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Approximating heat loss in smart buildings through large scale experimental and computational intelligence solutions

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dc.contributor.author Ben Khedher, Nidhal
dc.contributor.author Mukhtar, Azfarizal
dc.contributor.author Yasir, Ahmad Shah Hizam Md
dc.contributor.author Khalilpoor, Nima
dc.contributor.author Foong, Loke Kok
dc.contributor.author Le, Binh Nguyen
dc.contributor.author Yildizhan, Hasan
dc.date.accessioned 2024-09-27T12:38:33Z
dc.date.available 2024-09-27T12:38:33Z
dc.date.issued 2023-12
dc.identifier.citation Khedher, N. B., Mukhtar, A., Md Yasir, A. S. H., Khalilpoor, N., Foong, L. K., Nguyen Le, B., & Yildizhan, H. (2023). Approximating heat loss in smart buildings through large scale experimental and computational intelligence solutions. Engineering Applications of Computational Fluid Mechanics, 17(1), 2226725. https://doi.org/10.1080/19942060.2023.2226725 tr_TR
dc.identifier.issn 1994-2060
dc.identifier.issn 1997-003X
dc.identifier.uri http://openacccess.atu.edu.tr:8080/xmlui/handle/123456789/4242
dc.identifier.uri http://dx.doi.org/10.1080/19942060.2023.2226725
dc.description WOS indeksli yayınlar koleksiyonu. / WOS indexed publications collection. tr_TR
dc.description.abstract The attainment of energy sustainability in the building sector can be realised by implementing a green building programme, which has grown significantly over the last thirty years. Green building is considered a technical and management strategy within the building and construction industries. Many different prediction methods, both complex and simple, have been put out in recent years and used to solve a wide variety of issues. Several case studies have highlighted factors that impede energy and resource usage in green buildings. The utilisation, trends, and consequences of wall and thermal insulation materials are examined. The main scope of this investigation is to predict buildings' heat loss by applying artificial neural networks according to the heat transfer coefficients of walls and coating materials, as well as indoor, outdoor, and external surface temperatures. The data has been normalised and presented to two selected neural networks (Harmony search (HS) and particle swarm optimisation are used and contrasted (PSO)). For evaluating the accuracy of models, two statistical indexes are used (R (2) and RMSE). Model performance of PSO-MLP is shown by R (2) amounts of 0.97055 and 0.87381, respectively, and RMSE amounts of 0.02534 and 0.09685. Similarly, HS-MLP model accuracy is also indicated by R (2) amounts of 0.93839 and 0.84176 and RMSE amounts of 0.03635 and 0.10753. The analysis in this paper shows that PSO-MLP predicts heat loss with higher accuracy and improved performance. tr_TR
dc.language.iso en tr_TR
dc.publisher ENGINEERING APPLICATIONS OF COMPUTATIONAL FLUID MECHANICS / TAYLOR & FRANCIS tr_TR
dc.relation.ispartofseries 2023;Volume: 17 Issue: 1
dc.subject Green buildings tr_TR
dc.subject heat loss tr_TR
dc.subject harmony search tr_TR
dc.subject particle swarm optimisation tr_TR
dc.subject artificial neural network tr_TR
dc.title Approximating heat loss in smart buildings through large scale experimental and computational intelligence solutions tr_TR
dc.type Article tr_TR


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