📝 SummarXiv

Abstract

Rydberg atomic quantum receivers have been seen as novel radio frequency measurements and the high sensitivity to a large range of frequencies makes it attractive for communications reception. However, their unique physical characteristics enable two fundamental signal readout schemes: intensity-based detection and splitting-based detection. The former measures the electric fields through laser intensity, while the latter utilizes Autler-Townes splitting. In this work, we systematically categorize and model existing signal readout methods, classifying them into these two paradigms. Then, we derive the maximum likelihood estimation procedures and corresponding Cram\'er-Rao lower bounds (CRLB) for each detection modality. Through the analysis of the CRLB, we propose strategy for both readout schemes to enhance sensitivity and minimize estimation variance: acquiring data in regions with maximal slope magnitudes. While this approach has been implemented in intensity-based detection (e.g., superheterodyne schemes), its application to splitting-based detection remains unexplored. Implementation of non-uniform frequency scanning, with preferential sampling at regions exhibiting maximum peak slopes combined with our proposed maximum likelihood splitting estimation method, achieves significantly reduced estimation variance compared to conventional polynomial fitting. The comparative analysis reveals the optimal detection performance of the two detection schemes. This work also contributes to enhancing the accuracy of microwave calibration. Numerical results reveal that both fundamental signal readout methods achieve lower estimation variance based on our proposed maximum likelihood estimation approach.