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Efficient Watercolor Painting on Mobile Devices
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 Title & Authors
Efficient Watercolor Painting on Mobile Devices
Oh, Junkyu; Maeng, SeungRol; Park, Jinho;
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We present a novel watercolor painting drawing system which can work even on low powered computing machine such as tablet PC. Most digital watercolor systems are generated to perform on desktop, not low powered mobile computing system such as iPad. Our system can be utilized for art education besides professional painters. Our system is not a naïve imitation of real watercolor painting, but handles with properties of watercolor such as diffusion, boundary salience, and mixing of water and pigment.
watercolor painting system;fluid dynamics;lattice Boltzmann method;mobile device;
 Cited by
A. Hertzmann, "A survey of stroke-based rendering", IEEE Computer Graphics and Applications, vol. 23, 2003, pp. 70-81.

C. J. Curtis, S. E. Anderson, J. E. Seims, K. W. Fleischer, and D. H. Salesin, "Computer-generated watercolor", Proc. ACM SIGGRAPH, 1997, pp. 421-430.

T. V. Laerhoven and F. V. Reeth, "Real-time simulation of watery paint", Computer Animation and Virtual Worlds, vol. 16, 2005(July), pp. 429-439. crossref(new window)

N. Chu and C. Tai, "MoXi: real-time ink dispersion in absorbent paper", Proc. ACM SIGGRAPH, 2005, pp. 504-511.

W. Baxter, J. Wendt, and M. C. Lin, "IMPaSTo: a realistic, interactive model for paint", Proc. international symposium on Non-photorealistic animation and rendering, 2004, pp. 45-57.

N. Chu, W. Baxter, L. Wei, and N. Govindaraju, "Detailpreserving paint modeling for 3D brushes", Proc. International Symposium on Non-Photorealistic Animation and Rendering, 2010, pp. 27-34.

S. DiVerdi, A. Krishnaswamy, R. Mech, and D. Ito, "A lightweight, procedural, vector watercolor painting engine", Proc. ACM Symposium on Interactive 3D Graphics and Games, 2007, pp. 63-70.

J. Stam, "Stable fluids", Proc. ACM SIGGRAPH, 1999, pp. 121-128.

N. Foster and R. Fedkiw, "Practical animation of liquids", Proc. ACM SIGGRAPH, 2001, pp. 23-30.

D. Enright, S. Marschner, and R. Fedkiw, "Animation and rendering of complex water surfaces", Proc. ACM SIGGRAPH, 2002, pp. 736-744.

F. Losasso, F. Gibou, and R. Fedkiw, "Simulating water and smoke with an octree data structure", Proc. ACM SIGGRAPH, 2004, pp.457-462.

G. Irving and E. Guendelman, F. Losasso, and R. Fedkiw, "Efficient simulation of large bodies of water by coupling two and three dimensional techniques", Proc. ACM SIGGRAPH, 2006, pp. 805-811.

P. L. Bhatnagar, E. P. Grossa, and M. Krook, "A model for collision processes in gases. I. small amplitude processes in charged and neutral one-component systems", Physical Review, vol. 94, 1954, pp.511-525. crossref(new window)

X. He, Q. Zou, L. S. Luo, and M. Dembo, "Analytic solutions of simple flows and analysis of nonslip boundary conditions for the lattice Boltzmann BGK model", Journal of Statistical Physics, vol. 87, 1997, pp.115-136. crossref(new window)

Z. Guo, C. Zheng, and B. Shi, "Discrete lattice effects on the forcing term in the lattice Boltzmann method", Physical Review E, vol. 65, 2002.

X. Wei, W. Li, K. Mueller, and A. E. Kaufmann, "The lattice-Boltzmann method for simulating gaseous phenomena", IEEE Transactions on Visualization and Computer Graphics, vol. 10, 2004, pp. 164-176. crossref(new window)

N. Thurey and U. Rude, "Free surface lattice-Boltzmann fluid simulations with and without level sets", Workshop on Vision, Modeling, Visualization (VMV), 2004, pp. 199-208.

H. Zhu, K. Bao, E. Wu, and X. Liu, "Stable and efficient miscible liquid-liquid interactions", Virtual reality software and technology, 2007, pp. 55-64