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20030107Reaction-Diffusion by A.Sacan & S.Girgin1 Pattern Formation by Reaction-Diffusion Sertan Girgin Ahmet Saçan.

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Presentation on theme: "20030107Reaction-Diffusion by A.Sacan & S.Girgin1 Pattern Formation by Reaction-Diffusion Sertan Girgin Ahmet Saçan."— Presentation transcript:

1 20030107Reaction-Diffusion by A.Sacan & S.Girgin1 Pattern Formation by Reaction-Diffusion Sertan Girgin Ahmet Saçan

2 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 2 Game-plan Reaction-Diffusion defined. Mathematical Model Solution to RD Simulations Parameters History of RD: models & applications

3 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 3 Reaction Diffusion (RD) A chemical mechanism for pattern formation. First described by Alan Turing (1952). Two chemicals diffusing across a surface and reacting with one another can form stable patterns of chemical concentration.

4 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 4 RD in a line of cells The amount of chemical a in a cell changes based on the quantity of the chemicals a and b are already in the cell. If a particular cell has a higher concentration of chemical b than its neighbors, then that cell’s concentration of b will decrease over time by diffusion to its neighbors. Likewise, if the concentration of b is at minimum at a particular place along the row of cells, then more of b will diffuse from adjacent cells to this cell to raise the concentration of b at that cell.

5 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 5 Mathematical Model

6 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 6 Analytical Solution? Closed-form solution: difficult/impossible (except when F,G very simple). Therefore, Discretize and Solve numerically.

7 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 7 Turing’s Solution a i : concentration of 1st morphogen at i th cell. (inhibitor) b i : concentration of 2nd morphogen at i th cell. (activator) D a : diffusion rate of a. D b : diffusion rate of b. β : random substrate k : reaction rate Initial concentrations of a, b: 4

8 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 8 1-D Simulation Concentration of b over time.

9 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 9 2-D Simulation D a =0.1 D b =0.02 β=0.1 k=0.02 [a: black, b: yellow]ba

10 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 10 Reaction Diffusion Simulator Available at: http://menekse.ceng.metu.edu.tr/Ceng/566/RD/

11 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 11

12 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 12 3-D Simulation D a =0.125 D b =0.03125 β=0.1 k=0.0125

13 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 13 Possible Trends Oscillating chemical concentrations Unbounded increase (decrease) A Steady State Different diffusion rates Random perturbation

14 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 14 No Reaction Case D a =0.1 D b =0.02 β=0.1 k=0.0 ba

15 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 15 No Diffusion Case D a =0.0 D b =0.0 β=0.1 k=0.01 n=2000n=1000n=1

16 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 16 Parameter-Game: k D a =0.1 D b =0.02 β=0.1 k=0.001k=0.005k=0.01

17 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 17 Parameter: β D a =0.1 D b =0.02 k=0.005 β=0.05 β=0.1 β=3

18 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 18 D a =0.1 D b =0.02 k=0.001k=0.005k=0.01 β=0.1 β=3 β=0.05 k=0.002

19 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 19 Parameter: D a / D b D b =0.02 β=0.1 k=0.005 D a =0.08 Da=0.1Da=0.2

20 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 20 β=0.1 k=0.005 Da=0.1 Da=0.2 D b =0.02D b =0.01D b =0.007D b =0.015D b =0.018 Da=0.15 Da=0.08 Da=0.06

21 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 21 β=0.1 D b =0.01 Da=0.1 Da=0.2 k=0.005 Da=0.15 Da=0.08 Da=0.06 k=0.01k=0.002

22 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 22 Cascading D a =0.1 D b =0.02 β=0.05 k=0.001, n=30000 Freeze b:[0-4] k=0.01 Cheetah Freeze b:[0-4]  4 k=0.01 Leopard

23 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 23 History of RD Turing (1952) RD system on a sphere may be responsible for triggering gastrulation in the embryo. Bard and Lauder (1974) Computer simulations  Patterns generated by RD not regular enough to explain patterns in development. Can explain less regular patterns: leaf organization, distribution of hair follicles.

