Abstract
Abstract. Satellite Image Time Series (SITS) are becoming available at high spatial, spectral and temporal resolutions across the globe by the latest remote sensing sensors. These series of images can be highly valuable when exploited by classification systems to produce frequently updated and accurate land cover maps. The richness of spectral, spatial and temporal features in SITS is a promising source of data for developing better classification algorithms. However, machine learning methods such as Random Forests (RF), despite their fruitful application to SITS to produce land cover maps, are structurally unable to properly handle intertwined spatial, spectral and temporal dynamics without breaking the structure of the data. Therefore, the present work proposes a comparative study of various deep learning algorithms from the Convolutional Neural Network (CNN) family and evaluate their performance on SITS classification. They are compared to the processing chain coined iota2, developed by the CESBIO and based on a RF model. Experiments are carried out in an operational context using with sparse annotations from 290 labeled polygons. Less than 80 000 pixel time series belonging to 8 land cover classes from a year of Sentinel-2 monthly syntheses are used. Results show on a test set of 131 polygons that CNNs using 3D convolutions in space and time are more accurate than 1D temporal, stacked 2D and RF approaches. Best-performing models are CNNs using spatio-temporal features, namely 3D-CNN, 2D-CNN and SpatioTempCNN, a two-stream model using both 1D and 3D convolutions.
Highlights
Land cover maps provide spatial information on the variety of different types, or classes, covering the Earth’s surface
We focused on Convolutional Neural Network (CNN) for their (i) relative ease of training compared to recurrent models, (ii) ease of deployment in an operational production framework, and (iii) ability to efficiently blend spatial and temporal information in convolution kernels
Test results show that 3DCNN is the best performing model with a mean F1-score of 0.804
Summary
Land cover maps provide spatial information on the variety of different types, or classes, covering the Earth’s surface. Such maps were originally produced by using only spectral features available in satellite images sensed by Earth observation systems. As the Earth’s surface is rapidly changing due to natural and socioeconomic factors, land cover maps are an essential tool for mapping and monitoring its biophysical cover. They are highly valuable in many applications such as urbanization, natural resources management, and during extreme events accentuated by climate change such as drought, flooding, wildfires or biomass changes. The use of temporal dependencies has been poorly investigated as explained in (Gomez et al, 2016) and (Gbodjo et al, 2020)
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