SOLAR PHOTOVOLTAIC (PV) SYSTEM FAILURE EVALUATION IN PARTIAL SHADING CONDITIONS USING MACHINE LEARNING METHODS (REGRESSION)
Solar Power Generation System (PLTS) is one of the high-potential renewable energy utilization methods in Indonesia. The PLTS system is currently undergoing development in Indonesia. However, there are challenges in its development caused by the failure of the PLTS system. One of the common cause...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/74425 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Solar Power Generation System (PLTS) is one of the high-potential renewable
energy utilization methods in Indonesia. The PLTS system is currently undergoing
development in Indonesia. However, there are challenges in its development caused
by the failure of the PLTS system. One of the common causes of PLTS system failure
is partial shading, which results in a decrease in power output. Partial shading
refers to the condition where PV modules are covered by shadows or dirt. The
decrease in power output is influenced by the amount of shading that occurs on the
PV modules. Therefore, an evaluation of the failure due to power output reduction
is needed to prevent a decrease in the efficiency of the PLTS system, and an
estimation system for the amount of shading on the Photovoltaic module is required.
The average power loss from the normal condition to the shading condition of 11
modules is 97.49%. In the normal condition, the efficiency of the PV module reaches
13.27%, but in the shading condition of 11 PV modules, the efficiency of the PLTS
system is 0.32%. The reduction that occurs is 12.95%.
The estimation of the amount of shading on the Photovoltaic module is performed
using machine learning methods, including Support Vector Regression, Random
Forest, Decision Tree Regressor, and Extra Trees Regressor. These methods are
compared based on the estimation accuracy determined through three performance
indicators: RMSE (Root Mean Squared Error), MAE (Mean Absolute Error), and
Rsquare, as well as training and testing time. The model with the Extra Trees
Regressor method is the best model with an RMSE value of 0.307, MAE value of
0.113, and Rsquare value of 0.994, with a training time of 111.200 milliseconds
and testing time of 1.130 milliseconds. |
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