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PIER PIER B PIER C PIER M PIER Letters
2020-01-03
Optimal Design of Electrically-Small Loop Receiving Antenna
By
Timothy Bolton,

    Dr. Timothy Bolton

    Naval Undersea Warfare Center Division Newport

    USA

    Homepage

Morris B. Cohen

    Dr. Morris B. Cohen

    Department of Electrical and Computer Engineering

    Georgia Institute of Technology

    USA

    Homepage

Progress In Electromagnetics Research C, Vol. 98, 155-169, 2020
doi:10.2528/PIERC19090911
Abstract
There is a large body of literature for electrically-small loop receiving antennas including more recent work in demagnetization effects for magnetic materials which are used for reducing antenna size. Optimal design of loop antennas requires understanding the electromagnetic principles and is limited by the accuracy of predicting the electromagnetic parameters (resistance, inductance, capacitance, effective permeability, sensitivity). We present the design principles for electrically-small loop receiving antennas including recommended formulas, a novel approach to optimal design, and an application example for use in the VLF/LF band (1-100 kHz) for two different ferrite-core loop antennas including the optimum coil parameters. Using a ferrite magnetic core greatly complicates analysis and prediction of resistance, inductance, and sensitivity as a function of frequency due to the dependence on core material properties, core geometry, and wire coil geometry upon the core (capacitance is typically negligibly affected). Experimental results for the two ferrite-core loop antennas and an air-core loop antenna validate the optimal design approach with good overall agreement to theoretical prediction of resistance, inductance, and sensitivity. Discussion and comparison between air-core and ferrite-core designs demonstrate the trade-off between outer diameter, length, and mass vs. sensitivity.
Citation
Timothy Bolton, and Morris B. Cohen, "Optimal Design of Electrically-Small Loop Receiving Antenna," Progress In Electromagnetics Research C, Vol. 98, 155-169, 2020.
doi:10.2528/PIERC19090911
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