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Main Authors: Wang, Chunxiao, Duplessis, Bruno, Peirano, Eric, Schetelat, Pascal, Riederer, Peter
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.21407
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author Wang, Chunxiao
Duplessis, Bruno
Peirano, Eric
Schetelat, Pascal
Riederer, Peter
author_facet Wang, Chunxiao
Duplessis, Bruno
Peirano, Eric
Schetelat, Pascal
Riederer, Peter
contents Urban Building Energy Models (UBEM) support urbanscale energy decisions and have recently been applied to use cases requiring dynamic outputs like grid management. However, their predictive capability remains insufficiently addressed, limiting confidence in UBEM application when validation experiments (VE) are unavailable. This study proposes a Gaussian Process (GP)-based method to model the error structure of UBEM, involving: (1) creating a training dataset mapping VE conditions to validation errors, (2) fitting a GP model, and (3) using cross-validation to assess prediction accuracy and uncertainty while extrapolating to unknown scenarios. Applied to the Blagnac (France) district heating network with the UBEM DIMOSIM, GP models effectively capture the inherent structure of UBEM error and uncertainties. Results reveal relationships between model performance and application conditions (e.g., load variation and weather), and show great potential in estimating within-domain model error and extrapolating beyond the validation domain. Key Innovations: $\bullet$ Use GP based approach to quantify the error structure of a UBEM, $\bullet$ Extrapolate the UBEM predictive capability to unvalidated buildings, $\bullet$ Discover different interaction patterns between validation experiment (VE) conditions and UBEM performance. Practical Implications:This paper allows UBEM developpers to have a more comprehensive view of UBEM performance, and helps practionners to prioritise measurement campaigns and to better design further validation experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2504_21407
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Modelling the error structure in Urban Building Energy Models with a Gaussian Processbased approach
Wang, Chunxiao
Duplessis, Bruno
Peirano, Eric
Schetelat, Pascal
Riederer, Peter
Applications
Urban Building Energy Models (UBEM) support urbanscale energy decisions and have recently been applied to use cases requiring dynamic outputs like grid management. However, their predictive capability remains insufficiently addressed, limiting confidence in UBEM application when validation experiments (VE) are unavailable. This study proposes a Gaussian Process (GP)-based method to model the error structure of UBEM, involving: (1) creating a training dataset mapping VE conditions to validation errors, (2) fitting a GP model, and (3) using cross-validation to assess prediction accuracy and uncertainty while extrapolating to unknown scenarios. Applied to the Blagnac (France) district heating network with the UBEM DIMOSIM, GP models effectively capture the inherent structure of UBEM error and uncertainties. Results reveal relationships between model performance and application conditions (e.g., load variation and weather), and show great potential in estimating within-domain model error and extrapolating beyond the validation domain. Key Innovations: $\bullet$ Use GP based approach to quantify the error structure of a UBEM, $\bullet$ Extrapolate the UBEM predictive capability to unvalidated buildings, $\bullet$ Discover different interaction patterns between validation experiment (VE) conditions and UBEM performance. Practical Implications:This paper allows UBEM developpers to have a more comprehensive view of UBEM performance, and helps practionners to prioritise measurement campaigns and to better design further validation experiments.
title Modelling the error structure in Urban Building Energy Models with a Gaussian Processbased approach
topic Applications
url https://arxiv.org/abs/2504.21407