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Computational and Conceptual Emergence

Published online by Cambridge University Press:  01 January 2022

Abstract

A twofold taxonomy for emergence is presented into which a variety of contemporary accounts of emergence fit. The first taxonomy consists of inferential, conceptual, and ontological emergence; the second of diachronic and synchronic emergence. The adequacy of weak emergence, a computational form of inferential emergence, is then examined and its relationship to conceptual emergence and ontological emergence is detailed.

Type
Computational Emergence and Its Applications
Copyright
Copyright © The Philosophy of Science Association

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Footnotes

Conversations and correspondence with Mark Bedau, Philippe Huneman, and Cyrille Imbert have much improved this paper.

References

Anderson, P. W. (1972), “More Is Different”, More Is Different 177:393396.Google ScholarPubMed
Anderson, P. W. (1995), “Historical Overview of the Twentieth Century Physics”, in Brown, L. M., Pais, A., and Pippard, B. (eds.), Twentieth Century Physics. New York: American Institute of Physics Press, 20172032.Google Scholar
Bedau, Mark (1997), “Weak Emergence”, in Tomberlin, J. (ed.), Philosophical Perspectives: Mind, Causation, and World, Vol. 11. Malden, MA: Blackwell, 375399.Google Scholar
Bedau, Mark (2003), “Downward Causation and the Autonomy of Weak Emergence”, Downward Causation and the Autonomy of Weak Emergence 6:550.Google Scholar
Broad, C. D. (1925), The Mind and Its Place in Nature. London: Routledge and Kegan Paul.Google Scholar
Castellani, Elena (2002), “Reductionism, Emergence, and Effective Field Theories”, Reductionism, Emergence, and Effective Field Theories 33:251267.Google Scholar
Darley, Vince (1994), “Emergent Phenomena and Complexity”, in Brooks, R. and Maes, P. (eds.), Artificial Life IV: Proceedings of the Fourth International Workshop on the Synthesis and Simulation of Living Systems. Cambridge, MA: MIT Press, 411416.Google Scholar
Humphreys, Paul (1997a), “Emergence, Not Supervenience”, Emergence, Not Supervenience 64:S337S345.Google Scholar
Humphreys, Paul (1997b), “How Properties Emerge”, How Properties Emerge 64:117.Google Scholar
Humphreys, Paul (2004), Extending Ourselves: Computational Science, Empiricism, and Scientific Method. New York: Oxford University Press.CrossRefGoogle Scholar
Humphreys, Paul (2008), “Synchronic and Diachronic Emergence”, Synchronic and Diachronic Emergence 18:431442.Google Scholar
Imbert, Cyrille (2006), “Why Diachronically Emergent Properties Must Also Be Salient”, in Gershenson, Carlos, Aerts, Diederik, and Edmonds, Bruce (eds.), Philosophy and Complexity: Essays on Epistemology, Evolution, and Emergence. Singapore: World Scientific.Google Scholar
Kim, Jaegwon (1999), “Making Sense of Emergence”, Making Sense of Emergence 95:336.Google Scholar
McLaughlin, Brian (1997), “Emergence and Supervenience,” Intellectica 25:2543.Google Scholar
Nagel, Ernest (1961), The Structure of Science. New York: Harcourt.CrossRefGoogle Scholar
Rasmussen, Steen, and Barrett, Chris (1995), “Elements of a Theory of Simulation”, in European Conference on Artificial Life, Lecture Notes in Computer Science. Berlin: Springer-Verlag.Google Scholar
Rueger, Alexander (2000), “Physical Emergence, Diachronic and Synchronic”, Physical Emergence, Diachronic and Synchronic 124:297322.Google Scholar
van Cleve, James (1990), “Mind-Dust or Magic? Panpsychism versus Emergentism”, Mind-Dust or Magic? Panpsychism versus Emergentism 4:215226.Google Scholar