http://de.evo-art.org/index.php?action=history&feed=atom&title=Automatic_Evolution_of_Conceptual_Building_Architectures_TR 2026-05-13T04:04:15Z Versionsgeschichte dieser Seite in de_evolutionary_art_org MediaWiki 1.27.4 http://de.evo-art.org/index.php?title=Automatic_Evolution_of_Conceptual_Building_Architectures_TR&diff=3297&oldid=prev 2015-01-14T09:49:19Z

<p>Die Seite wurde neu angelegt: „== Reference == C. Coia and <a href="/index.php?title=Brian_J._Ross" title="Brian J. Ross">Brian J. Ross</a>: Automatic Evolution of Conceptual Building Architectures_TR | Automatic Evolution of Conceptual Building Archi…“</p> <p><b>Neue Seite</b></p><div>== Reference ==<br /> C. Coia and [[Brian J. Ross]]: [[Automatic Evolution of Conceptual Building Architectures_TR | Automatic Evolution of Conceptual Building Architectures]]. Brock COSC TR CS-11-02, January 2011. <br /> <br /> == DOI ==<br /> <br /> == Abstract ==<br /> An evolutionary approach to the automatic genera-<br /> tion of 3D building topologies is presented. Genetic programming<br /> is used to evolve shape grammars. When interpreted, the shape<br /> grammars generate 3D models of buildings. Fitness evaluation<br /> considers user-specified criteria that evaluate different aspects of<br /> the model geometry. Such criteria might include maximizing the<br /> number of unique normals, satisfying target height requirements,<br /> and conforming to supplied shape contours. Multi-objective<br /> evaluation is used to analyze and rank model fitness, based<br /> on the varied user-supplied criteria. A number of interesting<br /> models complying to given geometric specifications have been<br /> successfully evolved with the approach. A motivation for this<br /> research application is that it can be used as a generator of<br /> conceptual designs, to be used as inspirations for refinement or<br /> further exploration.<br /> <br /> == Extended Abstract ==<br /> <br /> == Bibtex == <br /> <br /> == Used References ==<br /> [1] F. D. Ching, Architecture - Form, Space, and Order. Wiley, 2007.<br /> <br /> [2] Vitruvius, Ten Books on Architecture. BiblioLife, 2009.<br /> <br /> [3] G. Stiny, “Introduction to shape and shape grammars,” Environment and<br /> Planning B, vol. 7, pp. 343–351, 1980.<br /> <br /> [4] ——, “Kindergarten grammars: designing with froebel’s building gifts,”<br /> Environment and Planning B: Planning and Design, vol. 7, no. 4, pp.<br /> 409–462, July 1980.<br /> <br /> [5] G. Stiny and J. Gips, “Shape grammars and the generative specifica-<br /> tion of painting and sculpture,” in Information Processing ’71, C. V.<br /> Friedman, Ed., Amsterdam, 1972, pp. 1460–1465.<br /> <br /> [6] M. Tapia, “A visual implementation of a shape grammar system,”<br /> Environment and Planning B: Planning and Design, vol. 26, pp. 59–<br /> 73, 1999.<br /> <br /> [7] N. Ando, N. Yamahata, S. Masumi, and M. Chatani, “Shape grammar<br /> and form properties of architectural figures,” Journal for Geometry and<br /> Graphics, vol. 5, no. 1, pp. 23–33, 2001.<br /> <br /> [8] “CityEngine,” 2011, last accessed January 4, 2011. [Online]. Available:<br /> http://www.procedural.com/<br /> <br /> [9] P. Muller, P. Wonka, S. Haegler, A. Ulmer, and L. V. Gool, “Procedural<br /> modeling of buildings,” in Proc. SIGGRAPH ’06. New York, NY, USA:<br /> ACM, 2006, pp. 614–623.<br /> <br /> [10] Y. I. H. Parish and P. M ̈uller, “Procedural modeling of cities,” in SIG-<br /> GRAPH ’01: Proceedings of the 28th annual conference on Computer<br /> graphics and interactive techniques. New York, NY, USA: ACM, 2001,<br /> pp. 301–308.<br /> <br /> [11] J. Halatsch, A. Kunze, and G. Schmitt, “Using shape grammars for<br /> master planning,” in Design Computing and Cognition ’08. Springer,<br /> 2008.<br /> <br /> [12] P. Bentley and D. Corne, Creative Evolutionary Systems.<br /> Morgan Kaufmann, 2002.<br /> <br /> [13] J. Romero and P. Machado, The Art of Artificial Evolution. Springer,<br /> 2008.