冷水机组模型抗协变量移位的准确性和鲁棒性

F. Acerbi, G. Nicolao, Josef Obiltschnig, Patrick Richter, Cristina De Luca
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引用次数: 1

摘要

多制冷机系统的能量优化管理需要建立制冷机能量效率数学模型。现有的灰盒或黑盒模型包括必须从实验数据估计的参数。迄今为止,已根据实验室测试产生的数据集或冷水机制造商提供的数据集评估和比较了各种备选模型的预测能力。在工业4.0的背景下,持续监测和收集现场数据揭示了新的机会,但也提出了本文要解决的鲁棒性问题。本文利用收集了六个月的大量实验数据集,对四种文献模型和一种新的机器学习方法进行了比较。第二个目标是评估五个模型对协变量移位的稳健性,即输入变量在不同月份发生的统计分布的变化。灰盒Gordon-Ng模型虽然在标称条件下不如双二次多项式和多元多项式模型准确,但证明对协变量移位更健壮。然而,在准确性和鲁棒性方面,两种机器学习方法都提供了最好的性能,其中高斯过程模型的性能优于MLP人工神经网络。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accuracy and Robustness Against Covariate Shift of Water Chiller Models
The optimal energy management of multiple chiller systems calls for the construction of mathematical models of chiller energy efficiency. The existing grey- or black-box models include parameters that have to be estimated from experimental data. So far, the predictive capabilities of alternative models have been assessed and compared on data sets created by laboratory tests or provided by chiller manufacturers. In an Industry 4.0 context, the continuous monitoring and collection of field data discloses new opportunities but raises also robustness issues that are herein addressed. Herein, exploiting an extensive experimental dataset collected over a six-month period, four literature models and a new machine learning approach are compared. The second objective is assessing the robustness of the five models against covariate shifts, i.e. variations in the statistical distribution of the input variables that occur across different months. The grey-box Gordon-Ng model, though less accurate in nominal conditions than the Bi-quadratic and Multivariate polynomial models, proves however more robust against covariate shifts. The best performances, both in term of accuracy and robustness, are however provided by the two machine learning methods, with the Gaussian Process model performing better than the MLP artificial neural network.
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