Long baseline bistatic radar imaging of tumbling space objects for enhancing space domain awareness

Alexander Serrano; Alexander Kobsa; Faruk Uysal; Delphine Cerutti‐Maori; Selenia Ghio; Andrew Kintz; Robert L. Morrison Jr.; Sarah Welch; Philip vanDorp; Gregory Hogan; Simon Garrington; Cees Bassa; Chris Saunders; Marco Martorella; Miguel Caro Cuenca; Isaac Lowe

doi:10.1049/rsn2.12511

IET Radar, Sonar & Navigation (Apr 2024)

Long baseline bistatic radar imaging of tumbling space objects for enhancing space domain awareness

Alexander Serrano,
Alexander Kobsa,
Faruk Uysal,
Delphine Cerutti‐Maori,
Selenia Ghio,
Andrew Kintz,
Robert L. Morrison Jr.,
Sarah Welch,
Philip vanDorp,
Gregory Hogan,
Simon Garrington,
Cees Bassa,
Chris Saunders,
Marco Martorella,
Miguel Caro Cuenca,
Isaac Lowe

Affiliations

Alexander Serrano: Massachusetts Institute of Technology – Lincoln Laboratory Lexington Massachusetts USA
Alexander Kobsa: Massachusetts Institute of Technology – Lincoln Laboratory Lexington Massachusetts USA
Faruk Uysal: TNO Den Haag the Netherlands
Delphine Cerutti‐Maori: Fraunhofer FHR Wachtberg Germany
Selenia Ghio: CNIT‐RaSS Parma Italy
Andrew Kintz: Massachusetts Institute of Technology – Lincoln Laboratory Lexington Massachusetts USA
Robert L. Morrison Jr.: Massachusetts Institute of Technology – Lincoln Laboratory Lexington Massachusetts USA
Sarah Welch: Massachusetts Institute of Technology – Lincoln Laboratory Lexington Massachusetts USA
Philip vanDorp: TNO Den Haag the Netherlands
Gregory Hogan: Massachusetts Institute of Technology – Lincoln Laboratory Lexington Massachusetts USA
Simon Garrington: University of Manchester Manchester UK
Cees Bassa: ASTRON Netherlands Institute for Radio Astronomy Dwingeloo the Netherlands
Chris Saunders: Goonhilly Earth Station Helston UK
Marco Martorella: University of Birmingham Birmingham UK
Miguel Caro Cuenca: TNO Den Haag the Netherlands
Isaac Lowe: US Space Command, Peterson AFB Colorado Springs Colorado USA

DOI: https://doi.org/10.1049/rsn2.12511
Journal volume & issue: Vol. 18, no. 4
pp. 598 – 619

Abstract

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Abstract Long baseline bistatic radar systems herald enhanced sensitivity and metric accuracy for space objects in geosynchronous orbits and beyond. Radio telescopes are ideal participants in such a system; in particular, they often feature large apertures with low‐noise temperatures and have stable, synchronised clocks. Pairing radio telescopes with high‐power radars creates new methodologies for Space Domain Awareness. This paper describes long baseline bistatic measurements using the Millstone Hill Radar in the USA, the Tracking and Imaging Radar in Germany, multiple receivers of the enhanced multi‐element remotely linked interferometer network array in the United Kingdom, and the Westerbork Synthesis Radio Telescope in the Netherlands. The authors, a Research Task Group formed by the NATO Science and Technology Organisation Sensors and Electronic Technology Panel (SET‐293), performed novel bistatic and monostatic radar imaging experiments with real on‐orbit tumbling rocket bodies. These experiments on tumbling objects at near‐geosynchronous orbits highlight successful demonstrations of advanced bistatic Doppler characterisation across diverse imaging geometries. Specialised Doppler processing on tumbling targets, such as the Doppler superpulse algorithm, enables high‐fidelity rotation period estimation and determination of minimum target size.

Published in IET Radar, Sonar & Navigation

ISSN: 1751-8784 (Print); 1751-8792 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Telecommunication
Website: https://ietresearch.onlinelibrary.wiley.com/journal/17518792

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Abstract

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