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Signal Reconstruction for FMCW Radar Interference Mitigation Using Deep Unfolding

Jeroen Overdevest, Arie Koppelaar, Marco J.G. Bekooij, Jun Young Youn, Ruud J. G. van Sloun

202313 citationsDOIOpen Access PDF

Abstract

Removal of frequency-modulated continuous wave (FMCW) interference by zeroing corrupted samples causes significant distortions and peak power losses in the range-Doppler map. Existing methods aim to diminish these distortions by utilizing data from one dimension to reconstruct the corrupted samples, which do not perform well when a large number of samples are interfered and have difficulty recovering weak target signals.In this paper, model-based deep learning interference mitigation algorithms, called ALISTA and ALFISTA, are presented that reduce these artifacts by leveraging the full integration gain using all uncorrupted fast-time and slow-time samples. Simulations with 50% corrupted samples show that target peak power loss and velocity peak-to-sidelobe ratio (VPSR) with a 20-layer ALFISTA improves with 5.5 and 9.6 dB compared to zeroing. Furthermore, significant improvements in precision and recall are observed, even when large amounts (50-80%) of samples are missing.

Topics & Concepts

Interference (communication)Computer scienceRadarDoppler effectSIGNAL (programming language)Range (aeronautics)Dimension (graph theory)Doppler radarTime–frequency analysisContinuous-wave radarPower (physics)Artificial intelligenceContinuous waveDeep learningRadar imagingAcousticsTelecommunicationsPhysicsChannel (broadcasting)MathematicsOpticsMaterials scienceComposite materialAstronomyLaserPure mathematicsQuantum mechanicsProgramming languageAdvanced SAR Imaging TechniquesRadar Systems and Signal ProcessingGeophysical Methods and Applications
Signal Reconstruction for FMCW Radar Interference Mitigation Using Deep Unfolding | Litcius