Generalized building energy and carbon emissions benchmarking with post-prediction analysis

Generalized building energy and carbon emissions benchmarking with post-prediction analysis

This study proposes a generalized building energy and carbon emissions benchmarking approach. Leveraging eleven years of real-world data from twelve U.S. cities, an advanced ensemble learning model is employed to predict building site, source energy, and carbon emissions. The generalizability is val...

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Bibliographic Details
Published in:Developments in the built environment Vol. 17; p. 100320
Main Authors: Li, Tian, Liu, Tianqi, Sawyer, Azadeh Omidfar, Tang, Pingbo, Loftness, Vivian, Lu, Yi, Xie, Jiarong
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-03-2024
Elsevier
Subjects:
Big data
Carbon emissions
Data-driven
Generalized energy benchmarking
Machine learning
Post-prediction analysis
Post-prediction analysis
Big data
Data-driven
Generalized energy benchmarking
Carbon emissions
Machine learning
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Summary:This study proposes a generalized building energy and carbon emissions benchmarking approach. Leveraging eleven years of real-world data from twelve U.S. cities, an advanced ensemble learning model is employed to predict building site, source energy, and carbon emissions. The generalizability is validated across seven climate zones, yielding R2 values ranging from 0.3 to 0.9. Additionally, a post-prediction analysis method is proposed that categorizes actual and predicted values into well-estimated, underestimated, and overestimated groups by an [−15%, 15%] acceptance interval (AI). This approach allows for assessing predictions related to energy, building types, and climate zones. The findings indicate the feasibility of a reliable generalized benchmarking tool. It’s been observed that energy in most underestimated groups tends to be higher than that of their overestimated counterparts. Over 63% of buildings' predictions perform within the well-estimated group by [−15%, 15%] AI. •Propose a generalized building energy and carbon emissions benchmarking tool.•Develop a post-prediction analysis approach by classifying the prediction results.•Achieve solid predictions from 0.3 to 0.9 of R2 for all seven climate zones.•Building type, area, and energy pattern are the top attributes impacting energy use.•Model performance varies by building types and climate zones significantly.
ISSN:2666-1659
2666-1659
DOI:10.1016/j.dibe.2024.100320