1. UAV images and deep-learning algorithms for detecting flavescence doree disease in grapevine orchards
- Author
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Musci, M. A., Persello, C., Lingua, A. M., Paparoditis, N., Mallet, C., Lafarge, F., Jiang, J., Shaker, A., Zhang, H., Liang, X., Osmanoglu, B., Soergel, U., Honkavaara, E., Scaioni, M., Zhang, J., Peled, A., Wu, L., Li, R., Yoshimura, M., Di, K., Altan, O., Abdulmuttalib, H.M., Faruque, F.S., Department of Earth Observation Science, UT-I-ITC-ACQUAL, and Faculty of Geo-Information Science and Earth Observation
- Subjects
lcsh:Applied optics. Photonics ,Deep-Learning ,Computer science ,Faster R-CNN ,Precision viticulture ,Unmanned Aerial Vehicle (UAV) ,Flavescence dorée grapevine disease ,Object Detection ,lcsh:Technology ,01 natural sciences ,Crop ,lcsh:T ,business.industry ,Deep learning ,010401 analytical chemistry ,lcsh:TA1501-1820 ,04 agricultural and veterinary sciences ,Object detection ,0104 chemical sciences ,Random forest ,lcsh:TA1-2040 ,Test set ,040103 agronomy & agriculture ,0401 agriculture, forestry, and fisheries ,Flavescence dorée ,Artificial intelligence ,lcsh:Engineering (General). Civil engineering (General) ,business ,Algorithm ,Classifier (UML) - Abstract
One of the major challenges in precision viticulture in Europe is the detection and mapping of flavescence dorée (FD) grapevine disease to monitor and contain its spread. The lack of effective cures and the need for sustainable preventive measures are nowadays crucial issues. Insecticides and the plants uprooting are commonly employed to withhold disease infection, even if these solutions imply serious economic consequences and a strong environmental impact. The development of a rapid strategy to identify the disease is required to cover large portions of the crop and thus to limit damages in a time-effective way. This paper investigates the use of Unmanned Aerial Vehicles (UAVs), a cost-effective approach to early detection of diseased areas. We address this task with an object detection deep network, Faster R-CNN, instead of a traditional pixel-wise classifier. This work tests Faster R-CNN performance on this specific application through a comparative analysis with a pixel-wise classification algorithm (Random Forest). To take advantage of the full image resolution, the experimental analysis is performed using the original UAV imagery acquired in real conditions (instead of the derived orthomosaic). The first result of this paper is the definition of a new dataset for FD disease identification by UAV original imagery at the canopy scale. Moreover, we demonstrate the feasibility of applying Faster-R-CNN as a quasi-real-time alternative solution to semantic segmentation. The trained Faster-R-CNN achieved an average precision of 82% on the test set.
- Published
- 2020