Development of a simulation-based ANN framework for predicting energy consumption metrics: a case study of an office building

IF 3.2 4区工程技术 Q3 ENERGY & FUELS

Energy Efficiency Pub Date : 2024-01-17 DOI:10.1007/s12053-024-10185-1

S. Haghighat Roodkoly, Z. Qavidel Fard, M. Tahsildoost, Z. Zomorodian, M. Karami

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Abstract

Building energy performance assessments are essential in High-Performance Building Design (HPBD) in order to reduce energy consumption and carbon emissions. With advancement in data analytics, rapid and accurate machine learning-based building energy consumption prediction models have emerged. These models can be used by non-professionals as an alternative to time-consuming energy simulation software, offering benefits in HPBD. Therefore, the main objective of the present study is to develop a prediction model using data generated by physics-based simulations of a typical open-plan office space. The model predicts annual energy consumption, CO₂ emissions, and percentage of comfort hours during the design phase. Various configurations of Artificial Neural Network (ANN), Support Vector Machine (SVM), Random Forrest (RF), and K-Nearest Neighbors (KNN) algorithms were trained and tested with the generated data via the DesignBuilder software. The technical parameters considered as inputs include U-values of envelope constructions, Window to Wall Ratio (WWR), orientation, and Heating, Ventilation, and Air-Conditioning (HVAC) systems. The results indicate that there is no clear linear relationship between individual inputs and the target indicators. However, ANN, with its ability to handle non-linear relationships, performed the best, achieving a maximum Coefficient of Determination (R²) value of 0.997 for predicting percentage of comfort hours and outperforms the other algorithms. Furthermore, the results show that RF is the next best algorithm, with 0.96 ≤ R²_Test ≤ 0.98 for predicting the various target variables. SVM with Radial Basis Function (SVM-RBF) follows, with 0.89 ≤ R²_Test ≤ 0.95. Contrary to ANN, SVM, and RF algorithms with high abilities to learn complex pattern between various independent parameters and the target variable, KNN exhibits the poorest performance, with 0.88 ≤ R²_Test ≤ 0.91. Additionally, it is observed that with a maximum time cost of 619 s, ANN with three layers is able to learn the relationships between the inputs and target indicators at a convenient speed. Since knowledge-based decision making in the early design stages is crucial for achieving the optimum solutions to reduce energy consumption and related CO₂ emissions while ensuring occupants’ comfort and minimizing future modifications and costs, high-speed and accurate prediction methods for design stage evaluation are essential.

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开发基于仿真的 ANN 框架以预测能耗指标：办公楼案例研究

为了降低能耗和碳排放，建筑能效评估在高性能建筑设计（HPBD）中至关重要。随着数据分析技术的发展，基于机器学习的快速、准确的建筑能耗预测模型应运而生。这些模型可供非专业人员使用，替代耗时的能源模拟软件，为 HPBD 带来益处。因此，本研究的主要目的是利用典型开放式办公空间的物理模拟生成的数据开发一个预测模型。该模型可预测设计阶段的年能耗、二氧化碳排放量和舒适时间百分比。人工神经网络 (ANN)、支持向量机 (SVM)、随机福斯特 (RF) 和 K-Nearest Neighbors (KNN) 算法的各种配置通过 DesignBuilder 软件对生成的数据进行了训练和测试。作为输入的技术参数包括围护结构的 U 值、窗墙比 (WWR)、朝向以及供暖、通风和空调系统 (HVAC)。结果表明，单个输入与目标指标之间没有明显的线性关系。然而，具有处理非线性关系能力的 ANN 表现最佳，在预测舒适时间百分比方面的最大决定系数 (R2) 值为 0.997，优于其他算法。此外，结果表明，RF 是次好的算法，在预测各种目标变量时，RF 值为 0.96 ≤ R2Test ≤ 0.98。具有径向基函数的 SVM（SVM-RBF）紧随其后，其预测结果为 0.89 ≤ R2Test ≤ 0.95。与 ANN、SVM 和 RF 算法学习各种独立参数和目标变量之间复杂模式的能力较强相反，KNN 的性能最差，为 0.88 ≤ R2Test ≤ 0.91。此外，我们还观察到，三层 ANN 的最大时间成本为 619 s，能够以较快的速度学习输入与目标指标之间的关系。由于在早期设计阶段基于知识的决策对于实现最佳解决方案以减少能源消耗和相关的二氧化碳排放，同时确保居住者的舒适度并最大限度地减少未来的修改和成本至关重要，因此设计阶段评估的高速准确预测方法至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Energy Efficiency ENERGY & FUELS-ENERGY & FUELS

CiteScore

5.80

自引率

6.50%

发文量

审稿时长

>12 weeks

期刊介绍： The journal Energy Efficiency covers wide-ranging aspects of energy efficiency in the residential, tertiary, industrial and transport sectors. Coverage includes a number of different topics and disciplines including energy efficiency policies at local, regional, national and international levels; long term impact of energy efficiency; technologies to improve energy efficiency; consumer behavior and the dynamics of consumption; socio-economic impacts of energy efficiency measures; energy efficiency as a virtual utility; transportation issues; building issues; energy management systems and energy services; energy planning and risk assessment; energy efficiency in developing countries and economies in transition; non-energy benefits of energy efficiency and opportunities for policy integration; energy education and training, and emerging technologies. See Aims and Scope for more details.