<br /> <br /> [14] R. Kicinger, T. Arciszewski, and K. Jong, “Evolutionary computation<br /> and structural design: A survey of the state-of-the-art”,” Computers and<br /> Structures, vol. 83, no. 23–24, pp. 1943–1978, 2005.<br /> <br /> [15] J. S. Gero, S. J. Louis, and S. Kundu, “Evolutionary learning of novel<br /> grammars for design improvement,” AIEDAM, vol. 8, pp. 83–94, 1994.<br /> <br /> [16] P. von Buelow, Genetically Engineered Architecture - Design Explo-<br /> ration with Evolutionary Computation. VDM Verlag, 2007.<br /> <br /> [17] H. Jackson, “Toward a symbiotic coevolutionary approach to architec-<br /> ture,” in Creative Evolutionary Systems. Academic Press, 2002.<br /> <br /> [18] M. Hemberg, U.-M. O’Reilly, A. Menges, K. Jones,<br /> M. da Costa Goncalves, and S. R. Fuchs, “Genr8: Architects’<br /> experience with an emergent design tool,” in The Art of Artificial<br /> Evolution. Springer, 2008.<br /> <br /> [19] M. O’Neill, J. Swafford, J. McDermott, J. Byrne, A. Brabazon, E. Shot-<br /> ton, C. McNally, and M. Hemberg, “Shape grammars and grammatical<br /> evolution for evolutionary design,” in Proc. GECCO ’09. ACM, 2009,<br /> pp. 1035–1042.<br /> <br /> [20] M. O’Neill, J. McDermott, J. Swafford, J. Byrne, E. Hemberg, and<br /> A. Brabazon, “Evolutionary design using grammatical evolution and<br /> shape grammars: designing a shelter,” Intl. Journal of Design Engineer-<br /> ing, vol. 3, pp. 4–24, 2010.<br /> <br /> [21] C. Soddu, “Recognizability of the idea: The evolutionary process of<br /> argenia,” in Creative Evolutionary Systems. Academic Press, 2002.<br /> <br /> [22] J.S.Gero and R. Sosa, “Complexity measures as a basis for mass<br /> customization of novel designs,” Environment and Planning B, vol. 35,<br /> no. 1, pp. 3–15, 2008.<br /> <br /> [23] G. Hornby, “Functional scalability through generative representations:<br /> the evolution of table designs,” Environment and Planning B, vol. 31,<br /> no. 4, pp. 569–587, 2005.<br /> <br /> [24] C. Jacob, “Evolving evolution programs: Genetic programming and L-<br /> systems,” in Proc. Genetic Programming 1996. MIT Press, 1996, pp.<br /> 107–115.<br /> <br /> [25] D. Beaumont and S. Stepney, “Grammatical evolution of l-systems,” in<br /> Proc. CEC 2009. IEEE Press, 2009, pp. 2446–2453.<br /> <br /> [26] C. Coia, “Automatic evolution of conceptual building architectures,”<br /> Master’s thesis, Department of Computer Science, Brock University,<br /> 2011, (expected).<br /> <br /> [27] R. Flack, “Robgp - robust object based genetic programming system,”<br /> Dept of Computer Science, Brock University, Tech. Rep., Nov. 2010.<br /> [Online]. Available: http://sourceforge.net/projects/robgp/<br /> <br /> [28] “Collada,” 2011, last accessed Jan 5, 2011. [Online]. Available:<br /> http://www.collada.org/<br /> <br /> [29] J. Koza, Genetic Programming: On the Programming of Computers by<br /> Means of Natural Selection. MIT Press, 1992.<br /> <br /> [30] C. M. Fonseca and P. J. Fleming, “An overview of evolutionary al-<br /> gorithms in multiobjective optimization,” in Evolutionary Computation,<br /> 1996, pp. 3(1):1–16.<br /> <br /> [31] Coello, C. Coello, Lamont, G.B., and Veldhuizen, Evolutionary Algo-<br /> rithms for Solving Multi-Objective Problems, 2nd ed. Kluwer, 2007.<br /> <br /> [32] P. Bentley and J. Wakefield, “Finding acceptable solutions in the<br /> pareto-optimal range using multiobjective genetic algorithms,” in Soft<br /> Computing in Engineering Design and Manufacturing. Spinger Verlag,<br /> 1997.<br /> <br /> [33] S. Bergen and B. Ross, “Evolutionary Art Using Summed Multi-<br /> objective Ranks,” in Genetic Programming - Theory and Practice.<br /> Springer, May 2010.<br /> <br /> [34] R. Flack, “Evolution of architectural floor plans,” Master’s thesis,<br /> Department of Computer Science, Brock University, 2010.<br /> <br /> <br /> == Links ==<br /> === Full Text === <br /> http://www.cosc.brocku.ca/files/downloads/research/cs1102.pdf<br /> <br /> [[intern file]]<br /> <br /> === Sonstige Links ===</div>

Gbachelier