环境监测传感器位置时空多变量优化的机器学习方法

Masudur R. Siddiquee, Aurelien O Meray, Zexuan Xu, Hansell Gonzalez-Raymat, Thomas Danielson, Himanshu Upadhyay, Leonel E. Lagos, Carol Eddy-Dilek, Haruko Wainwright
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摘要

长期环境监测对于管理污染场地的土壤和地下水至关重要。最近,最先进的传感器技术、通信网络和人工智能的改进为实现自动化、快速、稳健和预测性监测的现代化监测活动创造了机会。在这种现代化过程中,需要对传感器位置进行优化,以捕捉所有监测变量的时空动态,并使其具有成本效益。目标区域的传统监测数据集对进行这种优化非常重要。在本研究中,我们开发了一种基于集合监督学习和多数投票的机器学习方法,用于优化土壤和地下水监测的传感器位置。在空间优化方面,使用高斯过程回归(GPR)进行空间插值,而多数表决则用于适应多元时间维度。结果表明,这些算法在预测时空插值方面明显优于随机选择传感器位置。虽然该方法已应用于一个四维数据集(包含二维空间、时间和多种污染物),但我们预计它可以推广到更高维度的数据集,用于环境监测传感器位置优化。
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Machine Learning Approach for Spatiotemporal Multivariate Optimization of Environmental Monitoring Sensor Locations
Long-term environmental monitoring is critical for managing the soil and groundwater at contaminated sites. Recent improvementsin state-of-the-art sensor technology, communication networks, and artificial intelligence have created opportunities to modernize this monitoring activity for automated, fast, robust, and predictive monitoring. In such modernization, it is required that sensor locations be optimized to capture the spatiotemporal dynamics of all monitoring variables as well as to make it cost-effective. The legacy monitoring datasets of the target area are important to perform this optimization. In this study, we have developed a machine-learning approach to optimize sensor locations for soil and groundwater monitoring based on ensemble supervised learning and majority voting. For spatial optimization, Gaussian Process Regression (GPR) is used for spatial interpolation, while the majority voting is applied to accommodate the multivariate temporal dimension. Results show that the algorithms significantly outperform the random selection of the sensor locations for predictive spatiotemporal interpolation. While the method has been applied to a four-dimensional dataset (with two-dimensional space, time and multiple contaminants), we anticipate that it can be generalizable to higher dimensional datasets for environmental monitoring sensor location optimization.
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