Information hiding scheme for 3D models based on skeleton and inscribed sphere analysis

被引：2

作者：

Zhang, Tao ^{[1
]}

Mu, Dejun ^{[2
]}

Ren, Shuai ^{[3
]}

Ju, Yongfeng ^{[1
]}

Ling, Yao ^{[1
]}

机构：

[1] School of Electronic and Control Engineering, Chang'an Univ.

[2] College of Automation, Northwestern Polytechnical Univ

[3] School of Information Engineering, Chang'an Univ.

来源：

Xi'an Dianzi Keji Daxue Xuebao/Journal of Xidian University | 2014年 / 41卷 / 02期

关键词：

Carrier preprocessing of 3D models; Information hiding; Inscribed sphere analysis; Skeleton;

D O I：

10.3969/j.issn.1001-2400.2014.02.030

中图分类号：

学科分类号：

摘要：

An information hiding scheme based on skeleton theory and inscribed sphere analysis for 3D models is proposed to improve the robustness and capacity of the existing algorithms. According to the definition of the skeleton, the model is analyzed by the Euclidean inscribed sphere analysis theory with each skeleton point as the center of the sphere. The number of times of minimum inscribed sphere analysis of skeleton points is considered as the modification for secret information. Preprocessing of carriers is unrelated with the number of vertexes, the change of coordinates and topology modification, so visual changes of carriers due to secret information embedding can be minimized. Experimental results show that this scheme is of strong robustness and good imperceptivity. Especially robustness against rotation is up to 100%, robustness against other common attacks is strong, and the capacity is larger.

引用

页码：185 / 190

页数：5

共 14 条

[1]

Pan Z., Sun S., Li L., An overview of 3D model watermarking, Journal of Computer-aided Design & Computer Graphics, 18, 8, pp. 1103-1110, (2006)

[2]

Wang P., Pan Z., Liu Y., Recent advances in compression of point-based 3D models, Journal of Computer-aided Design & Computer Graphics, 21, 10, pp. 1359-1367, (2009)

[3]

Comaniciu D., Meer P., Mean shift: A robust approach toward feature space analysis, IEEE Transactions on Pattern Analysis and Machine Intelligence, 24, 5, pp. 603-619, (2002)

[4]

Luo M., Bors A.G., Surface-preserving robust watermarking of 3-D shapes, IEEE Transactions on Image Processing, 20, 10, pp. 2813-2826, (2011)

[5]

Yao Z., Pan R., Li F., Et al., A mesh partitioning approach for 3D mesh oblivious watermarking, Chinese Journal of Electronics, 19, 4, pp. 651-655, (2010)

[6]

Laha B., Sensharma K., Schiffbauer J.D., Et al., Effects of immersion on visual analysis of volume data, IEEE Transactions on Visualization and Computer Graphics, 18, 4, pp. 597-606, (2012)

[7]

Lebrun J., Vetterli M., High order balanced multi-wavelets: Theory factorization and design, IEEE Transactions on Signal Processing, 49, 9, pp. 1918-1929, (2001)

[8]

Cheng W., Huang J., Liu H., A color image watermarking algorithm based on 3D-DCT, Acta Electronica Sinica, 29, Z1, pp. 1778-1781, (2001)

[9]

Wang J.T., Yang Y.W., Chang Y.T., Et al., A high verification capacity reversible fragile watermarking scheme for 3d models, International Journal of Innovative Computing, Information and Control, 7, 1, pp. 365-378, (2011)

[10]

Marco L., Fabio G., Riccardo S., Reconstructing the Curve-skeletons of 3D Shapes Using the Visual Hull, IEEE Transactions on Visualization and Computer Graphics, 18, 11, pp. 1891-1901, (2012)

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