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A low-noise photonic heterodyne synthesizer and its application to millimeter-wave radar

Eric A. Kittlaus, Danny Eliyahu, Setareh Ganji, Skip Williams, Andrey B. Matsko, Ken B. Cooper, Siamak Forouhar

2021Nature Communications125 citationsDOIOpen Access PDF

Abstract

Microwave photonics offers transformative capabilities for ultra-wideband electronic signal processing and frequency synthesis with record-low phase noise levels. Despite the intrinsic bandwidth of optical systems operating at ~200 THz carrier frequencies, many schemes for high-performance photonics-based microwave generation lack broadband tunability, and experience tradeoffs between noise level, complexity, and frequency. An alternative approach uses direct frequency down-mixing of two tunable semiconductor lasers on a fast photodiode. This form of optical heterodyning is frequency-agile, but experimental realizations have been hindered by the relatively high noise of free-running lasers. Here, we demonstrate a heterodyne synthesizer based on ultralow-noise self-injection-locked lasers, enabling highly-coherent, photonics-based microwave and millimeter-wave generation. Continuously-tunable operation is realized from 1-104 GHz, with constant phase noise of -109 dBc/Hz at 100 kHz offset from carrier. To explore its practical utility, we leverage this photonic source as the local oscillator within a 95-GHz frequency-modulated continuous wave (FMCW) radar. Through field testing, we observe dramatic reduction in phase-noise-related Doppler and ranging artifacts as compared to the radar's existing electronic synthesizer. These results establish strong potential for coherent heterodyne millimeter-wave generation, opening the door to a variety of future applications including high-dynamic range remote sensing, wideband wireless communications, and THz spectroscopy.

Topics & Concepts

Phase noisePhotonicsSuperheterodyne receiverWidebandFrequency synthesizerIntermediate frequencyLocal oscillatorOptoelectronicsOpticsElectronic engineeringComputer scienceMicrowavePhysicsPhase-locked loopTelecommunicationsRadio frequencyEngineeringAdvanced Fiber Laser TechnologiesAdvanced Photonic Communication SystemsPhotonic and Optical Devices
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