Action-Oriented Representation

doi:10.1017/CBO9780511610608.009

8 - Action-Oriented Representation

Published online by Cambridge University Press: 02 February 2010

Pete Mandik

Edited by

Andrew Brook and

Kathleen Akins

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Pete Mandik: Affiliation:
Assistant Professor of Philosophy and Coordinator, Cognitive Science Lab, William Paterson University
Andrew Brook: Affiliation:
Carleton University, Ottawa
Kathleen Akins: Affiliation:
Simon Fraser University, British Columbia

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Introduction

Often, sensory input underdetermines perception. One such example is the perception of illusory contours. In illusory contour perception, the content of the percept includes the presence of a contour that is absent from the informational content of the sensation. (By “sensation” I mean merely information-bearing events at the transducer level. I intend no further commitment, such as the identification of sensations with qualia.) I call instances of perception underdetermined by sensation “underdetermined perception.”

The perception of illusory contours is just one kind of underdetermined perception (see Figure 8.1). The focus of this chapter is another kind of underdetermined perception: what I shall call “active perception.” Active perception occurs in cases in which the percept, while underdetermined by sensation, is determined by a combination of sensation and action. The phenomenon of active perception has been used by several to argue against the positing of representations in explanations of sensory experience, either by arguing that no representations need be posited or that far fewer than previously thought need be posited. Such views include, but are not limited to, those of J. Gibson (1966, 1986), P. S. Churchland et al. (1994), T. Jarvilehto (1998), and J. O'Regan and A. Noë (2001). In this chapter, I argue for the contrary position that active perception is actually best accounted for by a representational theory of perception. Along the way, this will require a relatively novel conception of what to count as representations.

Type: Chapter
Information: Cognition and the Brain
The Philosophy and Neuroscience Movement
, pp. 284 - 306

DOI: https://doi.org/10.1017/CBO9780511610608.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2005

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References

Austin, J. (1964). Sense and Sensibilia. New York: Oxford University PressGoogle Scholar

Bach-y-Rita, P. (1972). Brain Mechanisms in Sensory Substitution. New York and London: Academic PressGoogle Scholar

Baum, D. (2002). The Definitive Guide to LEGO MINDSTORMS, Second Edition. Berkeley, CA: ApressGoogle Scholar

Churchland, P. S., Ramachandran, V. S., and Sejnowski, T. J. (1994). “A critique of pure vision.” In Koch, C. and Davis, J. L. (eds.), Large-Scale Neuronal Theories of the Brain. Cambridge, MA: MIT Press, pp. 23–60Google Scholar

Clark, A. (1997). Being There. Cambridge, MA: MIT PressGoogle Scholar

Clark, A. (2000a). “A case where access implies qualia?” Analysis 60: 1: 30–37CrossRef Google Scholar

Clark, A. (2000b). “Phenomenal immediacy and the doors of sensation.” Journal of Consciousness Studies 7 (4): 21–24Google Scholar

Clark, A. (2002). “Visual experience and motor action: Are the bonds too tight?” Philosophical Review 110: 495–520CrossRef Google Scholar

Colby, C. (1999). “Parietal cortex constructs action-oriented spatial representations.” In Burgess, N., Jeffery, K. J., and O'Keefe, J. (eds.), The Hippocampal and Parietal Foundations of Spatial Cognition. New York: Oxford University Press, pp. 104–126Google Scholar

Cotterill, R. (1998). Enchanted Looms: Conscious Networks in Brains and Computers. Cambridge: Cambridge University PressGoogle Scholar

Dretske, F. (1995). Naturalizing the Mind. Cambridge, MA: MIT PressGoogle Scholar

Evans, G. (1985). “Molyneux's question.” In Evans, Gareth, The Collected Papers of Gareth Evans. London: Oxford University PressGoogle Scholar

Faillenot, I., Toni, I., Decety, J., Gregoire, M. C., and Jeannerod, M. (1997). “Visual pathways for object-oriented action and object identification: Functional anatomy with PET.” Cerebral Cortex 7: 77–85CrossRef Google Scholar

