Rydberg atomic quantum receivers for classical wireless communications and sensing: their models and performance
Rydberg atomic quantum receivers for classical wireless communications and sensing: their models and performance
The significant progress of quantum sensing technologies offer numerous radical solutions for measuring a multitude of physical quantities at an unprecedented precision. Among them, Rydberg atomic quantum receivers (RAQRs) emerge as an eminent solution for detecting the electric field of radio frequency(RF) signals, exhibiting great potential in assisting classical wireless communications and sensing. So far, most experimental studies have aimed for the proof of physical concepts to reveal its promise, while the practical signal model of RAQR-aided wireless communications and sensing remained under-explored. Furthermore, the performance of RAQR-based wireless receivers and their advantages over classical RF receivers have not been fully characterized. To fill these gaps, we introduce the RAQR to the wireless community by presenting an end-to-end reception scheme. We then develop a corresponding equivalent baseband signal model relying on a realistic reception flow. Our scheme and model provide explicit design guidance to RAQR-aided wireless systems. We next study the performance of RAQR-aided wireless systems based on our model, and compare them to classical RF receivers. The results show that Doppler broadening-free RAQRs are capable of achieving a substantial received signal-to-noise ratio (SNR) gain of over 27 decibel (dB) and 40 dB in the photon shot limit and standard quantum limit regimes, respectively.
Gong, Tierui
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Sun, Jiaming
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Yuen, Chau
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Hu, Guangwei
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Zhao, Yufei
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Guan, Yong Liang
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See, Chong Meng Samson
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Debbah, Merouane
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Hanzo, Lajos
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Liu, Xin
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Gong, Tierui
3800407f-0d7e-4cfa-a3e0-f0b91371507f
Sun, Jiaming
4066ca58-553a-4664-a110-7adc372692ce
Yuen, Chau
9f4920a1-d74b-44a5-bc81-de987e0fee84
Hu, Guangwei
1f9c0b8b-2f04-4898-88ac-526eb9008379
Zhao, Yufei
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Guan, Yong Liang
df09a087-ccea-4274-9e83-6f9d950e98d7
See, Chong Meng Samson
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Debbah, Merouane
bd20ab2e-28c0-4fae-8dad-b72bcf4344d7
Hanzo, Lajos
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Gong, Tierui, Sun, Jiaming, Yuen, Chau, Hu, Guangwei, Zhao, Yufei, Guan, Yong Liang, See, Chong Meng Samson, Debbah, Merouane and Hanzo, Lajos
(2026)
Rydberg atomic quantum receivers for classical wireless communications and sensing: their models and performance.
IEEE Transactions on Communications.
(In Press)
Abstract
The significant progress of quantum sensing technologies offer numerous radical solutions for measuring a multitude of physical quantities at an unprecedented precision. Among them, Rydberg atomic quantum receivers (RAQRs) emerge as an eminent solution for detecting the electric field of radio frequency(RF) signals, exhibiting great potential in assisting classical wireless communications and sensing. So far, most experimental studies have aimed for the proof of physical concepts to reveal its promise, while the practical signal model of RAQR-aided wireless communications and sensing remained under-explored. Furthermore, the performance of RAQR-based wireless receivers and their advantages over classical RF receivers have not been fully characterized. To fill these gaps, we introduce the RAQR to the wireless community by presenting an end-to-end reception scheme. We then develop a corresponding equivalent baseband signal model relying on a realistic reception flow. Our scheme and model provide explicit design guidance to RAQR-aided wireless systems. We next study the performance of RAQR-aided wireless systems based on our model, and compare them to classical RF receivers. The results show that Doppler broadening-free RAQRs are capable of achieving a substantial received signal-to-noise ratio (SNR) gain of over 27 decibel (dB) and 40 dB in the photon shot limit and standard quantum limit regimes, respectively.
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Accepted/In Press date: 4 April 2026
Identifiers
Local EPrints ID: 511645
URI: http://eprints.soton.ac.uk/id/eprint/511645
ISSN: 0090-6778
PURE UUID: 1356a931-9e63-4da2-97a9-846eba0d1367
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Date deposited: 26 May 2026 16:47
Last modified: 27 May 2026 01:32
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Contributors
Illustrator:
Xin Liu
Author:
Tierui Gong
Author:
Jiaming Sun
Author:
Chau Yuen
Author:
Guangwei Hu
Author:
Yufei Zhao
Author:
Yong Liang Guan
Author:
Chong Meng Samson See
Author:
Merouane Debbah
Author:
Lajos Hanzo
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