Classification of Crop Residue Cover in High-Resolution RGB Images Using Machine Learning

Highlights A machine learning framework estimated residue cover in RGB images taken at three resolutions from 88 locations. The best results primarily used texture features, the RFE-SVM feature selection method, and the SVM classifier. Accounting for shadows and plants plus modifying and optimizing...

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Veröffentlicht in:Journal of the ASABE 2022, Vol.65 (1), p.75-86
Hauptverfasser: Upadhyay, Parth C., Lory, John A., DeSouza, Guilherme N., Lagaunne, Timotius A. P., Spinka, Christine M.
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Sprache:eng
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Zusammenfassung:Highlights A machine learning framework estimated residue cover in RGB images taken at three resolutions from 88 locations. The best results primarily used texture features, the RFE-SVM feature selection method, and the SVM classifier. Accounting for shadows and plants plus modifying and optimizing the texture features may improve performance. An automated system developed using machine learning is a viable strategy to estimate residue cover from RGB images obtained with handheld or UAV platforms. Abstract . Maintaining plant residue on the soil surface contributes to sustainable cultivation of arable land. Applying machine learning methods to RGB images of residue could overcome the subjectivity of manual methods. The objectives of this study were to use supervised machine learning while identifying the best feature selection method, the best classifier, and the most effective image feature types for classifying residue levels in RGB imagery. Imagery was collected from 88 locations in 40 row-crop fields in five Missouri counties between early May and late June in 2018 and 2019 using a tripod-mounted camera (0.014 cm pixel-1 ground sampling distance, GSD) and an unmanned aerial vehicle (UAV, 0.05 and 0.14 GSD). At each field location, 50 contiguous 0.3 × 0.2 m region of interest (ROI) images were extracted from the imagery, resulting in a dataset of 4,400 ROI images at each GSD. Residue percentages for ground truth were estimated using a bullseye grid method (n = 100 points) based on the 0.014 GSD images. Representative color, texture, and shape features were extracted and evaluated using four feature selection methods and two classifiers. Recursive feature elimination using support vector machine (RFE-SVM) was the best feature selection method, and the SVM classifier performed best for classifying the amount of residue as a three-class problem. The best features for this application were associated with texture, with local binary pattern (LBP) features being the most prevalent for all three GSDs. Shape features were irrelevant. The three residue classes were correctly identified with 88%, 84%, and 81% 10-fold cross-validation scores for the 2018 training data and 81%, 69%, and 65% accuracy for the 2019 testing data in decreasing resolution order. Converting image-wise data (0.014 GSD) to location residue estimates using a Bayesian model showed good agreement with the location-based ground truth (r2 = 0.90). This initial assessment documents the use of RGB
ISSN:2769-3287
2769-3295
2769-3287
DOI:10.13031/ja.14572