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A theoretical and numerical approach for selecting miniaturized antenna topologies on magneto-dielectric substrates

Published online by Cambridge University Press:  18 May 2015

Alex Pacini*
Affiliation:
DEI – “Guglielmo Marconi”; II School of Architecture and Engineering, University of Bologna, Cesena Campus, Italy
Alessandra Costanzo
Affiliation:
DEI – “Guglielmo Marconi”; II School of Architecture and Engineering, University of Bologna, Cesena Campus, Italy DEI – “Guglielmo Marconi”; School of Architecture and Engineering, University of Bologna, Bologna, Italy
Diego Masotti
Affiliation:
DEI – “Guglielmo Marconi”; School of Architecture and Engineering, University of Bologna, Bologna, Italy
*
Corresponding author: A. Pacini Email: [email protected]

Abstract

An increasing interest is arising in developing miniaturized antennas in the microwave range. However, even when the adopted antennas dimensions are small compared with the wavelength, radiation performances have to be preserved to keep the system-operating conditions. For this purpose, magneto-dielectric materials are currently exploited as promising substrates, which allows us to reduce antenna dimensions by exploiting both relative permittivity and permeability. In this paper, we address generic antennas in resonant conditions and we develop a general theoretical approach, not based on simplified equivalent models, to establish topologies most suitable for exploiting high permeability and/or high-permittivity substrates, for miniaturization purposes. A novel definition of the region pertaining to the antenna near-field and of the associated field strength is proposed. It is then showed that radiation efficiency and bandwidth can be preserved only by a selected combinations of antenna topologies and substrate characteristics. Indeed, by the proposed independent approach, we confirm that non-dispersive magneto-dielectric materials with relative permeability greater than unit, can be efficiently adopted only by antennas that are mainly represented by equivalent magnetic sources. Conversely, if equivalent electric sources are involved, the antenna performances are significantly degraded. The theoretical results are validated by full-wave numerical simulations of reference topologies.

Type
Research Papers
Copyright
Copyright © Cambridge University Press and the European Microwave Association 2015 

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References

REFERENCES

[1] Costanzo, A.; Donzelli, F.; Masotti, D.; Rizzoli, V.: Rigorous design of RF multi-resonator power harvesters, in Proc. of the 4th EuCAP, 2010, 1–4.Google Scholar
[2] Ho, J.S.; Kim, S.; Poon, A.S.Y.: Midfield wireless powering for implantable systems. Proc. IEEE, 101 (2013), 1369.Google Scholar
[3] Mosallaei, H.; Sarabandi, K.: Magneto-dielectrics in electromagnetics: concept and applications. IEEE Trans. Antennas Propag., 52 (6) (2004), 15581567.Google Scholar
[4] Mosallaei, H.; Sarabandi, K.: Engineered meta-substrates for antenna miniaturization, in URSI International Symposium on Electromagnetic Theory, Pisa, Italy, 23–27 May 2004.Google Scholar
[5] Aldrigo, M.; Costanzo, A.; Masotti, D.; Baldisserri, C.; Dumitru, I.; Galassi, C.: Numerical and experimental characterization of a button-shaped miniaturized UHF antenna on magneto-dielectric substrate. Int. J. Microw. Wirel. Technol., 5 (3) (2013), 231239.Google Scholar
[6] Aldrigo, M.; Costanzo, A.; Masotti, D.; Galassi, C.: Exploitation of a novel magneto-dielectric substrate for miniaturization of wearable UHF antennas. Elsevier Mater. Lett., 87 (2012), 127130.Google Scholar
[7] Karilainen, A.O.; Ikonen, P.M.T.; Simovski, C.R.; Tretyakov, S.A.: Choosing dielectric or magnetic material to optimize the bandwidth of miniaturized resonant antennas. IEEE Trans. Antennas Propag., 59 (11) (2011), 39913998.Google Scholar
[8] Mikki, S.M.; Antar, Y.M.M.: A theory of antenna electromagnetic near field – part I. IEEE Trans. Antennas Propag., 59 (12) (2011), 46914705.CrossRefGoogle Scholar
[9] Ikonen, P.; Tretyakov, S.: On the advantages of magnetic materials in microstrip antenna miniaturization. Microw. Opt. Technol. Lett., 50 (12) (2008), 31313134.Google Scholar
[10] Love, A.E.H.: The integration of equations of propagation of electric waves. Trans. R. Soc. Lond., 197 (1901), 145.Google Scholar
[11] Pacini, A.; Costanzo, A.; Masotti, D.: A theoretical and numerical approach for selecting miniaturized antenna topologies on magneto-dielectric substrate's, in 44th Eur. Microwave Conf. (EuMC, 2014), 6–9 October 2014, 869–872.Google Scholar
[12] Wilcox, C.H.: An expansion theorem for electromagnetic fields. Commun. Pure Appl. Math., 9 (2) (1956), 115134.Google Scholar
[13]©2014 CST Computer Simulation Technology AG. All rights reserved. Website: http://www.cst.com Google Scholar
[14] Rizzoli, V.; Lipparini, A.: Propagazione Elettromagnetica Guidata, vol. 1, Progetto Leonardo, Bologna, 1991.Google Scholar
[15] Hansen, R.C.; Burke, M.: Antennas with magneto-dielectrics. Microw. Opt. Technol. Lett., 26 (2) (2000), 7578.Google Scholar
[16] Balanis, C.A.: Antenna Theory: Analysis and Design, 3rd ed., Wiley-Interscience, New York, 2005, 34.Google Scholar
[17] Ikonen, P.M.T.; Rozanov, K.N.; Osipov, A.V.; Alitalo, P.; Tretyakov, S.A.: Magnetodielectric substrates in antenna miniaturization: potential and limitations. IEEE Trans. Antennas Propag., 54 (2006), 33913399.Google Scholar
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