Electrically Large Circular Loops in the Estimation of an Incident Emitter's Direction-of-Arrival or Polarization

Electrically small loops have been the focus of the research literature on loop-antenna signal processing, but such electrically small loop-antennas are electromagnetically inefficient. Electrically large loop-antennas will instead be analyzed here in this paper, in the context of estimating an inci...

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Veröffentlicht in:	IEEE transactions on antennas and propagation 2018-06, Vol.66 (6), p.3046-3055
Hauptverfasser:	Khan, Salman, Wong, Kainam Thomas, Song, Yang, Tam, Wai-Yip
Format:	Artikel
Sprache:	eng
Schlagworte:	Antenna arrays Antenna measurements Antenna radiation patterns antennas Array signal processing arrays direction-of-arrival estimation Directive antennas loop antenna arrays loop antennas Magnetic resonance Manifolds parameter estimation polarimetry polarization polarization estimation radio direction finding signal processing antennas
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creator	Khan, Salman Wong, Kainam Thomas Song, Yang Tam, Wai-Yip
description	Electrically small loops have been the focus of the research literature on loop-antenna signal processing, but such electrically small loop-antennas are electromagnetically inefficient. Electrically large loop-antennas will instead be analyzed here in this paper, in the context of estimating an incident source's direction-of-arrival or polarization. Specifically, three large loop-antennas here are collocated and are oriented orthogonally, in order to measure all three Cartesian components of the incident magnetic field simultaneously all at one specific spatial position. This orthogonal triad offers azimuth-elevation bivariate directivity despite the three loops' spatial collocation. For such a triad of electrically large loops, this paper (first in the open literature) formulates the array manifold, develops the corresponding algorithms in closed form to estimate an incident source's azimuth-elevation direction-of-arrival or polarization, and demonstrates these proposed estimators' precision as close to the Cramér-Rao bounds.
doi_str_mv	10.1109/TAP.2018.2819727
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subjects	Antenna arrays Antenna measurements Antenna radiation patterns antennas Array signal processing arrays direction-of-arrival estimation Directive antennas loop antenna arrays loop antennas Magnetic resonance Manifolds parameter estimation polarimetry polarization polarization estimation radio direction finding signal processing antennas
title	Electrically Large Circular Loops in the Estimation of an Incident Emitter's Direction-of-Arrival or Polarization
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