用于建筑能源模型校准的新开源贝叶斯推理R平台的开发和性能评估。

Discover mechanical engineering Pub Date : 2023-01-01 Epub Date: 2023-10-31 DOI:10.1007/s44245-023-00027-2
Danlin Hou, Dongxue Zhan, Liangzhu Wang, Ibrahim Galal Hassan, Nurettin Sezer
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引用次数: 0

摘要

许多因素导致了建筑能耗建模的固有不确定性。为了管理这些不确定性,必须进行校准和灵敏度分析。尽管有几种校准方法可用,但它们往往具有确定性,缺乏量化的不确定性。此外,建筑能量建模中用于校准的参数的选择取决于用户的体验。因此,需要一个更加严格的选择过程。本研究开发了一个新的自动化贝叶斯推断校准平台,作为R包运行。灵敏度分析模块和贝叶斯推理模块分别确定校准参数和不确定性。为了节省计算时间,开发了元模型模块来代替马尔可夫链蒙特卡罗过程的建筑能量模型。该平台已在高温干旱气候下的一栋合成高层办公楼和一栋真正的高层住宅楼上成功演示。进一步讨论了校准参数的数量、校准性能和元模型精度之间的关系。本研究中开发的校准平台与现有平台相比具有明显的优势,能够在短的计算时间内合理估计建筑能源性能。
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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Development and performance assessment of a new opensource Bayesian inference R platform for building energy model calibration.

Many factors contribute to the inherent uncertainty of energy consumption modeling in buildings. It is essential to perform a calibration and sensitivity analysis in order to manage these uncertainties. Despite the availability of several calibration methods, they are often deterministic and lack quantified uncertainties. Moreover, the selection of parameters in building energy modeling for calibration depends on the user's experience. Therefore, a more rigorous selection process is required. This study developed a new automated Bayesian Inference calibration platform running as an R package. A sensitivity analysis module and a Bayesian inference module determine the calibration parameters and uncertainties, respectively. The Meta-model module is developed to replace the building energy model for the Markov Chain Monte Carlo process to save computing time. The proposed platform is successfully demonstrated on a synthetic high-rise office building and a real high-rise residential building in a hot and arid climate. The relationship between the number of calibration parameters, calibration performance, and the accuracy of the Meta-model is further discussed. The developed calibration platform in this study proved to have clear advantages over the existing platforms, with the ability to reasonably estimate building energy performance in a short computing time.

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