Abstract
Improving the accuracy of edge pixel classification is crucial for extracting the winter wheat spatial distribution from remote sensing imagery using convolutional neural networks (CNNs). In this study, we proposed an approach using a partly connected conditional random field model (PCCRF) to refine the classification results of RefineNet, named RefineNet-PCCRF. First, we used an improved RefineNet model to initially segment remote sensing images, followed by obtaining the category probability vectors for each pixel and initial pixel-by-pixel classification result. Second, using manual labels as references, we performed a statistical analysis on the results to select pixels that required optimization. Third, based on prior knowledge, we redefined the pairwise potential energy, used a linear model to connect different levels of potential energies, and used only pixel pairs associated with the selected pixels to build the PCCRF. The trained PCCRF was then used to refine the initial pixel-by-pixel classification result. We used 37 Gaofen-2 images obtained from 2018 to 2019 of a representative Chinese winter wheat region (Tai’an City, China) to create the dataset, employed SegNet and RefineNet as the standard CNNs, and a fully connected conditional random field as the refinement methods to conduct comparison experiments. The RefineNet-PCCRF’s accuracy (94.51%), precision (92.39%), recall (90.98%), and F1-Score (91.68%) were clearly superior than the methods used for comparison. The results also show that the RefineNet-PCCRF improved the accuracy of large-scale winter wheat extraction results using remote sensing imagery.
Highlights
The crop spatial distribution includes the shape, location, and area of each piece of crop planting area
We proposed a partly connected conditional random field (PCCRF) model to post-process the RefineNet extraction results, referred to as RefineNet-partly connected conditional random field model (PCCRF), to eventually achieve the goal of obtaining the high-quality winter wheat spatial distribution
The SegNet-PCCRF was superior to SegNet-Conditional random field (CRF), while the RefineNet-PCCRF was superior to the RefineNet-CRF; this demonstrated that the PCCRF was more suitable as a post-processing method
Summary
The crop spatial distribution includes the shape, location, and area of each piece of crop planting area. The accurate measurement of crop spatial distributions is of great significance for scientific research, food security, estimates of grain production, and agricultural management and policy [1,2,3]. Whether the edges are fine is a key indicator of the crop spatial distribution data quality; to achieve this, research related to obtaining large-scale and high-quality crop spatial distribution has attracted widespread attention [4,5]. Ground surveys can be used to obtain accurate crop spatial distributions. This method is highly labor-intensive and time-consuming, thereby making it difficult to obtain large-scale data [6]. The data obtained via ground surveys are mainly used to verify the data obtained using other technologies [7]
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