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Integrating Machine Learning and Genetic Algorithms to Optimize Building Energy and Thermal Efficiency Under Historical and Future Climate Scenarios

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  • Alireza Karimi

    (Instituto Universitario de Arquitectura y Ciencias de la Construcción, Escuela Técnica Superior de Arquitectura, Universidad de Sevilla, 41012 Sevilla, Spain)

  • Mostafa Mohajerani

    (Architecture and Energy, Faculty of Architectural Engineering and Urbanism, Shahrood University of Technology, Shahrood 3619995161, Iran)

  • Niloufar Alinasab

    (Department of Atmospheric and Geospatial Data Sciences, University of Szeged, Egyetem U. 2, 6722 Szeged, Hungary)

  • Fateme Akhlaghinezhad

    (Faculty of Architecture and Urban Planning, Shahid Beheshti University, Tehran 1983969411, Iran)

Abstract

As the global energy demand rises and climate change creates more challenges, optimizing the performance of non-residential buildings becomes essential. Traditional simulation-based optimization methods often fall short due to computational inefficiency and their time-consuming nature, limiting their practical application. This study introduces a new optimization framework that integrates Bayesian optimization, XGBoost algorithms, and multi-objective genetic algorithms (GA) to enhance building performance metrics—total energy (TE), indoor overheating degree (IOD), and predicted percentage dissatisfied (PPD)—for historical (2020), mid-future (2050), and future (2080) scenarios. The framework employs IOD as a key performance indicator (KPI) to optimize building design and operation. While traditional indices such as the predicted mean vote (PMV) and the thermal sensation vote (TSV) are widely used, they often fail to capture individual comfort variations and the dynamic nature of thermal conditions. IOD addresses these gaps by providing a comprehensive and objective measure of thermal discomfort, quantifying both the frequency and severity of overheating events. Alongside IOD, the energy use intensity (EUI) index is used to assess energy consumption per unit area, providing critical insights into energy efficiency. The integration of IOD with EUI and PPD enhances the overall assessment of building performance, creating a more precise and holistic framework. This combination ensures that energy efficiency, thermal comfort, and occupant well-being are optimized in tandem. By addressing a significant gap in existing methodologies, the current approach combines advanced optimization techniques with modern simulation tools such as EnergyPlus, resulting in a more efficient and accurate model to optimize building performance. This framework reduces computational time and enhances practical application. Utilizing SHAP (SHapley Additive Explanations) analysis, this research identified key design factors that influence performance metrics. Specifically, the window-to-wall ratio (WWR) impacts TE by increasing energy consumption through higher heat gain and cooling demand. Outdoor temperature (Tout) has a complex effect on TE depending on seasonal conditions, while indoor temperature (Tin) has a minor impact on TE. For PPD, Tout is a major negative factor, indicating that improved natural ventilation can reduce thermal discomfort, whereas higher Tin and larger open areas exacerbate it. Regarding IOD, both WWR and Tin significantly affect internal heat gains, with larger windows and higher indoor temperatures contributing to increased heat and reduced thermal comfort. Tout also has a positive impact on IOD, with its effect varying over time. This study demonstrates that as climate conditions evolve, the effects of WWR and open areas on TE become more pronounced, highlighting the need for effective management of building envelopes and HVAC systems.

Suggested Citation

  • Alireza Karimi & Mostafa Mohajerani & Niloufar Alinasab & Fateme Akhlaghinezhad, 2024. "Integrating Machine Learning and Genetic Algorithms to Optimize Building Energy and Thermal Efficiency Under Historical and Future Climate Scenarios," Sustainability, MDPI, vol. 16(21), pages 1-30, October.
    • Handle: RePEc:gam:jsusta:v:16:y:2024:i:21:p:9324-:d:1507620
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    References listed on IDEAS

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    1. Dawei Xia & Weien Xie & Jialiang Guo & Yukai Zou & Zhuotong Wu & Yini Fan, 2023. "Building Thermal and Energy Performance of Subtropical Terraced Houses under Future Climate Uncertainty," Sustainability, MDPI, vol. 15(16), pages 1-22, August.
    2. Gholamibozanjani, Gohar & Tarragona, Joan & Gracia, Alvaro de & Fernández, Cèsar & Cabeza, Luisa F. & Farid, Mohammed M., 2018. "Model predictive control strategy applied to different types of building for space heating," Applied Energy, Elsevier, vol. 231(C), pages 959-971.
    3. Moazami, Amin & Nik, Vahid M. & Carlucci, Salvatore & Geving, Stig, 2019. "Impacts of future weather data typology on building energy performance – Investigating long-term patterns of climate change and extreme weather conditions," Applied Energy, Elsevier, vol. 238(C), pages 696-720.
    4. A. T. D. Perera & Kavan Javanroodi & Dasaraden Mauree & Vahid M. Nik & Pietro Florio & Tianzhen Hong & Deliang Chen, 2023. "Challenges resulting from urban density and climate change for the EU energy transition," Nature Energy, Nature, vol. 8(4), pages 397-412, April.
    5. Nguyen, Anh-Tuan & Reiter, Sigrid & Rigo, Philippe, 2014. "A review on simulation-based optimization methods applied to building performance analysis," Applied Energy, Elsevier, vol. 113(C), pages 1043-1058.
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    1. Aylin Erdoğdu & Faruk Dayi & Ahmet Yanik & Ferah Yildiz & Farshad Ganji, 2025. "Innovative Solutions for Combating Climate Change: Advancing Sustainable Energy and Consumption Practices for a Greener Future," Sustainability, MDPI, vol. 17(6), pages 1-39, March.
    2. Farshid Dehghan & César Porras Amores, 2025. "Simulation-Based Multi-Objective Optimization for Building Retrofits in Iran: Addressing Energy Consumption, Emissions, Comfort, and Indoor Air Quality Considering Climate Change," Sustainability, MDPI, vol. 17(5), pages 1-51, February.

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