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一种利用物联网和人工碳氢网络对封闭建筑内热湿虚拟测量的智能气候监测系统。

An intelligent climate monitoring system for hygrothermal virtual measurement in closed buildings using Internet-of-things and artificial hydrocarbon networks.

作者信息

Ponce Hiram, Gutiérrez Sebastián, Botero-Valencia Juan, Marquez-Viloria David, Castano-Londono Luis

机构信息

Universidad Panamericana, Facultad de Ingeniería, Augusto Rodin 498, Ciudad de México, 03920, Mexico.

TECNUN Escuela de Ingeniería, Universidad de Navarra, Manuel Lardizabal 13, San Sebastián, 20018, Spain.

出版信息

Heliyon. 2024 May 23;10(11):e31716. doi: 10.1016/j.heliyon.2024.e31716. eCollection 2024 Jun 15.

DOI:10.1016/j.heliyon.2024.e31716
PMID:38828295
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11140809/
Abstract

Studies analyzing indoor thermal environments comprising temperature and humidity may be insufficient when obtaining data from sensors, which may be susceptible to inaccurate or failed information from internal and external factors. Therefore, this study proposes an intelligent climate monitoring using a supervised learning method for virtual hygrothermal measurement in enclosed buildings used to predict temperature and relative humidity when a sensor failure is detected. The methodology comprises the data collection from a wireless sensor network, the building of the learning model for predicting the dynamics of environmental variables, and the implementation of a sensor failure detection model. We use an artificial hydrocarbon network as the learning model for their simplicity and effectiveness under uncertain and noisy data. The experiments use data acquired in two settings: (1) a laboratory office and (2) a museum storage room. The first scenario has multiple workstations, and the staff turns on or off the air conditioning depending on the feeling of comfort, generating an uncontrolled environment for the variables of interest. The second scenario has controlled temperature and humidity to ensure the conservation conditions of the museum pieces. Both scenarios used 12 sensors that acquired data for one month, providing an average of 58,300 values for each variable. Results of the proposed methodology provide 95% of accuracy in terms of sensor failure detection and identification, and less than 0.22% of tolerance variability in temperature and humidity after sensor accommodation in both scenarios.

摘要

在从传感器获取数据时,分析包含温度和湿度的室内热环境的研究可能并不充分,因为传感器可能容易受到来自内部和外部因素的不准确或错误信息的影响。因此,本研究提出一种智能气候监测方法,该方法使用监督学习方法在封闭建筑中进行虚拟湿热测量,以便在检测到传感器故障时预测温度和相对湿度。该方法包括从无线传感器网络收集数据、构建用于预测环境变量动态的学习模型以及实施传感器故障检测模型。我们使用人工烃网络作为学习模型,因为它们在不确定和有噪声的数据下简单有效。实验使用在两种环境中获取的数据:(1)实验室办公室和(2)博物馆储藏室。第一种场景有多个工作站,工作人员根据舒适度感觉打开或关闭空调,从而为感兴趣的变量生成一个不受控制的环境。第二种场景具有受控的温度和湿度,以确保博物馆藏品的保存条件。两种场景都使用了12个传感器,这些传感器采集了一个月的数据,每个变量平均提供58300个值。所提出方法的结果在传感器故障检测和识别方面提供了95%的准确率,并且在两种场景中传感器调整后温度和湿度的容差变异性均小于0.22%。

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