Abstract
There is another evolutionary bridge to intelligent systems that I have barely mentioned yet. This is the strategy of forming social groups or communities. Of course, it is a phenomenon that has reached great complexity in humans, and we still aren’t sure why. It is still commonly supposed that humans started to socialise and become more cooperative as a result of their bigger brains and the more complex cognitive systems they'd already evolved: the result, that is, of an intelligent agreement to just get along together. Such an account is now considered to be too simple. The reason for that is the question of what it was that led to such fortuitous pre-adaptations — that is, big brains, complex intelligent systems — in the first place. We really need to know that if we are to understand the system at any level. The alternative — and, now, more acceptable view — is that social cooperation first emerged in other species as an occasional behaviour pattern; it’s advantages became manifest; and so, in certain circumstances, it became subject to natural selection. The more complex cognition that social cooperation demanded evolved with it. In this chapter I explore this possibility.
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Dworkin, M. and Kaiser, D. (eds) (2000) Myxobacteria II, Washington DC: American Society for Microbiology.
Queller, D.C., Ponte, E., Bozzaro, S. and Strassmann, J.E. (2003) ‘Single-gene greenbeard effects in the social amoeba, Dictyostelium discoideum’, Science, 299, 105–6.
Velicer, G.J. and Stredwick, K.L. (2002) ‘Experimental social evolution with Myxococcus xanthus’, Antonie van Leeuwenhoek, 81, 155–64.
Ostrowski E.A., Katoh. M., Shaulsky, G., Queller, D.C. and Strassmann, J.E. (2008) ‘Kin discrimination increases with genetic distance in a social amoeba’, PLoS Biology, 6, e287.
Scharf, M.E., Wu-Scharf, D., Pittendrigh, B.R. and Bennett, G.W. (2003) ‘Caste- and development-associated gene expression in a lower termite’, Genome Biology, 4, 1–11.
Theraulaz, G., Banabeau, E., et al. (2002) ‘Spatial patterns in ant colonies’, Proceedings of the National Academy of Sciences, 99, 9645–9.
Sulis, W. (2009) ‘Collective intelligence: observations and models’, in Guastello, S.J., Koopmans, M. and Pincus, D. (eds) Chaos and Complexity in Psychology, Cambridge: Cambridge University Press. p. 47.
Szuba, T. (2001) Computational Collective Intelligence, London: Wiley.
Miramontes, O. (1995) ‘Order-disorder transitions in the behavior of ant societies’, Complexity, 1, 56–60.
Vandermeer, J., Perfecto, I. and Philpott, S.M. (2008) ‘Clusters of ant colonies and robust criticality in a tropical agroecosystem’, Nature, 451, 457–9.
Guerin, S. and Kunkle, D. (2004) ‘Emergence of constraint in self-organizing systems’, Nonlinear Dynamics, Psychology, and Life Sciences, 8, p. 133.
Brown, C. and Laland, K.N. (2003) ‘Social learning in fishes: A review’, in Brown, C., Laland, K.N. and Krause, J. (eds) Learning in Fishes: Why They Are Smarter Than You Think. Fish and Fisheries, 4, p. 280.
Grünbaum, D., Viscido, S. and Parrish, J.K. (2005) ‘Extracting interactive control algorithms from group dynamics of schooling fish’, in Kumar, V., Leonard, N.E. and Morse, A.S. (eds) Cooperative Control (Proceedings of the Block Island Workshop), New York: Springer-Verlag.
Tien, J.H., Levin, S.A. and Rubenstein, D.I. (2004) ‘Dynamics of fish shoals: Identifying key decision rules’, Evolutionary Ecology Research, 6, 555–65.
Chase, I.D., Tovey, C., Spangler-Martin, D. and Manfredonia, M. (2002) ‘Individual differences versus social dynamics in the formation of animal dominance hierarchies’, Proceedings of the National Academy of Sciences, 99, 5744–9.
Hewitt, S.E., Macdonald, D.W. and Dugdale, H.L. (2009) ‘Context-dependent linear dominance hierarchies in social groups of European badgers Meles meles’, Animal Behaviour, 77, 161–9.
Adolphs, R. (2001) ‘The neurobiology of social cognition’, Current Opinion in Neurobiology, 11, p. 231.
Humphreys, G.W. and Forde, E.M.E. (2000) ‘Hierarchies, similarity and interactivity in object recognition: On the multiplicity of “category-specific” deficits in neuropsychological populations’, Behavioral and Brain Sciences, 24, 453–509.
Watve, M. (2002) ‘Bee-eaters (Merops orientalis) respond to what a predator can see’, Animal Cognition, 5, 253–9.
Emery, N.J. and Clayton, N.S. (2001) ‘Effects of experience and social context on prospective caching strategies by scrub jays’, Nature, 414, 443–6.
Paz-y-Miño, C.G., Bond, A.B., Kamil, A.C. and Balda, R.P. (2004) ‘Pinyon jays use transitive inference to predict social dominance’, Nature, 430, 778–88.
Shettleworth, S.J. (2009) Cognition, Evolution, and Behavior, Oxford: Oxford University Press.
