Modeling of the output current of a photovoltaic grid-connected system using random forests technique

Modeling of the output current of a photovoltaic grid-connected system using random forests technique

This study presents a prediction technique for the output current of a photovoltaic grid-connected system by using random forests technique. Experimental data of a photovoltaic grid-connected system are used to train and validate the proposed model. Three statistical error values, namely root mean s...

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Main Authors: Ibrahim A Ibrahim, Tamer Khatib, Azah Mohamed, Wilfried Elmenreich
Format: Article
Language:English
Published: SAGE Publishing 2018-01-01
Series:Energy Exploration & Exploitation
Online Access:https://doi.org/10.1177/0144598717723648
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spelling doaj-9818f77d65f245f18d0bc2fef16922ff2020-11-25T04:09:09ZengSAGE PublishingEnergy Exploration & Exploitation0144-59872048-40542018-01-013610.1177/0144598717723648Modeling of the output current of a photovoltaic grid-connected system using random forests techniqueIbrahim A Ibrahim0Tamer Khatib1Azah Mohamed2Wilfried Elmenreich3Department of Electrical, Electronic and Systems Engineering, Universiti Kebangsaan Malaysia, Bangi, MalaysiaEnergy Engineering and Environment Department, An-Najah National University, Nablus, PalestineDepartment of Electrical, Electronic and Systems Engineering, Universiti Kebangsaan Malaysia, Bangi, MalaysiaInstitute of Networked & Embedded Systems/Lakeside Labs, Alpen-Adria-Universität Klagenfurt, Klagenfurt, AustriaThis study presents a prediction technique for the output current of a photovoltaic grid-connected system by using random forests technique. Experimental data of a photovoltaic grid-connected system are used to train and validate the proposed model. Three statistical error values, namely root mean square error, mean bias error, and mean absolute percentage error, are used to evaluate the developed model. Moreover, the results of the proposed technique are compared with results obtained from an artificial neural network-based model to show the superiority of the proposed method. Results show that the proposed model accurately predicts the output current of the system. The root mean square error, mean absolute percentage error, and mean bias error values of the proposed method are 2.7482, 8.7151, and −2.5772%, respectively. Moreover, the proposed model is faster than the artificial neural network-based model by 0.0801 s.https://doi.org/10.1177/0144598717723648
collection DOAJ
language English
format Article
sources DOAJ
author Ibrahim A Ibrahim
Tamer Khatib
Azah Mohamed
Wilfried Elmenreich
spellingShingle Ibrahim A Ibrahim
Tamer Khatib
Azah Mohamed
Wilfried Elmenreich
Modeling of the output current of a photovoltaic grid-connected system using random forests technique
Energy Exploration & Exploitation
author_facet Ibrahim A Ibrahim
Tamer Khatib
Azah Mohamed
Wilfried Elmenreich
author_sort Ibrahim A Ibrahim
title Modeling of the output current of a photovoltaic grid-connected system using random forests technique
title_short Modeling of the output current of a photovoltaic grid-connected system using random forests technique
title_full Modeling of the output current of a photovoltaic grid-connected system using random forests technique
title_fullStr Modeling of the output current of a photovoltaic grid-connected system using random forests technique
title_full_unstemmed Modeling of the output current of a photovoltaic grid-connected system using random forests technique
title_sort modeling of the output current of a photovoltaic grid-connected system using random forests technique
publisher SAGE Publishing
series Energy Exploration & Exploitation
issn 0144-5987
2048-4054
publishDate 2018-01-01
description This study presents a prediction technique for the output current of a photovoltaic grid-connected system by using random forests technique. Experimental data of a photovoltaic grid-connected system are used to train and validate the proposed model. Three statistical error values, namely root mean square error, mean bias error, and mean absolute percentage error, are used to evaluate the developed model. Moreover, the results of the proposed technique are compared with results obtained from an artificial neural network-based model to show the superiority of the proposed method. Results show that the proposed model accurately predicts the output current of the system. The root mean square error, mean absolute percentage error, and mean bias error values of the proposed method are 2.7482, 8.7151, and −2.5772%, respectively. Moreover, the proposed model is faster than the artificial neural network-based model by 0.0801 s.
url https://doi.org/10.1177/0144598717723648
work_keys_str_mv AT ibrahimaibrahim modelingoftheoutputcurrentofaphotovoltaicgridconnectedsystemusingrandomforeststechnique
AT tamerkhatib modelingoftheoutputcurrentofaphotovoltaicgridconnectedsystemusingrandomforeststechnique
AT azahmohamed modelingoftheoutputcurrentofaphotovoltaicgridconnectedsystemusingrandomforeststechnique
AT wilfriedelmenreich modelingoftheoutputcurrentofaphotovoltaicgridconnectedsystemusingrandomforeststechnique
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