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dc.contributor.authorAlmaktoom, Abdulaziz
dc.contributor.authorKhan, Hajra
dc.contributor.authorMian Qaisar, Saeed
dc.contributor.authorWaqar, Asad
dc.contributor.authorKrichen, Moez
dc.contributor.authorNizami, Imran
dc.date.accessioned2023-05-07T07:39:20Z
dc.date.available2023-05-07T07:39:20Z
dc.date.issued2022-10-24
dc.identifier.citationKhan, H.; Nizami, I.F.; Qaisar, S.M.; Waqar, A.; Krichen, M.; Almaktoom, A.T. Analyzing Optimal Battery Sizing in Microgrids Based on the Feature Selection and Machine Learning Approaches. Energies 2022, 15, 7865. https://doi.org/10.3390/en15217865en_US
dc.identifier.doihttps://doi.org/10.3390/en15217865en_US
dc.identifier.urihttp://hdl.handle.net/20.500.14131/773
dc.description.abstractMicrogrids are becoming popular nowadays because they provide clean, efficient, and lowcost energy. Microgrids require bulk storage capacity to use the stored energy in times of emergency or peak loads. Since microgrids are the future of renewable energy, the energy storage technology employed should be optimized to provide power balancing. Batteries play a variety of essential roles in daily life. They are used at peak hours and during a time of emergency. There are different types of batteries i.e., lithium-ion batteries, lead-acid batteries, etc. Optimal battery sizing of microgrids is a challenging problem that limits modern technologies such as electric vehicles, etc. Therefore, it is imperative to assess the optimal size of a battery for a particular system or microgrid according to its requirements. The optimal size of a battery can be assessed based on the different battery features such as battery life, battery throughput, battery autonomy, etc. In this work, the mixed-integer linear programming (MILP) based newly generated dataset is studied for computing the optimal size of the battery for microgrids in terms of the battery autonomy. In the considered dataset, each instance is composed of 40 attributes of the battery. Furthermore, the Support Vector Regression (SVR) model is used to predict the battery autonomy. The capability of input features to predict the battery autonomy is of importance for the SVR model. Therefore, in this work, the relevant features are selected utilizing the feature selection algorithms. The performance of six best-performing feature selection algorithms is analyzed and compared. The experimental results show that the feature selection algorithms improve the performance of the proposed methodology. The Ranker Search algorithm with SVR attains the highest performance with a Spearman’s rank-ordered correlation constant of 0.9756, linear correlation constant of 0.9452, Kendall correlation constant of 0.8488, and root mean squared error of 0.0525.en_US
dc.publisherMDPIen_US
dc.subjectbattery autonomyen_US
dc.subjectbattery sizeen_US
dc.subjectfeature selectionen_US
dc.titleAnalyzing Optimal Battery Sizing in Microgrids Based on the Feature Selection and Machine Learning Approachesen_US
dc.source.volume15en_US
dc.source.issue21en_US
dc.contributor.researcherUniversity Collaborationen_US
dc.contributor.researcherExternal Collaborationen_US
dc.subject.KSAENERGYen_US
dc.source.indexScopusen_US
dc.source.indexWoSen_US
dc.contributor.departmentSupply Chain Managementen_US
dc.contributor.firstauthorKhan, Hajra


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