Informed Learning for Estimating Drought Stress at Fine-Scale Resolution Enables Accurate Yield Prediction

TL;DR

This paper introduces a physics-informed machine learning approach that couples crop water stress modeling with yield prediction, achieving high accuracy and explainability for fine-scale agricultural decision-making.

Contribution

It presents a novel coupling of physical crop water stress models with machine learning, incorporating a physics-informed loss to improve yield prediction accuracy and interpretability.

Findings

Achieves up to 0.82 R^2 in yield prediction.

Outperforms state-of-the-art models like LSTM and Transformers.

Provides physically consistent and explainable crop yield estimates.

Abstract

Water is essential for agricultural productivity. Assessing water shortages and reduced yield potential is a critical factor in decision-making for ensuring agricultural productivity and food security. Crop simulation models, which align with physical processes, offer intrinsic explainability but often perform poorly. Conversely, machine learning models for crop yield modeling are powerful and scalable, yet they commonly operate as black boxes and lack adherence to the physical principles of crop growth. This study bridges this gap by coupling the advantages of both worlds. We postulate that the crop yield is inherently defined by the water availability. Therefore, we formulate crop yield as a function of temporal water scarcity and predict both the crop drought stress and the sensitivity to water scarcity at fine-scale resolution. Sequentially modeling the crop yield response to water enables accurate yield prediction. To enforce physical consistency, a novel physics-informed loss function is proposed. We leverage multispectral satellite imagery, meteorological data, and fine-scale yield data. Further, to account for the uncertainty within the model, we build upon a deep ensemble approach. Our method surpasses state-of-the-art models like LSTM and Transformers in crop yield prediction with a coefficient of determination ($R^2$-score) of up to 0.82 while offering high explainability. This method offers decision support for industry, policymakers, and farmers in building a more resilient agriculture in times of changing climate conditions.