Abstract
We describe our efforts to evolve robot paintings using simulated robots. Our evolutionary framework considers only the initial positions and initial directions of the simulated robots. Our fitness functions depend on the global properties of the resulting robot paintings and on the behavior of the simulated robots that occurs while making the paintings. Our evolutionary framework therefore implements an optimization algorithm that can be used to try and help identify robot paintings with desirable aesthetic properties. The goal of this work is to better understand how art making by a collection of autonomous cooperating robots might occur in such a way that the robots themselves are able to participate in the evaluation of their creative efforts.
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References
McCormack, J.: Open problems in evolutionary music and art. In: Rothlauf, F., Branke, J., Cagnoni, S., Corne, D.W., Drechsler, R., Jin, Y., Machado, P., Marchiori, E., Romero, J., Smith, G.D., Squillero, G. (eds.) EvoWorkshops 2005. LNCS, vol. 3449, pp. 428–436. Springer, Heidelberg (2005)
Moura, L., Ramos, V.: Swarm paintings — nonhuman art. In: Maubant, J., et al. (eds.) Architopia: Book, Art, Architecture, and Science, Institut d’Art Contemporain, Lyon/Villeurbanne, France, pp. 5–24 (2002)
Moura, L., Pereira, H.:: Man + Robots: Symbiotic Art. In: Institut d’Art Contemporain, Lyon/Villeurbanne, France (2004)
Ramos, V.: Self-organizing the abstract: canvas as a swarm habitat for collective memory, perception and cooperative distributed creativity. In: Rekalde, J., et al. (eds.) First Art & Science Symposium, Models to Know Reality, Bilbao, Spain, vol. 59 (2003)
Theraulaz, G., Bonabeau, E.: A brief history of stigmergy. Artifical Life 5(2), 97–116 (1999)
Saunders, R., Gero, J.: Artificial creativity: a synthetic approach to the subject of creative behavior. In: Gero, J. (ed.) Proceedings of the Fifth Conference on Computational and Cognitive Models of Creative Design, Key Centre of Design Computing and Cognition, Sydney, Australia, pp. 113–139 (2001)
Ramos, V., Almeida, F.: Artificial ant colonies in digital image habitats - a mass behaviour effect study on pattern recognition. In: Bosma, W. (ed.) ANTS 2000. LNCS, vol. 1838, pp. 113–116. Springer, Heidelberg (2000)
Ramos, V.: On the implicit and on the artificial - morphogenesis and emergent aesthetics in autonomous collective systems. In: Maubant, J., et al. (eds.) Architopia: Book, Art, Architecture, and Science, Institut d’Art Contemporain, Lyon/Villeurbanne, France, pp. 25–27 (2002)
Ramos, V., Merelo, J.: Self-organized stigmergic document maps: environment as a mechanism for context learning. In: Alba, E., et al. (eds.) AEB 2002, First Spanish Conference on Evolutionary and Bio-Inspired Algorithms, Mérida, Spain, pp. 284–293 (2002)
Sims, K.: Artificial evolution for computer graphics. Computer Graphics 25, 319–328 (1991)
Aupetit, S., Bordeau, V., Slimane, M., Venturini, G., Monmarche, N.: Interactive evolution of ant paintings. In: McKay, B., et al. (eds.) 2003 Congress on Evolutionary Computation Proceedings, pp. 1376–1383. IEEE Press, Los Alamitos (2003)
Greenfield, G.: Evolutionary methods for ant colony paintings. In: Rothlauf, F., Branke, J., Cagnoni, S., Corne, D.W., Drechsler, R., Jin, Y., Machado, P., Marchiori, E., Romero, J., Smith, G.D., Squillero, G. (eds.) EvoWorkshops 2005. LNCS, vol. 3449, pp. 478–487. Springer, Heidelberg (2005)
Baluja, S., Pomerleau, D., Jochem, T.: Towards automated artificial evolution for computer-generated images. Connection Science 6, 325–354 (1994)
Greenfield, G.: On the co-evolution of evolving expressions. International Journal of Computational Intelligence and Applications 2(1), 17–31 (2002)
Machado, P., Cardoso, A.: Computing aesthetics. In: de Oliveira, F.M. (ed.) SBIA 1998. LNCS (LNAI), vol. 1515, pp. 219–228. Springer, Heidelberg (1998)
Bentley, K.: Exploring aesthetic pattern formation. In: Soddu, C. (ed.) Proceedings of the Fifth International Conference of Generative Art (GA 2002), Milan, Italy (2002); See http://www.generativeart.com/papersGA2002/20.pdf
Boden, M.: Agents and creativity. Communications of the ACM 37(7), 117–121 (1994)
Boden, M.: The Philosophy of Artificial Life. Oxford University Press, New York (1996)
Dorin, A.: Aesthetic fitness and artificial evolution for the selection of imagery from the mythical infinite library. In: Kelemen, J., Sosík, P. (eds.) ECAL 2001. LNCS (LNAI), vol. 2159, pp. 659–668. Springer, Heidelberg (2001)
Ramachandran, V., Hirstein, W.: The science of art: a neurological theory of aesthetic experience. Journal of Consciousness Studies 6, 15–52 (1999)
Whitelaw, M.: Metacreation: Art and Artificial Life. MIT Press, Cambridge (2004)
Harlan, R., Levine, D., McClarigan, S.: The Khepera robot and kRobot class: a platform for introducing robotics in the undergraduate curriculum. Technical Report 4, Bonaventure Undergraduate Robotics Laboratory, St. Bonaventure University, New York (2000)
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Greenfield, G. (2006). Robot Paintings Evolved Using Simulated Robots. In: Rothlauf, F., et al. Applications of Evolutionary Computing. EvoWorkshops 2006. Lecture Notes in Computer Science, vol 3907. Springer, Berlin, Heidelberg. https://doi.org/10.1007/11732242_58
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DOI: https://doi.org/10.1007/11732242_58
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-33237-4
Online ISBN: 978-3-540-33238-1
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