均方误差
生物量(生态学)
人工神经网络
卷积神经网络
环境科学
草原
生产力
牧场
植被(病理学)
计算机科学
遥感
人工智能
数学
农学
统计
农林复合经营
地理
生物
医学
病理
经济
宏观经济学
作者
Mohamed Ismail Vawda,Romano Lottering,Onisimo Mutanga,Kabir Peerbhay,Mbulisi Sibanda
出处
期刊:Sustainability
[Multidisciplinary Digital Publishing Institute]
日期:2024-01-25
卷期号:16 (3): 1051-1051
被引量:25
摘要
Grasslands are biomes of significant fiscal, social and environmental value. Grassland or rangeland management often monitors and manages grassland productivity. Productivity is determined by various biophysical parameters, one such being grass aboveground biomass. Advancements in remote sensing have enabled near-real-time monitoring of grassland productivity. Furthermore, the increase in sophisticated machine learning algorithms has provided a powerful tool for remote sensing analytics. This study compared the performance of two neural networks, namely, Artificial Neural Networks (ANN) and Convolutional Neural Networks (CNN), in predicting dry season aboveground biomass using open-access Sentinel-2 MSI data. Sentinel-2 spectral bands and derived vegetation indices were used as input data for the two algorithms. Overall, findings in this study showed that the deep CNN outperformed the ANN in estimating aboveground biomass with an R2 of 0.83, an RMSE of 3.36 g/m2 and an RMSE% of 6.09. In comparison, the ANN produced an R2 of 0.75, an RMSE of 5.78 g/m2 and an RMSE% of 8.90. The sensitivity analysis suggested that the blue band, Green Chlorophyll Index (GCl), and Green Normalised Difference Vegetation Index (GNDVI) were the most significant for model development for both neural networks. This study can be considered a pilot study as it is one of the first to compare different neural network performances using freely available satellite data. This is useful for more rapid biomass estimation, and this study exhibits the great potential of deep learning for remote sensing applications.
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