通过调整变换器模型对原始不规则时间序列(CRIT)进行分类,以绘制大面积土地覆被图

IF 5.7 Q1 ENVIRONMENTAL SCIENCES Science of Remote Sensing Pub Date : 2024-02-09 DOI:10.1016/j.srs.2024.100123
Hankui K. Zhang , Dong Luo , Zhongbin Li
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引用次数: 0

摘要

对于大地遥感卫星的土地覆被分类,由于大面积云层的变化和长时间采集计划的变化,时间序列观测值在一个时期(如一年)内的观测值数量和采集日期通常是不规则的。通常使用合成或时间百分位数计算将不规则的时间序列转换为规则的时间变量,以便应用机器学习和深度学习分类器。本研究认识到合成和百分位数计算会造成信息损失,因此通过改编变换器,提出了一种直接对原始不规则时间序列进行分类(CRIT)的方法("原始 "指的是不规则的高质量地表反射率时间序列,没有经过任何合成或时间百分位数推导)。CRIT 使用年采集日作为分类输入来调整时间序列,还将大地遥感卫星平台(大地遥感卫星 5 号、7 号和 8 号)作为输入来解决传感器间的反射率差异。CRIT 通过对大地遥感卫星分析就绪数据(ARD)地表反射率时间序列进行分类进行了演示,该时间序列是在大地遥感卫星可用性存在空间和时间变化的三年(1985 年、2006 年和 2018 年)内在美国大陆(CONUS)上跨一年采集的。使用了 20,047 个训练 30 米像素和 4949 个评估 30 米像素,其中每个像素每年都被注释为七个土地覆被类别之一。将 CRIT 与 16 天综合时间序列和时间百分位数进行了比较,并与一维卷积神经网络(CNN)方法进行了比较。结果表明,与 16 天复合时间序列分类相比,使用三年样本训练的 CRIT 在更少的计算时间内提高了 1.4-1.5%的总体准确度,比时间百分位数分类高出 2.3-2.4%。与 16 天合成数据相比,CRIT 在已开发(0.05 F1-score)和耕地(0.02 F1-score)类别以及混合或边界像素方面的优势更为明显。这也是合理的,因为 16 天合成图在这三年中的平均观测质量分别为 7.02、16.49 和 15.78,而原始不规则时间序列的观测质量分别为 7.89、27.72 和 26.60。在对原始不规则时间序列进行分类时,CNN 的效果不如 CRIT,因为 CNN 只是将没有观测值的时间位置填充为零,而 CRIT 则使用了屏蔽机制来排除观测值的贡献。CRIT 还可以将像素坐标和 DEM 变量作为输入,从而将总体准确率进一步提高了 1.1-2.6%,1985、2006 和 2018 年分类的总体准确率分别达到 84.33%、87.54% 和 87.01%。CRIT 的土地覆被图与美国地质调查局的土地变化监测、评估和预测(LCMAP)图一致。开发的代码、训练数据和地图已公开发布。
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Classifying raw irregular time series (CRIT) for large area land cover mapping by adapting transformer model

For Landsat land cover classification, the time series observations are typically irregular in the number of observations in a period (e.g., a year) and acquisition dates due to cloud cover variations over large areas and acquisition plan variations over long periods. Compositing or temporal percentile calculation are usually used to transform the irregular time series to regular temporal variables so that the machine and deep learning classifiers can be applied. Recognizing that the composite and percentile calculations have information loss, this study presents a method directly Classifying the Raw Irregular Time series (CRIT) (‘raw’ means irregular good-quality surface reflectance time series without any composite or temporal percentile derivation) by adapting Transformer. CRIT uses the acquisition day of year as classification input to align time series and also takes the Landsat satellite platform (Landsat 5, 7 and 8) as input to address the inter-sensor reflectance differences.

The CRIT was demonstrated by classifying Landsat analysis ready data (ARD) surface reflectance time series acquired across one year for three years (1985, 2006 and 2018) over the Conterminous United States (CONUS) with both spatial and temporal variations in Landsat availability. 20,047 training and 4949 evaluation 30-m pixel were used where each pixel was annotated as one of seven land cover classes for each year. The CRIT was compared with classifying 16-day composite time series and temporal percentiles and compared with a 1D convolution neural network (CNN) method. Results showed that the CRIT trained with three years of samples had 1.4–1.5% higher overall accuracies with less computation time than classifying 16-day composites and 2.3–2.4% higher than classifying temporal percentiles. The CRIT advantages over 16-day composites were pronounced for developed (0.05 F1-score) and cropland (0.02 F1-score) classes and for mixed or boundary pixels. This was reasonable as the 16-day composites had only on average 7.02, 16.49 and 15.78 good quality observations for the three years, respectively, in contrast to 7.89, 27.72, and 26.60 for the raw irregular time series. The CNN was not as good as CRIT in classifying the raw irregular time series as CNN simply filling temporal positions with no observations as zeros while the CRIT used a masking mechanism to rule out their contribution. The CRIT can also take the pixel coordinates and DEM variables as input which further increased the overall accuracies by 1.1–2.6% and achieved 84.33%, 87.54% and 87.01% overall accuracies for the 1985, 2006 and 2018 classifications, respectively. The CRIT land cover maps were shown consistent with the USGS Land Change Monitoring, Assessment, and Projection (LCMAP) maps. The developed codes, training data and maps were made publicly available.

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