地形
遥感
传感器融合
计算机科学
下层林
数字高程模型
激光雷达
足迹
仰角(弹道)
数据建模
人工智能
树冠
随机森林
机器学习
环境科学
地形地貌
遥感应用
天蓬
作者
Jiapeng Huang,Xinyue Cao,Yang Yu,Yanmin Shuai,Hua Wu
标识
DOI:10.1109/tgrs.2025.3615149
摘要
Accurate understory terrain estimation is a key challenge in ecological modeling and forest resource management. Traditional optical remote sensing is affected by significant signal saturation in vegetated areas, while spaceborne LiDAR systems such as ICESat-2 are limited in supporting regional-scale continuous modeling due to their sparse and discrete footprint coverage. This study integrates filtered ICESat-2 understory elevation control points with optical remote sensing data to comprehensively assess the applicability and predictive accuracy of various machine learning models across different regions. By carefully selecting and optimizing models, the most suitable approach for each study area was identified, enabling precise regional-scale understory terrain estimation. Through multi-source remote sensing data fusion, a continuous surface elevation model was constructed, substantially enhancing overall estimation accuracy. Experimental results demonstrate a notable accuracy improvement, with ME = 0.42 m, RMSE = 2.80 m, and STD = 2.77 m. Furthermore, this study systematically quantifies the influence of environmental factors such as forest type, landform features, slope, aspect, and forest canopy height on estimation accuracy. Beyond advancing methodologies for high-precision understory terrain estimation, this study leverages machine learning optimization and multi-source data fusion to overcome the limitations of ICESat-2’s footprint coverage, providing robust technical support for global-scale understory terrain monitoring and ecosystem research.
科研通智能强力驱动
Strongly Powered by AbleSci AI