Kuroshima, H., Fujita, K., Fuyuki, A. and Masuda, T. (2002) ‘Understanding of the relationship between seeing and knowing by tufted capuchin monkeys (Cebus apella)’, Animal Cognition, 5, 41–8.
Zimmer, C. (2003) ‘How the mind reads other minds’, Science, 300, 1079–80.
For review see Dunbar, R.I.M. (2003) ‘The social brain: Mind, language, and society in evolutionary perspective’, Annual Review of Anthropology, 32, 163–81.
Humphrey, N.K. (1976) ‘The social function of intellect’, in Bateson, P.P.G. and Hinde, R.A. (eds) Growing Points in Ethology, Cambridge: Cambridge University Press.
Byrne, R.W. and Whiten, A. (eds) (1988) Machiavellian Intelligence, Oxford: Clarendon Press.
Bjorklund, D.F., Yunger, J.L., Bering, J.M. and Ragan, P. (2002) ‘The generalization of deferred imitation in enculturated chimpanzees (Pan troglodytes)’, Animal Cognition, 5, 49–58.
Whiten, A., Horner, V. and de Waal, F.B.M. (2005) ‘Conformity to cultural norms of tool use in chimpanzees’, Nature, 437, 737–40.
Zentall, T.R. (2003) ‘Imitation by animals: How do they do it?’, Current Directions in Psychological Science, 12, 91–6.
Boysen, S.T and Himes, G.T. (1999) ‘Current issues and emergent theories in animal cognition’, Annual Reviews in Psychology, 50, p. 687.
Byrne, R.W., Barnard, P.J., Davidson, I., Janik, V.M., McGrew, W.C., Miklósi, Á. and Wiessner, P. (2004) ‘Understanding culture across species’, Trends in Cognitive Sciences, 8, 341–6.
Rowell, T. (2005) ‘The myth of peculiar primates’, in Box, H.O. and Gibson, K.R. (eds) Mammalian Social Learning: Comparative and Ecological Perspectives, Cambridge: Cambridge University Press.
Gallese, V. (2009) ‘Mirror Neurons’, in Baynes, T., Cleeremans, A. and Wilken, P. (eds) The Oxford Companion to Consciousness, Oxford: Oxford University Press.
Gallese, V., Keysers, C. and Rizzolatti, G. (2004) ‘A unifying view of the basis of social cognition’, Trends in Cognitive Sciences, 8, 396–404.
Bush, E.C. and Allman, J.M. (2004) ‘The scaling of frontal cortex in primates and carnivores’, Proceedings of the National Academy of Sciences, 101, 3962–6.
Reader, S.M. and Laland, K.N. (1999) ‘Forebrain size, opportunism and the evolution of social learning in nonhuman primates’, Ethology, 34, 50.
McKinney, M.L. and McNamara, K.J. (1990) Heterochrony: The Evolution of Ontogeny, New York: Plenum Press.
Dunbar, R. (1998) ‘The social brain hypothesis’, Evolution and Anthropology, 6, 178–90.
Dunbar, R.I.M. (2003) ‘The social brain: mind, language, and society in evolutionary perspective’, Annual Review of Anthropology, 32, 163–81.
Finarelli, J.A. and Flynn, J.J. (2009) ‘Brain-size evolution and sociality in Carnivora’, Proceedings of the National Academy of Sciences, 106, 9345–9.
Reader, S.M. and Laland, K.N. (2002) ‘Social intelligence, innovation and enhanced brain size in primates’, Proceedinsg of the National Academy of Sciences, 99, 4436–41.
Jerison, H. (1993) ‘The evolved mind’, Behavioral and Brain Sciences, 16, 763–4.
Falk, D. and Gibson, K.R. (eds) (2006) Evolutionary Anatomy of the Primate Cerebral Cortex, Cambridge: Cambridge University Press.
Allman, J.M., Hakeem, A., Erwin, J.M., Nimchinsky, E. and Hof, P. (2001) ‘Anterior cingulated cortex: the evolution of an interface between emotion and cognition’, Annals of the New York Academy of Sciences, 935, 107–17.
Premack, D. and Premack, A.J. (1996) ‘Why animals lack pedagogy and some cultures have more of it than others, in Olson, D.R. and Torrance, N. (eds) The Handbook of Human Development and Education, Oxford: Blackwell.
Tomasello, M. and Warnekan, F. (2008) ‘Human behaviour: Share and share alike’, Nature, 454, 1057–8.
Carruthers, P. (2002) ‘The cognitive functions of language’, Behavioral and Brain Sciences, 25, 657–726.
Bshary, R., Wickler, W. and Fricke, H. (2002) ‘Fish cognition: a primate’s eye view’, Animal Cognition, 5, p. 5.
Dugatkin, L.A. (1997) Cooperation Among Animals, Oxford: Oxford University Press.
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© 2010 Ken Richardson
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Richardson, K. (2010). Social Intelligence. In: The Evolution of Intelligent Systems. Palgrave Macmillan, London. https://doi.org/10.1057/9780230299245_9
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DOI: https://doi.org/10.1057/9780230299245_9
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