利用机器学习对 ICESat-2 数据进行去噪和林冠高度估算

IF 7.6 Q1 REMOTE SENSING
Dan Kong, Yong Pang
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引用次数: 0

摘要

有监督的分类方法可以从不同的特征角度区分冰、云和陆地高程卫星-2(ICESat-2)数据中的噪声和信号,并自主优化参数。然而,在实际应用中,模型的通用性仍然是一个重要的限制因素。本研究的重点是利用机器学习算法为 ICESat-2 开发通用去噪模型,并分析其在各种森林和地形条件下的空间可移植性。基于对森林地区光子三维分布的分析,开发了一个光子去噪特征参数系统。该系统减少了依赖于绝对物理量的参数,增加了受地形和森林特征影响较小的参数,以提高模型的可移植性。随后,自动机器学习算法(AutoML)被用于六个非参数回归模型的模型选择和参数优化。我们评估了局部模型、全局模型和转移模型在估算中国四个代表性林区冠层高度时的准确性。结果表明,该算法能有效区分信号光子和噪声光子。信号光子估算的树冠高度与机载激光扫描(ALS)获得的高度高度高度一致,皮尔逊相关系数(r)为 0.89,均方根误差(RMSE)为 3.75 米,相对均方根误差(rRMSE)为 0.值得注意的是,与 ICESat-2 土地植被沿轨迹产品(ATL08)相比,全球模式的冠层高度估计精度平均提高了 21%。此外,该模型还显示出显著的空间转移能力,转移模型的准确度超过了 ATL08 的准确度,幅度从 4% 到 41% 不等。这项研究标志着光子去噪方法的重大进步,为大规模环境数据分析提供了一种稳健、可转移的解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
ICESat-2 data denoising and forest canopy height estimation using Machine Learning
Supervised classification methods can distinguish between noise and signal in ice, cloud, and land elevation satellite-2 (ICESat-2) data across various feature perspectives and autonomously optimize parameters. Nevertheless, model generalization remains a significant limitation for practical applications. This study focuses on developing a universal denoising model for ICESat-2 using machine learning algorithms and analyzing its spatial transferability under various forest and terrain conditions. A photon-denoising feature parameter system is developed based on the analysis of the three-dimensional distribution of photons in forested regions. This system reduces the parameters dependent on absolute physical quantities and increases those that are less influenced by terrain and forest features to enhance the model’s transferability. Subsequently, automated machine learning algorithms (AutoML) are used for model selection and parameter optimization across six non-parametric regression models. We evaluate the accuracies of the local, global, and transfer models in estimating canopy height across four representative forested areas in China. Results show that the algorithm can effectively distinguish between signal and noise photons. The estimated canopy heights from signal photons are highly consistent with heights obtained using airborne laser scanning (ALS), exhibiting a Pearson correlation coefficient (r) of 0.89, root mean square errors (RMSE) of 3.75 m, relative root mean square error (rRMSE) of 0.27, relative bias (rBias) of −0.11 and mean Bias of −1.45 m. Notably, the accuracy of canopy height estimation by the global model has increased by an average of 21 % compared to ICESat-2 land-vegetation along-track products (ATL08). Furthermore, the model exhibits significant spatial transfer capabilities, with the accuracies of the transfer model exceeding those of ATL08 by margins ranging from 4 % to 41 %. This study marks a significant advancement in photon-denoising methodologies, providing a robust and transferable solution for large-scale environmental data analysis.
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来源期刊
International journal of applied earth observation and geoinformation : ITC journal
International journal of applied earth observation and geoinformation : ITC journal Global and Planetary Change, Management, Monitoring, Policy and Law, Earth-Surface Processes, Computers in Earth Sciences
CiteScore
12.00
自引率
0.00%
发文量
0
审稿时长
77 days
期刊介绍: The International Journal of Applied Earth Observation and Geoinformation publishes original papers that utilize earth observation data for natural resource and environmental inventory and management. These data primarily originate from remote sensing platforms, including satellites and aircraft, supplemented by surface and subsurface measurements. Addressing natural resources such as forests, agricultural land, soils, and water, as well as environmental concerns like biodiversity, land degradation, and hazards, the journal explores conceptual and data-driven approaches. It covers geoinformation themes like capturing, databasing, visualization, interpretation, data quality, and spatial uncertainty.
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