Hybrid deep learning and remote sensing for the delineation of artificial groundwater recharge zones

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Rami Al-Ruzouq , Abdallah Shanableh , Ratiranjan Jena , Sunanda Mukherjee , Mohamad Ali Khalil , Mohamed Barakat A. Gibril , Biswajeet Pradhan , Nezar Atalla Hammouri
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Abstract

The increase in water demand and the scarcity of fresh water in arid regions have contributed to the depletion of groundwater. Artificial Groundwater Recharge (AGR) is an advanced strategy that contributes to combating water shortage issues. Limited efforts have been exerted to evaluate and demarcate AGR potential zones in the United Arab Emirates (UAE). The current study aims to delineate AGR potential zone mapping using the traditional analytical hierarchy process (AHP) and a hybrid deep learning model namely, Convolutional Neural Network-Xtreme Gradient Boosting (CNN-XGB) was used for the optimal prediction-based suitability assessment. A total of nine hydrogeological factors were considered for AGR mapping. First, the influence of each parameter was determined based on expert opinion and literature reviews for the AHP approach (0.007 consistency ratio). Second, a hybrid CNN-XGB model (90.8 % accuracy) predicted the AGR and non-AGR classes as part of binary classification and generated an AGR potential zone map. Moreover, the contributing factors were analyzed deeply for the AGR site selection to understand the intercorrelation, importance, and prediction interaction. Using both approaches, a comparative assessment was conducted in the eastern, central, and western parts of Sharjah. The AGR zone based on the CNN-XGB model achieved a precision of (0.8168), recall (0.7873), and F1-score (0.8018). The critical contributing factors for AGR mapping were found to be geology (20%), geomorphology (15%), rainfall (10%), and groundwater level (10%). The AGR map is expected to help explore new sites with potentially higher favourability to retain water, deal with water scarcity, and improve water management in the UAE.

混合深度学习和遥感技术用于人工地下水补给区划定
水资源需求的增加和干旱地区淡水的稀缺导致了地下水的枯竭。人工地下水回灌(AGR)是一种有助于解决水资源短缺问题的先进战略。阿拉伯联合酋长国(UAE)在评估和划分 AGR 潜力区方面所做的努力有限。目前的研究旨在利用传统的分析层次法(AHP)和混合深度学习模型(即卷积神经网络-极梯度提升(CNN-XGB))来划分 AGR 潜在区域图,以进行基于预测的最佳适宜性评估。绘制 AGR 图共考虑了九个水文地质因素。首先,根据专家意见和 AHP 方法的文献综述确定了每个参数的影响程度(一致性比为 0.007)。其次,混合 CNN-XGB 模型(准确率为 90.8%)预测了二元分类中的 AGR 和非 AGR 类别,并生成了 AGR 潜在区域图。此外,还对 AGR 选址的促成因素进行了深入分析,以了解其相互关系、重要性和预测交互作用。利用这两种方法,对沙迦东部、中部和西部地区进行了比较评估。基于 CNN-XGB 模型的 AGR 区域精确度为 0.8168,召回率为 0.7873,F1 分数为 0.8018。绘制 AGR 地图的关键因素包括地质(20%)、地貌(15%)、降雨(10%)和地下水位(10%)。预计 AGR 地图将有助于在阿联酋探索具有潜在较高保水能力的新地点,解决水资源短缺问题,并改善水资源管理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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