Quantum compressed sensing of ultra-wideband radio-frequency signal

Quantum compressed sensing of ultra-wideband radio-frequency signal

Real-time sensing of ultra-wideband radio-frequency signal with high frequency resolution is challenging, which is confined by the sampling rate of electronic analog-to-digital converter and the capability of digital signal processing. By combining quantum mechanics with compressed sensing, quantum...

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Veröffentlicht in:arXiv.org 2021-07
Hauptverfasser: Hu, Jianyong, Han, Yanrui, Li, Wei, Liu, Yang, Wu, Shuxiao, Chen, Ruiyun, Qin, Chengbing, Zhang, Guofeng, Xiao, Liantuan, Jia, Suotang
Format: Artikel
Sprache:eng
Schlagworte:
Analog to digital conversion
Analog to digital converters
Digital signal processing
Fourier transforms
Frequency measurement
Frequency spectrum
Photons
Quantum mechanics
Radio frequency
Radio signals
Real time
Ultrawideband
Vibration
Wave functions
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Zusammenfassung:Real-time sensing of ultra-wideband radio-frequency signal with high frequency resolution is challenging, which is confined by the sampling rate of electronic analog-to-digital converter and the capability of digital signal processing. By combining quantum mechanics with compressed sensing, quantum compressed sensing is proposed for wideband radio-frequency signal frequency measurement. By using an electro-optical crystal as a sensor which modulates the wave function of the coherent photons with the signal to be measured. The frequency spectrum could be recovered by detecting the modulated sparse photons with a low time-jitter single-photon detector and a time-to-digital converter. More than 50 GHz real-time analysis bandwidth is demonstrated with the Fourier transform limit resolution. The further simulation shows it can be extended to more than 300 GHz with the present technologies.
ISSN:2331-8422