Paper
24 September 2011 From index to metric: using differential geometry to define a global visual quality metric
Thomas Richter
Author Affiliations +
Abstract
While traditional image quality metrics like MSE are mathematically well understood and tractable, they are known to correlate weakly to image distortion as observed by human observers. To address this situation, many full reference quality indices have been suggested over the years that correlate better to human perception, one of them being the well-known Structural Similarity Index by Wang and Bovik. However, while these expressions show higher correlations, they are often not very tractable mathematically, and in specific are rarely metrics in the strict mathematical sense. Specifically, the triangle inequality is often not satisfied, which could either be seen as an effect of the human visual system being unable to compare images that are visually too different, or as a defect of the index capturing the global situation correctly. In this article, the latter position is taken, and it is shown how the SSIM can be understood as a local approximation of a global metric, namely the geodesic distance on a manifold. While the metric cannot be computed explicitly in most cases, it is nevertheless shown that in specific cases its expression is identical to Weber's Law of luminance sensitivity of the human eye.
© (2011) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Thomas Richter "From index to metric: using differential geometry to define a global visual quality metric", Proc. SPIE 8135, Applications of Digital Image Processing XXXIV, 813512 (24 September 2011); https://doi.org/10.1117/12.896091
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Cited by 1 scholarly publication.
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KEYWORDS
Visualization

Image compression

Image quality

Optical spheres

Differential equations

Digital image processing

Distortion

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