Investigating the success of spatial coevolution

Subscribe (Full Service)


	Search: The ACM Digital Library The Guide

	Feedback

Investigating the success of spatial coevolution

Full text

Pdf (868 KB)

Source

Genetic And Evolutionary Computation Conference archive
Proceedings of the 2005 conference on Genetic and evolutionary computation table of contents

Washington DC, USA

SESSION: Coevolution table of contents

Pages: 523 - 530

Year of Publication: 2005

ISBN:1-59593-010-8

Authors

Nathan Williams	Veriwave, Inc., Beaverton, OR
Melanie Mitchell	Portland State University, Portland, OR

Sponsors

SIGEVO: ACM Special Interest Group on Genetic and Evolutionary Computation
ACM: Association for Computing Machinery

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 4, Downloads (12 Months): 20, Citation Count: 1

Additional Information:

abstract references cited by index terms collaborative colleagues

Tools and Actions:	Review this Article Save this Article to a Binder Display Formats: BibTex EndNote ACM Ref

DOI Bookmark:	Use this link to bookmark this Article: http://doi.acm.org/10.1145/1068009.1068096 What is a DOI?

ABSTRACT

We investigate the results of coevolution of spatially distributed populations. In particular, we describe work in which a simple function approximation problem is used to compare different spatial evolutionary methods. Our work shows that, on this problem, spatial coevolution is dramatically more successful than any other spatial evolutionary scheme we tested. Our results support two hypotheses about the source of spatial coevolution's superior performance: (1) spatial coevolution allows population diversity to persist over many generations; and (2) spatial coevolution produces training examples ("parasites") that specifically target weaknesses in models ("hosts"). The precise mechanisms by which the combination of spatial embedding and coevolution produces these results are still not well understood.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	John Cartlidge , Seth Bullock, Combating Coevolutionary Disengagement by Reducing Parasite Virulence, Evolutionary Computation, v.12 n.2, p.193-222, June 2004 [doi>10.1162/106365604773955148]
	2	W. Daniel Hillis, Co-evolving parasites improve simulated evolution as an optimization procedure, Physica D, v.42 n.1-3, p.228-234, June 1990
	3	Hugues Juillé , Jordan B. Pollack, Coevolutionary Learning: A Case Study, Proceedings of the Fifteenth International Conference on Machine Learning, p.251-259, July 24-27, 1998
	4	John R. Koza, Genetic programming: a paradigm for genetically breeding populations of computer programs to solve problems, Stanford University, Stanford, CA, 1990
	5	John R. Koza, Genetic programming: on the programming of computers by means of natural selection, MIT Press, Cambridge, MA, 1992
	6	Pagie, L. & Hogeweg, P. (1997); Evolutionary consequences of coevolving targets. Evolutionary Computation 5(4):401--418.
	7	Pagie, L. & Mitchell, M. (2002). A comparison of evolutionary and coevolutionary search. International Journal of Computational Intelligence and Applications, 2(1), 53--69.
	8	Christopher Darrell Rosin, Coevolutionary search among adversaries, University of California at San Diego, La Jolla, CA, 1997
	9	Christopher D. Rosin , Richard K. Belew, Methods for Competitive Co-Evolution: Finding Opponents Worth Beating, Proceedings of the 6th International Conference on Genetic Algorithms, p.373-381, July 15-19, 1995
	10	Watson, R.A. and Pollack, J.B. (2001). Coevolutionary Dynamics in a Minimal Substrate. In Spector, L. et al. (Eds), Proceedings of the 2001 Genetic and Evolutionary Computation Conference, pp. 702--709 San Mateo, CA: Morgan Kaufmann.
	11	Werfel, J., Mitchell, M., and Crutchfield, J. P. (2000). Resource sharing and coevolution in evolving cellular automata. IEEE Transactions on Evolutionary Computation, 4(4), 388--393