Fodor, J. (1987). Psychosemantics. Cambridge, MA: MIT PressGoogle Scholar

Gallese, V., Craighero, Laila, Fadiga, Luciano, and Fogassi, Leonardo (1999). “Perception through action.” Psyche 5 (21): http://psyche.cs.monash.edu.au/v5/psyche-5-21-gallese.htmlGoogle Scholar

Gibson, J. (1966). The Senses Considered as Perceptual Systems. Boston: Houghton MifflinGoogle Scholar

Gibson, J. (1986). The Ecological Approach to Visual Perception. Hillsdale, NJ: Lawrence ErlbaumGoogle Scholar

Gould, S. (1991). “Exaptation: A crucial tool for evolutionary psychology. Journal of Social Issues 47: 43–65CrossRef Google Scholar

Grice, H. (1961). “The causal theory of perception.” Proceedings of the Aristotelian Society, sup. vol. 35: 121–152CrossRef Google Scholar

Grush, R. (1998). “Skill and spatial content.” Electronic Journal of Analytic Philosophy 6: http://ejap.louisiana.edu/EJAP/1998/grusharticle98.htmlGoogle Scholar

Grush, Rick (2001). “Self, world and space: On the meaning and mechanisms of egocentric and allocentric spatial representation.” Brain and Mind 1 (1): 59–92CrossRef Google Scholar

Hanneton, S., Gapenne, O., Genouel, C., Lenay, C., and Marque, C. (1999). “Dynamics of shape recognition through a minimal visuo-tactile sensory substitution interface.” Third International Conference on Cognitive and Neural Systems, pp. 26–29Google Scholar

Helmholtz, H. (1867). Handbuch der Physiologischen Optik. In Karsten, G. (ed.), Allgemeine Encyklopädie der Physik, vol. 9. Leipzig: VossGoogle Scholar

Hubel, D. H., and Wiesel, T. N. (1962). “Receptive fields, binocular interaction, and functional architecture in the cat's visual cortex.” Journal of Physiology 195: 215–243CrossRef Google Scholar

Hurley, S. (1998). Consciousness in Action. Cambridge, MA: Harvard University PressGoogle Scholar

Hyman, J. (1992). “The causal theory of perception.” Philosophical Quarterly 42 (168): 277–296CrossRef Google Scholar

Jarvilehto, T. (1998). “Efferent influences on receptors in knowledge formation.” Psycoloquy 9 (41): http://www.cogsci.soton.ac.uk/cgi/psyc/newpsy?9.41Google Scholar

Jeannerod, M. (1999). “A dichotomous visual brain?” Psyche 5 (25): http://psyche.cs.monash.edu.au/v5/psyche-5-25-jeannerod.htmlGoogle Scholar

Keeley, B. (2002). “Making sense of the senses: Individuating modalities in humans and other animals.” Journal of Philosophy 99: 5–28Google Scholar

Koshland, D. (1977). “A response regulator model in a simple sensory system. Science 196: 1055–1063CrossRef Google Scholar

Koshland, D. (1980). “Bacterial chemotaxis in relation to neurobiology.” In Cowan, W. C. et al. (eds.), Annual Review of Neurosciences 3. Palo Alto: Annual Reviews, pp. 43–75Google Scholar

Kosslyn, S., Ganis, G., and Thompson, W. (2001). “Neural foundations of imagery.” Nature Reviews Neuroscience 2: 635–642CrossRef Google Scholar PubMed

Larsson, J., Amunts, K., Gulyas, B., Malikovic, A., Zilles, K., and Roland, P. (1999). “Neuronal correlates of real and illusory contour perception: Functional anatomy with PET.” Eur J Neurosci. 11 (11): 4024–4036CrossRef Google Scholar PubMed

Lenay, C., Cannu, S., and Villon, P. (1997). “Technology and perception: The contribution of sensory substitution systems.” In Second International Conference on Cognitive Technology. Aizu, Japan, and Los Alamitos, CA: IEEE, pp. 44–53

