic environment. This distilled knowledge facilitates the identification of optimal optical setups associated with maximal QFI. Subsequently, DQS employs a trigonometric interpolation algorithm to recover the unknown parameter estimates for the identified optical setups. Extensive experiments are conducted to investigate the performance of DQS under different settings up to eight photons. Our findings not only offer a different lens through which to accelerate optical quantum sensing tasks but also catalyze future research integrating deep learning and quantum mechanics. |
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College of Computing and Data Science |
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College of Computing and Data Science Zhou, Zeqiao Du, Yuxuan Yin, Xu-Fei Zhao, Shanshan Tian, Xinmei Tao, Dacheng |
| format |
Article |
| author |
Zhou, Zeqiao Du, Yuxuan Yin, Xu-Fei Zhao, Shanshan Tian, Xinmei Tao, Dacheng |
| author_sort |
Zhou, Zeqiao |
| title |
Optical quantum sensing for agnostic environments via deep learning |
| title_short |
Optical quantum sensing for agnostic environments via deep learning |
| title_full |
Optical quantum sensing for agnostic environments via deep learning |
| title_fullStr |
Optical quantum sensing for agnostic environments via deep learning |
| title_full_unstemmed |
Optical quantum sensing for agnostic environments via deep learning |
| title_sort |
optical quantum sensing for agnostic environments via deep learning |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182123 |
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1821237190735167488 |