Abstract
Extraction of farming progress information in rice–wheat rotation regions is an important topic in smart field research. In this study, a new method for the classification of farming progress types using unmanned aerial vehicle (UAV) RGB images and the proposed regional mean (RM) model is presented. First, RGB information was extracted from the images to create and select the optimal color indices. After index classification, we compared the brightness reflection of the corresponding grayscale map, the classification interval, and the standard deviation of each farming progress type. These comparisons showed that the optimal classification color indices were the normalized red–blue difference index (NRBDI), the normalized green–blue difference index (NGBDI), and the modified red–blue difference index (MRBDI). Second, the RM model was built according to the whole-field farming progress classification requirements to achieve the final classification. We verified the model accuracy, and the Kappa coefficients obtained by combining the NRBDI, NGBDI, and MRBDI with the RM model were 0.86, 0.82, and 0.88, respectively. The proposed method was then applied to predict UAV RGB images of unharvested wheat, harvested wheat, and tilled and irrigated fields. The results were compared with those obtained with traditional machine learning methods, that is, the support vector machine, maximum likelihood classification, and random forest methods. The NRBDI, NGBDI, and MRBDI were combined with the RM model to monitor farming progress of ground truth ROIs, and the Kappa coefficients obtained were 0.9134, 0.8738, and 0.9179, respectively, while traditional machine learning methods all produced a Kappa coefficient less than 0.7. The results indicate a significantly higher accuracy of the proposed method than those of the traditional machine learning classification methods for the identification of farming progress type. The proposed work provides an important reference for the application of UAV to the field classification of progress types.
Highlights
Farmland plays an important role in the material basis of human survival and development
NRBDI + RM: normalized red–blue difference index combined with regional mean model; NGBDI + RM: normalized green–blue difference index combined with regional mean model; MRBDI + RM: modified red–blue difference index combined with regional mean model
We verified the model accuracy, and the Kappa coefficients obtained by combining the NRBDI, NGBDI, and MRBDI with the RM model were 0.86, 0.82, and 0.88, respectively
Summary
Farmland plays an important role in the material basis of human survival and development. In 2003, the Russian Ministry of Agriculture established a national agricultural monitoring system [3] This system acquires information on farmland area, maps of farmland use status, and crop growth status. In the African region, Egypt used multi-temporal MODIS data and time series analysis methods to analyze the satellite images of irrigated regions at different stages [4]. This program has achieved the goals of farmland area surveying and monitoring of dynamic changes throughout Egypt. Monitoring farming progress in rice–wheat rotation fields is an essential part of ensuring grain production At present, this monitoring is generally conducted by manual field surveys that are time-consuming and inefficient. Inadequate monitoring of the farming conditions during the wheat harvesting stage could directly affect wheat harvesting and rice planting, resulting in a decrease in farmland utilization
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