Abstract
In recent years, technology advancement has led to an enormous increase in the amount of satellite data. The availability of huge datasets of remote sensing measurements to be processed, and the increasing need for near-real-time data analysis for operational uses, has fostered the development of fast, efficient-retrieval algorithms. Deep learning techniques were recently applied to satellite data for retrievals of target quantities. Forward models (FM) are a fundamental part of retrieval code development and mission design, as well. Despite this, the application of deep learning techniques to radiative transfer simulations is still underexplored. The DeepLIM project, described in this work, aimed at testing the feasibility of the application of deep learning techniques at the design of the retrieval chain of an upcoming satellite mission. The Land Surface Temperature Mission (LSTM) is a candidate for Sentinel 9 and has, as the main target, the need, for the agricultural community, to improve sustainable productivity. To do this, the mission will carry a thermal infrared sensor to retrieve land-surface temperature and evapotranspiration rate. The LSTM land-surface temperature retrieval chain is used as a benchmark to test the deep learning performances when applied to Earth observation studies. Starting from aircraft campaign data and state-of-the-art FM simulations with the DART model, deep learning techniques are used to generate new spectral features. Their statistical behavior is compared to the original technique to test the generation performances. Then, the high spectral resolution simulations are convolved with LSTM spectral response functions to obtain the radiance in the LSTM spectral channels. Simulated observations are analyzed using two state-of-the-art retrieval codes and deep learning-based algorithms. The performances of deep learning algorithms show promising results for both the production of simulated spectra and target parameters retrievals, one of the main advances being the reduction in computational costs.
Highlights
We focus on land-surface temperature (LST) retrievals from five Thermal Infra-Red (TIR) channels used by satellite missions
Even if in this work we focused on LST retrievals, for completeness, the developed deep learning model, called the deep learning inversion model (DLIM), is conceived to retrieve the land surface emissivity (LSE) fields
The use of deep learning techniques for Earth observation studies can be extended to a variety of other remote sensing datasets
Summary
Simulation of instrumental satellite observations is a crucial step in satellite mission developments. The radiance that reaches the sensor can be simulated by radiative transfer models (RTMs). RTMs are used in the prelaunch phase to study the feasibility of a mission, to assess its requirements and its target sensitivity, and, to develop the target retrieval chain. Several forward models (FMs) have been developed during the past decades to model sensor observations in different spectral ranges, accounting for different physical processes
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