Radiation Pattern Analysis of Mills Cross Array of Patch Antennas for 5G Mobile Handset Applications

Authors

  • M. J. Martínez Silva Universidad De Guadalajara, Guadalajara, Jalisco, Blvd. Marcelino García Barragán #1421, C.P. 44430, México
  • M. S. Ruiz Palacios Universidad De Guadalajara, Guadalajara, Jalisco, Blvd. Marcelino García Barragán #1421, C.P. 44430, México

DOI:

https://doi.org/10.53555/eee.v3i12.373

Keywords:

Mills cross, planar antenna array, 5G antenna.

Abstract

This document presents the analysis of the radiation pattern of Mills cross arrays of patch antennas for a 5G mobile handset in the 28 GHz band. Emphasis is given to determine the radiation coverage in the z>0 hemisphere. As a reference to compare the performance of the Mills cross, a square planar array is used. It is found that although square planar array have better performance, the Mills cross can
produce directivities up to 16.7 dB with 17 antennas, having total azimuthal coverage up to =40°, while it is necessary to use 91 antennas in a square planar array to cover up to =50°.

Downloads

Download data is not yet available.

References

Balanis, Constantine A., (2005). Antenna Theory, Analysis and Design. Wiley-Interscience.

Degel C., F. H. (2014). 3D Sonar System based on Mills Cross Antenna Configuration. Procc. of 2014 Oceans. St. John's, N. L., Canada: IEEE.

Birtill, E. J.,(1965). The Application of Phased Arrays to the Analysis of Seismic Body Wave. Series A. Mathematical and Physical Sciences, Phisosophical Transactions of the Roysal Society of London , 421-493.Groups, Radiocommunication Study. (29 de June de 2016).

Recuperado el 11 de August de 2017, de https://www.itu.int/es/ITU-R/Pages/default.aspxMacPhieR.H.,(2007 ). "A Mills Cross Multipicative Array with the Power Pattern of a Convensional Planar Array". IEEE Antennas and Propagation Society International Symposium. Honolulu, Hawaii: IEEE.

MarzettaT.L.,(2015). Massive MIMO: An Introduction. Bell Labs Technical Journal .

MacPhieR.H.,(2011). "A modified mills cross with elements spaced one wavelength apart". URSI General Assembly and Scientific Symposium. Istambul, Turkey: IEEE.

Mills, B. Y. (1953). A High Resolution Aeriual Systema of a New Type. Australian J. Phys. , 272-278.

Razavi, B. (2009). Design of millimeter-wave CMOS Radios: A Tutorial. IEEE Transactions on Circuits Systems , 4-16.

Recommendation ITU-R. (12 de October de 2015). M.2083-0, M Series Mobile, radiodetermination, amateur and related satellite services.

Recuperado el 21 de August de 2017, de https://www.itu.int/es/ITU-R/Pages/default.aspx

Slattery, B. R. (1966). Use of Mills cross receivinf arrays in radar system. Proc. IEE , 1712-1722.

Working Party 5D. (22 de February de 2017). Minimum requirements related to technical performance for IMT-2020 radio interface(s), Document 5/40-E. Recuperado el 30 de May de 2017, de https://www.itu.int/es/ITU-R/Pages/default.aspx

Y. Huo, X. D. (2017). 5G Cellular User Equipment: From Theory to Practial Haerdawre Designs. IEEE , 13992 -14010.

Downloads

Published

2017-12-31

How to Cite

Silva, M. J. M., & Palacios, M. S. R. (2017). Radiation Pattern Analysis of Mills Cross Array of Patch Antennas for 5G Mobile Handset Applications. International Journal For Research In Electronics & Electrical Engineering, 3(12), 01–06. https://doi.org/10.53555/eee.v3i12.373