Improved Landsat-based snow cover mapping accuracy using a spatiotemporal NDSI and generalized linear mixed model

IF 5.7 Q1 ENVIRONMENTAL SCIENCES
Charlotte Poussin , Pablo Timoner , Bruno Chatenoux , Gregory Giuliani , Pascal Peduzzi
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引用次数: 2

Abstract

Snow cover extent and distribution over the years have a significant impact on hydrological, terrestrial, and climatologic processes. Snow cover mapping accuracy using remote sensing data is then particularly important. This study analyses Landsat-8 NDSI snow cover datasets over time and space using different NDSI-based approach. The objectives are (i) to investigate the relation snow-NDSI with different environmental variables, (ii) to evaluate the accuracy of the common NDSI threshold of 0.4 against in-situ snow depth measurement and (iii) to develop a method that optimises snow cover mapping accuracy and minimises snow cover detection errors of omission and commission. Landsat-8 snow cover datasets were compared to ground snow depth measurements of climate stations over Switzerland for the period 2014–2020. It was found that there is a consistent relationship between NDSI values and land cover type, elevation, seasons, and snow depth measurements. The global NDSI threshold of 0.4 may not be always optimal for the Swiss territory and tends to underestimate the snow cover extent. Best NDSI thresholds vary spatially and are generally lower than 0.4 for the three snow depth threshold tested. We therefore propose a new spatiotemporal NDSI method to maximize snow cover mapping accuracy by using a generalized linear mixed model (GLMM). This model uses three environmental variables (i.e., elevation, land cover type and seasons) and raw NDSI values and improves snow cover mapping accuracy by 24% compared to the fixed threshold of 0.4. By using this method omissions errors decrease considerably while keeping a very low value of commission errors. This method will then be integrated in the Snow Observation from Space (SOfS) algorithm used for snow detection in Switzerland.

利用时空NDSI和广义线性混合模型提高landsat积雪制图精度
多年来的积雪范围和分布对水文、陆地和气候过程有重大影响。因此,利用遥感数据绘制积雪地图的准确性尤为重要。本研究使用不同的基于NDSI的方法分析了Landsat-8 NDSI积雪数据集的时间和空间。目标是(i)研究雪NDSI与不同环境变量的关系,(ii)根据现场雪深测量评估0.4的通用NDSI阈值的准确性,以及(iii)开发一种优化积雪测绘精度并将遗漏和调试的积雪检测误差降至最低的方法。Landsat-8积雪数据集与瑞士气候站2014-2010年期间的地面积雪深度测量值进行了比较。研究发现,NDSI值与土地覆盖类型、海拔、季节和雪深测量值之间存在一致的关系。全球NDSI阈值0.4可能并不总是瑞士领土的最佳值,而且往往低估了积雪范围。最佳NDSI阈值在空间上变化,并且对于测试的三个雪深阈值而言通常低于0.4。因此,我们提出了一种新的时空NDSI方法,通过使用广义线性混合模型(GLMM)来最大限度地提高积雪测绘精度。该模型使用了三个环境变量(即海拔、土地覆盖类型和季节)和原始NDSI值,与0.4的固定阈值相比,积雪测绘精度提高了24%。通过使用这种方法,在保持非常低的佣金误差值的同时,遗漏误差显著减少。然后,该方法将被集成到瑞士用于雪探测的太空雪观测(SOfS)算法中。
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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CiteScore
12.20
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0.00%
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