A physics-aware data-driven surrogate approach for fast atmospheric radiative transfer inversion

TL;DR

This paper introduces a fast, physics-aware, data-driven surrogate model for atmospheric radiative transfer inversion, enabling near-instantaneous retrieval of atmospheric properties from satellite radiance spectra, which enhances real-time climate monitoring.

Contribution

It presents a novel two-phase neural network-based approach that approximates the inverse mapping for atmospheric retrieval, incorporating climatological data to improve accuracy and speed.

Findings

Provides near-instantaneous atmospheric property estimates

Enhances initial retrieval accuracy with climatological data

Offers a scalable surrogate for real-time climate monitoring

Abstract

FORUM (Far-infrared Outgoing Radiation Understanding and Monitoring) was selected in 2019 as the ninth Earth Explorer mission by the European Space Agency (ESA). Its primary objective is to collect interferometric measurements in the Far-InfraRed (FIR) spectral range, which accounts for 50\% of Earth's outgoing longwave radiation emitted into space, and will be observed from space for the first time. Accurate measurements of the FIR at the top of the atmosphere are crucial for improving climate models. Current instruments are insufficient, necessitating the development of advanced computational techniques. To ensure the quality of the mission data, an End-to-End Simulator (E2ES) was developed to simulate the measurement process and evaluate the effects of instrument characteristics and environmental factors. The core challenge of the mission is solving the retrieval problem, which involves estimating atmospheric properties from the radiance spectra observed by the satellite. This problem is ill-posed and regularization techniques are necessary. In this work, we present a novel and fast data-driven approach to approximate the inverse mapping. In the first phase, we generate an initial approximation of the inverse mapping using only simulated FORUM data. In the second phase, we improve this approximation by introducing climatological data as a priori information and using a neural network to estimate the optimal regularization parameters. While our approach does not match the precision of full-physics retrieval methods, its key advantage is the ability to deliver results almost instantaneously, making it highly suitable for real-time applications. Furthermore, the proposed method can provide more accurate a priori estimates for full-physics methods, thereby improving the overall accuracy of the retrieved atmospheric profiles.