Automated detection of landslide using synergizing dual Graph Convolutional Networks, googlenet, and machine learning techniques

IF 1.7 4区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Journal of South American Earth Sciences Pub Date : 2025-03-07 DOI:10.1016/j.jsames.2025.105457

Anuradha B , Hadeel Alsolai , Randa Allafi , Munya A. Arasi

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引用次数: 0

Abstract

This study explores a synergistic approach to automated landslide detection in Centro Fluminense, leveraging advanced deep learning and machine learning frameworks. The proposed methodology integrates dual Graph Convolutional Networks (DGCN) with GoogLeNet to analyze topographic and 175 pre-historic landslide data for precise mapping. A curated dataset of landslide and 195 topographic images underscores the novelty and effectiveness of this approach. The framework employs dual Graph Convolutional Networks to capture spatial dependencies and GoogLeNet to extract deep spatial features effectively. A machine learning model complements these networks to refine predictions through iterative learning processes. The study evaluates network modelling through DGCN and GoogLeNet, focusing on training and validation accuracy. Training datasets demonstrated consistent improvement in classification accuracy, increasing from 66% to 93%, while validation datasets achieved high precision, with values rising from 78% to 99%. The results emphasize the model's robustness and scalability in addressing spatial heterogeneity and complex topographic conditions. Performance metrics were rigorously analyzed, indicating a significant alignment with ground-truth data, as evidenced by a coefficient of determination (R²) of 0.92 and a mean absolute error (MAE) of 4%. The integration of DGCN and GoogLeNet outperformed conventional methods by capturing intricate spatial and contextual features. This comprehensive framework ensures reliable and automated detection, crucial for disaster risk management in regions prone to landslides. In addition to predictive modelling, the study highlights the role of preprocessing techniques, including hillside and LULC analysis, in enhancing detection capabilities. A comparative analysis of models reveals the superiority of the dual network approach over single-framework architectures, particularly in terms of accuracy and adaptability to diverse datasets. This study provides a novel contribution to landslide mapping by combining topographical insights with advanced network architectures. The proposed framework demonstrates the potential for deployment in other regions with similar geological settings, paving the way for improved disaster preparedness and management strategies.

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使用协同对偶图卷积网络、googlenet和机器学习技术的滑坡自动检测

本研究利用先进的深度学习和机器学习框架，探索了Centro Fluminense自动滑坡检测的协同方法。所提出的方法将双图卷积网络（DGCN）与GoogLeNet集成在一起，分析地形和175个史前滑坡数据，以进行精确测绘。一个整理好的滑坡数据集和195个地形图像强调了这种方法的新颖性和有效性。该框架采用双图卷积网络捕获空间依赖关系，使用GoogLeNet有效提取深度空间特征。机器学习模型补充了这些网络，通过迭代学习过程来改进预测。该研究通过DGCN和GoogLeNet评估网络建模，重点关注训练和验证准确性。训练数据集在分类精度上表现出一致的提高，从66%提高到93%，而验证数据集的分类精度也很高，从78%提高到99%。结果强调了该模型在处理空间异质性和复杂地形条件方面的鲁棒性和可扩展性。对性能指标进行了严格的分析，表明与实际数据有显著的一致性，如决定系数（R2）为0.92和平均绝对误差（MAE）为4%所证明。通过捕获复杂的空间和上下文特征，DGCN和GoogLeNet的集成优于传统方法。这一综合框架确保了可靠和自动化的探测，这对易发生山体滑坡的地区的灾害风险管理至关重要。除了预测建模之外，该研究还强调了预处理技术（包括山坡和LULC分析）在增强探测能力方面的作用。模型的比较分析揭示了双网络方法优于单框架体系结构，特别是在准确性和对不同数据集的适应性方面。该研究通过将地形分析与先进的网络架构相结合，为滑坡制图提供了新的贡献。拟议的框架显示了在具有类似地质环境的其他地区部署的潜力，为改进备灾和管理战略铺平了道路。

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来源期刊

Journal of South American Earth Sciences 地学-地球科学综合

CiteScore

3.70

自引率

22.20%

发文量

364

审稿时长

6-12 weeks

期刊介绍： Papers must have a regional appeal and should present work of more than local significance. Research papers dealing with the regional geology of South American cratons and mobile belts, within the following research fields: -Economic geology, metallogenesis and hydrocarbon genesis and reservoirs. -Geophysics, geochemistry, volcanology, igneous and metamorphic petrology. -Tectonics, neo- and seismotectonics and geodynamic modeling. -Geomorphology, geological hazards, environmental geology, climate change in America and Antarctica, and soil research. -Stratigraphy, sedimentology, structure and basin evolution. -Paleontology, paleoecology, paleoclimatology and Quaternary geology. New developments in already established regional projects and new initiatives dealing with the geology of the continent will be summarized and presented on a regular basis. Short notes, discussions, book reviews and conference and workshop reports will also be included when relevant.