Ackley, D., & Littman, M. (1992). Interactions between learning and evolution. In C. G. Langton et al. (Eds.), Proceedings of Artificial Life II (pp. 487-509). Redwood City, CA: Addison-Wesley.
2.
Baldwin, J.M. (1896). A new factor in evolution. The American Naturalist, 30, 441-451, 536-553.
3.
Barandiaran, X. (2008). Mental life. A naturalized approach to the autonomy of cognitive agents. Unpublished doctoral dissertation, University of the Basque Country, Spain. http://barandiaran.net/phdthesis/
4.
Barandiaran, X., & Moreno, A. (2006). Alife models as epistemic artefacts. In L. M. Rocha, L. S. Yaeger, M. A. Bedau, D. Floreano, R. L. Goldstone , & A. Vespignani (Eds.), Artificial Life X: 10th International Conference on the Simulation and Synthesis of Living Systems (pp. 513- 519). Cambridge, MA: MIT Press.
5.
Bedau, M.A. (1998). Philosophical content and method of artificial life. In T. W. Bynum & J. H. Moor (Eds.), The digital phoenix: How computers are changing philosophy (pp. 135-152). Oxford, UK: Basil Blackwell.
6.
Bersini, H. (2004). Whatever emerges should be intrinsically useful . In Artificial Life 9 (pp. 226-231). Cambridge, MA: MIT Press.
7.
Bongard, J., & Paul, C. (2000). Investigating morphological symmetry and locomotive efficiency using virtual embodied evolution. In J.-A. Meyer et al. (Eds.), From Animals to Animats: The Sixth International Conference on the Simulation of Adaptive Behavior .
8.
Casti, J. (1997). Would-be worlds. New York: John Wiley.
9.
Chemero, A. (2000). Anti-representationalism and the dynamical stance . Philosophy of Science, 67(4), 625-647.
10.
Chemero, A. (2009). Radical embodied cognitive science. Cambridge, MA: MIT Press.
11.
Crutchfield, J.P. (1994). The calculi of emergence: Computation, dynamics, and induction, Physica D, 75, 11-54.
12.
Dennett, D. (1994). Artificial life as philosophy. Artificial Life, 1(3), 291-292.
13.
Di Paolo, E.A., Noble, J., & Bullock, S. (2000). Simulation models as opaque thought experiments . In M. A. Bedau, J. S. MacCaskill, N. H. Packard , & S. Rasmussen (Eds.), Artificial Life VII: The Seventh International Conference on the Simulation and Synthesis of Living Systems, (pp. 497-506). Cambridge, MA: MIT Press.
14.
Harvey, I. (2000). Robotics: Philosophy of mind using a screwdriver In T. Gomi (Ed.), Evolutionary Robotics: From Intelligent Robots to Artificial Life, Vol. III (pp. 207-230). Ontario, Canada: AAI Books.
15.
Hinton, G.E., & Nowlan, S.J. (1987). How learning can guide evolution. Complex Systems, 1, 495-502.
16.
Horgan, J. (1995). From complexity to perplexity. Scientific American, 272, 104-109.
17.
Mills, R., & Watson, R.A. (2005). Genetic assimilation and canalization in the Baldwin effect. In M. Capcarrere et al. (Eds.), Proceedings of the Eighth European Conference on Artificial Life (pp. 353-362). Berlin: Springer Verlag.
18.
Ray, T. (1992). An approach to the synthesis of life. In C. G. Langton, C. Taylor, J. D. Farmer, & S. Rasmussen (Eds.), Artificial Life II. Proceedings of the Workshop on Artificial Life (pp. 325-371). Redwood City, CA: Addison-Wesley.
19.
Suzuki, R., & Arita, T. (2004). Drastic changes in roles of learning in the course of evolution. In J. B. Pollack, M. Bedau, P. Husbands , T. Ikegami, & R. A. Watson (Eds.), Proceedings of Artificial Life IX (pp. 369-374). Cambridge, MA: MIT press.
20.
Vickerstaff, R.J., & Di Paolo, E.A. , (2005). Evolving neural models of path integration. Journal of Experimental Biology, 208, 3349-3366.
21.
Weber, B. H., & Depew, D. J. (Eds.) (2003). Evolution and learning. The Baldwin effect reconsidered. Cambridge, MA: MIT Press.
