Remote Radar Based on Chaos Generation and Radio Over Fiber

Remote Radar Based on Chaos Generation and Radio Over Fiber

An ultrawideband (UWB) radar system for remote ranging based on microwave-photonic chaotic signal generation and fiber-optic distribution is proposed and demonstrated experimentally. In this system, an optical-feedback semiconductor laser with optical injection in the central office generates photon...

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Main Authors: Mingjiang Zhang, Yongning Ji, Yongning Zhang, Yuan Wu, Hang Xu, Weipeng Xu
Format: Article
Language:English
Published: IEEE 2014-01-01
Series:IEEE Photonics Journal
Online Access:https://ieeexplore.ieee.org/document/6894267/
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spelling doaj-5e34d73128e742e09bed9cdef98b7a992021-03-29T17:19:38ZengIEEEIEEE Photonics Journal1943-06552014-01-016511210.1109/JPHOT.2014.23526286894267Remote Radar Based on Chaos Generation and Radio Over FiberMingjiang Zhang0Yongning Ji1Yongning Zhang2Yuan Wu3Hang Xu4Weipeng Xu5Key Lab. of Adv. Transducers & Intell. Control Syst., Taiyuan Univ. of Technol., Taiyuan, ChinaKey Lab. of Adv. Transducers & Intell. Control Syst., Taiyuan Univ. of Technol., Taiyuan, ChinaKey Lab. of Adv. Transducers & Intell. Control Syst., Taiyuan Univ. of Technol., Taiyuan, ChinaKey Lab. of Adv. Transducers & Intell. Control Syst., Taiyuan Univ. of Technol., Taiyuan, ChinaKey Lab. of Adv. Transducers & Intell. Control Syst., Taiyuan Univ. of Technol., Taiyuan, ChinaKey Lab. of Adv. Transducers & Intell. Control Syst., Taiyuan Univ. of Technol., Taiyuan, ChinaAn ultrawideband (UWB) radar system for remote ranging based on microwave-photonic chaotic signal generation and fiber-optic distribution is proposed and demonstrated experimentally. In this system, an optical-feedback semiconductor laser with optical injection in the central office generates photonic UWB chaos as probing signal, and two single-mode fibers transport the optical signal to the remote antenna monitoring terminal and return the corresponding echoed signal back to the central office. In the remote antenna terminal, the photonic signal is transformed into microwave chaos by a fast photodetector and then launched to target by a transmitting antenna, and the echoed signal received by another antenna is converted into optical domain by modulating a laser diode. The target ranging is achieved at the central office by correlating the echoed signal with the reference signal. We experimentally realize a detection range of 8 m, for a free-space target, after 24-km remote distance, and achieve a ranging resolution of 3 cm for single target and 8 cm for double targets. In another fiber link branch with 15-km fiber transmission, we obtained the 2-cm ranging resolution for a single target.https://ieeexplore.ieee.org/document/6894267/
collection DOAJ
language English
format Article
sources DOAJ
author Mingjiang Zhang
Yongning Ji
Yongning Zhang
Yuan Wu
Hang Xu
Weipeng Xu
spellingShingle Mingjiang Zhang
Yongning Ji
Yongning Zhang
Yuan Wu
Hang Xu
Weipeng Xu
Remote Radar Based on Chaos Generation and Radio Over Fiber
IEEE Photonics Journal
author_facet Mingjiang Zhang
Yongning Ji
Yongning Zhang
Yuan Wu
Hang Xu
Weipeng Xu
author_sort Mingjiang Zhang
title Remote Radar Based on Chaos Generation and Radio Over Fiber
title_short Remote Radar Based on Chaos Generation and Radio Over Fiber
title_full Remote Radar Based on Chaos Generation and Radio Over Fiber
title_fullStr Remote Radar Based on Chaos Generation and Radio Over Fiber
title_full_unstemmed Remote Radar Based on Chaos Generation and Radio Over Fiber
title_sort remote radar based on chaos generation and radio over fiber
publisher IEEE
series IEEE Photonics Journal
issn 1943-0655
publishDate 2014-01-01
description An ultrawideband (UWB) radar system for remote ranging based on microwave-photonic chaotic signal generation and fiber-optic distribution is proposed and demonstrated experimentally. In this system, an optical-feedback semiconductor laser with optical injection in the central office generates photonic UWB chaos as probing signal, and two single-mode fibers transport the optical signal to the remote antenna monitoring terminal and return the corresponding echoed signal back to the central office. In the remote antenna terminal, the photonic signal is transformed into microwave chaos by a fast photodetector and then launched to target by a transmitting antenna, and the echoed signal received by another antenna is converted into optical domain by modulating a laser diode. The target ranging is achieved at the central office by correlating the echoed signal with the reference signal. We experimentally realize a detection range of 8 m, for a free-space target, after 24-km remote distance, and achieve a ranging resolution of 3 cm for single target and 8 cm for double targets. In another fiber link branch with 15-km fiber transmission, we obtained the 2-cm ranging resolution for a single target.
url https://ieeexplore.ieee.org/document/6894267/
work_keys_str_mv AT mingjiangzhang remoteradarbasedonchaosgenerationandradiooverfiber
AT yongningji remoteradarbasedonchaosgenerationandradiooverfiber
AT yongningzhang remoteradarbasedonchaosgenerationandradiooverfiber
AT yuanwu remoteradarbasedonchaosgenerationandradiooverfiber
AT hangxu remoteradarbasedonchaosgenerationandradiooverfiber
AT weipengxu remoteradarbasedonchaosgenerationandradiooverfiber
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