Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR

Spaceborne Synthetic Aperture Radar (SAR) sensors play an ever increasingly important role in Earth observation in the fields of science, geomatics, defence, commercial products and services. The user community requirements for large, high temporal and spatial resolution swaths has driven the need f...

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Bibliographic Details
Main Author: Gema, Kevin
Other Authors: Inggs, Michael
Format: Dissertation
Language:English
Published: Faculty of Engineering and the Built Environment 2020
Subjects:
Online Access:http://hdl.handle.net/11427/31505
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spelling ndltd-netd.ac.za-oai-union.ndltd.org-uct-oai-localhost-11427-315052020-12-10T05:11:02Z Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR Gema, Kevin Inggs, Michael Gaffar, Mohammed Yunus Abdul electrical engineering Spaceborne Synthetic Aperture Radar (SAR) sensors play an ever increasingly important role in Earth observation in the fields of science, geomatics, defence, commercial products and services. The user community requirements for large, high temporal and spatial resolution swaths has driven the need for low-cost, high-performance systems. The increasing availability of commercial launch vehicles shall bolster the manufacturing and industrialisation of a smaller class sensor. This work deals with the performance comparison between a small satellite class planar array and reflector antenna system. Here the focus lies on digital beamforming techniques for the operation in wide-swath, high-resolution stripmap mode. For this the sensor sensitivity and ambiguity suppression performance in range and azimuth are derived. The Jupyter notebook environment with code in the Python language served as a convenient mechanism for modelling and verifying different performance aspects. These performance metrics are simulated and verified against existing systems. The limitations the spherical Earth geometry has on the transmitter timing and the imaged scene are derived. This together with the SAR platform orbital characteristics lead to the establishment of antenna design constraints. A planar array and reflector system are modelled with common design specifications and compared to a sea ice monitoring scenario. The use of digital beamforming techniques together with a high gain reflector antenna surface provided evidence that a reflector antenna would serve as a feasible alternative to planar arrays for spaceborne SAR missions. 2020-03-06T11:34:56Z 2020-03-06T11:34:56Z 2019 2020-03-06T11:33:14Z Master Thesis Masters MSc (Eng) http://hdl.handle.net/11427/31505 eng application/pdf Faculty of Engineering and the Built Environment Department of Electrical Engineering
collection NDLTD
language English
format Dissertation
sources NDLTD
topic electrical engineering
spellingShingle electrical engineering
Gema, Kevin
Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR
description Spaceborne Synthetic Aperture Radar (SAR) sensors play an ever increasingly important role in Earth observation in the fields of science, geomatics, defence, commercial products and services. The user community requirements for large, high temporal and spatial resolution swaths has driven the need for low-cost, high-performance systems. The increasing availability of commercial launch vehicles shall bolster the manufacturing and industrialisation of a smaller class sensor. This work deals with the performance comparison between a small satellite class planar array and reflector antenna system. Here the focus lies on digital beamforming techniques for the operation in wide-swath, high-resolution stripmap mode. For this the sensor sensitivity and ambiguity suppression performance in range and azimuth are derived. The Jupyter notebook environment with code in the Python language served as a convenient mechanism for modelling and verifying different performance aspects. These performance metrics are simulated and verified against existing systems. The limitations the spherical Earth geometry has on the transmitter timing and the imaged scene are derived. This together with the SAR platform orbital characteristics lead to the establishment of antenna design constraints. A planar array and reflector system are modelled with common design specifications and compared to a sea ice monitoring scenario. The use of digital beamforming techniques together with a high gain reflector antenna surface provided evidence that a reflector antenna would serve as a feasible alternative to planar arrays for spaceborne SAR missions.
author2 Inggs, Michael
author_facet Inggs, Michael
Gema, Kevin
author Gema, Kevin
author_sort Gema, Kevin
title Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR
title_short Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR
title_full Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR
title_fullStr Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR
title_full_unstemmed Performance comparison of reflector and AESA-based digital beamforming for small satellite spaceborne SAR
title_sort performance comparison of reflector and aesa-based digital beamforming for small satellite spaceborne sar
publisher Faculty of Engineering and the Built Environment
publishDate 2020
url http://hdl.handle.net/11427/31505
work_keys_str_mv AT gemakevin performancecomparisonofreflectorandaesabaseddigitalbeamformingforsmallsatellitespacebornesar
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