Analysis of SSIM based Quality Assessment across Color Channels of Images

Analysis of SSIM based Quality Assessment across Color Channels of Images

T. Chandrakanth (Department of Computer Science and Engineering, M.V.S.R Engineering College, Nadargul, India) and B. Sandhya (Department of Computer Science and Engineering, M.V.S.R Engineering College, Nadargul, India)
Copyright: © 2015 |Pages: 13
DOI: 10.4018/IJSDA.2015070102
OnDemand PDF Download:
No Current Special Offers


Advances in imaging and computing hardware have led to an explosion in the use of color images in image processing, graphics and computer vision applications across various domains such as medical imaging, satellite imagery, document analysis and biometrics to name a few. However, these images are subjected to a wide variety of distortions during its acquisition, subsequent compression, transmission, processing and then reproduction, which degrade their visual quality. Hence objective quality assessment of color images has emerged as one of the essential operations in image processing. During the last two decades, efforts have been put to design such an image quality metric which can be calculated simply but can accurately reflect subjective quality of human perception. In this paper, the authors evaluated the quality assessment of color images using SSIM (structural similarity index) metric across various color spaces. They experimented to study the effect of color spaces in metric based and distance based quality assessment. The authors proposed a metric using CIE Lab color space and SSIM, which has better correlation to the subjective assessment in a benchmark dataset.
Article Preview

2. Previous Work

Identifying the image quality measures that have highest sensitivity to distortions would help systematic design of coding, communication and imaging systems and of improving or optimizing the picture quality for a desired quality of service at a minimum cost. Image quality measurement basically consists of two approaches: Subjective measurements and Objective measurements.

Figure 1 shows the classification of IQA measures. Subjective measurements are the result of human experts providing their opinion of the image quality and objective measurements are performed with mathematical algorithms. The goal of research in objective image quality assessment is to develop quantitative measures that can automatically predict perceived image quality (VQEG, 2000). An objective image quality metric can play a variety of roles in image processing applications. It can be used to dynamically monitor and adjust image quality. It can be used to optimize algorithms and parameter settings of image processing systems. It can be used to benchmark image processing systems and algorithms (Pappas et al.,2000).

Figure 1.

Classification of image assessment


In full-reference image quality assessment methods, the quality of a reproduced image is evaluated by comparing it with the original image that is assumed to have perfect quality. In reduced-reference image quality assessment methods, limited information are available for both reproduced image and original image to evaluate the quality of the test images. No-reference metrics try to assess the quality of an image without any reference to the original one.

Complete Article List

Search this Journal:
Volume 11: 5 Issues (2022)
Volume 10: 4 Issues (2021)
Volume 9: 4 Issues (2020)
Volume 8: 4 Issues (2019)
Volume 7: 4 Issues (2018)
Volume 6: 4 Issues (2017)
Volume 5: 4 Issues (2016)
Volume 4: 4 Issues (2015)
Volume 3: 4 Issues (2014)
Volume 2: 4 Issues (2013)
Volume 1: 4 Issues (2012)
View Complete Journal Contents Listing