Presentation of Robust Method in Image Contrast Enhancement Using Particle Swarm Optimization

Abstract-One of the most important processes in digital image processing is image contrast enhancement. Contrast enhancement may be itself a primary objective of the process or is performed as one of the pre-processing stages in order to obtain better quality for operating next major stages such as detection. In this thesis, multiobjective developed Particle Swarm Optimization (PSO) algorithm use to enhance gray digital image contrast so that image information content is maximized and also the mean intensity of the image is preserved as much as possible. The proposed method will be implemented on different images

Enhancing digital cephalic radiography with mixture models and local gamma correction

We present a new algorithm, called the soft-tissue filter, that can make both soft and bone tissue clearly visible in digital cephalic radiographies under a wide range of exposures. It uses a mixture model made up of two Gaussian distributions and one inverted lognormal distribution to analyze the image histogram. The image is clustered in three parts: background, soft tissue, and bone using this model. Improvement in the visibility of both structures is achieved through a local transformation based on gamma correction, stretching, and saturation, which is applied using different parameters for bone and soft-tissue pixels. A processing time of 1 s for 5 Mpixel images allows the filter to operate in real time. Although the default value of the filter parameters is adequate for most images, real-time operation allows adjustment to recover under- and overexposed images or to obtain the best quality subjectively. The filter was extensively clinically tested: quantitative and qualitative results are reported here

Enhancing digital cephalic radiography with mixture models and local gamma correction

We present a new algorithm, called the soft-tissue filter, that can make both soft and bone tissue clearly visible in digital cephalic radiographies under a wide range of exposures. It uses a mixture model made up of two Gaussian distributions and one inverted lognormal distribution to analyze the image histogram. The image is clustered in three parts: background, soft tissue, and bone using this model. Improvement in the visibility of both structures is achieved through a local transformation based on gamma correction, stretching, and saturation, which is applied using different parameters for bone and soft-tissue pixels. A processing time of 1 s for 5 M pixel images allows the filter to operate in real time. Although the default value of the filter parameters is adequate for most images, real-time operation allows adjustment to recover under- and overexposed images or to obtain the best quality subjectively. The filter was extensively clinically tested: quantitative and qualitative results are reported here