Abstract
To achieve ambitious climate goals, it is necessary to increase the rate of purposeful retrofit measures in the building sector. As a result, Energy Performance Certificates have been designed as important evaluation and rating criterion to increase the retrofit rate in the EU and Germany. Yet, today’s most frequently used and legally required methods to quantify building energy performance show low prediction accuracy, as recent research reveals. To enhance prediction accuracy, the research community introduced data-driven methods which obtained promising results. However, there are no insights in how far Energy Quantification Methods are particularly suited for energy performance prediction. In this research article the data-driven methods Artificial Neural Network, D-vine copula quantile regression, Extreme Gradient Boosting, Random Forest, and Support Vector Regression are compared with and validated by real-world Energy Performance Certificates of German residential buildings issued by qualified auditors using the engineering method required by law. The results, tested for robustness and systematic bias, show that all data-driven methods exceed the engineering method by almost 50% in terms of prediction accuracy. In contrast to existing literature favoring Artificial Neural Networks and Support Vector Regression, all tested methods show similar prediction accuracy with marginal advantages for Extreme Gradient Boosting and Support Vector Regression in terms of prediction accuracy. Given the higher prediction accuracy of data-driven methods, it seems appropriate to revise the current legislation prescribing engineering methods. In addition, data-driven methods could support different organizations, e.g., asset management, in decision-making in order to reduce financial risk and to cut expenses.
Highlights
Human-made climate change is in full swing and revealing first negative effects (Larsen et al 2020)
Even though the applied solutions and the respective problem in this research are technically known, we argue that we contribute an improvement to existing solutions in terms of Gregor and Hevner (2013) for the following reasons: (1) We are among the first to compare existing solutions in terms of solution maturity within a new application domain of the annual Final Energy Performance (FEP) prediction for residential buildings, filling the research gap of missing data at the residential building level and the application of data-driven Energy Quantification Methods (EQM). (2) Because data-driven EQMs must be designed for specific applications to unleash their full potential (Mosavi et al 2019), existing knowledge about the performance of data-driven EQMs on non-residential buildings cannot be transferred to the residential building stock directly
The only notable difference occurs for the Mean Absolute Percentage Error (MAPE), where the Artificial Neural Network (ANN) shows the highest prediction accuracy, reducing error by more than 50% compared to the engineering EQM
Summary
Human-made climate change is in full swing and revealing first negative effects (Larsen et al 2020). The United Nations’ Paris Agreement declared ambitious climate goals and aims to decrease energy end-use below 1990 levels by 2030 (Boden et al 2017). Current efforts are not sufficient to achieve the intended goals and additional steps are necessary (European Environment Agency 2019). One of the largest single energy consuming sectors in Germany are residential single- and two-family buildings, accounting for 11% of the overall final energy consumption, 84% of which relates to heating and hot. Wiethe: Benchmarking Energy Quantification Methods to..., Bus Inf Syst Eng 63(3):223242 (2021)
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