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Hlavná stránka > Tutoriály > Morfogenéza
Lindenmayerove systémy > Morfogenéza

Obsah
Úvod
Reakčno-difúzne modely
Modely jednoduchých štruktúr
CA a L-systémy v modelovaní rastlín
Princípy v modelovaní rastlín
Rastlina a okolie
Literatúra

Ostatné kapitoly
Lindenmayerove systémy
Modelovanie ekosystémov
Dawkinsove biomorfy
Reakčno-difúzne modely
Difúzne ohraničené zhlukovanie
Voronoiove diagramy
Časticové systémy
Fibbonaciho čísla a zlatý rez

Tutoriály

Celulárne automaty
Morfogenéza
Simulátory
Evolučné algoritmy
Chaos
Roboty
Rôzne

Literatúra

J. Battjes, K. Bachmann, and F. Bouman. Early development of capitula in Microseris pygmaea D. Don strains C96 and A92 (Asteraceae: Lactuceae). Botanische Jahrbücher Systematik, 113(4):461-475, 1992.

A. D. Bell. On the astogeny of six-cornered clones: an aspect of modular construction. In J. White, editor, Studies on plant demography: A festschrift for John L. Harper, str. 187-207. Academic Press, Londýn, 1985

S. Camazine. Designed by Nature. The World and I, str. 202-208, March 1993.

N. Chiba, S. Ohkawa, K. Muraoka, and M. Miura. Visual simulation of botanical trees based on virtual heliotropism and dormancy break.The Journal of Visualization and Computer Animation, 5:3-15, 1994.

V. Clausnitzer and J.W. Hopmans. Simultaneous modeling of transient three-dimensional root growth and soild water flow. Plant and Soil, 164:299-314, 1994.

P. Coats. Great gardens of the Western world. G. P. Putnam's Sons, New York, 1963.

D. Cohen. Computer simulation of biological pattern generation processes.Nature, 216:246-248, October 1967.

M. Eden. A two-dimensional growth process. In Proceedings of Fourth Berkeley Symposium on Mathematics, Statistics, and Probability, volume 4, str. 223-239. University of California Press, Berkeley, 1960.

D. Fowler, P. Prusinkiewicz, and J. Battjes. A collision-based model of spiral phyllotaxis. Computer Graphics (SIGGRAPH '92 Proceedings), 26:361-368, July 1992.

H. Fujikawa and M. Matsushita. Bacterial fractal growth in the concentration field of nutrient. Journal of the Physical Society of Japan, 60(1):88-94, 1991.

A. Gierer and H. Meinhardt. A theory of biological pattern formation. Kybernetik, 12, 30-39, 1972.

N. Greene. Voxel space automata: Modeling with stochastic growth processes in voxel space. Computer Graphics 23,4 (August 1989), str. 175-184.

N. Greene. Detailing tree skeletons with voxel automata. SIGGRAPH '91 Course Notes on Photorealistic Volume Modeling and Rendering Techniques, 1991.

H. Honda, P. B. Tomlinson, and J. B. Fisher. Computer Simulation of Branch Interaction and Regulation by Unequal Flow Rates in Botanical Trees. American Journal of Botany,68:569-585, 1981.

J. Kaandorp. Modeling growth forms of biological objects using fractals. PhD thesis, University of Amsterdam, May 1992.

J. Kaandorp. Fractal modelling: Growth and form in biology. Springer-Verlag, Berlin, 1994. In press.

A. Lindenmayer. Mathematical models for cellular interaction in development, Parts I and II. Journal of Theoretical Biology, 18:280-315, 1968.

B. Mandelbrot and C. Evertsz. The potential distribution around growing fractal clusters. Nature, volume 348, str. 143-145, 1990.

