Rapidly Tunable Dual-Comb RF Photonic Filter for Ultrabroadband RF Spread Spectrum Applications

Kim, Hyoung-Jun; Leaird, Daniel E.; Weiner, Andrew M.

doi:10.1109/tmtt.2016.2599162

Cited by 24 publications

(5 citation statements)

References 62 publications

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“…Our approach is a swept frequency version of multiheterodyne detection 23 of optical frequency combs, commonly referred to as dual-comb spectroscopy. This technique has attained widespread attention and application in (nonlinear) optical and THz spectroscopy 24 – 26 , optical microscopy 27 , 28 , distance measurement 29 – 31 , two-way time-frequency transfer 32 , microwave photonics 33 , multi-dimensional spectroscopy 34 , coherent anti-Stokes Raman imaging 35 , and recently demonstrated spectrally interleaved broadband spectroscopy with frequency swept electro-optical dual-comb 36 , 37 . This method decodes all individual low frequency (MHz bandwidth) channels using a single high speed (GHz) coherent ‘intradyne’ detector by radio-frequency multiplexing.…”

Section: Resultsmentioning

confidence: 99%

Dual chirped microcomb based parallel ranging at megapixel-line rates

et al. 2022

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Laser-based ranging (LiDAR) - already ubiquitously used in industrial monitoring, atmospheric dynamics, or geodesy - is a key sensor technology. Coherent laser ranging, in contrast to time-of-flight approaches, is immune to ambient light, operates continuous-wave allowing higher average powers, and yields simultaneous velocity and distance information. State-of-the-art coherent single laser-detector architectures reach hundreds of kilopixel per second sampling rates, while emerging applications - autonomous driving, robotics, and augmented reality - mandate megapixel per second point sampling to support real-time video-rate imaging. Yet, such rates of coherent LiDAR have not been demonstrated. Recent advances in photonic chip-based microcombs provide a route to higher acquisition speeds via parallelization but require separation of individual channels at the detector side, increasing photonic integration complexity. Here we overcome the challenge and report a hardware-efficient swept dual-soliton microcomb technique that achieves coherent ranging and velocimetry at megapixel per second line scan measurement rates with up to 64 optical channels. Multiheterodyning two synchronously frequency-modulated microcombs yields distance and velocity information of all individual ranging channels on a single receiver alleviating the need for individual separation, detection, and digitization. The reported LiDAR implementation is compatible with photonic integration and demonstrates the significant advantages of acquisition speed afforded by the convergence of optical telecommunication and metrology technologies.

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Section: Resultsmentioning

confidence: 99%

Dual chirped microcomb based parallel ranging at megapixel-line rates

et al. 2022

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“…There is also a significant interest in the frequency chirp generations using Fourier pulse shaping and frequency to time mapping, especially the demonstration compact photonic integration [43], flexible tuning of chirp rate [37], control of chirp sign [44] and the ability of shaping the waveform envelop [45]. There are also applications of arbitrary waveform generation for measuring and compensating for multipath channel propagation that overcomes inter-symbol interference [46] and for rapidly reconfigurable RF filtering [38,47]. There are also significant activities in the field of waveform generation based on microwave photonic filtering, particularly the generation of triangular wave train [48,49].…”

Section: Recent Developmentsmentioning

confidence: 99%

A Review of Photonic Generation of Arbitrary Microwave Waveforms

Bui¹

2017

PIER B

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“…For frequency hopping receivers, the hopping speed is one of the key characteristics since it is relevant to the anti-jamming and anti-interception performance. For analog receivers, the receiving linearity [2], [6], [12], [15], [25] and the receiving radio frequency (RF) gain [4], [5], [7], [13] are two important characteristics since they indicate the quality of the received signals by affecting the average signal-to-noise ratio (SNR). For the average SNR of the frequency hopping receiver, a time window with fixed duration should be chosen, because the receiving RF gain varies in different frequencies, and it affects the average SNR.…”

Section: Introductionmentioning

confidence: 99%

Performance Analysis on Interference and Frequency-to-Time Mapping Based Frequency Hopping Receiver

Sun

Chen

et al. 2023

IEEE Photonics J.

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The receiving performance of a frequency hopping receiver based on interference and frequency-to-time mapping are analyzed. The broadening of the receiving passband induced by high frequency hopping speed is theoretically analyzed. The spurious-free dynamic range (SFDR), the frequency-dependent RF gain, and the average signal-to-noise ratio (SNR) corresponding to the RF gain are theoretically derived to indicate the receiving performance. Experimental verifications on the SFDR and RF gain were conducted. The SFDR of the passband at 7.21 GHz is 77.23dBc, and for the passbands located from 7GHz to 23GHz, the SFDR variance is below 3.2dB, which fits well with the simulated results with the difference of less than 3.7dB. The RF gain for passbands located from 2.6GHz to 40.9GHz were tested, and the difference is less than 2dB compared to the theoretical results.

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Rapidly Tunable Dual-Comb RF Photonic Filter for Ultrabroadband RF Spread Spectrum Applications

Cited by 24 publications

References 62 publications

Dual chirped microcomb based parallel ranging at megapixel-line rates

Dual chirped microcomb based parallel ranging at megapixel-line rates

A Review of Photonic Generation of Arbitrary Microwave Waveforms

Performance Analysis on Interference and Frequency-to-Time Mapping Based Frequency Hopping Receiver

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