A Digital Grain Generation Method Suitable for Geometric Textures

Ryoji Miyachi; Shin Usuki; Kenjiro T. Miura

doi:10.20965/ijat.2016.p0209

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IJAT Vol.10 No.2 pp. 209-213

doi: 10.20965/ijat.2016.p0209

(2016)

Paper:

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A Digital Grain Generation Method Suitable for Geometric Textures

Ryoji Miyachi^†, Shin Usuki, and Kenjiro T. Miura

Shizuoka University
3-5-1 Jouhoku, Naka-ku, Hamamatsu, Shizuoka 432-8561, Japan

^†Corresponding author,

Received:

October 29, 2015

Accepted:

January 21, 2016

Online released:

March 4, 2016

Published:

March 5, 2016

Keywords:

texturing, graining, angle based flattening

Abstract

The automated production of products using digital data has been realized in recent years through the development of manufacturing machines. Digital data are also used for automatic texturing. In a product texturing system using digital data, texture information needs to be incorporated in the generation of digital data. However, it is difficult to generate such data manually since it is not easy to fit the texture to the product or to prevent the texture pattern from being stretched or shortened. Therefore, what is needed is a method of automatically generating digital data that yields a seamless texture with little distortion and a method of fitting the texture to the product shape. In this paper, the application of the Angle Based Flattening (ABF) method by Sheffer and de Sturler to the generation of digital data of textures is proposed. Another method to extend the ABF technic to make it more suitable to geometric textures is also proposed.

Cite this article as:

R. Miyachi, S. Usuki, and K. Miura, “A Digital Grain Generation Method Suitable for Geometric Textures,” Int. J. Automation Technol., Vol.10 No.2, pp. 209-213, 2016.

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References

[1] Y. Zhou, S. Zhang, S. Zhao, and H. Chen, “Computer Texture Mapping for Laser Texturing of Injection Mold,” Advances in Mechanical Engineering, Article ID 681563, 5pp., 2014.
[2] H. Aoyama and S. Nakatsuka, “Study on Digital Style Design – Development of Wrinkle Pattern (Texture) Design System –,” The Journal of The Japan Society for Precision Engineering, Vol.75, No.7, pp. 847-852, 2009.
[3] Y. Kobayashi, K. Shirai, Y. Hara, T. Mizoguchi, and K. Kawasaki, “Generation and Assessment of Random Surface Texture over a Wide Area,” IJAT, Vol.5, No.2, pp. 185-189, 2010.
[4] D. Uzuyama, M. Kikuta, and K. T. Miura, “Development of a Grain Milling System by Use of Digital Data,” Computer-Aided Design & Applications, Vol.7, No.3, pp. 291-296, 2010.
[5] K. T. Miura, D. Uzuyama, and M. Kikuta, “Extension of Image Quilting into 3D and Its Application to Grain Generation,” Computer-Aided Design & Applications, Vol.8, No.4, pp. 545-555, 2011, DOI: 10.3722/cadaps.2011.545-555.
[6] D. Uzuyama, M. Kikuta, and K. T. Miura, “A Grain Generation Method for Large Die Data by Use of the Out-of-Core Method,” The Journal of The Japan Society for Precision Engineering, 2011.
[7] C. N. Tang, D. Uzuyama, K. T. Miura, S. Usuki, and M. Kikuta, “A Grain Generation Method for Large Die Data Using the Out-of-Core Method,” Computer-Aided Design & Applications, Vol.9, No.6, pp. 915-923, 2012, DOI: 10.3722/cadaps.2012.915-923.
[8] A. Sheffer and E. de Sturler, “Parameterization of faceted surfaces for meshing using angle based flattening,” Engineering with Computers, Vol.17, No.3, pp. 326-337, 2001.
[9] A. Sheffer, B. L’evy, M. Mogilnitsky, and A. Bogomyakov, “ABF++: Fast and Robust Angle Based Flattening,” ACM Transactions on Graphics, Association for Computing Machinery, Vol.24, No.2, pp. 311-330, 2004.

This article is published under a Creative Commons Attribution-NoDerivatives 4.0 Internationa License.

[1] [1] Y. Zhou, S. Zhang, S. Zhao, and H. Chen, “Computer Texture Mapping for Laser Texturing of Injection Mold,” Advances in Mechanical Engineering, Article ID 681563, 5pp., 2014.

[2] [2] H. Aoyama and S. Nakatsuka, “Study on Digital Style Design – Development of Wrinkle Pattern (Texture) Design System –,” The Journal of The Japan Society for Precision Engineering, Vol.75, No.7, pp. 847-852, 2009.

[3] [3] Y. Kobayashi, K. Shirai, Y. Hara, T. Mizoguchi, and K. Kawasaki, “Generation and Assessment of Random Surface Texture over a Wide Area,” IJAT, Vol.5, No.2, pp. 185-189, 2010.

[4] [4] D. Uzuyama, M. Kikuta, and K. T. Miura, “Development of a Grain Milling System by Use of Digital Data,” Computer-Aided Design & Applications, Vol.7, No.3, pp. 291-296, 2010.

[5] [5] K. T. Miura, D. Uzuyama, and M. Kikuta, “Extension of Image Quilting into 3D and Its Application to Grain Generation,” Computer-Aided Design & Applications, Vol.8, No.4, pp. 545-555, 2011, DOI: 10.3722/cadaps.2011.545-555.

[6] [6] D. Uzuyama, M. Kikuta, and K. T. Miura, “A Grain Generation Method for Large Die Data by Use of the Out-of-Core Method,” The Journal of The Japan Society for Precision Engineering, 2011.

[7] [7] C. N. Tang, D. Uzuyama, K. T. Miura, S. Usuki, and M. Kikuta, “A Grain Generation Method for Large Die Data Using the Out-of-Core Method,” Computer-Aided Design & Applications, Vol.9, No.6, pp. 915-923, 2012, DOI: 10.3722/cadaps.2012.915-923.

[8] [8] A. Sheffer and E. de Sturler, “Parameterization of faceted surfaces for meshing using angle based flattening,” Engineering with Computers, Vol.17, No.3, pp. 326-337, 2001.

[9] [9] A. Sheffer, B. L’evy, M. Mogilnitsky, and A. Bogomyakov, “ABF++: Fast and Robust Angle Based Flattening,” ACM Transactions on Graphics, Association for Computing Machinery, Vol.24, No.2, pp. 311-330, 2004.

A Digital Grain Generation Method Suitable for Geometric Textures

Ryoji Miyachi†, Shin Usuki, and Kenjiro T. Miura

Ryoji Miyachi^†, Shin Usuki, and Kenjiro T. Miura