Semantic segmentation of multisensor remote sensing imagery with deep ConvNets and higher-order conditional random fields

Liu, Yansong; Piramanayagam, Sankaranarayanan; Monteiro, Sildomar T.; Saber, Eli

doi:10.1117/1.jrs.13.016501

Cited by 29 publications

(21 citation statements)

References 44 publications

(74 reference statements)

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“…In addition, since the OSM building map did not provide a precise building mask, particularly for the building boundaries, we verified inaccuracies in some parts of the images. This problem was alleviated by implementing a Conditional Random Field method (CRF), which has been primarily investigated in the literature as a refinement over the U-net or Fully Connected Networks (FCNs) results [56,77,78]. Accordingly, a fully/dense CRF model developed by Krähenbühl and Koltun [79] was employed to optimize the ResUnet results.…”

Section: Step 4: Updating the Building Databasementioning

confidence: 99%

Post-Disaster Building Database Updating Using Automated Deep Learning: An Integration of Pre-Disaster OpenStreetMap and Multi-Temporal Satellite Data

et al. 2019

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First responders and recovery planners need accurate and quickly derived information about the status of buildings as well as newly built ones to both help victims and to make decisions for reconstruction processes after a disaster. Deep learning and, in particular, convolutional neural network (CNN)-based approaches have recently become state-of-the-art methods to extract information from remote sensing images, in particular for image-based structural damage assessment. However, they are predominantly based on manually extracted training samples. In the present study, we use pre-disaster OpenStreetMap building data to automatically generate training samples to train the proposed deep learning approach after the co-registration of the map and the satellite images. The proposed deep learning framework is based on the U-net design with residual connections, which has been shown to be an effective method to increase the efficiency of CNN-based models. The ResUnet is followed by a Conditional Random Field (CRF) implementation to further refine the results. Experimental analysis was carried out on selected very high resolution (VHR) satellite images representing various scenarios after the 2013 Super Typhoon Haiyan in both the damage and the recovery phases in Tacloban, the Philippines. The results show the robustness of the proposed ResUnet-CRF framework in updating the building map after a disaster for both damage and recovery situations by producing an overall F1-score of 84.2%.

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Section: Step 4: Updating the Building Databasementioning

confidence: 99%

Post-Disaster Building Database Updating Using Automated Deep Learning: An Integration of Pre-Disaster OpenStreetMap and Multi-Temporal Satellite Data

et al. 2019

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“…Our applied focus in this paper is land cover classification based on remote sensing. Lately, the FCNs and encoderdecoder architectures have been widely adapted and applied to the ISPRS [8] Semantic Labeling Contest [20], [21], [22], [23], [24], [25], [26], [27], [28], [29], and the DeepGlobe CVPR-2018 [9] challenge of automatic classification of land cover types [30], [31], [32], [33], [34], [35], [36]. Paisitkriangkrai et al [20] proposed a scheme for high-resolution land cover classification using a combination of a patchbased CNN and a random forest classification that is trained on hand-crafted features.…”

Section: Introductionmentioning

confidence: 99%

Dense Dilated Convolutions’ Merging Network for Land Cover Classification

Liu

Kampffmeyer

Jenssen

et al. 2020

IEEE Trans. Geosci. Remote Sensing

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Land cover classification of remote sensing images is a challenging task due to limited amounts of annotated data, highly imbalanced classes, frequent incorrect pixel-level annotations, and an inherent complexity in the semantic segmentation task. In this work, we propose a novel architecture called the Dense Dilated Convolutions Merging Network (DDCM-Net) to address this task. The proposed DDCM-Net consists of dense dilated image convolutions merged with varying dilation rates. This effectively utilizes rich combinations of dilated convolutions that enlarge the network's receptive fields with less parameters and features compared to the state-of-the-art approaches in the remote sensing domain. Importantly, DDCM-Net obtains fused local and global context information, in effect incorporating surrounding discriminative capability for multi-scale and complex shaped objects with similar color and textures in very high resolution aerial imagery. We demonstrate the effectiveness, robustness and flexibility of the proposed DDCM-Net on the publicly available ISPRS Potsdam and Vaihingen data, as well as the DeepGlobe land cover dataset. Our single model, trained on 3-band Potsdam and Vaihingen data, achieves better accuracy in terms of both mean intersection over union (mIoU) and F1-score compared to other published models trained with more than 3band data. We further validate our model on the DeepGlobe dataset, achieving state-of-the-art result 56.2% mIoU with much less parameters and at a lower computational cost compared to related recent work.

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“…As CRFs have the ability to capture both local and long-range dependencies within an image, they significantly improve CNN segmentation results [59]. The existing CRFs, such as the fully connected CRF modeling processes, are complicated and require a large number of calculations [60]. 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].…”

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

Remote Sensing

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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.

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Semantic segmentation of multisensor remote sensing imagery with deep ConvNets and higher-order conditional random fields

Cited by 29 publications

References 44 publications

Post-Disaster Building Database Updating Using Automated Deep Learning: An Integration of Pre-Disaster OpenStreetMap and Multi-Temporal Satellite Data

Post-Disaster Building Database Updating Using Automated Deep Learning: An Integration of Pre-Disaster OpenStreetMap and Multi-Temporal Satellite Data

Dense Dilated Convolutions’ Merging Network for Land Cover Classification

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

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