Showing total 3 results

1. Co-Salient Object Detection Based on Deep Saliency Networks and Seed Propagation Over an Integrated Graph.

Author

Jeong, Dong-ju, Hwang, Insung, and Cho, Nam Ik

Subjects

OBJECT recognition (Computer vision), SEMANTICS, FEATURE extraction, GRAPH theory, SUPERVISED learning

Abstract

This paper presents a co-salient object detection method to find common salient regions in a set of images. We utilize deep saliency networks to transfer co-saliency prior knowledge and better capture high-level semantic information. The resulting initial co-saliency maps are enhanced by seed propagation steps over an integrated graph. The deep saliency networks are trained in a supervised manner to avoid weakly supervised online learning and exploit them not only to extract high-level features but also to produce both intra- and inter-image saliency maps. Through a refinement step, the initial co-saliency maps can uniformly highlight co-salient regions and locate accurate object boundaries. To handle input image groups inconsistent in size, we propose to pool multi-regional descriptors including both within-segment and within-group information. In addition, the integrated multilayer graph is constructed to find the regions that the previous steps may not detect by seed propagation with low-level descriptors. In this paper, we utilize the useful complementary components of high- and low-level information and several learning-based steps. Our experiments have demonstrated that the proposed approach outperforms comparable co-saliency detection methods on widely used public databases and can also be directly applied to co-segmentation tasks. [ABSTRACT FROM AUTHOR]

Published

2018

2. A Co-Saliency Model of Image Pairs.

Author

Li, Hongliang and Ngan, King Ngi

Subjects

IMAGE registration, FEATURE extraction, ALGORITHMS, PYRAMIDS (Geometry), IMAGE segmentation, SIMILARITY (Geometry), IMAGE processing, PERFORMANCE evaluation

Abstract

In this paper, we introduce a method to detect co-saliency from an image pair that may have some objects in common. The co-saliency is modeled as a linear combination of the single-image saliency map (SISM) and the multi-image saliency map (MISM). The first term is designed to describe the local attention, which is computed by using three saliency detection techniques available in literature. To compute the MISM, a co-multilayer graph is constructed by dividing the image pair into a spatial pyramid representation. Each node in the graph is described by two types of visual descriptors, which are extracted from a representation of some aspects of local appearance, e.g., color and texture properties. In order to evaluate the similarity between two nodes, we employ a normalized single-pair SimRank algorithm to compute the similarity score. Experimental evaluation on a number of image pairs demonstrates the good performance of the proposed method on the co-saliency detection task. [ABSTRACT FROM AUTHOR]

Published

2011

3. Cluster-Based Co-Saliency Detection.

Author

Fu, Huazhu, Cao, Xiaochun, and Tu, Zhuowen

Subjects

SUPERVISED learning, VISUAL perception, HISTOGRAMS, K-means clustering, PIXELS, RECEPTIVE fields (Neurology)

Abstract

Co-saliency is used to discover the common saliency on the multiple images, which is a relatively underexplored area. In this paper, we introduce a new cluster-based algorithm for co-saliency detection. Global correspondence between the multiple images is implicitly learned during the clustering process. Three visual attention cues: contrast, spatial, and corresponding, are devised to effectively measure the cluster saliency. The final co-saliency maps are generated by fusing the single image saliency and multiimage saliency. The advantage of our method is mostly bottom-up without heavy learning, and has the property of being simple, general, efficient, and effective. Quantitative and qualitative experiments result in a variety of benchmark datasets demonstrating the advantages of the proposed method over the competing co-saliency methods. Our method on single image also outperforms most the state-of-the-art saliency detection methods. Furthermore, we apply the co-saliency method on four vision applications: co-segmentation, robust image distance, weakly supervised learning, and video foreground detection, which demonstrate the potential usages of the co-saliency map. [ABSTRACT FROM PUBLISHER]

Published

2013