Livingstone, M., and Hubel, D. (1988). “Segregation of form, color, movement and depth: Anatomy, physiology and perception.” Science 240 (4853): 740–749CrossRef Google Scholar PubMed

Mach, E. (1885). Die Analyse der Empfindungen. Jena: FischerGoogle Scholar

Mandik, P. (1999). “Qualia, space, and control.” Philosophical Psychology 12 (1): 47–60CrossRef Google Scholar

Mandik, P. (2001). “Mental representation and the subjectivity of consciousness.” Philosophical Psychology 14 (2): 179–202CrossRef Google Scholar

Mandik, P. (2002). “Synthetic neuroethology.” In Bynum, T. W. and Moor, J. H. (eds.), CyberPhilosophy: The Intersection of Philosophy and Computing. New York: Blackwell, 2003, pp. 8–25Google Scholar

Mandik, P. (2003). “Varieties of representation in evolved and embodied neural networks.” Biology and Philosophy 18 (1): 95–130CrossRef Google Scholar

Millikan, R. (1996). “Pushmi-pullyu representations.” In May, L., Friedman, M., and Clark, A. (eds.), Minds and Morals. Cambridge, MA: MIT Press, pp. 145–161Google Scholar

Milner, D., and Goodale, M. (1995). The Visual Brain in Action. Oxford: Oxford University PressGoogle Scholar

Oakes, R. (1978). “How to rescue the traditional causal theory of perception.” Philosophy and Phenomenological Research 38 (3): 370–383CrossRef Google Scholar

O'Craven, K., and Kanwisher, N. (2000). “Mental imagery of faces and places activates corresponding stimulus-specific brain regions.” Journal of Cognitive Neuroscience 12: 1013–1023CrossRef Google Scholar

O'Regan, J., and Noë, A. (2001). “A sensorimotor account of vision and visual consciousness.” Behavioral and Brain Sciences 24 (5): 939–1011CrossRef Google Scholar PubMed

Perrett, D., Mistlin, A., and Chitty, A. (1989). “Visual neurons responsive to faces.” Trends in Neurosciences 10: 358–364CrossRef Google Scholar

Peterhans, E., and der Heydt, R. (1991). “Subjective contours – bridging the gap between psychophysics and physiology.” Trends in Neurosciences 14: 112–119CrossRef Google Scholar PubMed

Prinz, J. (2000). “The ins and outs of consciousness.” Brain and Mind 1 (2): 245–256CrossRef Google Scholar

Prinz, J. (2001). “Functionalism, dualism, and the neural correlates of consciousness.” In Bechtel, W., Mandik, P., Mundale, J., and Stufflebeam, R. (eds.), Philosophy and the Neurosciences: A Reader. Oxford: BlackwellGoogle Scholar

Rosenthal, D. (1997). “A theory of consciousness.” In Ned Block, Flanagan, O., and Guzeldere, G. (eds.), The Nature of Consciousness. Cambridge, MA: MIT PressGoogle Scholar

Stevens, J., Emerson, R., Gerstein, G., Kallos, T., Neufield, G., Nichols, C., and Rosenquist, A. (1976). “Paralysis of the awake human: Visual perceptions.” Vision Research 16: 93–98CrossRef Google Scholar PubMed

Sullins, J. (2002). “Building simple mechanical minds: Using LEGO® robots for research and teaching in philosophy.” In Bynum, T. W. and Moor, J. H. (eds.), CyberPhilosophy: The Intersection of Philosophy and Computing. New York: Blackwell, 2003, pp. 104–116Google Scholar

Tye, M. (1995). Ten Problems of Consciousness: A Representational Theory of the Phenomenal Mind. Cambridge, MA: MIT PressGoogle Scholar

der Heydt, R., Peterhans, E., and Baumgartner, G. (1984). “Illusory contours and cortical neuron responses.” Science 224: 1260–1262CrossRef Google Scholar

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8 - Action-Oriented Representation

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