LOW ENERGY OFFICE BUILDING DESIGN BASED ON NON-DOMINATED SORTING GENETIC ALGORITHM 2 AND EXTREME GRADIENT BOOSTING-ARTIFICIAL NEURAL NETWORK, 194-202. SI

Sha Song

References

1. [1] H.R. Patel and V.A. Shah, Shadowed type-2 fuzzy sets indynamic parameter adaption in cuckoo search and flowerpollination algorithms for optimal design of fuzzy fault-tolerantcontrollers, Mathematical and Computational Applications,27(6), 2022, 89.
2. [2] H.R. Patel and V.A. Shah, A metaheuristic approach forinterval type-2 fuzzy fractional order fault-tolerant controllerfor a class of uncertain nonlinear system, Automatika: ˇcasopis zaautomatiku, mjerenje, elektroniku, raˇcunarstvo i komunikacije,63(4), 2022, 656–675.
3. [3] H.R. Patel, Fuzzy-based metaheuristic algorithm for optimiza-tion of fuzzy controller: Fault-tolerant control application,International Journal of Intelligent Computing and Cybernet-ics, 15(4), 2022, 599–624.
4. [4] D. D’Agostino and L. Mazzarella, What is a nearly zeroenergy building? overview, implementation and comparisonof definitions, Journal of Building Engineering, 21(1), 2019,200–212.
5. [5] Z. Liu, Y. Liu, B.J. He, W. Xu, G. Jin, and X. Zhang,Application and suitability analysis of the key technologiesin nearly zero energy buildings in China, Renewable andSustainable Energy Reviews, 101(1), 2019, 329–345.
6. [6] X. Li, Y. Zhou, S. Yu, G. Jia, H. Li, and W. Li, Urban heatisland impacts on building energy consumption: A review ofapproaches and findings, Energy, 174(3), 2019, 407–419.
7. [7] F. Ascione, N. Bianco, G.M. Mauro, and G.P. Vanoli, A newcomprehensive framework for the multi-objective optimizationof building energy design: Harlequin, Applied Energy, 241(5),2019, 331–361.
8. [8] Y. Jiang, G. Tong, H. Yin, and N. Xiong, A pedestrian detectionmethod based on genetic algorithm for optimize XGBoosttraining parameters, IEEE Access, 7(1), 2019, 118310–118321.
9. [9] X. Deng, M. Li, S. Deng, and L. Wang, Hybrid gene selectionapproach using XGBoost and multi-objective genetic algorithmfor cancer classification, Medical & Biological Engineering &Computing, 60(3), 2022, 663–681.
10. [10] J. Chen, F. Zhao, Y. Sun, and Y. Yin, Improved XGBoostmodel based on genetic algorithm, International Journal ofComputer Applications in Technology, 62(3), 2020, 240–245.
11. [11] P. Satrio, T.M.I. Mahlia, N. Giannetti, and K. Saito,Optimization of HVAC system energy consumption in abuilding using artificial neural network and multi-objectivegenetic algorithm, Sustainable Energy Technologies andAssessments, 35(1), 2019, 48–57.
12. [12] A.O. Acheampong and E.B. Boateng, Modelling carbonemission intensity: Application of artificial neural network,Journal of Cleaner Production, 225(1), 2019, 833–856.
13. [13] Z. Liu, D. Wu, Y. Liu, Z. Han, L. Lun, J. Gao, and G. Cao,Accuracy analyses and model comparison of machine learningadopted in building energy consumption prediction, EnergyExploration & Exploitation, 37(4), 2019, 1426–1451.
14. [14] M. Barma and U.M. Modibbo, Multiobjective mathematicaloptimization model for municipal solid waste management witheconomic analysis of reuse/recycling recovered waste materials,Journal of Computational and Cognitive Engineering, 1(3),2022, 122–137.
15. [15] M.A. Budiyanto and F. Zhafari, Simulation study usingbuilding-design energy analysis to estimate energy consumptionof refrigerated container, Energy Procedia, 156(1), 2019,207–211.

Important Links:

• Abstract
• DOI: 10.2316/J.2024.201-0468
• From Journal (201) Mechatronic Systems and Control - 2024

Go Back