http://de.evo-art.org/index.php?action=history&feed=atom&title=Algorithmic_Fluid_Imagery 2026-05-17T00:23:06Z Versionsgeschichte dieser Seite in de_evolutionary_art_org MediaWiki 1.27.4 http://de.evo-art.org/index.php?title=Algorithmic_Fluid_Imagery&diff=3997&oldid=prev 2015-01-29T11:54:25Z

<p>Die Seite wurde neu angelegt: „ == Reference == Mark J. Stock: <a href="/index.php?title=Algorithmic_Fluid_Imagery" title="Algorithmic Fluid Imagery">Algorithmic Fluid Imagery</a>. In: <a href="/index.php?title=Bridges_2011" title="Bridges 2011">Bridges 2011</a>. Pages 155–162 == DOI == == Abstract == The capability of computers a…“</p> <p><b>Neue Seite</b></p><div><br /> <br /> == Reference ==<br /> Mark J. Stock: [[Algorithmic Fluid Imagery]]. In: [[Bridges 2011]]. Pages 155–162 <br /> <br /> == DOI ==<br /> <br /> == Abstract ==<br /> The capability of computers and algorithms to solve once-intractable problems arising in physics gives new media<br /> artists powerful tools for communication and creation. In this paper, we will present two common methods for<br /> simulating a variety of physical systems: one based on discretizations of field values onto cells, and the other onto<br /> particles. We will draw parallels between these and much simpler Cellular Automata, and give many examples of<br /> work using a variety of methods. Although the emphasis will be on fluid dynamics, the equations and algorithms<br /> summarized herein are applicable to many fields of physics.<br /> <br /> == Extended Abstract ==<br /> <br /> == Bibtex == <br /> <br /> == Used References ==<br /> [1] T.A. Witten Jr. and L.M. Sander. Diffusion-limited aggregation, a kinetic critical phenomenon. Phys.<br /> Rev. Lett., 47:1400–1403, 1981.<br /> <br /> [2] Ryoichi Ando and Reiji Tsuruno. Vector fluid: A vector graphics depiction of surface flow. In NPAR<br /> ’10 Proceedings of the 8th International Symposium on Non-Photorealistic Animation and Rendering,<br /> pages 87–96. ACM, 2010.<br /> <br /> [3] Alexis Angelidis and Fabrice Neyret. Simulation of smoke based on vortex filament primitives. In SCA<br /> ’05: Proceedings of the 2005 ACM SIGGRAPH/Eurographics symposium on Computer animation,<br /> pages 87–96, New York, NY, USA, 2005. ACM Press.<br /> <br /> [4] Robert Bridson. Fluid Simulation for Computer Graphics. A K Peters, 2008.<br /> <br /> [5] Georges-Henri Cottet and Petros Koumoutsakos. Vortex Methods: Theory and Practice. Cambridge<br /> Univ. Press, Cambridge, UK, 1999.<br /> <br /> [6] M. Gardner. Mathematical Games: The fantastic combinations of John Conway’s new solitaire game<br /> “life”. Scientific American, 223:120–123, October 1970.<br /> <br /> [7] Charles Hirsch. Numerical Computation of Internal and External Flows, volume 1: Fundamentals of<br /> Numerical Discretization. John Wiley &amp; Sons, New York, NY, 1988.<br /> <br /> [8] A. N. Kolmogorov. The local structure of turbulence in incompressible viscous fluid for very large<br /> Reynolds numbers. Royal Society of London Proceedings Series A, 434:9–13, July 1991.<br /> <br /> [9] Mitchel Resnick. Turtles, Termites, and Traffic Jams: Explorations in Massively Parallel Microworlds.<br /> MIT Press, 1997.<br /> <br /> [10] Mark Joseph Stock. A Regularized Inviscid Vortex Sheet Method for Three Dimensional Flows With<br /> Density Interfaces. PhD thesis, University of Michigan, 2006.<br /> <br /> [11] Stephen Wolfram. A New Kind of Science. Wolfram Media, 2002.<br /> <br /> [12] Ling Xu and David Mould. Magnetic Curves: Curvature-Controlled Aesthetic Curves Using Magnetic<br /> Fields. pages 1–8, Victoria, British Columbia, Canada, 2009. Eurographics Association.<br /> <br /> <br /> == Links ==<br /> === Full Text === <br /> http://archive.bridgesmathart.org/2011/bridges2011-155.pdf<br /> <br /> [[intern file]]<br /> <br /> === Sonstige Links ===<br /> http://archive.bridgesmathart.org/2011/bridges2011-155.html</div>

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