Planar antenna design for contactless energizing applications: resonance analysis

Authors

DOI:

https://doi.org/10.61467/2007.1558.2024.v15i1.390

Keywords:

Contactless voltage source, planar antennas

Abstract

Advances in medical technology suggest that the application of implantable medical devices or Smart Hospital Devices (SHD) can enhance the control and treatment of chronic disorders. However, most of these developments require an electrical power source for operation, making the use of batteries unfeasible. This paper presents the design and resonance analysis of four different geometries for the fabrication of planar antennas as an alternative to a contactless power supply. Previously published software [19] was used to calculate the electrical parameters for each coil design. Operating trials were executed under laboratory conditions, and a bracket manufactured using polylactic acid (PLA) through a 3D printer was used to accurately define the distances between coils to achieve correct alignment between them. Based on the experimental results, it was possible to calculate the resonant frequency of the inductive links at a 5 mm spacing. Similarly, it is possible to calculate the capacitive effect necessary to improve the resonant circuit in different transmitter-receiver planar antenna pairs. The most efficient combination to induce voltage in these links is to use the hexagonal profile design as a transmitter and receiver antenna, applying a sinusoidal signal with 8 MHz frequency.

Author Biographies

Jorge Santiago-Amaya, Tecnológico de Estudios Superiores de Chalco

Jorge Santiago-Amaya obtained his PhD. In Communications and Electronics from the National Polytechnic Institute (IPN-Mexico) in 2019. His line of research is focused on the area of biomedical engineering, medical devices design, development of web systems, wireless and control devices. He is a professor of Electronic Engineering program at Tecnólogico de Estudios Superiores de Chalco in the Department of Electronic Engineering.

Diego Escamilla-Amador , Tecnológico de Estudios Superiores de Chalco

Diego Escamilla-Amador Student of the last course of Electronic Engineering program at the Tecnológico de Estudios Superiores de Chalco. His interest of research is focused on wireless devices automatic control, robotics, automation and green energy.

Francisco Rafael Trejo-Macotela , Polytechnic University of Pachuca

Francisco Rafael Trejo-Macotela received the PhD. Degree in Electronics from the National Institute of Astrophysics, Optics and Electronics, Puebla, Mexico. Currently, he is a professor in the Master's in Mechatronics and Master's in ICT programs at the Polytechnic University of Pachuca, Mexico. His main research interests are Integrated Circuit Design, Analog and Digital Design, Embedded Systems, RF Electronics, Telecommunications Systems, Precision Agriculture, Internet of Things, among others.

Daniel Robles-Camarillo, Polytechnic University of Pachuca

Daniel Robles-Camarillo. He obtained his PhD. in Communications and Electronics from the National Polytechnic Institute (IPN-Mexico) in 2011. His research interests include the applications of embedded systems, electronic instrumentation and communication, wireless sensor networks, and cyber-physical systems, complemented by machine learning algorithms. Currently, he is a professor at the Graduate School of Information and Communication Technologies at the Polytechnic University of Pachuca (Mexico)

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Published

2024-05-24

How to Cite

Santiago-Amaya, J., Escamilla-Amador , D., Trejo-Macotela , F. R., & Robles-Camarillo, D. (2024). Planar antenna design for contactless energizing applications: resonance analysis. International Journal of Combinatorial Optimization Problems and Informatics, 15(1), 20–31. https://doi.org/10.61467/2007.1558.2024.v15i1.390

Issue

Vol. 15 No. 1 (2024)

Section

Articles

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Copyright (c) 2024 International Journal of Combinatorial Optimization Problems and Informatics

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