Semantic Image Segmentation via Deep Parsing Network

Liu, Ziwei; Li, Xiaoxiao; Luo, Ping; Loy, Chen Change; Tang, Xiaoou

doi:10.1109/iccv.2015.162

Cited by 604 publications

(400 citation statements)

References 38 publications

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“…More recently, deep learning techniques have been adopted in brain tumor segmentation studies following their success in general image analysis fields, such as images classification (Krizhevsky et al, 2012), objects detection (Girshick et al, 2014), and semantic segmentation (Long et al, 2015 ; Zheng et al, 2015 ; Liu et al, 2015). Particularly, Convolutional Neural Networks (CNNs) were adopted for brain tumor image segmentation in the Multimodal Brain Tumor Image Segmentation Challenge (BRATS) 2014 (Zikic et al, 2014 ; Davy et al, 2014 ; Urban et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…To take the local dependencies of labels into account, Havaei et al constructed a cascaded architecture by taking the pixel-wise probability segmentation results obtained by CNNs trained at early stages as additional input to their following CNNs (Havaei et al, 2015, 2017). To take into consideration appearance and spatial consistency of the segmentation results, Markov Random Fields (MRFs), particularly Conditional Random Fields (CRFs), have been integrated with deep learning techniques in image segmentation studies, either used as a post-process step of CNNs (Kamnitsas et al, 2017 ; Chen et al, 2014) or formulated as neural networks (Zheng et al, 2015 ; Liu et al, 2015). In the latter setting, both CNNs and MRFs/CRFs can be trained with back-propagation algorithms, tending to achieve better segmentation performance.…”

Section: Introductionmentioning

confidence: 99%

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A deep learning model integrating FCNNs and CRFs for brain tumor segmentation

Zhao

Song

et al. 2018

Medical Image Analysis

655

336

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Accurate and reliable brain tumor segmentation is a critical component in cancer diagnosis, treatment planning, and treatment outcome evaluation. Build upon successful deep learning techniques, a novel brain tumor segmentation method is developed by integrating fully convolutional neural networks (FCNNs) and Conditional Random Fields (CRFs) in a unified framework to obtain segmentation results with appearance and spatial consistency. We train a deep learning based segmentation model using 2D image patches and image slices in following steps: 1) training FCNNs using image patches; 2) training CRFs as Recurrent Neural Networks (CRF-RNN) using image slices with parameters of FCNNs fixed; and 3) fine-tuning the FCNNs and the CRF-RNN using image slices. Particularly, we train 3 segmentation models using 2D image patches and slices obtained in axial, coronal and sagittal views respectively, and combine them to segment brain tumors using a voting based fusion strategy. Our method could segment brain images slice-by-slice, much faster than those based on image patches. We have evaluated our method based on imaging data provided by the Multimodal Brain Tumor Image Segmentation Challenge (BRATS) 2013, BRATS 2015 and BRATS 2016. The experimental results have demonstrated that our method could build a segmentation model with Flair, T1c, and T2 scans and achieve competitive performance as those built with Flair, T1, T1c, and T2 scans.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A deep learning model integrating FCNNs and CRFs for brain tumor segmentation

Zhao

Song

et al. 2018

Medical Image Analysis

655

336

View full text Add to dashboard Cite

show abstract

“…Our previous study [7] only shows the possibility on 2-Dimension image segmentation problem. Specifically, we employ dynamic node linking to construct graph in N -D space, which results in a model of N -D high-order MRF.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Markov Random Field for Semantic Segmentation

Liu

Luo

et al. 2018

IEEE Trans. Pattern Anal. Mach. Intell.

Self Cite

151

110

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Abstract-Semantic segmentation tasks can be well modeled by Markov Random Field (MRF). This paper addresses semantic segmentation by incorporating high-order relations and mixture of label contexts into MRF. Unlike previous works that optimized MRFs using iterative algorithm, we solve MRF by proposing a Convolutional Neural Network (CNN), namely Deep Parsing Network (DPN), which enables deterministic end-to-end computation in a single forward pass. Specifically, DPN extends a contemporary CNN to model unary terms and additional layers are devised to approximate the mean field (MF) algorithm for pairwise terms. It has several appealing properties. First, different from the recent works that required many iterations of MF during back-propagation, DPN is able to achieve high performance by approximating one iteration of MF. Second, DPN represents various types of pairwise terms, making many existing models as its special cases. Furthermore, pairwise terms in DPN provide a unified framework to encode rich contextual information in high-dimensional data, such as images and videos. Third, DPN makes MF easier to be parallelized and speeded up, thus enabling efficient inference. DPN is thoroughly evaluated on standard semantic image/video segmentation benchmarks, where a single DPN model yields state-of-the-art segmentation accuracies on PASCAL VOC 2012, Cityscapes dataset and CamVid dataset.

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“…Image segmentation is a fundamental technique in image processing [42] and is the premise of object recognition and image interpretation. An image-segmentation problem typically involves extracting the consistent region and objects of interest from an image-processing process [43].…”

Section: Analysis Of Effect Of Coarse-segmentation Methods On Recognitmentioning

confidence: 99%

Recognition of Wheat Spike from Field Based Phenotype Platform Using Multi-Sensor Fusion and Improved Maximum Entropy Segmentation Algorithms

et al. 2018

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Abstract:To obtain an accurate count of wheat spikes, which is crucial for estimating yield, this paper proposes a new algorithm that uses computer vision to achieve this goal from an image. First, a home-built semi-autonomous multi-sensor field-based phenotype platform (FPP) is used to obtain orthographic images of wheat plots at the filling stage. The data acquisition system of the FPP provides high-definition RGB images and multispectral images of the corresponding quadrats. Then, the high-definition panchromatic images are obtained by fusion of three channels of RGB. The Gram-Schmidt fusion algorithm is then used to fuse these multispectral and panchromatic images, thereby improving the color identification degree of the targets. Next, the maximum entropy segmentation method is used to do the coarse-segmentation. The threshold of this method is determined by a firefly algorithm based on chaos theory (FACT), and then a morphological filter is used to de-noise the coarse-segmentation results. Finally, morphological reconstruction theory is applied to segment the adhesive part of the de-noised image and realize the fine-segmentation of the image. The computer-generated counting results for the wheat plots, using independent regional statistical function in Matlab R2017b software, are then compared with field measurements which indicate that the proposed method provides a more accurate count of wheat spikes when compared with other traditional fusion and segmentation methods mentioned in this paper.

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Semantic Image Segmentation via Deep Parsing Network

Cited by 604 publications

References 38 publications

A deep learning model integrating FCNNs and CRFs for brain tumor segmentation

A deep learning model integrating FCNNs and CRFs for brain tumor segmentation

Deep Learning Markov Random Field for Semantic Segmentation

Recognition of Wheat Spike from Field Based Phenotype Platform Using Multi-Sensor Fusion and Improved Maximum Entropy Segmentation Algorithms

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