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Modeling SAR Observables by Combining a Crop-Growth Model With Machine Learning

Tina Nikaein, Paco López‐Dekker, Susan Steele‐Dunne, Vineet Kumar, Manuel Huber

2023IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing12 citationsDOIOpen Access PDF

Abstract

Our aim is to estimate Synthetic Aperture Radar (SAR) observables, such as backscatter in VV and VH polarizations, as well as the VH/VV ratio, cross-ratio (CR), and interferometric coherence in VV, from agricultural fields. In this study, we use the Decision Support System for Agrotechnology Transfer (DSSAT) crop growth simulation model to simulate parcel-level phenological and growth parameters for over 1500 parcels of silage maize in the Netherlands. The crop model was calibrated using field data, including silage maize phenological phases, leaf area index (LAI), and above-ground dry biomass (AGB). The simulations incorporate fine-resolution gridded precipitation data and soil parameters to model the interaction between soil-plant-atmosphere and genotype in DSSAT. The crop variables produced by DSSAT are then used as inputs to a Support Vector Regression (SVR) model. This model is trained to simulate SAR observables in 2017, 2018, and 2019, and its performance is evaluated using independent fields in each of these years. The results show a close fit between modeled and observed SAR C-band observables. The importance of vegetation variables in the estimation of SAR observables is assessed. The AGB showed significant importance in the estimation of backscatter. This study demonstrates the potential value of combining crop growth simulation models and machine learning to simulate SAR observables. For example, the SVR model developed here could be used as an observation operator in an assimilation context to constrain vegetation and soil water dynamics in a crop growth model.

Topics & Concepts

DSSATLeaf area indexSynthetic aperture radarObservableContext (archaeology)Environmental scienceRemote sensingAtmospheric sciencesCrop yieldPhysicsAgronomyGeographyQuantum mechanicsArchaeologyBiologySoil Moisture and Remote SensingPrecipitation Measurement and AnalysisSynthetic Aperture Radar (SAR) Applications and Techniques
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