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Newton's colour circle and Palmer's “normal” colour space

Published online by Cambridge University Press:  01 February 2004

Gábor A. Zemplén*
Affiliation:
Department of Philosophy and History of Science (MTA TKI), Budapest University of Technology and Economics, H-1111Budapest, Hungaryhttp://hps.elte.hu/~zemplen

Abstract:

Taking the real Newtonian colour circle – and not the one Palmer depicts as Newton's – we don't have to wait 300 years for Palmer to say no to the Lockean aperçu about the inverted spectrum. One of the aims of this historical detour is to show that one's commitment about the “topology” of the colour space greatly affects Palmer's argument.

Type
Continuing Commentary
Copyright
Copyright © Cambridge University Press 2004

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References

Beegan, J. A., Ingling, C. R., Jr., Billock, V. A. & Tsou, B. H. (1999) Nonlinear dynamics of human color vision: Order effects in the spectral locations of unique hues are meaningful. Investigative Ophthalmology and Visual Science 40 (Suppl.): 981. [VAB]Google Scholar
Billock, V. A. (1996) Consequences of retinal color coding for cortical color decoding. Science 274:2118–19. [VAB]Google Scholar
Billock, V. A., Gleason, G. A. & Tsou, B. H. (2001) Perception of forbidden colors in retinally stabilized equiluminant images: An indication of softwired cortical color opponency? Journal of the Optical Society of America A 18:2398–403. [VAB]Google Scholar
Block, N. (1999) Jack and Jill have shifted spectra. Behavioral and Brain Sciences 22:946–47. [VAB]Google Scholar
Boynton, R. M. (1966) Vision. In: Experimental methods in instrumentation and psychology, ed. Sidowski, J. B. McGraw Hill. [VAB]Google Scholar
Cobb, S. R. (1975) The unique green phenomena and colour vision. Clinical Genetics 7:274–79. [VAB]Google Scholar
Dedrick, D. (1996) Can colour be reduced to anything? Philosophy of Science 63:134142. (Proceedings of the Philosophy of Science Association Meetings.) [GAZ]Google Scholar
Descartes, René (1644/1931) The principles of philosophy. In: The Philosophical Works of Descartes. Corrected edition, vol. I, trans. Haldane, Elizabeth S. & Ross, G. R. T. Cambridge University Press. (English translation, 1931). [RK]Google Scholar
Hardin, C. L. (1988) Color for philosophers. Hackett Publishing. [VAB]Google Scholar
Hardin, C. L. (1999) Color relations and the power of complexity. Behavioral and Brain Sciences 22(6):953–54. [RK]Google Scholar
Hovis, J. K. & van Arsdel, R. (1997) The influence of white light on the location of unique green. In: John Dalton's colour vision legacy, ed. Dickerson, C., Murray, I. & Carden, D. Taylor & Francis. [VAB]Google Scholar
Hurvich, L. M. & Jameson, D. (1974) Opponent processes as a model of neural organization. American Psychologist 29:88102. [VAB]Google Scholar
Hurvich, L. M., Jameson, D. & Cohen, J. D. (1968) The experimental determination of unique green in the spectrum. Perception and Psychophysics 4:6568. [VAB]Google Scholar
Ingling, C. R. Jr., (1977) The spectral sensitivity of the opponent-color channels. Vision Research 17:1083–89. [VAB]Google Scholar
Ingling, C. R. Jr., Martinez-Uriegas, E. & Grigsby, S. S. (1990) Test for a correlation between Vl and the +y opponent channel sensitivity. Color Research and Application 15:285–90. [VAB]Google Scholar
Ingling, C. R. Jr., Russell, P. W., Rea, M. S. & Tsou, B. H. (1978). Red-green opponent spectral sensitivity: Disparity between cancellation and direct matching methods. Science 201:1221–23. [VAB]Google Scholar
