Sparse Reconstruction in Co-Pulsing and Co-STAP FDA Radar
Target localization based on frequency diverse array (FDA) radar has lately garnered significant research interest. A linear frequency offset (FO) across FDA antennas yields a range-angle dependent beampattern that allows for joint estimation of range and direction-of-arrival (DoA). Prior works on FDA largely focus on the one-dimensional linear array to estimate only azimuth angle and range while ignoring the elevation and Doppler velocity. However, in many applications, the latter two parameters are also essential for target localization. Further, there is also an interest in radar systems that employ fewer measurements in temporal, Doppler, or spatial signal domains. We address these multiple challenges by proposing a co-prime L-shaped FDA, wherein co-prime FOs are applied across the elements of an L-shaped co-prime array and each element transmits at a non-uniform co-prime pulse repetition interval (C3 or C-Cube). This co-pulsing FDA yields significantly large degrees of freedom (DoFs) for target localization in the range-azimuth-elevation-Doppler domain while also reducing the time-on-target and transmit spectral usage. By exploiting these DoFs, we develop a C-Cube auto-pairing (CCing) algorithm, in which all the parameters are ipso facto paired during a joint estimation. We benchmark the performance of this new radar configuration by deriving lower error bounds and theoretical guarantees. Next, we examine range-dependent clutter suppression for co-pulsing radar via space-time adaptive processing (Co-STAP). Here, we propose an approximate method of three-dimensional (3-D) clutter subspace estimation leveraging the well-known discrete prolate spheroidal sequences (DPSS) to make a trade-off between the clutter suppression performance and computational cost. Compared to the conventional FDA-STAP algorithm, the proposed DPSS-based method for Co-STAP exhibits the merits of better clutter suppression performance, lower computational complexity, and robustness to interference.
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- Date: 16 Mar 2023
- Time: 07:00 PM to 08:30 PM
- All times are (UTC-07:00) Pacific Time (US & Canada)
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- 31416 Agoura Rd
- WESTLAKE VILLAGE, California
- United States 91361
- Building: Cal Lutheran Center for Entrepreneurship - Hub101
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- Starts 27 February 2023 10:20 AM
- Ends 16 March 2023 06:20 PM
- All times are (UTC-07:00) Pacific Time (US & Canada)
- No Admission Charge
Speakers
Dr. Kumar Vijay Mishra
Biography:
Kumar Vijay Mishra (S’08-M’15-SM’18) obtained a Ph.D. in electrical engineering and M.S. in mathematics from The University of Iowa in 2015, and M.S. in electrical engineering from Colorado State University in 2012, while working on NASA’s Global Precipitation Mission Ground Validation (GPM-GV) weather radars. He received his B. Tech. summa cum laude (Gold Medal, Honors) in electronics and communication engineering from the National Institute of Technology, Hamirpur (NITH), India in 2003. He is currently Senior Fellow at the United States Army Research Laboratory (ARL), Adelphi; Technical Adviser to Singapore-based automotive radar start-up Hertzwell and Boston-based imaging radar startup Aura Intelligent Systems; and honorary Research Fellow at SnT - Interdisciplinary Centre for Security, Reliability and Trust, University of Luxembourg. Previously, he had research appointments at Electronics and Radar Development Establishment (LRDE), Defence Research and Development Organisation (DRDO) Bengaluru; IIHR - Hydroscience & Engineering, Iowa City, IA; Mitsubishi Electric Research Labs, Cambridge, MA; Qualcomm, San Jose; and Technion - Israel Institute of Technology.
Agenda
6:30 PM Socializing
7:00 PM Talk