Showing total 5 results

1. An Entropy Interpretation of the Logarithmic Image Processing Model With Application to Contrast Enhancement.

Author

Guang Deng

Subjects

INFORMATION processing, IMAGING systems, COMPUTER graphics, IMAGE processing, ERGODIC theory, COMPUTER vision

Abstract

The logarithmic image processing (LIP) model is a mathematical theory that provides new operations for image processing. The contrast definition has been shown to be consistent with some important physical laws and characteristics of human visual system. In this paper, we establish an information-theoretic interpretation of the contrast definition. We show that it can be expressed as a combination of the relative entropy and Shannon's information content. Based on this new interpretation, we propose an adaptive algorithm for enhancing the contrast and sharpness of noisy images. [ABSTRACT FROM AUTHOR]

Published

2009

2. Edge Grouping Combining Boundary and Region Information.

Author

Stahl, Joachim S. and Song Wang

Subjects

IMAGE processing, IMAGE reconstruction, IMAGING systems, COMPUTER vision, COMPUTER graphics, INFORMATION processing, INFORMATION technology, PHOTOGRAPHS, DIGITAL images

Abstract

This paper introduces a new edge-grouping method to detect perceptually salient structures in noisy images. Specifically, we define a new grouping cost function in a ratio form, where the numerator measures the boundary proximity of the resulting structure and the denominator measures the area of the resulting structure. This area term introduces a preference towards detecting larger-size structures and, therefore, makes the resulting edge grouping more robust to image noise. To find the optimal edge grouping with the minimum grouping cost, we develop a special graph model with two different kinds of edges and then reduce the grouping problem to finding a special kind of cycle in this graph with a minimum cost in ratio form. This optimal cycle-finding problem can be solved in polynomial time by a previously developed graph algorithm. We implement this edge-grouping method, test it on both synthetic data and real images, and compare its performance against several available edge-grouping and edge-linking methods. Furthermore, we discuss several extensions of the proposed method, including the incorporation of the well-known grouping cues of continuity and intensity homogeneity, introducing a factor to balance the contributions from the boundary and region information, and the prevention of detecting self-intersecting boundaries. [ABSTRACT FROM AUTHOR]

Published

2007

3. Self-Similar Random Field Models in Discrete Space.

Author

Seungsin Lee and Rao, Raghuveer M.

Subjects

IMAGE processing, INFORMATION processing, COMPUTER vision, STOCHASTIC processes, RANDOM fields, COMPUTER graphics

Abstract

Self-similar random fields are of interest in various areas of image processing since they fit certain types of natural pat- terns and textures. Current treatments of self-similarity in continuous two-dimensional (2-D) space use a definition that is a direct extension of the one-dimensional definition, which requires invariance of the statistics of a random process to time scaling. Current discrete-space 2-D approaches do not consider scaling, but, instead, are based on ad hoc formulations, such as digitizing continuous random fields. In this paper, we show that the current statistical self-similarity definition in continuous space is restrictive and provide an alternative, more general definition. We also provide a formalism for discrete-space statistical self-similarity that relies on a new scaling operator for discrete images. Within the new framework, it is possible to synthesize a wider class of discrete-space self-similar random fields and texture images. [ABSTRACT FROM AUTHOR]

Published

2006

4. Distance Regularized Level Set Evolution and Its Application to Image Segmentation.

Author

Li, Chunming, Xu, Chenyang, Gui, Changfeng, and Fox, Martin D.

Subjects

IMAGE analysis, IMAGE processing, COMPUTER vision, MATHEMATICAL models, INFORMATION processing, IMAGING systems, COMPUTER graphics, LEVEL set methods

Abstract

Level set methods have been widely used in image processing and computer vision. In conventional level set formulations, the level set function typically develops irregularities during its evolution, which may cause numerical errors and eventually destroy the stability of the evolution. Therefore, a numerical remedy, called reinitialization, is typically applied to periodically replace the degraded level set function with a signed distance function. However, the practice of reinitialization not only raises serious problems as when and how it should be performed, but also affects numerical accuracy in an undesirable way. This paper proposes a new variational level set formulation in which the regularity of the level set function is intrinsically maintained during the level set evolution. The level set evolution is derived as the gradient flow that minimizes an energy functional with a distance regularization term and an external energy that drives the motion of the zero level set toward desired locations. The distance regularization term is defined with a potential function such that the derived level set evolution has a unique forward-and-backward (FAB) diffusion effect, which is able to maintain a desired shape of the level set function, particularly a signed distance profile near the zero level set. This yields a new type of level set evolution called distance regularized level set evolution (DRLSE). The distance regularization effect eliminates the need for reinitialization and thereby avoids its induced numerical errors. In contrast to complicated implementations of conventional level set formulations, a simpler and more efficient finite difference scheme can be used to implement the DRLSE formulation. DRLSE also allows the use of more general and efficient initialization of the level set function. In its numerical implementation, relatively large time steps can be used in the finite difference scheme to reduce the number of iterations, while ensuring sufficient numerical accuracy. To demonstrate the effectiveness of the DRLSE formulation, we apply it to an edge-based active contour model for image segmentation, and provide a simple narrowband implementation to greatly reduce computational cost. [ABSTRACT FROM AUTHOR]

Published

2010

5. A Self-Organizing Approach to Background Subtraction for Visual Surveillance Applications.

Author

Maddalena, Lucia and Petrosino, Alfredo

Subjects

ARTIFICIAL neural networks, IMAGING systems, PATTERN recognition systems, INFORMATION processing, COMPUTER vision, STREAMING technology, IMAGE processing, COMPUTER graphics, ELECTRONIC surveillance

Abstract

Detection of moving objects in video streams is the first relevant step of information extraction in many computer vision applications. Aside from the intrinsic usefulness of being able to segment video streams into moving and background components, detecting moving objects provides a focus of attention for recognition, classification, and activity analysis, making these later steps more efficient. We propose an approach based on self organization through artificial neural networks, widely applied in human image processing systems and more generally in cognitive science. The proposed approach can handle scenes containing moving backgrounds, gradual illumination variations and camouflage, has no bootstrapping limitations, can include into the background model shadows cast by moving objects, and achieves robust detection for different types of videos taken with stationary cameras. We compare our method with other modeling techniques and report experimental results, both in terms of detection accuracy and in terms of processing speed, for color video sequences that represent typical situations critical for video surveillance systems. [ABSTRACT FROM AUTHOR]

Published

2008