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网格搜索以寻找预测设施栽培系统中最佳传感器位置时的最低均方根误差

Grid Search for Lowest Root Mean Squared Error in Predicting Optimal Sensor Location in Protected Cultivation Systems.

作者信息

Uyeh Daniel Dooyum, Iyiola Olayinka, Mallipeddi Rammohan, Asem-Hiablie Senorpe, Amaizu Maryleen, Ha Yushin, Park Tusan

机构信息

Department of Bio-Industrial Machinery Engineering, Kyungpook National University, Daegu, South Korea.

Upland-Field Machinery Research Center, Kyungpook National University, Daegu, South Korea.

出版信息

Front Plant Sci. 2022 Jul 7;13:920284. doi: 10.3389/fpls.2022.920284. eCollection 2022.

DOI:10.3389/fpls.2022.920284
PMID:35873973
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9301965/
Abstract

Irregular changes in the internal climates of protected cultivation systems can prevent attainment of optimal yield when the environmental conditions are not adequately monitored and controlled. Key to indoor environment monitoring and control and potentially reducing operational costs are the strategic placement of an optimal number of sensors using a robust method. A multi-objective approach based on supervised machine learning was used to determine the optimal number of sensors and installation positions in a protected cultivation system. Specifically, a gradient boosting algorithm, a form of a tree-based model, was fitted to measured (temperature and humidity) and derived conditions (dew point temperature, humidity ratio, enthalpy, and specific volume). Feature variables were forecasted in a time-series manner. Training and validation data were categorized without randomizing the observations to ensure the features remained time-dependent. Evaluations of the variations in the number and location of sensors by day, week, and month were done to observe the impact of environmental fluctuations on the optimal number and location of placement of sensors. Results showed that less than 32% of the 56 sensors considered in this study were needed to optimally monitor the protected cultivation system's internal environment with the highest occurring in May. In May, an average change of -0.041% in consecutive RMSE values ranged from the 1st sensor location (0.027°C) to the 17th sensor location (0.013°C). The derived properties better described the ambient condition of the indoor air than the directly measured, leading to a better performing machine learning model. A machine learning model was developed and proposed to determine the optimal sensors number and positions in a protected cultivation system.

摘要

当环境条件未得到充分监测和控制时,设施栽培系统内部气候的不规则变化可能会妨碍实现最佳产量。使用可靠方法战略性地布置最佳数量的传感器是室内环境监测与控制以及潜在降低运营成本的关键。一种基于监督式机器学习的多目标方法被用于确定设施栽培系统中传感器的最佳数量和安装位置。具体而言,一种基于树模型的梯度提升算法被拟合到测量的(温度和湿度)以及推导的条件(露点温度、湿度比、焓和比容)上。特征变量以时间序列方式进行预测。训练和验证数据在不随机化观测值的情况下进行分类,以确保特征保持时间依赖性。对按天、周和月划分的传感器数量和位置变化进行评估,以观察环境波动对传感器最佳数量和布置位置的影响。结果表明,本研究中考虑的56个传感器中,不到32%的传感器是最佳监测设施栽培系统内部环境所必需的,其中五月所需传感器数量最多。在五月,从第1个传感器位置(0.027°C)到第17个传感器位置(0.013°C),连续均方根误差值的平均变化为-0.041%。推导得出的属性比直接测量的更能描述室内空气的环境状况,从而产生性能更好的机器学习模型。开发并提出了一种机器学习模型,用于确定设施栽培系统中传感器的最佳数量和位置。

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