Chip‐Based Microwave‐Photonic Radar for High‐Resolution Imaging

Radar is the only sensor that can realize target imaging at all time and all weather, which would be a key technical enabler for future intelligent society. Poor resolution and large size are the two critical issues for radar to gain ground in civil applications. Conventional electronic radars are d...

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Veröffentlicht in:	Laser & photonics reviews 2020-10, Vol.14 (10), p.n/a
Hauptverfasser:	Li, Simin, Cui, Zhengze, Ye, Xingwei, Feng, Jing, Yang, Yue, He, Zhengqiang, Cong, Rong, Zhu, Dan, Zhang, Fangzheng, Pan, Shilong
Format:	Artikel
Sprache:	eng
Schlagworte:	Aperture imaging Broadband chip‐based radar Extremely high frequencies Imaging radar integrated microwave photonics Microwave photonics microwave‐photonic radar Radar imaging Signal generators silicon photonics Synthetic apertures Target recognition Weather
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creator	Li, Simin Cui, Zhengze Ye, Xingwei Feng, Jing Yang, Yue He, Zhengqiang Cong, Rong Zhu, Dan Zhang, Fangzheng Pan, Shilong
description	Radar is the only sensor that can realize target imaging at all time and all weather, which would be a key technical enabler for future intelligent society. Poor resolution and large size are the two critical issues for radar to gain ground in civil applications. Conventional electronic radars are difficult to address due to both issues, especially in the Ka band or lower. In this work, a chip‐based microwave‐photonic radar based on silicon photonic platform, which can implement high‐resolution imaging with very small footprint, is proposed and experimentally demonstrated. Both the wideband signal generator and the de‐chirp receiver are integrated on the chip. A broadband microwave‐photonic imaging radar occupying the full Ku band is experimentally established. A high‐precision range measurement with a resolution of 2.7 cm and an error of less than 2.75 mm is obtained. Inverse synthetic aperture imaging of multiple targets with complex profiles is also implemented. A chip‐based microwave‐photonic radar is experimentally demonstrated. Key optical devices in the radar transceiver are integrated on a single chip, which generates a flat linear frequency‐modulated signal occupying the full Ku band (12–18 GHz) and performs wideband de‐chirp processing of the radar echoes. Inverse synthetic aperture radar imaging with a range resolution of 2.7 cm is implemented.
doi_str_mv	10.1002/lpor.201900239
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subjects	Aperture imaging Broadband chip‐based radar Extremely high frequencies Imaging radar integrated microwave photonics Microwave photonics microwave‐photonic radar Radar imaging Signal generators silicon photonics Synthetic apertures Target recognition Weather
title	Chip‐Based Microwave‐Photonic Radar for High‐Resolution Imaging
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