High-Resolution On-Chip S -Band Radar System Using Stretch Processing

In this paper, an S-band radar system that uses stretch processing is developed at the chip level. The novelty in this paper lies in providing an integrated, compact and miniaturized high-performance S-band radar system chipset. The radar has many characteristics that ensure high performance: 1) a w...

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Veröffentlicht in:	IEEE sensors journal 2016-06, Vol.16 (12), p.4749-4759
Hauptverfasser:	Al-Alem, Yazan, Albasha, Lutfi, Mir, Hasan
Format:	Artikel
Sprache:	eng
Schlagworte:	Architecture Bandwidth Chips (electronics) Chirp Clutter Design engineering Dynamic range High dynamic range radar High resolution radar Linearity Negative gm voltage controlled oscillator Quad passive mixer Radar Rain Receivers S-Band transceiver Signal processing Signal resolution Stretch processing
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creator	Al-Alem, Yazan Albasha, Lutfi Mir, Hasan
description	In this paper, an S-band radar system that uses stretch processing is developed at the chip level. The novelty in this paper lies in providing an integrated, compact and miniaturized high-performance S-band radar system chipset. The radar has many characteristics that ensure high performance: 1) a wide bandwidth signal (600 MHz) that provides high resolution to distinguish between close objects; 2) an usage of stretch processing, which dramatically reduces the required sampling rates and relaxes the specifications of analog-to-digital converters; 3) high dynamic range (58 dB) that allows weak signals to be detected from targets masked by the high levels of clutter (such as snow and rain); 4) multiple receiver channels that enable digital antenna beamforming at the receiver to mitigate any strong interferer; and 5) operation in the S-band (2-4 GHz) that provides high immunity against clutter in long range surveillance applications. The architecture study revealed a super-hetrodyne modulator and receiver architecture offered the best solution. The high-order filters were pushed off-chip to reduce silicon area, reduce power consumption, and improve filtering results. The circuit-level design focused on designing the receiver blocks. The design included a high linearity quad passive mixer, IF cascode and common source amplifiers, and a negative-gm voltage controlled oscillator. The total receiver system of the radar chipset was designed and simulated at the circuit level on IBM 180-nm CMOS technology. To the best knowledge of the authors, this is the first integrated and smallest high-performance S-band radar to be designed.
doi_str_mv	10.1109/JSEN.2016.2550099
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The high-order filters were pushed off-chip to reduce silicon area, reduce power consumption, and improve filtering results. The circuit-level design focused on designing the receiver blocks. The design included a high linearity quad passive mixer, IF cascode and common source amplifiers, and a negative-gm voltage controlled oscillator. The total receiver system of the radar chipset was designed and simulated at the circuit level on IBM 180-nm CMOS technology. To the best knowledge of the authors, this is the first integrated and smallest high-performance S-band radar to be designed.</abstract><pub>IEEE</pub><doi>10.1109/JSEN.2016.2550099</doi><tpages>11</tpages></addata></record>
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subjects	Architecture Bandwidth Chips (electronics) Chirp Clutter Design engineering Dynamic range High dynamic range radar High resolution radar Linearity Negative gm voltage controlled oscillator Quad passive mixer Radar Rain Receivers S-Band transceiver Signal processing Signal resolution Stretch processing
title	High-Resolution On-Chip S -Band Radar System Using Stretch Processing
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