Deep convolutional learning for general early design stage prediction models

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Sundaravelpandian Singaravel
  • Johan Suykens
  • Philipp Florian Geyer

External Research Organisations

  • KU Leuven
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Details

Original languageEnglish
Article number100982
JournalAdvanced engineering informatics
Volume42
Early online date12 Sept 2019
Publication statusPublished - Oct 2019
Externally publishedYes

Abstract

Designers rely on performance predictions to direct the design toward appropriate requirements. Machine learning (ML) models exhibit the potential for rapid and accurate predictions. Developing conventional ML models that can be generalized well in unseen design cases requires an effective feature engineering and selection. Identifying generalizable features calls for good domain knowledge by the ML model developer. Therefore, developing ML models for all design performance parameters with conventional ML will be a time-consuming and expensive process. Automation in terms of feature engineering and selection will accelerate the use of ML models in design. Deep learning models extract features from data, which aid in model generalization. In this study, we (1) evaluate the deep learning model's capability to predict the heating and cooling demand on unseen design cases and (2) obtain an understanding of extracted features. Results indicate that deep learning model generalization is similar to or better than that of a simple neural network with appropriate features. The reason for the satisfactory generalization using the deep learning model is its ability to identify similar design options within the data distribution. The results also indicate that deep learning models can filter out irrelevant features, reducing the need for feature selection.

Keywords

    Convolutional neural network, Energy predictions, Feature learning, Machine learning

ASJC Scopus subject areas

Cite this

Deep convolutional learning for general early design stage prediction models. / Singaravel, Sundaravelpandian; Suykens, Johan; Geyer, Philipp Florian.
In: Advanced engineering informatics, Vol. 42, 100982, 10.2019.

Research output: Contribution to journalArticleResearchpeer review

Singaravel S, Suykens J, Geyer PF. Deep convolutional learning for general early design stage prediction models. Advanced engineering informatics. 2019 Oct;42:100982. Epub 2019 Sept 12. doi: 10.1016/j.aei.2019.100982
Singaravel, Sundaravelpandian ; Suykens, Johan ; Geyer, Philipp Florian. / Deep convolutional learning for general early design stage prediction models. In: Advanced engineering informatics. 2019 ; Vol. 42.
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