An End-to-End Conditional Random Fields and Skip-Connected Generative Adversarial Segmentation Network for Remote Sensing Images

Urban land cover classification for high-resolution images is a fundamental yet challenging task in remote sensing image analysis. Recently, deep learning techniques have achieved outstanding performance in high-resolution image classification, especially the methods based on deep convolutional neural networks (DCNNs). However, the traditional CNNs using convolution operations with local receptive fields are not sufficient to model global contextual relations between objects. In addition, multiscale objects and the relatively small sample size in remote sensing have also limited classification accuracy. In this paper, a relation-enhanced multiscale convolutional network (REMSNet) method is proposed to overcome these weaknesses. A dense connectivity pattern and parallel multi-kernel convolution are combined to build a lightweight and varied receptive field sizes model. Then, the spatial relation-enhanced block and the channel relation-enhanced block are introduced into the network. They can adaptively learn global contextual relations between any two positions or feature maps to enhance feature representations. Moreover, we design a parallel multi-kernel deconvolution module and spatial path to further aggregate different scales information. The proposed network is used for urban land cover classification against two datasets: the ISPRS 2D semantic labelling contest of Vaihingen and an area of Shanghai of about 143 km 2 . The results demonstrate that the proposed method can effectively capture long-range dependencies and improve the accuracy of land cover classification. Our model obtains an overall accuracy (OA) of 90.46% and a mean intersection-over-union (mIoU) of 0.8073 for Vaihingen and an OA of 88.55% and a mIoU of 0.7394 for Shanghai.Automatic urban land cover classification in remote sensing images is a difficult task due to several challenges. First of all, high-resolution remote sensing images with abundant details generally have characteristics of high intraclass variance and low inter-class variance [10]. For example, different classes of ground objects may have a similar appearance in remote sensing images, such as trees and low vegetation or roofs and roads. Meanwhile, there is occlusion between different objects. To solve this issue, context information has been widely studied in remote sensing image classification [11]. Contextual information refers to the dependencies between objects, such as cars on roads. Misclassification will be reduced when taking these context relationships into account. In addition, ground objects often have various scales in remote sensing images. Cars and buildings have large differences in size. It is difficult to simultaneously distinguish objects with distinct scales. Generally, deeper layers with larger receptive fields are more suited for segmenting large objects, while shallower layers with smaller receptive fields are suitable to segment small objects [12]. Therefore, it is necessary to enhance global context relationships and fuse multiscale information for pixel-...

Section: Semantic Segmentation For High-resolution Aerial Imagesmentioning

confidence: 99%

Urban Land Cover Classification of High-Resolution Aerial Imagery Using a Relation-Enhanced Multiscale Convolutional Network

Liu

Zeng

et al. 2020

“…Moreover, the term abs means to take the absolute value of the amount in the associated brackets. In the paper [35], g loss contains a cross-entropy loss term, an L1 loss term, and an adversarial loss term g GAN . From Equations 3and 6, it can be found that the L1 loss calculates the absolute difference between the labels, and the cross-entropy is the degree of correlation between the label probabilities.…”

Section: Loss Functionmentioning

confidence: 99%

“…Luc et al [28] first used GAN to image segmentation for the purpose of enhancing long-range spatial label contiguity without increasing the complexity of the model used in the test. Subsequently, a variety of GAN-based segmentation methods [29][30][31][32][33][34][35] were proposed. Zhu et al [29] proposed an end-to-end network with the trained adversarial deep structure to improve the robustness of a small data model and prevent over-fitting.…”

Section: Introductionmentioning

confidence: 99%

An End-To-End Bayesian Segmentation Network Based on a Generative Adversarial Network for Remote Sensing Images

Xiong

Liu

et al. 2020

Self Cite

Due to the development of deep convolutional neural networks (CNNs), great progress has been made in semantic segmentation recently. In this paper, we present an end-to-end Bayesian segmentation network based on generative adversarial networks (GANs) for remote sensing images. First, fully convolutional networks (FCNs) and GANs are utilized to realize the derivation of the prior probability and the likelihood to the posterior probability in Bayesian theory. Second, the cross-entropy loss in the FCN serves as an a priori to guide the training of the GAN, so as to avoid the problem of mode collapse during the training process. Third, the generator of the GAN is used as a teachable spatial filter to construct the spatial relationship between each label. Some experiments were performed on two remote sensing datasets, and the results demonstrate that the training of the proposed method is more stable than other GAN based models. The average accuracy and mean intersection (MIoU) of the two datasets were 0.0465 and 0.0821, and 0.0772 and 0.1708 higher than FCN, respectively.

“…To complete the calculations, previous studies have used approximate calculations [60,61], reduction of the number of samples involved in modeling [62,63], and introduced conditional independence [64][65][66]. However, in doing so, the performance of the CRFs gets reduced [67]. To combine a CNN and CRFs, and achieve end-to-end training, several studies [67][68][69] have converted the CRF into an iterative calculation, while others [64] have converted the CRF into a convolution operation.…”

Section: Introductionmentioning

confidence: 99%

“…However, in doing so, the performance of the CRFs gets reduced [67]. To combine a CNN and CRFs, and achieve end-to-end training, several studies [67][68][69] have converted the CRF into an iterative calculation, while others [64] have converted the CRF into a convolution operation.…”

Section: Introductionmentioning

confidence: 99%

Improved Winter Wheat Spatial Distribution Extraction Using A Convolutional Neural Network and Partly Connected Conditional Random Field

Wang

Zhang

et al. 2020

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.