Suggesting a Stochastic Fractal Search Paradigm in Combination with Artificial Neural Network for Early Prediction of Cooling Load in Residential Buildings
Copyright policy )Suggesting a Stochastic Fractal Search Paradigm in Combination with Artificial Neural Network for Early Prediction of Cooling Load in Residential Buildings
Early prediction of thermal loads plays an essential role in analyzing energy-efficient buildings’ energy performance. On the other hand, stochastic algorithms have recently shown high proficiency in dealing with this issue. These are the reasons that this study is dedicated to evaluating an innovative hybrid method for predicting the cooling load (CL) in buildings with residential usage. The proposed model is a combination of artificial neural networks and stochastic fractal search (SFS–ANNs). Two benchmark algorithms, namely the grasshopper optimization algorithm (GOA) and firefly algorithm (FA) are also considered to be compared with the SFS. The non-linear effect of eight independent factors on the CL is analyzed using each model’s optimal structure. Evaluation of the results outlined that all three metaheuristic algorithms (with more than 90% correlation) can adequately optimize the ANN. In this regard, this tool’s prediction error declined by nearly 23%, 18%, and 36% by applying the GOA, FA, and SFS techniques. Moreover, all used accuracy criteria indicated the superiority of the SFS over the benchmark schemes. Therefore, it is inferred that utilizing the SFS along with ANN provides a reliable hybrid model for the early prediction of CL.
- Duy Tan University Viet Nam
- Bauhaus University, Weimar Germany
- Norwegian University of Life Sciences Norway
- Bauhaus University, Weimar Germany
- Óbuda University Hungary
Technology, T, energy-efficiency, deep learning, HVAC, cooling load, machine learning, big data, energy-efficiency; HVAC; machine learning; cooling load; deep learning; big data; artificial intelligence; nature-inspired metaheuristic; building energy; zero energy; smart city; smart buildings, automotive_engineering
Technology, T, energy-efficiency, deep learning, HVAC, cooling load, machine learning, big data, energy-efficiency; HVAC; machine learning; cooling load; deep learning; big data; artificial intelligence; nature-inspired metaheuristic; building energy; zero energy; smart city; smart buildings, automotive_engineering
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