Jakab, Z. (1999) Overlooking the resources of functionalism? Behavioral and Brain Sciences 22(6):957. [RK]Google Scholar
Jameson, K. & D’Andrade, R. G. (1997) It's not really red, green, yellow, blue: An inquiry into perceptual color space. In: Color categories in thought and language, ed. Hardin, C. L. & Maffi, L. Cambridge University Press. [GAZ]Google Scholar
MacLennan, B. (1999) Neurophenomenological constraints and pushing back the subjectivity barrier. Behavioral and Brain Sciences 22(6):961–63. [RK]Google Scholar
Malcolm, N. L. (1999) Consciousness – subject to agreement. Behavioral and Brain Sciences 22(6):963. [GAZ]Google Scholar
Miyahara, E., Pokorny, J., Smith, V. C., Baron, R. & Baron, E. (1998) Color vision in two observers with highly biased LWS /MWS cone ratios. Vision Research 38:601–12. [VAB]Google Scholar
Mollon, J. D. (1982) Color vision. Annual Review of Psychology 33:4185. [VAB]Google Scholar
Mollon, J. D. & Jordan, G. (1997) On the nature of unique hues. In: John Dalton's colour vision legacy, ed. Dickerson, C., Murray, I. & Carden, D. Taylor & Francis. [VAB]Google Scholar
Myin, E. (1999) Beyond intrinsicness and dazzling blacks. Behavioral and Brain Sciences 22(6):964–65. [RK]Google Scholar
Newton, I. (1704/1730/1952) Opticks. Dover. (First edition, 1704. Fourth edition 1730, used for Dover 1952 reprint.) [GAZ]Google Scholar
Palmer, S. E. (1999) Color, consciousness, and the isomorphism constraint. Behavioral and Brain Sciences 22(6):923–89. [VAB, RK, GAZ]Google Scholar
Pauen, M. (1999) Phenomenal experience and science: Separated by a “brick wall”? Behavioral and Brain Sciences 22(6):968. [RK]Google Scholar
Pokorny, J. & Smith, V. C. (1977) Evaluation of a single pigment shift model of anomalous trichromacy. Journal of the Optical Society of America 67:11961209. [VAB]Google Scholar
Pokorny, J., Smith, V. C. & Wesner, M. F. (1991) Variability in cone populations and implications. In: From pigments to perception, ed. Valberg, A. & Lee, B. B. Plenum Press. [VAB]Google Scholar
Regan, D. (1991) The Prentice Award Lecture: Specific tests and specific blindnesses: Keys, locks and parallel processing. Optometry and Visual Science 68:489512. [VAB]Google Scholar
Richards, W. (1967) Differences among color normals: Classes I and II. Journal of the Optical Society of America 57:1047–55. [VAB]Google Scholar
Roorda, A. & Williams, D. R. (1999) The arrangement of the three cone classes in the living human eye. Nature 397:520–22. [VAB]Google Scholar
Ross, P. W. (1999) An externalist approach to understanding color experience. Behavioral and Brain Sciences 22(6):968. [GAZ]Google Scholar
Rubin, M. L. (1961) Spectral hue loci of normal and anomalous trichromates. American Journal of Ophthalmology 52:166–72. [VAB]Google Scholar
Saunders, B. (1999) One machine among many. Behavioral and Brain Sciences 22(6):969. [GAZ]Google Scholar
Schröder, J. (1999) Computation, levels of abstraction, and the intrinsic character of experience. Behavioral and Brain Sciences 22(6):970–71. [RK]Google Scholar
Tolliver, J. T. (1999) Sensory holism and functionalism. Behavioral and Brain Sciences 22(6):972–73. [RK]Google Scholar
Van Gulick, R. (1999) Out of sight but not out of mind: Isomorphism and absent qualia. Behavioral and Brain Sciences 22(6):974. [RK]Google Scholar
Viger, C. D. (1999) The possibility of subisomorphic experiential differences. Behavioral and Brain Sciences 22(6):975. [RK]Google Scholar
Waaler, G. H. M. (1967) Heredity of two types of normal colour vision. Nature 215:406. [VAB]Google Scholar
Wallstein, R. S. (1981) Photopigment variation and the perception of equilibrium yellow. Doctoral dissertation, University of Chicago. [VAB]Google Scholar