M. Matsushita and H. Fujikawa. Diffusion-limited growth in bacterial colony formation. Physica A, 168:498-508, 1990.

P. Meakin. A new model for biological pattern formation. Journal of Theoretical Biology, 118:101-113, 1986.

H. Meinhardt. Models of biological pattern formation. Academic Press, London, 1982.

R. Mech and P. Prusinkiewicz. Visual models of plants interacting with their environment. Computer Graphics (SIGGRAPH '96 Proceedings), 30:397-410, 1996.

H. Meinhardt. Models for positional signalling, the threefold subdivision of segments and the pigmentation patterns of molluscs. J. Embryol. exp. Morph., 83:289-311, 1984.Supplement.

H. Meinhardt and M. Klinger. Pattern formation by coupled oscillations: The pigmentation patterns on the shells of molluscs. In Lecture Notes in Biomathematics, volume 71, str. 184-198. Springer-Verlag, Berlin, 1987.

H. Meinhardt and M. Klinger. A model for pattern formation on the shells of molluscs. Journal of Theoretical Biology, 126:63-89, 1987.

P. Prusinkiewicz and A. Lindenmayer. The algorithmic beauty of plants. Springer-Verlag, New York, 1990. With J. S. Hanan, F. D. Fracchia, D. R. Fowler, M. J. M. de Boer, and L. Mercer.

P. Prusinkiewicz. Modeling and visualization of biological structures. In Proceedings of Graphics Interface '93, str. 128-137, 1993.

P. Prusinkiewicz. Visual Models of Morphogenesis. In Artificial Life, 1(1/2):67-74, 1994.

P. Prusinkiewicz, W. Remphrey, C. Davidson, and M. Hammel. Modeling the architecture of expanding Fraxinus pennsylvanica shoots using L-systems. Canadian Journal of Botany, 72:701-714, 1994.

P. Prusinkiewicz, M. James, and R. Mech. Synthetic Topiary. Computer Graphics (SIGGRAPH '94 Proceedings), 28:351-358, 1994.

P. M. Room, L. Maillette, and J. Hanan. Module and metamer dynamics and virtual plants. Advances in Ecological Research, 25:105-157, 1994.

P. M. Room, J. S. Hanan, and P. Prusinkiewicz. Virtual plants: new perspectives for ecologists, pathologists, and agricultural scientists. Trends in Plant Science, 1:33-38, 1996.

A. R. Smith. Plants, fractals, and formal languages. Computer Graphics, 18, 3 (July 1984), str. 1-10.

A. Takenaka. A simulation model of tree architecture development based on growth response to local light environment.Journal of Plant Research, 107:321-330, 1994.

C. E. Taylor ``Fleshing Out''Artificial Life II. In C. G. Langton, C. Taylor, J. D. Farmer, and S. Rasmussen, editors, Artificial Life II, str. 25-38. Addison-Wesley, Redwood City, 1992.

A. Turing. The chemical basis of morphogenesis. Philosophical Transactions of the Royal Society B, 237:37-72, 1952.

G. Turk. Generating textures on arbitrary surfaces using reaction-diffusion. Computer Graphics, 25, 4 (Júl 1991), str. 28-298.

S. Ulam. On some mathematical properties connected with patterns of growth of figures. In Proceedings of Symposia on Applied Mathematics, volume 14, str. 215-224. American Mathematical Society, 1962.

A. Witkin and M. Kass. Reaction-diffusion textures. Computer Graphics, 25, 4 (July 1991), str. 299-308.

T. Witten and L. Sander. Diffusion-limited aggregation. Phys. Rev. B 27:5686-5697, 1983.

D. A. Young. A local activator-inhibitor model of vertebrate skin patterns. Math. Biosciences, 72:51-58, 1984.

Linky

http://www.ctpm.uq.edu.au/virtualplants/ipivp.html

počítačové simulácie štrukturálneho vývoja a rastu rastlín v 3D, obrázky, animácie, software

http://forsys.cfr.washington.edu/svs.html

vizualizačný software

http://magnolia.metla.fi/webdocs/lignum/lignum_model.html

LIGNUM modely štruktúry a funkcie jednoduchých stromov, fotosyntéza, dýchanie, štruktúra vetvenia v jednom modeli

