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On an Euler-Lagrange equation for color to grayscale conversion
Hans Jakob Rivertz
  DOI :  10.2352/issn.2169-2629.2019.27.18  Published OnlineOctober 2019
Abstract

In this paper we give a new method to find a grayscale image from a color image. The idea is that the structure tensors of the grayscale image and the color image should be as equal as possible. This is measured by the energy of the tensor differences. We deduce an Euler-Lagrange equation and a second variational inequality. The second variational inequality is remarkably simple in its form. Our equation does not involve several steps, such as finding a gradient first and then integrating it. We show that if a color image is at least two times continuous differentiable, the resulting grayscale image is not necessarily two times continuous differentiable.

Journal Title : Color and Imaging Conference
Publisher Name : Society for Imaging Science and Technology
Subject Areas :
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 DOI 10.2352/issn.2169-2629.2019.27.18
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Hans Jakob Rivertz, "On an Euler-Lagrange equation for color to grayscale conversionin Proc. IS&T 27th Color and Imaging Conf.,  2019,  pp 95 - 98,  https://doi.org/10.2352/issn.2169-2629.2019.27.18

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Copyright © Society for Imaging Science and Technology 2019
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Color and Imaging Conference
color imaging conf
2166-9635
Society for Imaging Science and Technology
10.2352/issn.2169-2629.2019.27.18
2166-9635(20191021)2019:1L.95;1-
s18.phd
/ist/cic/2019/00002019/00000001/art00018
Articles
On an Euler-Lagrange equation for color to grayscale conversion
RivertzHans Jakob
21102019
2019
1
95
98
2019
In this paper we give a new method to find a grayscale image from a color image. The idea is that the structure tensors of the grayscale image and the color image should be as equal as possible. This is measured by the energy of the tensor differences. We deduce an Euler-Lagrange equation and a second variational inequality. The second variational inequality is remarkably simple in its form. Our equation does not involve several steps, such as finding a gradient first and then integrating it. We show that if a color image is at least two times continuous differentiable, the resulting grayscale image is not necessarily two times continuous differentiable.