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Reactive Agents and Perceptual Ambiguity
Michel van Dartel
Department of Computer Science/IKAT, University of Maastricht, mf.vandartel{at}cs.unimaas.nl
Ida Sprinkhuizen-Kuyper
Department of Computer Science/IKAT, University of Maastricht, kuyper{at}cs.unimaas.nl
Eric Postma
Department of Computer Science/IKAT, University of Maastricht, postma{at}cs.unimaas.nl
Jaap van den Herik
Department of Computer Science/IKAT, University of Maastricht, herik{at}cs.unimaas.nl
Reactive agents are generally believed to be incapable of coping with perceptual ambiguity (i.e., identical sensory states that require different responses). However, a recent finding suggests that reactive agents can cope with perceptual ambiguity in a simple model (Nolfi, 2002). This paper investigates to what extent reactive and nonreactive agents can cope with perceptual ambiguity, and which strategies are employed when doing so. A model of active categorical perception (called Acp) is introduced. In Acp, situated agents with different types of neurocontrollers are optimized to categorize objects by adaptively coordinating action and perception. Our experiments show that both nonreactive and reactive agents can cope with perceptual ambiguity. An analysis of the behavior reveals that nonreactive agents use their internal memory to cope with perceptual ambiguity, while reactive agents use the environment as an external memory to compensate for their lack of an internal memory. We conclude that reactive agents can cope with perceptual ambiguity in the context of active categorical perception, and that they can organize their behavior according to stimuli that are no longer present, especially when they incorporate a nonlinear sensorimotor mapping. Moreover, we may conclude that sensory state-transition diagrams provide insight into the strategies employed by reactive agents to deal with perceptual ambiguity, and their use of the environment as an external memory.
Key Words: sensorimotor coordination • perceptual ambiguity • reactive agents • behavioral attractors • external memory
References
- Aloimonos, J.Y., Weiss, I., & Bandopadhay, A. (1988). Active vision . International Journal of Computer Vision, 2, 333-356 .
- Bajcsy, R. (1988). Active perception . In H. Li & J. R. Kender (Eds.), Proceedings of the IEEE. Special issue on computer vision (Vol. 76, pp. 996-1005 ). Piscataway, NJ: IEEE Press.
- Bakker, B., & van der Voortvan der Kleij, G. (2000). Trading off perception with internal state: Reinforcement learning and analysis of q-Elman networks in a Markovian task . In S.-I. Amari, C. L. Giles, M. Gori, & V.Piuri (Eds.), Proceedings of the International Joint Conference on Neural Networks (Vol. 3, pp. 213-218 ).Piscataway, NJ: IEEE Press.
- Balkenius, C. (1995). Natural intelligence in artificial creatures (Cognitive Studies Series, Vol. 37). Lund, Sweden: Lund University Press .
- Beer, R. D. (1996). Toward the evolution of dynamical neural networks for minimally cognitive behavior . In P. Maes, M. J. Mataric, J.-A. Meyer, J. Pollack, & S. W. Wilson (Eds.), From animals to animats 4: Proceedings of the Fourth International Conference on Simulation of Adaptive Behavior (pp. 421-429 ). Cambridge, MA: MIT Press.
- Beer, R. D. (2003). The dynamics of active categorical perception in an evolved model agent . Adaptive Behavior, 11, 209-243 .[Abstract]
- Brower, J.V. (1958). Experimental studies of mimicry in some north american butterflies . Evolution, 12, 32-47 .
- Chambers, D., & Reisberg, D. (1985). Can mental images be ambiguous? Journal of Experimental Psychology: Human Perception and Performance, 11, 317-328 .
- Clancey, W. J. (1997). Situated cognition: On human knowledge and computer representations. Cambridge: Cambridge University Press .
- Elman, J. L. (1990). Finding structure in time . Cognitive Science, 14, 179-211 .
- Goldberg, D. E. (1986). Genetic algorithms in search, optimization, and machine learning. Reading, MA: Addison-Wesley .
