This branch focuses on lossy compression of noisy concepts. In opposite to lossy compression of clamor-free images, there are few peculiarities relating to cacophony filtering effect and analysis of condensation technique act. As a result of specific noise cleaning, the so-called optimal movement point (OOP) may survive. OOP is related to such limits of a coder that quality of a compressed figure is closer to the matching noise-free (true) concept compared to quality of uncompressed (original, boisterous) image where feature is characterized by the metric, conventional or optical one. If OOP for a given cacophonous image lives, it is expedient to automatically compress an countenance under interest in OOP or, at least, its surroundings. However, since the valid image is not at disposal in essence, it occurs impossible to decide does OOP exist or not. In this affiliate, we demonstrate that it is, usually, possible to predict OOP life (according to different versification) before image condensation. It is also possible to fairly set the coder parameters for the better compact graphics (BPG) coder, which command a price of the main attention. The first part concerns a basic case of additive silver Gaussian noise in one-component (grayscale) countenances. We demonstrate that increase (decline) of the conventional metric PSNR and able to be seen with eyes quality metric PSNR-HVS-M maybe predicted. If increase is anticipated, the decision on OOP existence is tackled and vice versa. For the case of OOP absence, a habit for setting the parameter Q that controls condensation in BPG is proposed. Thus, it enhances possible to carry out lossy condensation automatically. The extensions of the projected approach to joint compression of three-component concepts are proposed. OOP existence in this place case is even more probable. Image sub-examining in color components is studied. The chance of OOP existence for ocular quality metrics PSNR-HA and MDSI is illustrated.
Author(s) Details:
Vladimir Lukin,
National
Aerospace University, Kharkov, Ukraine.
Bogdan
Kovalenko,
National
Aerospace University, Kharkov, Ukraine.
Sergii Kryvenko,
National Aerospace University, Kharkov, Ukraine.
Victoriya Naumenko,
National Aerospace University, Kharkov, Ukraine.
Benoit
Vozel,
University
of Rennes 1, Lannion, France.
Please see the link here: https://stm.bookpi.org/COSTR-V9/article/view/8755
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