http://sawww.epfl.ch/SIC/SA/publications/SCR96/scr8-page11.html

3D modely štruktúry drevných vlákien počas spracovania

http://www.ccsf.caltech.edu/ismap/image.html

Reakčno-difúzny systém, popis rovníc, obrázky, animácie

http://pespmc1.vub.ac.be/ASC/MORPHOGENES.html

definícia morfogenézy by Principia Cybernetica

http://www.cs.cmu.edu/afs/cs.cmu.edu/Web/Groups/acse/lessons.html

dve elektronické lekcie týkajúce sa morfogenézy

http://www.gg.caltech.edu/~kurt/kurt.html

práca Kurta Fleischera "A Multiple-Mechanism Developmental Model for Defining Self-Organizing Geometric Structures"

http://www.muohio.edu/~botcwis/bot/rdm.html

Roger D. Meicenheimer sa zaoberá morfogenézou rastlín, vznikom patternov...

http://www.rochester.edu/College/BIO/olmstedlab/olmstedhp.html

bunková morfogenéza

http://www.iephb.ru/genmorph.html

práca A.Spirova: geny a morfogenéza, simulácia a vizualizácia morfogenézy, reakčno-difúzne modely, dymanika morfogenézy ...

http://www.shef.ac.uk/misc/rec/ps/efi/mmorphog.html

veľmi zaujímavé vraj "morphogenesis music"

http://www.science.gmu.edu/~mlachhab/activities.html

difúzne-ohraničené zhlukovanie, Edenov model a rôzne variácie, rôzne ďalšie modely, pekný názorný popis

http://www-white.media.mit.edu/~shers/mlattice.html

M-Latice systém rieši problémy s difúzne-ohraničenou a., ukážky zaujímavých aplikácii

http://ampere.scale.uiuc.edu/~m-lexa/cell/cell.html

virtuálne bunky rastlín, obrázky

http://www.natur.cuni.cz/~fatima/fc/virtbot.htm

prechádzka virtuálnou záhradou, L-systémy a pohľad na modelovanie rastlín z biologického hľadiska

http://www-cg.cis.iwate-u.ac.jp/lab/index-e.html

skvelé simulácie stromov, rastlín, prostredia, bonsajov a zvierat, vydarené obrázky

http://sgi.felk.cvut.cz/~benes/

modely rastlín naťahujúcich sa za svetlom, obrázky, animácie

http://www.povray.org/

Persistence of Vision Raytracer, software ktorý vie štruktúry z Lparsera obaliť hmotou, vrhnúť tiene ...

http://apricot.ap.polyu.edu.hk/~lam/dla/dla.html

pekný Java aplet názorne ukazuje priebeh difúzne-ohraničeného zhlukovania

http://www.swin.edu.au/astronomy/pbourke/fractals/fracintro/

úvod do fraktálov, DLA modely, popis modelovania rastlín pomocou L-systémov

http://www.cco.caltech.edu/~jsu/dla/dla.html

difúzne-ohraničené zhlukovanie + programček, ktorý to robí

http://www.oche.de/~ecotopia/dla/

difúzne-ohraničené zhlukovanie, príklady, simulácie, odkazy

www.edpsciences.com/articles/epjb/pdf/1999/19/b8592.pdf

stochastický Edenov model, práca v pdf formáte

Niektoré práce Prusinkiewicza v ps formáte:

Vizuálne modely rastlín v interakcii s prostredím (časť prvá , časť druhá)

je tam podrobný popis tvorby modelov (rastlín a okolia) spomínaných v tejto práci

Modelovanie a vizualizácia biologických štruktúr (časť prvá , časť druhá)

podrobný popis modelov, DLA, reakčno-difúzny

Synthetic topiary

podrobný popis tvorby topiarov

Hore

Kontakt: Marek Bundzel