UWB Sensor Characterization for Radar Sensing and Imaging in Superluminal Propagation Regions

UWB Sensor Characterization for Radar Sensing and Imaging in Superluminal Propagation Regions

This article investigates the pulse propagation in the near field of a transmitter and reflector from the perspective of radar sensing and imaging. The peaks of the radiated and reflected pulses were found to have traveled at superluminal speeds in the near field of radar. The conceptual explanation...

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Veröffentlicht in:IEEE transactions on microwave theory and techniques 2021-01, Vol.69 (1), p.297-307
Hauptverfasser: Winter, Robert S. C., Oloumi, Daniel, Rambabu, Karumudi
Format: Artikel
Sprache:eng
Schlagworte:
Antenna measurements
Antenna near field
Apertures
Dipole antennas
electromagnectic (EM) pulses
Engineering
Engineering, Electrical & Electronic
Huygens principle
Imaging
near field radar imaging
Near fields
Propagation
Pulse propagation
Pulse shape
Radar
Radar imaging
Science & Technology
Shape
Superluminal propagation
superluminal pulse propagation
synthetic aperture radar (SAR)
Synthetic apertures
Technology
Ultrawideband
Ultrawideband radar
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Beschreibung
Zusammenfassung:This article investigates the pulse propagation in the near field of a transmitter and reflector from the perspective of radar sensing and imaging. The peaks of the radiated and reflected pulses were found to have traveled at superluminal speeds in the near field of radar. The conceptual explanation and experimental demonstration of the unique properties of the radiated and reflected pulses and their impact on near field radar imaging are presented in this article. To confirm the superluminal propagation, in this study, we considered several ultrawideband (UWB) sensors and scatterers. The physics behind the superluminal propagation and pulse shape change in the radar near field is demonstrated using the Huygens principle, and a method to improve the imaging of radar in the near field while using synthetic aperture techniques is also proposed.
ISSN:0018-9480
1557-9670
DOI:10.1109/TMTT.2020.3023095