Investigating Cooling Load Estimation via Hybrid Models Based on the Radial Basis Function

To advance energy conservation in cooling systems within buildings, a pivotal technology known as cooling load prediction is essential. Traditional industry computational models typically employ forward or inverse modeling techniques, but these methods often demand extensive computational resources...

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Bibliographic Details
Published in:International journal of advanced computer science & applications Vol. 15; no. 4
Main Authors: Zhang, Sirui, Zheng, Hao
Format: Journal Article
Language:English
Published: West Yorkshire Science and Information (SAI) Organization Limited 2024
Subjects:
Algorithms
Artificial intelligence
Building materials
Cooling
Cooling loads
Cooling systems
Optimization
Optimization algorithms
Prediction models
Predictions
Radial basis function
Weather
ISSN:2158-107X, 2156-5570
Online Access:Get full text
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Summary:To advance energy conservation in cooling systems within buildings, a pivotal technology known as cooling load prediction is essential. Traditional industry computational models typically employ forward or inverse modeling techniques, but these methods often demand extensive computational resources and involve lengthy procedures. However, artificial intelligence (AI) surpasses these approaches, with its models exhibiting the capability to autonomously discern intricate patterns, adapt dynamically, and enhance their performance as data volumes increase. AI models excel in forecasting cooling loads, accounting for various factors like weather conditions, building materials, and occupancy. This results in agile and responsive predictions, ultimately leading to heightened energy efficiency. The dataset of this study, which comprised 768 samples, was derived from previous studies. The primary objective of this study is to introduce a novel framework for the prediction of Cooling Load via integrating the Radial Basis Function (RBF) with 2 innovative optimization algorithms, specifically the Dynamic Arithmetic Optimization Algorithm (DAO) and the Golden Eagle Optimization Algorithm (GEO). The predictive outcomes indicate that the RBDA prediction model outperforms RBF in cooling load predictions, with RMSE=0.792, approximately half as much as those of RBF. Furthermore, the RBDA model's performance, especially in the training phase, confirmed the optimal value of R2=0.993.
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ISSN:2158-107X
2156-5570
DOI:10.14569/IJACSA.2024.01504102