- Gray, W. D., & Fu, W. (2004). Soft constraints in interactive behavior: The case of ignoring perfect knowledge in-the-world for imperfect knowledge in-the-head . Cognitive Science, 28, 359-382 .[CrossRef]
- Harnad, S. (1987). Categorical perception: The groundwork of cognition. Cambridge: Cambridge University Press .
- Harnad, S. (2003). Cognition is categorization . Paper presented at UQaM Cognitive Science Summer Institute on Categorization, Montreal.
- Hartcup, G. (1979). Camouflage: A history of concealment and deception in war. Newton Abbot, UK: David and Charles .
- Hesslow, G. (2002). Conscious thought as simulation of behaviour and perception . Trends in Cognitive Sciences, 6, 242-247 .[CrossRef][Web of Science][Medline]
[Order article via Infotrieve]
- Hutchins, E. (1995). How a cockpit remembers its speed . Cognitive Science, 19, 265-288 .[CrossRef][Web of Science]
- Kirsh, D. (1995). Complementary strategies: why we use our hands when we think . In J. D. Moore, J. F. Lehman, & A. Ram (Eds.), Proceedings of the Seventeenth Annual Conference of the Cognitive Science Society (pp. 212-217 ). Hillsdale, NJ: Lawrence Erlbaum.
- Kirsh, D., & Maglio, P. (1992). Reaction and reflection in tetris . J. Hendler (Ed.), Artificial intelligence planning systems: Proceedings of the First Annual International Conference(pp. 283-284 ). San Mateo, CA: Morgan Kaufman.
- Lacroix, J. P. W., Murre, J. M. J., Postma, E. O., & van den Herik, H. J. (2004). The natural input memory model . In K. Fobus, D. Gentner, & T. Regier (Eds.), Proceedings of the Cognitive Science Conference. Austin, TX: Cognitive Science Society.
- Lorenz, K. (1973). Foundations of ethology. New York: Springer .
- Miller, B. L., & Goldberg, D. E. (1995). Genetic algorithms, tournament selection, and the effects of noise . Complex Systems, 9, 193-212 .
- Nolfi, S. (2002). Power and limits of reactive agents . Neurocomputing, 42, 119-145 .[CrossRef]
- Nolfi, S., & Marocco, D. (2001). Evolving robots able to integrate sensory-motor information over time . Theory in Biosciences, 120, 287-310 .[CrossRef]
- Nolfi, S., & Parisi, D. (1999). Exploiting the power of sensory-motor coordination . In D. Floreano, J.-D. Nicoud, & F. Mondada (Eds.), Advances in artificial life: Proceedings of the Fifth European conference on artificial life (pp. 73-182 ). Berlin: Springer.
- O’Regan, J. K. (1992). Solving the real mysteries of visual perception: The world as an outside memory . Canadian Journal of Psychology, 46, 461-488 .[Medline]
[Order article via Infotrieve]
- O’Regan, J. K., & Noë, A. (2001). A sensorimotor account of vision and visual consciousness . Behavioral and Brain Sciences, 24, 939-1031 .
- Pfeifer, R., & Scheier, C. (1997). Sensory-motor coordination: the metaphor and beyond . Robotics and Autonomous Systems, 20, 157-178 .
- Ramachandran, V. S., & Gregory, R. L. (1991). Perceptual filling in of artificially induced scotomas in human vision . Nature, 350, 699-702 .[CrossRef][Medline]
[Order article via Infotrieve]
- Thelen, E. (1995). Motor development: A new synthesis . American Psychologist, 50(2), 79-95 .[CrossRef][Medline]
[Order article via Infotrieve]
- Tijsseling, A. (1998). Connectionist models of categorization: A dynamical approach to cognition. Unpublished doctoral dissertation, University of Southampton, UK.
- Tinbergen, N. (1951). The study of instinct. New York: Oxford University Press .
Adaptive Behavior, Vol. 13, No. 3,
227-242 (2005)
DOI: 10.1177/105971230501300304
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