Harnessing Rydberg Atomic Receivers: From Quantum Physics to Wireless Communications

TL;DR

This paper explores the integration of Rydberg atomic receivers into wireless communication systems, demonstrating significant SNR improvements and practical modeling for quantum-based wireless signal detection.

Contribution

It introduces a novel wireless model for Rydberg atomic receivers, including LO-dressed and LO-free configurations, and demonstrates their superior SNR performance through simulations.

Findings

LO-dressed Rydberg receivers achieve 40-50 dB SNR gain.

The developed model aligns with classical RF frameworks.

Enhanced SNR enables higher-order modulation with lower error rates.

Abstract

The intrinsic integration of Rydberg atomic receivers into wireless communication systems is proposed, by harnessing the principles of quantum physics in wireless communications. More particularly, we conceive a pair of Rydberg atomic receivers, one incorporates a local oscillator (LO), referred to as an LO-dressed receiver, while the other operates without an LO and is termed an LO-free receiver. The appropriate wireless model is developed for each configuration, elaborating on the receiver's responses to the radio frequency (RF) signal, on the potential noise sources, and on the signal-to-noise ratio (SNR) performance. The developed wireless model conforms to the classical RF framework, facilitating compatibility with established signal processing methodologies. Next, we investigate the associated distortion effects that might occur, specifically identifying the conditions under which distortion arises and demonstrating the boundaries of linear dynamic ranges. This provides critical insights into its practical implementations in wireless systems. Finally, extensive simulation results are provided for characterizing the performance of wireless systems, harnessing this pair of Rydberg atomic receivers. Our results demonstrate that LO-dressed systems achieve a significant SNR gain of approximately 40~50 dB over conventional RF receivers in the standard quantum limit regime. This SNR head-room translates into reduced symbol error rates, enabling efficient and reliable transmission with higher-order constellations.