Abstract
Rice is one of the world’s major staple foods, especially in China. Highly accurate monitoring on rice-producing land is, therefore, crucial for assessing food supplies and productivity. Recently, the deep-learning convolutional neural network (CNN) has achieved considerable success in remote-sensing data analysis. A CNN-based paddy-rice mapping method using the multitemporal Landsat 8, phenology data, and land-surface temperature (LST) was developed during this study. First, the spatial–temporal adaptive reflectance fusion model (STARFM) was used to blend the moderate-resolution imaging spectroradiometer (MODIS) and Landsat data for obtaining multitemporal Landsat-like data. Subsequently, the threshold method is applied to derive the phenological variables from the Landsat-like (Normalized difference vegetation index) NDVI time series. Then, a generalized single-channel algorithm was employed to derive LST from the Landsat 8. Finally, multitemporal Landsat 8 spectral images, combined with phenology and LST data, were employed to extract paddy-rice information using a patch-based deep-learning CNN algorithm. The results show that the proposed method achieved an overall accuracy of 97.06% and a Kappa coefficient of 0.91, which are 6.43% and 0.07 higher than that of the support vector machine method, and 7.68% and 0.09 higher than that of the random forest method, respectively. Moreover, the Landsat-derived rice area is strongly correlated (R2 = 0.9945) with government statistical data, demonstrating that the proposed method has potential in large-scale paddy-rice mapping using moderate spatial resolution images.
Highlights
Food security has always been a problem for China and the rest of the world [1,2]
The results show that the proposed method achieved an overall accuracy of 97.06% and a Kappa coefficient of 0.91, which are 6.43% and 0.07 higher than that of the support vector machine method, and 7.68% and 0.09 higher than that of the random forest method, respectively
When one Landsat 8 spectral image was considered, the image acquired in July, the heading stage of single-season rice and the ripening of double-cropping rice had the highest classification accuracy, followed by that acquired in September, the ripening stage of the single-season rice and the heading stage for the double-cropping rice, and that acquired in June, the flowering stage of the double-cropping rice and the tillering stage of the single-season rice
Summary
Food security has always been a problem for China and the rest of the world [1,2]. As one of the major staple foods, is widely planted in China [3,4]. Rice production in some areas has been recently facing some challenges. The growing population has higher demand on rice, while on the other hand, the area of rice paddies has been decreasing with urbanization. Natural degradation and hazards like floods and droughts are a problem impacting rice production [5,6,7]. The timely and accurate assessment of rice production is necessary for government decisions, which can be achieved by the high spatial–temporal resolution monitoring of rice-producing lands
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