Random walks on graphs to model saliency in images

Gopalakrishnan, Viswanath; Hu, Yiqun; Rajan, Dinesh

doi:10.1109/cvpr.2009.5206767

Cited by 89 publications

(41 citation statements)

References 10 publications

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“…In Hou and Zhang [5], the gist of the scene is represented with the average Fourier envelope and the differential spectral components are used to extract salient regions. This is replaced by the phase spectrum of the Fourier transform in [34] because it is more effective and computationally efficient. Some researchers including Bruce and Tsotsos [4] and Zhang et al [10] attempted to define visual saliency based on information theory.…”

Section: Related Workmentioning

confidence: 99%

Salient Object Detection: A Benchmark

Borji

Sihite

Itti

2012

Lecture Notes in Computer Science

636

768

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Abstract. Several salient object detection approaches have been published which have been assessed using different evaluation scores and datasets resulting in discrepancy in model comparison. This calls for a methodological framework to compare existing models and evaluate their pros and cons. We analyze benchmark datasets and scoring techniques and, for the first time, provide a quantitative comparison of 35 stateof-the-art saliency detection models. We find that some models perform consistently better than the others. Saliency models that intend to predict eye fixations perform lower on segmentation datasets compared to salient object detection algorithms. Further, we propose combined models which show that integration of the few best models outperforms all models over other datasets. By analyzing the consistency among the best models and among humans for each scene, we identify the scenes where models or humans fail to detect the most salient object. We highlight the current issues and propose future research directions.

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Section: Related Workmentioning

confidence: 99%

Salient Object Detection: A Benchmark

Borji

Sihite

Itti

2012

Lecture Notes in Computer Science

636

768

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show abstract

“…However, such propagations may incur errors if the unlabeled adjacent superpixels are inhomogeneous or very dissimilar to the labeled ones. For example, [7] and [10] formulate the saliency propagation process as random walks on the graph. [21] and [27] conduct the propagations by employing personalized PageRank [29] and manifold based diffusion [29], respectively.…”

Section: Introductionmentioning

confidence: 99%

Saliency propagation from simple to difficult

Gong

Tao

Liu³

et al. 2015

2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR)

131

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“…Visual saliency models selecting the most salient region in an image are based on, among others, local contrast, 24 entropy, 25 and graph-based random walks. 26,27 High-contrast regions have maximum information and hence higher entropy. 25 Regions with high classification uncertainty also have high entropy, indicating a correspondence between information content of salient regions and classification uncertainty.…”

Section: Active Learning Query Strategymentioning

confidence: 99%

Visual saliency-based active learning for prostate magnetic resonance imaging segmentation

Mahapatra

Buhmann

2016

J. Med. Imag

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Abstract. We propose an active learning (AL) approach for prostate segmentation from magnetic resonance images. Our label query strategy is inspired from the principles of visual saliency that have similar considerations for choosing the most salient region. These similarities are encoded in a graph using classification maps and lowlevel features. Random walks are used to identify the most informative node, which is equivalent to the label query sample in AL. To reduce computation time, a volume of interest (VOI) is identified and all subsequent analysis, such as probability map generation using semisupervised random forest classifiers and label query, is restricted to this VOI. The negative log-likelihood of the probability maps serves as the penalty cost in a second-order Markov random field cost function, which is optimized using graph cuts for prostate segmentation. Experimental results on the Medical Image Computing and Computer Assisted Intervention (MICCAI) 2012 prostate segmentation challenge show the superior performance of our approach to conventional methods using fully supervised learning.

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Random walks on graphs to model saliency in images

Cited by 89 publications

References 10 publications

Salient Object Detection: A Benchmark

Salient Object Detection: A Benchmark

Saliency propagation from simple to difficult

Visual saliency-based active learning for prostate magnetic resonance imaging segmentation

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