Resumen
En los tiempos actuales con la creciente contaminación ambiental la cosecha de energía en Radio Frecuencia (RF), brinda la oportunidad de crear dispositivos inalámbricos autosustentables capaces de aprovechar los recursos de energía que abundan en la atmósfera, lo anterior convierte a la cosecha de energía en una fuente de energía limpia y amigable para el medio ambiente. Para un sistema de cosecha de energía, la eficiencia de un cosechador de energía depende de diversas etapas, una de los más importantes es el proceso de rectificación y multiplicación de voltaje. En este trabajo se analiza la salida de voltaje de dos multiplicadores de voltaje propuestos para la cosecha de energía, el multiplicador Dickson y el multiplicador Cockcroft-Walton. El análisis se realiza de una potencia de -20 a 20 dbm, con resistencias de carga de 1,000, 10,000 y 100,000Ω obteniendo un voltaje de salida similar para ambos multiplicadores de voltaje, sin embargo, se obtuvo una mayor eficiencia para una potencia de entrada de 10 dBm.
Palabras claves: Cosecha de energía, eficiencia, multiplicador de voltaje.

Abstract
In today's time with increasing environmental pollution, the harvesting of energy in Radio Frequency (RF) provides the opportunity to create self-sustaining wireless devices capable of leveraging the energy resources that abound in the atmosphere, making energy harvesting a clean and environmentally friendly source of energy. For an energy harvesting system, the efficiency of an energy harvester of various parameters, one of the most important is the process of rectification and multiplication of voltage. This work analyzes the voltage output of two voltage multipliers, the Dickson multiplier and the Cockcroft-Walton multiplier. The analysis is performed from a power of -20 to 20 dbm, with load resistors of 1,000, 10,000 and 100,000Ω obtaining a similar output voltage for both voltage multipliers, however, a higher efficiency was obtained for an input power of 10 dBm.
Keywords: energy harvesting, voltage multiplier, efficiency.

Akter, N., Hossain, B., Kabir, M., Bhuiyan, A., Yeasmin, M., Sultana, S. Design and Performance Analysis of 10-Stage Voltage Doublers RF Energy Harvesting Circuit for Wireless Sensor Network. Journal of Communications Engineering and Networks. 2. 84-91, 2014.

Keysight Tecnologies, ADS (2017). Product Release, https://www.keysight.com/en/pd-2854156/ads-2017.

Luo, Yu., Pu, L., Wang, G., Zhao, Y. RF Energy Harvesting Wireless Communications: RF Environment, Device Hardware and Practical Issues. Sensors, 2019.

Mishra, D., De, S., Jana, S., Basagni, S., Chowdhury, K., Heinzelman, W. Smart RF Energy Harvesting Communications: Challenges and Opportunities. Communications Magazine, IEEE. 53. 70-78, 2015.

Mohammed Al-Azawy, M., Sarı, F. Analysis of Dickson Voltage Multiplier for RF Energy Harvesting, 2019.

Nikhil, M., High Voltage Generation by using Cockcroft-Walton Multiplier, 2015.

Nintanavongsa, P., Muncuk, U., Lewis, D., Chowdhury, K. Design Optimization and Implementation for RF Energy Harvesting Circuits. Emerging and Selected Topics in Circuits and Systems, IEEE Journal on. 2. 24-33, 2012.

Rashid, M.H. Circuitos microelectrónicos analisís y diseño. 1a ed. International Thomson, 2000.

Rashid, M.H. Electrónica de Potencia, Circuitos, Dispositivos y Aplicaciones 3a ed. PrenticeHall, 2004.

Sarı, F., Uzun, Y. A comparative study: voltage multipliers for RF energy harvesting system. 61. 12-23, 2019.

Selim, K., Wu, S., Saleeb. RF Energy Scavenging with a Wide-range Input Power Level. IEEE Access. 2019.

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, pp. 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.