Resumen

La cosecha de energía en las bandas de radiofrecuencia (RF) es una solución prometedora para lograr sistemas de comunicación inalámbricos energéticamente auto-sustentables. La cosecha de energía busca captar energía del entorno que pueda ser recolectada y utilizada para alimentar dispositivos electrónicos. En este trabajo se analizan las oportunidades de cosecha de energía en RF dentro y fuera de la banda ISM de 2.4 GHz a través del diseño y simulación una de antena F-invertida impresa (PIFA). Se utiliza información de la energía disponible en el espectro en la banda de 1800 a 2600 MHz por medio de una campaña de medición espectral en la ciudad de San Luis Potosí.  Al analizar el ancho de banda de la antena se logra estimar la cantidad de energía de RF que pudiera ser cosechada dentro y fuera de la banda ISM de 2.4 GHz en el rango de 2-3 GHz.

Palabras Claves: cosecha de energía, diseño de antena F-invertida impresa, radiofrecuencia.

Abstract

Energy harvesting in the radio frequency (RF) bands is a promising solution to achieve self-sustaining energy-efficient wireless communication systems. The energy harvesting seeks to capture energy from the environment that can be collected and used to power electronic devices. This paper analyzes the opportunities for harvesting energy in RF inside and outside the 2.4 GHz ISM band through the design and simulation of a printed inverted F antenna (PIFA). Information on the energy available in the spectrum in the 1800-2600 MHz band is used through a spectral measurement campaign in the city of San Luis Potosí. By analyzing the bandwidth of the antenna, it is possible to estimate the amount of RF energy that could be harvested inside and outside the 2.4 GHz ISM band in the 2-3 GHz range.

Keywords: energy harvesting, printed inverted F antenna design, radiofrequency.

Arista, D., Cárdenas, M., Pineda, U., Arce A. & Stevens, E. Spectrum Occupancy Measurements in the Sub-6 Ghz Band for Smart Spectrum Applications. 2018 IEEE Latin-American Conference on Communications (LatinCom), p. 1-5, Guadalajara, 2018.

Balanis, C.A. Antenna Theory. Analysis and Design. John Wiley & Sons, Inc., 2a. edición, 1997.

Kim, S., Vyas, R., Bito, J., Niotaki, K., Collado, A., Georgiadis, A. & Tentzeris, M. Ambient RF Energy-Harvesting Technologies for Self-Sustainable Standalone Wireless Sensors Platforms. Proceedings of the IEEE, Vol 102, No. 11, p. 1649-1666, 2014.

Instituto Federal de Telecomunicaciones, Cuadro Nacional de Atribución de Frecuencias (CNAF), http://cnaf.ift.org.mx. 2019.

López, M. & Casadevall, F. Spectrum usage in cognitive radio networks: From field measurements to empirical methods. IEICE Transactions on Communications, Vol. 97, No. 2, p. 242-250, 2014.

Rocke, S. Out-of-Band radiation: Opportunities for antenna-based RF energy harvesting in wireless devices?. 2015 IEEE Online Conference on Green Communications (OnlineGreenComm), p. 53-58, On-line, 2015.

Srinivasu, G., Sharma, V., Anveshkumar, N. A Survey on Conceptualization of RF Energy Harvesting. JASC: Journal of Applied Science and Computations, Vol. VI, Issue: II, p. 791-800, 2019.

Tran, L., Cha, H., Park, W. RF Power Harvesting: a review on designing methodologies and applications. Micro and Nano Systems Letters, 5:14, 2017.

Vandelle, E., Ngan Bui, D., Voung, T., Ardila, G., Wu, K., Hermour, S. Harvesting Ambient RF Energy Efficientrly with Optimal Angular Coverage. IEEE Transactions on Antennas and Propagation, Vol. 67, No. 3, p. 1862-1873, 2019.

Zeng, M., Andrenko, A., Liu, X., Li, Z., Tan, H. A Compact Fractal Loop Rectenna for RF Energy Harvesting. IEEE Antennas and Wireless Propagation Letters, Vol. 16, p. 2424-2427, 2017.