Resumen
Este trabajo aborda el análisis de rendimiento de un sistema fotovoltaico interconectado a la red seleccionando como caso de estudio una ubicación en el estado de Guerrero, México. Se consideran variables meteorológicas locales para el dimensionamiento, y con el objetivo de observar cómo estas pueden influir en el rendimiento del sistema fotovoltaico. Se usan herramientas de software como PVGIS y POWER para la extracción de datos meteorológicos de la zona, así como el software PVsyst para la simulación del sistema. Se analiza el comportamiento que tienen los módulos fotovoltaicos bajo la influencia de las variables meteorológicas y se comprueba la producción energética del sistema, así como las pérdidas que tiene en cada una de sus etapas. Como resultado se obtuvo un sistema con una proporción de rendimiento del 76.5%, esto debido principalmente a las pérdidas generadas por la influencia de la temperatura en los módulos y otras etapas del sistema.
Palabras Clave: Energías renovables, Dimensionamiento fotovoltaico, Pérdidas en sistemas fotovoltaicos, Producción energética, Variables meteorológicas.

Abstract
This work deals with the performance analysis of a grid-connected photovoltaic system, selecting as a case study a location in the state of Guerrero, Mexico. Local meteorological variables are considered for sizing, and with the objective of observing how these can influence the performance of the PV system. Software tools such as PVGIS and POWER are used for the extraction of meteorological data from the area, as well as PVsyst software for the simulation of the system. The behavior of the photovoltaic modules under the influence of meteorological variables is analyzed and the energy production of the system is verified, as well as the losses in each of its stages. As a result, a system with an efficiency ratio of 76.5% was obtained, mainly due to the losses generated by the influence of the temperature in the modules and other stages of the system.
Keywords: Energy production, Losses in photovoltaic systems, Meteorological variables, Photovoltaic sizing, Renewable energies.

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