Related papers: 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

URL: http://arxiv.org/abs/2412.05554v1
Date: Sat, 07 Dec 2024 06:25:54 GMT
Title: Rydberg Atomic Quantum Receivers for Classical Wireless Communications and Sensing: Their Models and Performance
Authors: Tierui Gong, Jiaming Sun, Chau Yuen, Guangwei Hu, Yufei Zhao, Yong Liang Guan, Chong Meng Samson See, Mérouane Debbah, Lajos Hanzo,
Abstract summary: Rydberg atomic quantum receivers (RAQRs) are an eminent solution for detecting the electric field of radio frequency (RF) signals. We introduce the superheterodyne version of RAQRs 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.
Score: 78.76421728334013
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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 a 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 the conventional RF receivers have not been fully characterized. To fill the gap, we introduce the superheterodyne version of RAQRs 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 a half-wavelength dipole antenna based conventional RF receiver. The results show that the RAQR is capable of achieving a substantial receive signal-to-noise ratio (SNR) gain of $\sim 22.6$ decibel (dB) and $\sim 33.5$ dB in the standard (unoptimized) and optimized configurations, respectively.

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