A Study on Hyperspectral Soil Moisture Content Prediction by Incorporating a Hybrid Neural Network into Stacking Ensemble Learning

Agronomy Pub Date : 2024-09-08 DOI:10.3390/agronomy14092054
Yuzhu Yang, Hongda Li, Miao Sun, Xingyu Liu, Liying Cao
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Abstract

The accurate prediction of soil moisture content helps to evaluate the quality of farmland. Taking the black soil in the Nanguan District of Changchun City as the research object, this paper proposes a stacking ensemble learning model integrating hybrid neural networks to address the issue that it is difficult to improve the accuracy of inversion soil moisture content by a single model. First, raw hyperspectral data are processed by removing edge noise and standardization. Then, the gray wolf optimization (GWO) algorithm is adopted to optimize a convolutional neural network (CNN), and a gated recurrent unit (GRU) and an attention mechanism are added to construct a hybrid neural network model (GWO–CNN–GRU–Attention). To estimate soil water content, the hybrid neural network model is integrated into the stacking model along with Bagging and Boosting algorithms and the feedforward neural network. Experimental results demonstrate that the GWO–CNN–GRU–Attention model proposed in this paper can better predict soil water content; the stacking method of integrating hybrid neural networks overcomes the limitations of a single model’s instability and inferior accuracy. The relative prediction deviation (RPD), root mean square error (RMSE), and coefficient of determination (R2) on the test set are 4.577, 0.227, and 0.952, respectively. The average R2 and RPD increased by 0.056 and 1.418 in comparison to the base learner algorithm. The study results lay a foundation for the fast detection of soil moisture content in black soil areas and provide a data source for intelligent irrigation in agriculture.
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将混合神经网络纳入堆叠集合学习的高光谱土壤含水量预测研究
准确预测土壤含水量有助于评价耕地质量。本文以长春市南关区的黑土地为研究对象,针对单一模型难以提高反演土壤含水量精度的问题,提出了混合神经网络的叠加集合学习模型。首先,通过去除边缘噪声和标准化处理原始高光谱数据。然后,采用灰狼优化(GWO)算法优化卷积神经网络(CNN),并加入门控递归单元(GRU)和注意机制,构建混合神经网络模型(GWO-CNN-GRU-Attention)。为了估算土壤含水量,混合神经网络模型与 Bagging 算法、Boosting 算法和前馈神经网络一起被集成到堆叠模型中。实验结果表明,本文提出的 GWO-CNN-GRU-Attention 模型能更好地预测土壤含水量;集成混合神经网络的堆叠方法克服了单一模型不稳定和精度低的局限性。测试集的相对预测偏差(RPD)、均方根误差(RMSE)和判定系数(R2)分别为 4.577、0.227 和 0.952。与基础学习算法相比,平均 R2 和 RPD 分别增加了 0.056 和 1.418。研究结果为快速检测黑土区土壤含水量奠定了基础,并为农业智能灌溉提供了数据源。
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