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Multiply concurrent replication

Published online by Cambridge University Press:  15 June 2005

David L. Hull*
Affiliation:
Department of Philosophy, Northwestern University, IL60208
Sigrid S. Glenn*
Affiliation:
Department of Behavior Analysis, University of North Texas, Denton, TX76203

Abstract:

If selection is interpreted as involving repeated cycles of replication, variation, and environmental interaction so structured that environmental interaction causes replication to be differential, then selection in gene-based biological evolution and the reaction of the immune system to antigens are relatively unproblematic examples of selection processes. Operant learning and cultural evolution pose more serious problems. In this response we deal with operant learning as a selection process.

Type
Authors' Response
Copyright
Copyright © Cambridge University Press 2004

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Footnotes

Commentary onDavid L. Hull, Rodney E. Langman & Sigrid S. Glenn (2001). A general account of selection: Biology, immunology, and behavior. BBS 24(3):511–573.

References

Accardi, L. & Fedullo, A. (1982) On the statistical meaning of complex numbers in quantum mechanics. Nuovo Cimento 34(7):161–72.[LG]Google Scholar
Aerts, D. (1986) A possible explanation for the probabilities of quantum mechanics. Journal of Mathematical Physics 27:202–10.[LG]Google Scholar
Aerts, D. & Aerts, S. (1997) Application of quantum statistics in psychological studies of decision processes. In: Topics in the foundation of statistics, ed. an Fraassen, B. V.. Kluwer. [LG]Google Scholar
Aerts, D. & Gabora, L. (2005a) A state-context-property model of concepts and their combinations I: The structure of the sets of contexts and properties. Kybernetes 34(1&2):151–75. (Special issue dedicated to Heinz Von Foerster.) Available at: http://www.vub.ac.be/CLEA/liane/papers/hvf1.pdf [LG]Google Scholar
Aerts, D. & Gabora, L. (2005b) A state-context-property model of concepts and their combinations II: A Hilbert space representation. Kybernetes 34(1&2):176205. (Special issue dedicated to Heinz Von Foerster.) Available at: http://www.vub.ac.be/CLEA/liane/papers/hvf2.pdf [LG]Google Scholar
Aerts, D. & Gabora, L. (2005b) (in press) Toward a general theory of evolution. Foundations of Science. [LG]Google Scholar
Gabora, L. (2004) Ideas are not replicators but minds are. Biology and Philosophy 19(1):127–43. Available at: www.vub.ac.be/CLEA/liane/papers/replicator.pdf [LG]Google Scholar
Gabora, L. & Aerts, D. (2002) Contextualizing concepts using a mathematical generalization of the quantum formalism. Journal of Experimental and Theoretical Artificial Intelligence 14(4):327–58. Available at: www.vub.ac.be/CLEA/liane/papers/ccmgqf.pdf [LG]Google Scholar
Gabora, L. & Aerts, D. (2005a) Evolution as context-driven actualization of potential. Interdisciplinary Science Reviews 30(1):120. Available at: www.vub.ac.be/CLEA/liane/papers/cap.pdf [LG]Google Scholar
Gabora, L. & Aerts, D. (2005b) Distilling the essence of an evolutionary process, and implications for a formal description of culture. In: Proceedings of the Center for Human Evolution Workshop 4: Cultural Evolution, May 2000, ed. Kistler, W.. Foundation for the Future, Available at: www.vub.ac.be/CLEA/liane/papers/deep.html [LG]Google Scholar
Gabora, L. & Aerts, D. (2005b) (in press) Creative thought as a non-Darwinian evolutionary process. Journal of Creative Behavior. Available at: www.vub.ac.be/CLEA/liane/papers/ct.htm [LG]Google Scholar
Gabora, L., Rosch, E. & Aerts, D. (2005) How context actualizes the potentiality of a concept. In: Worldviews, science and us: Bridging knowledge and perspectives on the world, eds. Aerts, D., D’Hooghe, B. & Note, N.. World Scientific.[LG]Google Scholar
Glenn, S. S. (2003) Operant contingencies and the origin of cultures. In: Behavior theory and philosophy, ed. Lattal, K. A. & Chase, P. N., pp. 223–42. Kluwer/ Plenum.[rDLH]Google Scholar
Hull, D. L. (1988) Science as a process: An evolutionary account of the social and conceptual development of science. University of Chicago Press.[rDLH]Google Scholar
Hull, D. L., Langman, R. E. & Glenn, S. S. (2001) A general account of selection: Biology, immunology, and behavior. Behavioral and Brain Sciences 24(3):511–28 [LG, rDLH]Google Scholar
Okasha, S. (2001) Which processes are selection processes? [Commentary on Hull et al. (2001).] Behavioral and Brain Sciences 24(3):548–49. [LG, rDLH]Google Scholar
Pepper, J. W. & Knudsen, T. (2001) Selection without multiple replicators? [Commentary on Hull et al. (2001).] Behavioral and Brain Sciences 24(3):550–51.[LG, rDLH]Google Scholar
Piron, C. (1976) Foundations of quantum physics. W. A. Benjamin. [LG]Google Scholar
Pitowski, I. (1989) Quantum probability–Quantum logic: Lecture notes in physics 321, Springer [LG]Google Scholar
Randall, C. & Foulis, D. (1976) A mathematical setting for inductive reasoning. In: Foundations of probability theory, statistical inference, and statistical theories of science III, ed. Hooker, C., p. 169. Reidel. [LG]Google Scholar
Skinner, B. F. (1969) Contingencies of reinforcement: A theoretical analysis. Appleton-Century-Crofts.[rDLH]Google Scholar