Mark A. Bedau, John S. McCaskill, Norman H. Packard, Steen Rasmussen, Chris Adami, David G. Green, Takashi Ikegami, Kunihiko Kaneko, and Thomas S. Ray. Open problems in artificial life. Artificial Life, 6:363--376, 2000.  Home/Search   Document Details and Download   Summary   Related Articles   Check

....markets and computational agents for direct practical application, particularly on the Internet. Eventually, then, ACE researchers might need to address the same ethical challenges already confronting the ALife community regarding the autonomous proliferation and evolution of artificial life forms [15]. Additional comparisons between ACE and ALife research will be made in Section 3 after a more detailed discussion of ACE research is given in Section 2. Before proceeding, an important disclaimer is in order. The primary objective of this survey is modest in scope: to introduce, motivate, and ....

....by Menczer and Below [66] In addition, as stressed by Marks [64] it might be desirable to permit agents to evolve their information processing capabilities along with their rule sets. Parallel concerns arise regarding the modeling of learning in ALife frameworks. For example, Bedau et al. [15] pose the following three open questions for Alife researchers: Question 7: Determine minimal conditions for evolutionary transitions from specific to generic response systems. Question 10: Develop a theory of information processing, information flow, and information generation for evolving ....

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Bedau, M., McCaskill, J. S., Packard, N., Rasmussen, S., Adami, C., Green, D. G., Ikegami, T., Kaneko, K., and Ray, T. (2000). Open problems in artificial life. Artificial Life 6, 363--376.

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M. A. Bedau, J. S. McCaskill, N. H. Packard, S. Rasmussen, C. Adami, D. G. Green, T. Ikegami, K. Kaneko, and T. S. Ray, "Open Problems in Artificial Life," Artificial Life 6, 363-376 (2000).

....but the theoretical implications of evolvability are also significant. There is general agreement that evolvability is crucial for understanding the orgin of complex adaptations [9, 10, 21, 34, 23] as well as the process of open ended evolution [32, 26] a central open problem in artificial life [7, 8, 5]. In addition, Wagner and Altenberg [1, 34] argue that evolvability can unify and explain a host of seemingly related issues, including epistasis, genetic canalization, genetic modularity, developmental constraints, developmental and morphological integration, and biological versatility. Studies ....

Bedau, M. A., McCaskill, J. S., Packard, N. H., Rasmussen, S., Adami, C. Green, D. G., Ikegami, T., Kaneko, K., Ray, T. S. 2000. Open problems in artificial life. Artificial Life 6, 363--376. 16

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Mark A. Bedau, John S. McCaskill, Norman H. Packard, Steen Rasmussen, Chris Adami, David G. Green, Takashi Ikegami, Kunihiko Kaneko, and Thomas S. Ray. Open problems in artificial life. Artificial Life, 6:363--376, 2000.

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Bedau, M.A. et al. 2001. Open Problems in Artificial Life. Artificial Life 6:363-376.

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Bedau et al.: "Open Problems in Artificial Life". Artificial Life 6, MA, (2000) 363-376. http://mitpress.mit.edu/journals/ARTL/Bedau.pdf

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Bedau, M., McCaskill, J.S., Packard, N., Rasmussen, S., Adami, C., Green, D. G., Ikegami, T., Kaneko, K., and Ray, T. (2000. Openproblems in artificial life. Artificial Life 6, 363--376.

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