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Main Authors: Xu, Jiaxin, Xu, Lechen, Liu, Jingyang, Ding, Huajian, Wang, Qin
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.09069
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author Xu, Jiaxin
Xu, Lechen
Liu, Jingyang
Ding, Huajian
Wang, Qin
author_facet Xu, Jiaxin
Xu, Lechen
Liu, Jingyang
Ding, Huajian
Wang, Qin
contents Quantum communication and quantum sensing, which leverage the unique characteristics of quantum systems, enable information-theoretically secure communication and high-precision measurement of physical quantities. However, they both face numerous challenges on the path to practical application. Artificial intelligence (AI), as a major technological advancement in current scientific landscape, offers powerful data processing and analytical capabilities, providing new ideas and methods for optimizing and enhancing quantum communication and sensing systems. In quantum communication, AI techniques have greatly improved the performance and security of quantum key distribution, quantum memory, and quantum networks through parameter optimization, real-time feedback control, and attack detection. In quantum sensing, quantum sensing technology enables ultra-high sensitivity detection of physical quantities such as time and magnetic fields. The introduction of AI has opened up new avenues for achieving high-precision and high-sensitivity quantum measurements. With AI, sensor performance is optimized, and measurement accuracy is further enhanced through data analysis. This paper also analyzes the current challenges in using AI to empower quantum communication and sensing systems, such as implementing efficient algorithm deployment and system feedback control under limited computational resources, and addressing complex task environments, dynamically changing scenarios, and multi-task coordination requirements. Finally, this paper discusses and envisions future development prospects in this field.
format Preprint
id arxiv_https___arxiv_org_abs_2511_09069
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Research progress of artificial intelligence empowered quantum communication and quantum sensing systems
Xu, Jiaxin
Xu, Lechen
Liu, Jingyang
Ding, Huajian
Wang, Qin
Quantum Physics
Quantum communication and quantum sensing, which leverage the unique characteristics of quantum systems, enable information-theoretically secure communication and high-precision measurement of physical quantities. However, they both face numerous challenges on the path to practical application. Artificial intelligence (AI), as a major technological advancement in current scientific landscape, offers powerful data processing and analytical capabilities, providing new ideas and methods for optimizing and enhancing quantum communication and sensing systems. In quantum communication, AI techniques have greatly improved the performance and security of quantum key distribution, quantum memory, and quantum networks through parameter optimization, real-time feedback control, and attack detection. In quantum sensing, quantum sensing technology enables ultra-high sensitivity detection of physical quantities such as time and magnetic fields. The introduction of AI has opened up new avenues for achieving high-precision and high-sensitivity quantum measurements. With AI, sensor performance is optimized, and measurement accuracy is further enhanced through data analysis. This paper also analyzes the current challenges in using AI to empower quantum communication and sensing systems, such as implementing efficient algorithm deployment and system feedback control under limited computational resources, and addressing complex task environments, dynamically changing scenarios, and multi-task coordination requirements. Finally, this paper discusses and envisions future development prospects in this field.
title Research progress of artificial intelligence empowered quantum communication and quantum sensing systems
topic Quantum Physics
url https://arxiv.org/abs/2511.09069