Artificial Neural Network (ANN) based Soil Temperature model of Highly Plastic Clay

IF 1.7 Q3 ENGINEERING, GEOLOGICAL
M. S. Khan, J. Ivoke, M. Nobahar, F. Amini
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引用次数: 4

Abstract

ABSTRACT Artificial neural networks (ANNs) are one of the popular methods of artificial intelligence that seek to follow the human mind function and nervous system with its successful application increased in many areas of engineering. The current study is focused to develop an ANN-based predictive model of the soil temperature of Yazoo clay using based on field instrumentation data. To provide an acceptable dataset for developing the predictive model, the investigation was carried out in six instrumented slopes within the 25 miles (40.2 km) radius from metropolitan Jackson in Mississippi. The six selected slopes were instrumented with soil moisture sensors, automated rain gauge, air, and soil temperature sensors starting from mid-August 2018. Volumetric moisture content, precipitation, air, and soil temperature values at 1.5 m (5 ft) depth at the crest of the six slopes were collected using automated data loggers and observed for more than seventeen months. The established database consisting of 13650 datasets was implemented for ANN intelligent system and multiple-degree Fourier series non-linear regression technique for predicting the hourly soil temperature. The total hourly natural rainfall and time, average previous soil temperature, and average hourly air temperature were set to be the inputs of the model and the hourly soil temperature was set to be the output of the model. These datasets were used as the training data and validated with each target slope. Sensitivity analysis was also conducted, and the most influential input parameters on the data output were determined. In this study, the change of soil temperature with atmospheric temperature was investigated, and a predictor model was developed by adopting the Levenberg-Marquardt (LM) algorithm method and the Tan-sigmoid transfer function. The developed ANNs model showed an excellent fit with the observed field values.
基于人工神经网络的高塑性粘土土壤温度模型
摘要人工神经网络(Artificial neural networks, ann)是人工智能的一种流行方法,它试图模仿人类的思维功能和神经系统,在许多工程领域得到了成功的应用。目前的研究重点是基于现场仪器数据,建立基于人工神经网络的亚祖粘土土壤温度预测模型。为了提供一个可接受的数据集来开发预测模型,调查在密西西比州杰克逊市区半径25英里(40.2公里)内的六个仪器斜坡上进行。从2018年8月中旬开始,在六个选定的斜坡上安装了土壤湿度传感器、自动雨量计、空气和土壤温度传感器。使用自动数据记录仪收集了六个斜坡顶部1.5米(5英尺)深度的体积水分含量、降水、空气和土壤温度值,并观察了超过17个月。建立了由13650个数据集组成的数据库,并将其应用于人工神经网络智能系统和多层傅立叶级数非线性回归技术进行逐时土壤温度预测。将小时自然总降雨量和时间、以前平均土壤温度和小时平均气温设置为模型的输入,将小时土壤温度设置为模型的输出。这些数据集被用作训练数据,并对每个目标斜率进行验证。并进行敏感性分析,确定对数据输出影响最大的输入参数。本研究以土壤温度随大气温度的变化为研究对象,采用Levenberg-Marquardt (LM)算法和Tan-sigmoid传递函数建立了预测模型。所建立的人工神经网络模型与实测场值拟合良好。
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来源期刊
CiteScore
3.80
自引率
0.00%
发文量
27
期刊介绍: Geomechanics is concerned with the application of the principle of mechanics to earth-materials (namely geo-material). Geoengineering covers a wide range of engineering disciplines related to geo-materials, such as foundation engineering, slope engineering, tunnelling, rock engineering, engineering geology and geo-environmental engineering. Geomechanics and Geoengineering is a major publication channel for research in the areas of soil and rock mechanics, geotechnical and geological engineering, engineering geology, geo-environmental engineering and all geo-material related engineering and science disciplines. The Journal provides an international forum for the exchange of innovative ideas, especially between researchers in Asia and the rest of the world.
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