1. ch 91 Sensation & Perception Ch. 9: Perceiving Color © Takashi Yamauchi (Dept. of Psychology, Texas A&M University) Main topics Functions of color Trichromatic theory Color deficiency Lightness constancy

2. ch 92 University of Iowa’s pick locker room http://sports.espn.go.com/ncf/news/story?id=2174828

3. ch 93 Paintings by impressionists

4. ch 94 A Sunday afternoon on the island of :La Grande Jatte: G. Seurat Alfalfa field, Saint-Denis: G. Seurat

5. ch 95 Water Lilies: C. Monet Sisley

6. ch 96 Bridge at Villeneuve-la- Garenne: Sisley

7. ch 97 Poplar along the River Epte, Autumn: C. Monet

8. ch 98 Why are these painting so bright?

9. ch 99 Aristotle contemplating a bust of homer: Rembrandt (1653) Bridge at Villeneuve-la- Garenne: Sisley

10. ch 910 Ingres: 1839

11. ch 911 Ingres: 1859

12. ch 912 Why are impressionists’ paintings so bright? Subject matter –Landscape, not much mythological figures Scientists discovered the physiological mechanism of color perception

13. ch 913 Color Physiologists: –Helmholtz (1821-1894) http://en.wikipedia.org/wiki/Hermann_von_Helmholtz –Hering (1834-1918) Impressionist painters: –Monet (1840-1926) –Seurat (1859-1891) –Pissarro (1830-1903) –Sisley (1839-1899)

14. ch 914 Impressionists were influenced by the theory of color perception

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21. ch 921 © Takashi Yamauchi

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23. ch 923 Colors, what are they? A brief review on vision

24. ch 924 What we see is electromagnetic energy

25. ch 925 What does the eye do? Capturing electromagnetic energy. –As the radio and TV do –Discerning different wave lengths

26. ch 926 What does the eye do?  Transducing light energy into neural energy

27. ch 927 Two types of photo receptors Cones and Rods Cones are for color vision

28. ch 928 Eye Photo receptors Two types of photo receptors – rod & cone

29. ch 929 3 types of cones There are three types cones that are selectively tuned to three different lengths of electromagnetic waves (Short, Medium, and Long)

30. ch 930 Short: –These cones react primarily to the waves whose length are about 419 nm (nano-meter) Medium: –These cones react primarily to the waves with 531 nm Long –These cones react primarily to the waves with 558 nm

31. ch 931 Color perception is produced by combinations of these 3 types of cones: Demonstration: VL 9-4

32. ch 932 Different objects reflect light in a different manners. Some objects (tomato) absorb short waves while reflect long waves  create a red surface. Absorb short waves but reflect long waves

33. ch 933 Mixing paints

34. ch 934 Demonstration: Mixing lights (VL 9-1)

35. ch 935 What the computer does is the same thing Pixel Bit Illuminating the phosphor with three different electron guns. Illuminate each pixel with red, green, and blue electron guns

36. ch 936 3 types of electron guns: a red gun, a green gun, and a blue gun

37. ch 937 Why do the impressionists’ paintings so bright?  They did the same thing.  Computer scientists and impressionists developed their ideas based on the psychological theory of color perception.

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42. ch 942 My paintings

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49. ch 949 After Image

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56. ch 956 Why do we get after-images? After-images have something to do with adaptation. What is adaptation? –Motion –Spatial frequency Look at the demonstration of motion adaptation

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59. ch 959 Simultaneous Color Contrast Why do the X’s look different in the two rectangles? Some sort of inhibitory mechanism is going on?

60. ch 960 More Phenomenological Observations Visualize something red (apple, fire engine) –Now reddish-yellow –Now reddish-green Visualize something blue (sky, pool) –Now bluish-green –Now bluish-yellow Which is hardest to visualize? Note – very little overlap in color sensation of blue and yellow, and of red and green People who are color-deficient for red also lack green; same with blue and yellow

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63. ch 963 Trichromatic  Opponent- process Trichromatic stage: 3 kinds of cone receptors (S, M, L) Opponent process At the bipolar or ganglion cells, the difference between S and (M+L) (Circuit 1) and the difference between M and L (Circuit 2) is assessed. The first circuit (Circuit 1) processes the blue-yellow difference. The second circuit (Circuit 2) processes the red-green difference.

64. ch 964 Opponent-process theory (Hering/Hurvich & Jameson) Color vision is caused by opposing responses generated by blue and yellow, and by red and green.

65. ch 965 After images: Red  Green Green  Red Blue  Yellow Yellow  Blue RGBY Color perception

66. ch 966 R G BY adaptation After image

67. ch 967 Trichromatic  Opponenct- process Two stages in color perception Trichromatic stage: 3 kinds of cone receptors (S, M, L) Opponent process At the bipolar or ganglian cells, the difference between S and (M+L) (Circuit 1) and the difference between M and L (Circuit 2) is assessed. The first circuit (Circuit 1) processes the blue-yellow difference. The second circuit (Circuit 2) processes the red-gree difference.

68. ch 968 Fig. 7-20, p. 155 Responses of opponent cells in the monkey’s LGN

69. ch 969 From S. Palmer (1999) Vision Science

70. ch 970 Opponent-process theory Inhibitory Excitatory S M L Relativeresponses S M L S, M, and L cones have inhibitory and excitatory connections at LGN.

71. Opponent-process theory Inhibitory Excitatory S M L Relativeresponses S M L S, M, and L cones have inhibitory and excitatory connections at LGN.

72. ch 972 Demonstration VL 9-12

73. ch 973 Opponent-process theory The opponent-process is more like a mechanism to detect the different responses in the three types of cones. This allows the visual system to record differences between the responses of cones, rather than each type of cone's individual response.

74. ch 974 Why is this process efficient? Distinguishing the two wavelengths, 1 and 2 is very hard using just the M and L receptors. Opponent process create two categorical responses  + or –

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78. ch 978 Huichol masks (Mexican Indian tribe)

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81. ch 981 Color blindness Can be caused by the disorder in cone receptors, optic nerves, and/or other higher brain areas responsible for color perception (e.g., V4). Most problems in color vision is associated with problems with the cone receptors in the retina.

82. ch 982 Monochromat –Cannot distinguish any color from gray. (all or two of the cone systems are compromised) Dichromat –Only one cone system is compromised.

83. ch 983 Constancy Color constancy –We perceive the colors of objects as being relatively constant even under changing illumination. –A green sweater is green no matter where you see it. –How come?

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85. ch 985 Background knowledge and your memory contribute to color constancy. You compare the color of your sweater with other surrounding things. Adaptation

86. ch 986 Lightness constancy Both top-down and bottom-up processes are going on.

87. ch 987 Different amounts of light are reflected from the same surface in (a) and (b). But our perception of lightness is pretty much the same (lightness constancy) How come?

88. ch 988 Lightness constancy Constancy is so prevalent that we even don’t notice that. My skin reflects much less light in this room than in outside. But people don’t think that my skin color changes every time I enter a building.

89. ch 989 Ratio principle Perceive lightness of an object with respect to the surrounding area. E.g., –When I enter a building, everything loses illumination, so perceived lightness of my face remains the same.

90. ch 990 How does the visual system distinguish reflected light from illuminated light?

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92. ch 992 The LGN is the first stop in the visual pathway. The LGN receives more input back from the cortex than from the retina.