Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform

Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform

Traditionally, multi-mission applications in airborne radar are implemented through very expensive phased array architectures. The emerging applications from civilian surveillance, on the other hand, prefer low-cost and low-SWaP (space, weight and power) systems. This study introduces asoftware-base...

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Bibliographic Details
Main Authors: Ramesh Nepal, Yan Zhang, William Blake
Format: Article
Language:English
Published: MDPI AG 2017-03-01
Series:Aerospace
Subjects:
multi-mission
airborne radar
iterative adaptive approach
adaptive pulse compression
matched filter
Online Access:http://www.mdpi.com/2226-4310/4/1/11
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spelling doaj-b5422b8846d54a41b12de0915ea9120d2020-11-24T21:37:18ZengMDPI AGAerospace2226-43102017-03-01411110.3390/aerospace4010011aerospace4010011Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar PlatformRamesh Nepal0Yan Zhang1William Blake2Intelligent Aerospace Radar Team (IART), School of Electrical and Computer Engineering, Advanced Radar Research Center (ARRC), University of Oklahoma, Norman, OK 73019-0390, USAIntelligent Aerospace Radar Team (IART), School of Electrical and Computer Engineering, Advanced Radar Research Center (ARRC), University of Oklahoma, Norman, OK 73019-0390, USAGarmin Aviation Weather Radar, Garmin International Inc., Olathe, KS 66062-3426, USATraditionally, multi-mission applications in airborne radar are implemented through very expensive phased array architectures. The emerging applications from civilian surveillance, on the other hand, prefer low-cost and low-SWaP (space, weight and power) systems. This study introduces asoftware-basedsolutionthatintendstouselow-costhardwareandadvancedalgorithms/processing backend to meet the remote sensing goals for multi-mission applications. The low-cost airborne radar platform from Garmin International is used as a representative example of the system platform. The focus of this study is the optimal operating mode, data quality and algorithm development in cases of all-weather sense and avoid (SAA) applications. The main challenges for the solution are the resolution limitation due to the small aperture size, limitations from the field-of-view (FOV) and the scan speed from mechanical scanning. We show that the basic operational needs can be satisfied with software processing through various algorithms. The concept and progress of polarimetric airborne radar for dual-function operations at X-band Generation 1 (PARADOX1) based on the platform are also discussed.http://www.mdpi.com/2226-4310/4/1/11multi-missionairborne radariterative adaptive approachadaptive pulse compressionmatched filter
collection DOAJ
language English
format Article
sources DOAJ
author Ramesh Nepal
Yan Zhang
William Blake
spellingShingle Ramesh Nepal
Yan Zhang
William Blake
Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform
Aerospace
multi-mission
airborne radar
iterative adaptive approach
adaptive pulse compression
matched filter
author_facet Ramesh Nepal
Yan Zhang
William Blake
author_sort Ramesh Nepal
title Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform
title_short Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform
title_full Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform
title_fullStr Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform
title_full_unstemmed Sense and Avoid Airborne Radar Implementations on a Low-Cost Weather Radar Platform
title_sort sense and avoid airborne radar implementations on a low-cost weather radar platform
publisher MDPI AG
series Aerospace
issn 2226-4310
publishDate 2017-03-01
description Traditionally, multi-mission applications in airborne radar are implemented through very expensive phased array architectures. The emerging applications from civilian surveillance, on the other hand, prefer low-cost and low-SWaP (space, weight and power) systems. This study introduces asoftware-basedsolutionthatintendstouselow-costhardwareandadvancedalgorithms/processing backend to meet the remote sensing goals for multi-mission applications. The low-cost airborne radar platform from Garmin International is used as a representative example of the system platform. The focus of this study is the optimal operating mode, data quality and algorithm development in cases of all-weather sense and avoid (SAA) applications. The main challenges for the solution are the resolution limitation due to the small aperture size, limitations from the field-of-view (FOV) and the scan speed from mechanical scanning. We show that the basic operational needs can be satisfied with software processing through various algorithms. The concept and progress of polarimetric airborne radar for dual-function operations at X-band Generation 1 (PARADOX1) based on the platform are also discussed.
topic multi-mission
airborne radar
iterative adaptive approach
adaptive pulse compression
matched filter
url http://www.mdpi.com/2226-4310/4/1/11
work_keys_str_mv AT rameshnepal senseandavoidairborneradarimplementationsonalowcostweatherradarplatform
AT yanzhang senseandavoidairborneradarimplementationsonalowcostweatherradarplatform
AT williamblake senseandavoidairborneradarimplementationsonalowcostweatherradarplatform
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