24 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 24 Bard (1981), Murray (1981) independently RD can explain the patterns on coats of animals. Bard (1981) Spot and stripe patterns. Small, white spots on a deer. Large, dark spots on a giraffe. Murray (1981) Spot-size dependent on size of animal. Paterns found on butterfly wings.

25 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 25 Meinhardt (1982) Stripe patterns (by 5-morphogen RD) Veins on a leaf. Swindale (1980) Simulation by activation/inhibition between synapses. Young (1984) Irregular striped patterns Ocular dominance columns in mammalian visual system. Meinhardt and Klinger (1987) Patterns of pigment found on mollusc shells

26 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 26 Kauffman et al. (1978), Lacalli (1990), Hunding et al. (1990) Segmentation of fruit fly (Drosophila) embryos Turk (1991) Cascading Clusters of spots on leopards and jaguars (rosettes) Zebra’s pajamas. Mapping on arbitrary surfaces.

27 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 27

28 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 28 Whitkin and Kass (1991). Emphasize anisotropy. “diffusion map”: diffusion varies across a surface.

29 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 29 Space Cookie

30 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 30 Pearson (1993) Gray-Scott Model Well-Defined range of behavior for parameters. D u = 2E-5 and D v = 1E-5 F: rate of the process that feeds U and drains U,V and P k: rate of conversion of V to P

31 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 31

32 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 32 Xmorphia

33 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 33 Xmorphia

34 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 34 M-Lattice Sherstinsky, Picard (1994) State variables are guaranteed to be bound. Applied to image-restoration and half-toning.

35 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 35

36 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 36

37 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 37

38 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 38 Texture Completion Acton, Mukherjee, Havlicek, Bovik (2001). Reconstruction of large missing regions of homogeneous oriented textures. RD seeded with noise identically distributed to surrounding region to match graylevel distribution. occludedAM-FM RDstripe formation

39 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 39

40 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 40 wood-grain wood rock AM-FM RDLevel-line method

41 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 41 Web-Resources Code Zebra (collection of RD links) http://www.codezebra.net/zebraSite/archive.html Greg Turk’s page: www.gvu.gatech.edu/people/faculty/greg.turk/reaction_ diffusion/reaction_diffusion.html Xmorphia: http://www.cacr.caltech.edu/ismap/image.html 3D images: http://www.cs.utah.edu/~gk/papers/tvcg00/node7.html Visual models of morphogenesis http://www.cpsc.ucalgary.ca/Research/bmv/

42 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 42 References A. Turing. “The Chemical Basis of Morphogenesis,” Philosophical Transactions of the Royal Society B, vol. 237, pp 37-72 (August 14, 1952). Greg Turk. "Texture Synthesis on Surfaces", SIGGRAPH 2001, pp. 347-354, (August 2001). A. Witkin and M. Kass. Computer Graphics (Proc. SIGGRAPH '91) Graphics, Vol. 25, No. 3, July, 1991. J.E. Pearson. Complex patterns in a simple system. Science, 261:189-192, (July 1993).

43 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 43 A. Sherstinsky, R. W. Picard. Restoration and Enhancement of Fingerprint Images Using M- Lattice. Proc. of the Internat. Conf. on Pattern Recognition (1994). S. T. Acton, D. P. Mukherjee, J. P. Havlicek, A. C. Bovik. Oriented Texture Completion by AM-FM Reactoin Diffusion. IEEE Transactions on Image Processing, Vol 10, No.6, (June 2001).

44 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 44 J. Bard, I. Lauder, “How Well Does Turing’s Theory of Morphogenesis Work?,” Journal of Theoretical Biology, vol.45, no.2, pp.501-531 (June 1974). P. Prusinkiewicz, “Modeling and Visualization of Biological Structures”, Proceeding of Graphics Interface ’93,pp.128-137 (May 1993)

45 20030107 Reaction-Diffusion by A.Sacan & S.Girgin 45

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