Background Subtraction Based on Low-Rank and Structured Sparse Decomposition

Liu, Xin; Zhao, Guoying; Yao, Jiawen; Qi, Chun

doi:10.1109/tip.2015.2419084

Cited by 217 publications

(126 citation statements)

References 35 publications

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“…[22] and WallFlower [21] results: top row is the original image, second row is the ground truth, the third row is our unrefined results with no post-processing. We used the same frames as [24], [13], [25], [26], [27], and [28], for qualitative comparison. [29] .0903 (10) .2574 (9) .4473 (10) .4344 (10) .3602 (10) .6554 (8) .5713 (7) .3561 (10) .2751 (9) .3830 (10) Stauffer [30] .7570 (5) .6854 (6) .7948 (7) .7580 (8) .6519 (6) .5363 (10) .3335 (10) .3838 (9) .1388 (10) .4842 (9) Culibrk [27] .5256 (7) .4636 (8) .7540 (8) .7368 (9) .6276 (9) .5696 (9) .3923 (9) .4779 (8) .4928 (8) .5600 (8) DECOLOR [7] .3416 (9) .2075 (10) .9022 (5) .8700 (4) .646 (8) .6822 (5) .8169 (3) .6589 (4) .7480 …”

Section: Resultsmentioning

confidence: 99%

“…Structural information about nonzero patterns of variables have been developed and used in sparse signal recovery, and many approaches have been applied to these problems successfully, such as Lattice Matching Pursuit (LaMP) [8], Dynamic Group Sparsity (DGS) recovery [9], Bayesian Robust Matrix Factorization (BRMF) [10],and the Proximal Operator using Network Flow (ProxFlow) [11]. However, the majority of related methods [12], [13] typically assume that the block structure and its location is known or will suffer in regularization or bootstrapping. In contrast, our method does not assume a prior size or location or structure for sparsity, and dynamically updates these to best fit the natural object shape in the scene, without a separate training phase.…”

Section: Related Workmentioning

confidence: 99%

See 1 more Smart Citation

Dynamic tree-structured sparse RPCA via column subset selection for background modeling and foreground detection

Ebadi

Ones

Izquierdo

2016

2016 IEEE International Conference on Image Processing (ICIP)

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Video analysis often begins with background subtraction, which consists of creation of a background model that allows distinguishing foreground pixels. Recent evaluation of background subtraction techniques demonstrated that there are still considerable challenges facing these methods. Processing per-pixel basis from the background is not only time-consuming but also can dramatically affect foreground region detection, if region cohesion and contiguity is not considered in the model. We present a new method in which we regard the image sequence to be made up of the sum of a low-rank background matrix and a dynamic tree-structured sparse matrix, and solve the decomposition using our approximated Robust Principal Component Analysis method extended to handle camera motion. Furthermore, to reduce the curse of dimensionality and scale, we introduce a low-rank background modeling via Column Subset Selection that reduces the order of complexity, decreases computation time, and eliminates the huge storage need for large videos.

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Section: Resultsmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Dynamic tree-structured sparse RPCA via column subset selection for background modeling and foreground detection

Ebadi

Ones

Izquierdo

2016

2016 IEEE International Conference on Image Processing (ICIP)

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“…i2R results: top row is the original image, second row is the ground truth, and the last row is our unrefined results without post-processing. We used the same frames as [15,16,[22][23][24][25], for qualitative comparison.…”

Section: Qualitative Resultsmentioning

confidence: 99%

“…The authors of [14] used a two-pass RPCA framework, in which the first pass generates a saliency map that corresponds to locations of the outliers, and then the second pass uses pre-defined salient blocks in the image, to favor spatially contiguous outliers. In another effort [15] used a group sparse structure, in which overlapping pre-defined groups of pixels in a region of an image are used in conjunction with a maximum norm regularization to take into account the spatial connection of foreground regions. In a recent work [16] a superpixel-based max-norm matrix decomposition approach has been proposed, in which homogeneous static or dynamic regions of image are classified as a graph partitioning problem, via Generalized Fused Lasso.…”

Section: Related Workmentioning

confidence: 99%

Foreground Segmentation via Dynamic Tree-Structured Sparse RPCA

Ebadi

Izquierdo

2016

Computer Vision – ECCV 2016

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Abstract. Video analysis often begins with background subtraction which consists of creation of a background model, followed by a regularization scheme. Recent evaluation of representative background subtraction techniques demonstrated that there are still considerable challenges facing these methods. We present a new method in which we regard the image sequence as being made up of the sum of a low-rank background matrix and a dynamic tree-structured sparse outlier matrix and solve the decomposition using our approximated Robust Principal Component Analysis method extended to handle camera motion. Our contribution lies in dynamically estimating the support of the foreground regions via a superpixel generation step, so as to impose spatial coherence on these regions, and to obtain crisp and meaningful foreground regions. These advantages enable our method to outperform state-of-the-art alternatives in three benchmark datasets.

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“…Image segmentation is the premise of image analysis, 15,16 which is key to extract the image features and identify the defects. The maximum interclass variance method (OTSU) is used to segment the insulators; we find that it is difficult for the segmentation by OTSU in RGB space to identify the insulators under the complex background, as shown in Fig.…”

Section: Identification Of Glass Insulator Stringmentioning

confidence: 99%

Automatic identification and location technology of glass insulator self-shattering

Huang

Zhang

2017

J. Electron. Imaging

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Abstract. The insulator of transmission lines is one of the most important infrastructures, which is vital to ensure the safe operation of transmission lines under complex and harsh operating conditions. The glass insulator often self-shatters but the available identification methods are inefficient and unreliable. Then, an automatic identification and localization technology of self-shattered glass insulators is proposed, which consists of the cameras installed on the tower video monitoring devices or the unmanned aerial vehicles, the 4G/OPGW network, and the monitoring center, where the identification and localization algorithm is embedded into the expert software. First, the images of insulators are captured by cameras, which are processed to identify the region of insulator string by the presented identification algorithm of insulator string. Second, according to the characteristics of the insulator string image, a mathematical model of the insulator string is established to estimate the direction and the length of the sliding blocks. Third, local binary pattern histograms of the template and the sliding block are extracted, by which the self-shattered insulator can be recognized and located. Finally, a series of experiments is fulfilled to verify the effectiveness of the algorithm. For single insulator images, Ac, Pr , and Rc of the algorithm are 94.5%, 92.38%, and 96.78%, respectively. For double insulator images, Ac, Pr , and Rc are 90.00%, 86.36%, and 93.23%, respectively.

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Background Subtraction Based on Low-Rank and Structured Sparse Decomposition

Cited by 217 publications

References 35 publications

Dynamic tree-structured sparse RPCA via column subset selection for background modeling and foreground detection

Dynamic tree-structured sparse RPCA via column subset selection for background modeling and foreground detection

Foreground Segmentation via Dynamic Tree-Structured Sparse RPCA

Automatic identification and location technology of glass insulator self-shattering

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