Quantifying vegetation biophysical variables from imaging spectroscopy data: a review on retrieval methods

TL;DR

This review summarizes current retrieval methods for estimating vegetation biophysical variables from imaging spectroscopy data, emphasizing their applications, challenges like spectral multicollinearity, and recommendations for operational processing.

Contribution

It categorizes and evaluates state-of-the-art retrieval techniques, providing a comprehensive overview and guidance for future operational spectroscopy-based vegetation analysis.

Findings

Identification of four main retrieval method categories.

Discussion on spectral multicollinearity challenges.

Recommendations for processing chains in operational settings.

Abstract

An unprecedented spectroscopic data stream will soon become available with forthcoming Earth-observing satellite missions equipped with imaging spectroradiometers. This data stream will open up a vast array of opportunities to quantify a diversity of biochemical and structural vegetation properties. The processing requirements for such large data streams require reliable retrieval techniques enabling the spatiotemporally explicit quantification of biophysical variables. With the aim of preparing for this new era of Earth observation, this review summarizes the state-of-the-art retrieval methods that have been applied in experimental imaging spectroscopy studies inferring all kinds of vegetation biophysical variables. Identified retrieval methods are categorized into: (1) parametric regression, including vegetation indices, shape indices, and spectral transformations; (2) non-parametric regression, including linear and non-linear machine learning regression algorithms; (3) physically-based, including inversion of radiative transfer models (RTMs) using numerical optimization and look-up-table approaches; and (4) hybrid regression methods, which combine RTM simulations with machine learning regression methods. For each of these categories, an overview of widely applied methods with application to mapping vegetation properties is given. In view of processing imaging spectroscopy data, a critical aspect involves the challenge of dealing with spectral multicollinearity. The ability to provide robust estimates, retrieval uncertainties, and acceptable retrieval processing speed are other important aspects in view of operational processing. Recommendations towards new-generation spectroscopy-based processing chains for the operational production of biophysical variables are given.