In recent times data-driven approaches to parametrically optimize and explore
building geometry has been proven to be a powerful tool that can replace computationally expensive and time-consuming simulations for energy prediction in the early
design process. In this research, we explore the use of surrogate models, i.e. efficient
statistical approximations of expensive physics-based building simulation models, to
lower the computational burden of large-scale building geometry analysis. We try
different approaches and techniques to train a machine learning model using multiple
datasets to analyze the impact of geometry and envelope features on the energy efficiency of buildings. These contributions are presented in the form of two conference
papers and one journal paper (being prepared for submission) that iteratively build
up the underlying methodology.
The first conference paper contains preliminary experiments using 4 manually
generated building geometries for office buildings. Data were generated by simulating various building samples in EnergyPlus for different geometries. We used the
generated data to train a machine learning model using support vector regression.
We trained two separate models for predicting heating and cooling loads. The lesson
learned from this first experiment was that the prediction of the models was not great
due to insufficient geometric features explaining the variability in geometry and the
lack of sufficient data for varied geometries.
The second conference paper developed a novel dataset of 38,000 building energy
models for varied geometry using 2D images of real-world residences. We developed
a workflow in the Grasshopper/Rhino environment which can convert 2D images of
a floor plan into a vector format then into a building energy model ready to be simulated in EnergyPlus. The workflow can also extract up to 20 geometric features from
the model, to be used as features in the machine learning process. We used these
features and the simulation results to train a neural network-based surrogate model.
A sensitivity analysis was performed to understand the impact and importance of
each feature to the energy use of the building. From the results of the experiment,
we found that off-the-shelf neural network-based surrogates provided with engineered
features can very well emulate the desired simulation outputs. We also repeated
the experiment for 6 different climatic zones across Canada to understand the impact of geometric features across various climates; these findings are presented in an
appendix.
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In the journal paper, we explored two different methodologies to train surrogate
models: monolithic and component-based. We explored the component-based modeling technique as it allows the model to be more versatile if we need to add more
components to it, ultimately increasing the usability of the model. We conducted
further experiments by adding complexity to the geometry surrogate model. We introduced 10 envelope features as an input to the surrogate along with the 20 geometric
features. We trained 6 different surrogate models using different datasets by varying
geometric and envelope features. From the results of the experiment, we found that
the monolithic model performs the best but the component-based surrogate also falls
into an acceptable range of accuracy.
From the overall results across the three papers, we see that simple neural network-based surrogate models perform really well to emulate simulation outcomes over a
wide variety of geometries and envelope features / Graduate
| Identifer | oai:union.ndltd.org:uvic.ca/oai:dspace.library.uvic.ca:1828/13636 |
| Date | 22 December 2021 |
| Creators | Bhatta, Bhumika |
| Contributors | Evins, Ralph |
| Source Sets | University of Victoria |
| Language | English, English |
| Detected Language | English |
| Type | Thesis |
| Format | application/pdf |
| Rights | Available to the World Wide Web |
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