PoseShop: Human Image Database Construction and Personalized Content Synthesis

Chen, Tao; Tan, Ping; Ma, Liqian; Cheng, Ming–Ming; Shamir, Ariel; Hu, Shi‐Min

doi:10.1109/tvcg.2012.148

Cited by 62 publications

(41 citation statements)

References 58 publications

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“…This kind of decomposition is a key component of many computer vision and graphics tasks. Rather than focusing on predicting human fixation points [6,32] (another major research direction of visual attention modeling), salient region detection methods aim at uniformly highlighting entire salient object regions, thus benefiting a large number of applications, including objectof-interest image segmentation [19], adaptive compression [17], object recognition [44], content aware image editing [51], object level image manipulation [12,15,53], and internet visual media retrieval [10,11,13,29,24,23].…”

Section: Introductionmentioning

confidence: 99%

Efficient Salient Region Detection with Soft Image Abstraction

Cheng

Warrell

Lin

et al. 2013

2013 IEEE International Conference on Computer Vision

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474

317

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Section: Introductionmentioning

confidence: 99%

Efficient Salient Region Detection with Soft Image Abstraction

Cheng

Warrell

Lin

et al. 2013

2013 IEEE International Conference on Computer Vision

Self Cite

474

317

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“…Exploiting this fact, visual saliency computation has been widely used in applications such as image segmentation [25], adaptive compression [26], and image retrieval [27]. Since all color quantization methods inevitably introduce approximation, it is reasonable to give priority to salient regions, while pushing the approximation error to the less important regions.…”

Section: Saliency Detectionmentioning

confidence: 99%

Efficient, Edge-Aware, Combined Color Quantization and Dithering

Huang

Martin

et al. 2016

IEEE Trans. on Image Process.

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Abstract-In this paper we present a novel algorithm to simultaneously accomplish color quantization and dithering of images. This is achieved by minimizing a perception-based cost function which considers pixel-wise differences between filtered versions of the quantized image and the input image. We use edge aware filters in defining the cost function to avoid mixing colors on opposite sides of an edge. The importance of each pixel is weighted according to its saliency. To rapidly minimize the cost function, we use a modified multi-scale iterative conditional mode (ICM) algorithm which updates one pixel a time while keeping other pixels unchanged. As ICM is a local method, careful initialization is required to prevent termination at a local minimum far from the global one. To address this problem, we initialize ICM with a palette generated by a modified mediancut method. Compared to previous approaches, our method can produce high quality results with fewer visual artifacts but also requires significantly less computational effort.Index Terms-Color quantization, dithering, optimizationbased image processing.

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“…All such methods compare user sketches with image edges (or boundaries), suffering from influence of background edges when finding a desired object. Salient object region extraction [11,12,34] and multiresolution region representation [32] have been used to handle background clutter. We also use explicit region information to support SBIR.…”

Section: Sketch Based Image Retrieval (Sbir)mentioning

confidence: 99%

“…Determining characteristic or salient regions of images allows transitioning from low-level pixels to more meaningful high-level regions, and thus form an essential step for many computer graphics and computer vision applications, including interactive image editing [14,16,41,51,53], image retrieval [12,27,28,30], and internet visual media processing [11,33,34,40]. Recently, significant success has been reported in saliency-based image segmentation producing near ground-truth performance on simple images ( [1,13,15,41] and references therein).…”

Section: Introductionmentioning

confidence: 99%

SalientShape: group saliency in image collections

et al. 2013

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Efficiently identifying salient objects in large image collections is essential for many applications including image retrieval, surveillance, image annotation, and object recognition. We propose a simple, fast, and effective algorithm for locating and segmenting salient objects by analysing image collections. As a key novelty, we introduce group saliency to achieve superior unsupervised salient object segmentation by extracting salient objects (in collections of pre-filtered images) that maximize between-image similarities and within-image distinctness. To evaluate our method, we construct a large benchmark dataset consisting of 15 K images across multiple categories with 6000+ pixel-accurate ground truth annotations for salient object regions where applicable. In all our tests, group saliency consistently outperforms state-of-the-art single-image saliency algorithms, resulting in both higher precision and better recall. Our algorithm successfully handles image collections, of an order larger than any existing benchmark datasets, consisting of diverse and heterogeneous images from various internet sources.

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PoseShop: Human Image Database Construction and Personalized Content Synthesis

Cited by 62 publications

References 58 publications

Efficient Salient Region Detection with Soft Image Abstraction

Efficient Salient Region Detection with Soft Image Abstraction

Efficient, Edge-Aware, Combined Color Quantization and Dithering

SalientShape: group saliency in image collections

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