Abstract
Modelling the heating load (HL) and cooling load (CL) is the cornerstone of the designing of energy-efficient buildings, since it determines the heating and cooling equipment requirements needed to retain comfortable indoor air conditions. Advanced and specialised modelling tools for energy-efficient buildings may provide a reliable estimation of the effect of alternative building designs. However, implementing these tools can be a labour-intensive task, very time-consuming and dependent on user experiences. Hence, in this study, four advanced computational frameworks including relevance vector machine (RVM), group method of data handling (GMDH), hybridization of adaptive neuro-fuzzy interface system (ANFIS) and biogeography-based optimisation (BBO), i.e. ANFIS-BBO, and hybridization of ANFIS and improved particle swarm optimisation (IPSO), i.e. ANFIS-IPSO, are proposed as novel approaches to predict the heating load (HL) and cooling load (CL) of residential buildings. Obtained results from the proposed models are compared using several performance parameters. In addition, several visualisation methods including Taylor diagram, regression characteristic curve, a novel method called accuracy matrix and rank analysis are used to demonstrate the model with the best performance. Furthermore, Anderson–Darling’ Normality (A-D) test and Mann–Whitney U’ (M − W) tests are studied as non-parametric statistical test for further investigations of the models. Obtained results indicate the excellent ability of the applied models to map the non-linear relationships between the input and output variables. Result also identified RVM as the best predictive model among four proposed models. Finally, two equations are derived from the RVM model to address the HL and CL of residential buildings.
Published Version
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