Title
Nanosar-case study of synthetic aperture radar for nano-satellites
Author
Engelen, S.
van den Oever, M.
Mahapatra, P.
Sundaramoorthy, P.
Gill, E.
Meijer, R.J.
Verhoeven, C.
Publication year
2012
Abstract
Nano-satellites have a cost advantage due to their low mass and usage of commercial-off-the-shelf technologies. However, the low mass also restricts the functionality of a nano-satellite's payload. Typically, this would imply instruments with very low to low resolution and accuracy, essentially ruling out applications such as remote sensing. However, multiple nano-satellites can cooperate to improve the overall system performance, for example by increasing the frequency of the observations. The objective of this study is to design a radar system that can be accommodated in a nano-satellite, and investigate the feasibility of using multiples of these nano-satellites to perform high temporal resolution remote sensing. In this paper therefore, the concept of a nano-satellite sized Synthetic Aperture Radar (Nano-SAR) is investigated. Nano-satellites have very constrained power and volume budgets, and there are limits to how much surface area they can unfold for use in radar. Given these constraints, a SAR system for use in a nano-satellite in a 350 km orbit was sized, and approaches to tackle the deficits in the radar link budget are proposed. When applying state-of-the-art technologies, both on the component level, as well as on an architectural level, one arrives at a closed link budget. The proposed radar system consists of a patch antenna array with a span of 1.14 m by 0.18 m, operating at a frequency of 5.8 GHz. Power amplification and phase shifting is performed on the panel, using digital radio frequency (RF) integrated Complementary Metal Oxide Semiconductor (CMOS) circuits. This results in a swath width of 60 km, with pixel sizes of 10 m in elevation direction. Given these performance values, coupled with the increased revisit times, it was obvious this radar, when flown in a larger swarm of nano-satellites, would allow faster now-casting for weather prediction. With significant investment in technology development, it could be possible to use this system for SAR interferometry, for near-real-time monitoring of fast ground deformation phenomena such as earthquakes and volcanoes. Other applications could lie in the field of near-real-time ship motion detection and oil spill spread detection. Many technical challenges need to be solved still and platforms need to be designed, capable of supporting this system, before this payload would be ready for deployment. Preliminary design suggests the cost of such an instrument is substantially higher than what is common for nano-satellite components. However, the potential of such a system is extremely promising, and merits further investigation.©2012 by the International Astronautical Federation.
Subject
Radar
Architectural levels
Commercial off-the-shelf technology
Complementary metal oxide semiconductors
High temporal resolution
Investment in technology
Near-real-time monitoring
State-of-the-art technology
Technical challenges
Antenna arrays
Budget control
CMOS integrated circuits
Digital radio
Nanosatellites
Oil spills
Radar systems
Remote sensing
Synthetic aperture radar
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http://resolver.tudelft.nl/uuid:d9152196-6e2b-4427-99b3-8aeb34cc8258
TNO identifier
478782
ISBN
9781622769797
ISSN
0074-1795
Source
63rd International Astronautical Congress 2012, IAC 2012, 1 October 2012 through 5 October 2012, Naples, 10, 8159-8164
Series
Proceedings of the International Astronautical Congress, IAC
Bibliographical note
Sponsors: Agenzia Spaziale Italiana (ASI); Finmeccanica SpA; Sangemini S.p.A.
Document type
conference paper