Abstract
This paper proposes a Machine-learning-based methodology for the real-time prediction of Daylight Factor (DF)
during the conceptual design phase of architecture. The predictions allow the designer to quickly assess DF
regulatory compliance and support decision-making at early design stages. To achieve this goal, a digital surrogate dataset is generated from a real-life design scenario. Image-based and numerical-based modelling approaches are developed, deployed, evaluated, and reported in this paper, supported by different encodings
derived from the dataset. The first method uses point-by-point DF prediction through numerical geometrical and
performance data encoding. It trains numerical regression models, namely an Artificial Neural Network and
XGBoost model. The second approach uses image-based encoding. The dataset is translated into false colour
images of the DF values per room floor plan with a 128 × 128 resolution and is used to train a Pix2Pix model. The
paper compares the two modelling approaches and evaluates their advantages and disadvantages, demonstrated
through the early-stage design use case. Results have shown that both approaches can accurately interpret DF
prediction quantitatively with sufficient accuracy; however, the qualitative implications of the two modelling
approaches are discussed.
during the conceptual design phase of architecture. The predictions allow the designer to quickly assess DF
regulatory compliance and support decision-making at early design stages. To achieve this goal, a digital surrogate dataset is generated from a real-life design scenario. Image-based and numerical-based modelling approaches are developed, deployed, evaluated, and reported in this paper, supported by different encodings
derived from the dataset. The first method uses point-by-point DF prediction through numerical geometrical and
performance data encoding. It trains numerical regression models, namely an Artificial Neural Network and
XGBoost model. The second approach uses image-based encoding. The dataset is translated into false colour
images of the DF values per room floor plan with a 128 × 128 resolution and is used to train a Pix2Pix model. The
paper compares the two modelling approaches and evaluates their advantages and disadvantages, demonstrated
through the early-stage design use case. Results have shown that both approaches can accurately interpret DF
prediction quantitatively with sufficient accuracy; however, the qualitative implications of the two modelling
approaches are discussed.
| Originalsprog | Engelsk |
|---|---|
| Tidsskrift | Building and Environment |
| Vol/bind | 274 |
| Antal sider | 17 |
| ISSN | 0360-1323 |
| DOI | |
| Status | Udgivet - apr. 2025 |
Kunstnerisk udviklingsvirksomhed (KUV)
- Nej