Advancements in Onboard Processing of Synthetic Aperture Radar (SAR) Data: Enhancing Efficiency and Real-Time Capabilities

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Xuất bản năm:	IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing vol. 17 (2024), p. 16625
Tác giả chính:	Laura Parra Garcia
Tác giả khác:	Furano, Gianluca, Ghiglione, Max, Zancan, Valentina, Imbembo, Ernesto, Ilioudis, Christos, Clemente, Carmine, Trucco, Paolo
Được phát hành:	The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Những chủ đề:	Environmental monitoring Artificial intelligence Data processing Image resolution Power consumption Radar Remote sensing Data analysis Disaster management Remote monitoring Machine learning Downlinking Decision making Data reduction Data compression Synthetic aperture radar Onboard Network latency Onboard data processing Onboard equipment Algorithms Compression Latency Real time SAR (radar) Ground stations Environmental
Truy cập trực tuyến:	Citation/Abstract
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022			\|a 1939-1404
022			\|a 2151-1535
024	7		\|a 10.1109/JSTARS.2024.3406155 \|2 doi
035			\|a 3109487138
045	2		\|b d20240101 \|b d20241231
084			\|a 121645 \|2 nlm
100	1		\|a Laura Parra Garcia \|u University of Strathclyde, Glasgow, U.K.
245	1		\|a Advancements in Onboard Processing of Synthetic Aperture Radar (SAR) Data: Enhancing Efficiency and Real-Time Capabilities
260			\|b The Institute of Electrical and Electronics Engineers, Inc. (IEEE) \|c 2024
513			\|a Journal Article
520	3		\|a Satellite-borne synthetic aperture radar (SAR) technology has revolutionized remote sensing applications by providing high-resolution and all-weather imaging capabilities. With the increasing availability of SAR data, the need for efficient data processing has become crucial. Onboard processing has emerged as a promising solution to address the challenges associated with limited downlink capacity and final data products latency. Performing data processing and compression directly on the airborne platform reduces the raw data transmitted to ground stations, which offers several key benefits. First, it significantly reduces the data volume to be downlinked, optimizing the usage of limited bandwidth and minimizing transmission delays. Second, onboard processing enables faster access to processed data products, allowing for quicker decision-making and timely response to dynamic events, enhancing the real-time capabilities of the system that are particularly valuable in time-critical applications. This article discusses various onboard processing techniques employed in SAR systems and explores their challenges, like computational constraints, architectural impacts, power consumption, and algorithm optimization. Furthermore, it examines the potential future developments in onboard processing, such as the integration of artificial intelligence and machine learning techniques to enhance data analysis and decision-making capabilities. The advancements in onboard processing have the potential to revolutionize the way SAR missions are conducted. By leveraging these techniques, SAR systems can achieve improved operational efficiency, reduced data latency, and enhanced real-time capabilities. This article emphasizes the significance of onboard processing in meeting the growing demands of SAR applications and underscores its role in advancing remote sensing capabilities for various sectors, including environmental monitoring, disaster response, and surveillance.
653			\|a Environmental monitoring
653			\|a Artificial intelligence
653			\|a Data processing
653			\|a Image resolution
653			\|a Power consumption
653			\|a Radar
653			\|a Remote sensing
653			\|a Data analysis
653			\|a Disaster management
653			\|a Remote monitoring
653			\|a Machine learning
653			\|a Downlinking
653			\|a Decision making
653			\|a Data reduction
653			\|a Data compression
653			\|a Synthetic aperture radar
653			\|a Onboard
653			\|a Network latency
653			\|a Onboard data processing
653			\|a Onboard equipment
653			\|a Algorithms
653			\|a Compression
653			\|a Latency
653			\|a Real time
653			\|a SAR (radar)
653			\|a Ground stations
653			\|a Environmental
700	1		\|a Furano, Gianluca \|u European Space Agency, Paris, France
700	1		\|a Ghiglione, Max \|u European Space Agency, Paris, France
700	1		\|a Zancan, Valentina \|u Politecnico di Milano, Milano, Italy
700	1		\|a Imbembo, Ernesto \|u European Space Agency, Paris, France
700	1		\|a Ilioudis, Christos \|u University of Strathclyde, Glasgow, U.K.
700	1		\|a Clemente, Carmine \|u University of Strathclyde, Glasgow, U.K.
700	1		\|a Trucco, Paolo \|u Politecnico di Milano, Milano, Italy
773	0		\|t IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing \|g vol. 17 (2024), p. 16625
786	0		\|d ProQuest \|t Advanced Technologies & Aerospace Database
856	4	1	\|3 Citation/Abstract \|u https://www.proquest.com/docview/3109487138/abstract/embedded/7BTGNMKEMPT1V9Z2?source=fedsrch