Evaluation of supervised machine learning regression models for CFD-based surrogate modelling in indoor airflow field reconstruction

Xueren Li, Weijie Sun, Chao Qin, Yihuan Yan, Liwei Zhang, Jiyuan Tu*

*Corresponding author for this work

Research output: Contribution to journalJournal articlepeer-review

Abstract

Fast and reliable prediction of indoor airflow distribution is critical for indoor environment control. While neural networks (NN), often interchangeably referred to as Back Propagation Neural Networks (BPNNs), are popular for airflow predictions, optimising these models is challenging due to their ”black box” nature and complex network structures. This study explores alternative robust regression models, including decision-tree-based models (e.g., XGBoost, LightGBM, Random Forest) and Support Vector Regression (SVR), for predicting indoor airflow. Two BPNN structures were initially developed to evaluate feasibility of NN models. BPNN A was trained using airflow velocities from two inlets as input neurons to directly predict the airflow velocity distribution within the domain. BPNN B was trained additionally with spatial information, including space samples and boundary wall data. Higher-dimensional training structures of BPNN B were applied to decision tree-based models and SVR to assess their capability in predicting non-linear airflow patterns. Results indicated that BPNN A achieved the highest accuracy, while the inclusion of higher-dimensional data in BPNN B led to decreased accuracy. Among all decision-tree-based models, XGBoost demonstrated the greatest potential, achieving an R2 above 99.5% and predictive errors below 10%. XGBoost also outperformed both BPNN models in speed, being 15.78 times faster than BPNN A and 252 times faster than BPNN B. The interpretability of XGBoost was further explored by analysing feature importance, which helps identify the most influential input variables while predicting the airflow velocity. This analysis is expected to offer an enhanced understanding of boundary conditions leading to optimised indoor environment strategy.

Original languageEnglish
Article number112173
Number of pages16
JournalBuilding and Environment
Volume267, Part B
DOIs
Publication statusPublished - 1 Jan 2025

Scopus Subject Areas

  • Environmental Engineering
  • Civil and Structural Engineering
  • Geography, Planning and Development
  • Building and Construction

User-Defined Keywords

  • Back propagation neural network (BPNN)
  • CFD
  • Decision tree-based model
  • eXtreme gradient boosting (XGB)
  • Indoor airflow
  • Support vector regression (SVR)

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