1. Chapter 9: Color What is color? Color mixtures –Intensity-distribution curves –Additive Mixing –Partitive Mixing Specifying colors –RGB Color –Chromaticity

2. What is Color? Wavelength is a property of an electromagnetic wave in the frequency range we call “light” Color is a psychological phenomenon that occurs when light waves of different wavelengths interact with the human visual system Light wave with wavelength 650 nm Human eye Human visual system and brain Color

3. Color Mixtures A spectral color is a single line on this graph: Green laser pointer 532 nm

4. Color Mixtures Almost everything we see is not a spectral color but a mixture of many spectral colors.

5. Intensity-Distribution Curves Both of these lights would appear white, so we can see there may be several intensity distributions that generate the same color

6. Additive Color Mixing How can we describe the sensation of a mixture of lights?

7. Additive Primary Colors Red, green and blue are called the additive primaries We want to select primary colors that allow us to create the largest possible number of other colors using just those primary colors Most colors can be described in terms of mixtures of red, green and blue cyan magenta yellow 650-nm red 530-nm green 460-nm blue

8. Additive Mixing: Yellow

9. Additive Mixing: Cyan

10. Additive Mixing: Magenta

11. RGB Color Specification RGB (red green blue) is another way of specifying colors. White is made by maximum saturation of all three colors Instead of hue, saturation and brightness, you can specify the amount of each color cyan magenta yellow 650-nm red 530-nm green 460-nm blue

12. RGB Colors: Example Hue: 35° Saturation: 100% Brightness: 100%

13. RGB Colors: Example Hue: 60° Saturation: 100% Brightness: 35%

14. RGB Colors: Example Hue: 60° Saturation: 0% Brightness: 40%

15. Complementary Colors We’ve seen that red light plus green light plus blue light equals white light: R + G + B = White But we also know that red light plus green light equals yellow light: R + G = Y If we do some dodgy “color math”, we get that yellow light plus blue light equals white light: Y + B = White

16. Complementary Colors We then define blue and yellow as complementary colors: When additively mixed, complementary colors produce white. Additive mixing NOT additive mixing

17. Concept Question What is the complementary color to green? A.Red B.Magenta C.Blue D.Yellow E.Cyan cyan magenta yellow 650-nm red 530-nm green 460-nm blue Recall: R + G + B = White We want: G + ?? = White

18. Chromaticity This is a chromaticity diagram (see color plate 9.2 in the book) We are not going to discuss where this comes from, please read that section of the book

19. Chromaticity A chromaticity diagram has a fixed brightness or lightness for all colors The most saturated colors (of different hues) are around the rim (perimeter) Inside are the less saturated colors, including white at the interior Saturated colors Unsaturated colors

20. Chromaticity The colors on the curved part of the edge are wavelength colors The colors on the straight part are non-wavelength colors, but are still 100% saturated. Wavelength colors Non-wavelength colors

21. Chromaticity: Lightness saturation lightness hue saturation hue

22. Uses of Chromaticity Diagrams To identify colors with three numbers To predict the results of additive mixing To understand complementary colors To find the dominant hue of a color To understand color gamuts and the significance of RGB mixing

23. Chromaticity: Identifying Colors The numbers that we use to identify a color are its x-value and y-value inside the diagram and a z-value to indicate its brightness or lightness x and y specify the chromaticity of a color Example: Apple pickers are told around the country that certain apples are best picked when they are a certain red (see black dot) x = 0.57 y = 0.28

24. Chromaticity: Identifying Colors The "purest" white is at x = 0.33 y = 0.33

25. Chromaticity: Color Mixtures An additive mixture of two wavelength colors lies along the line joining them Example: The colors seen by mixing 700 nm red and 500 nm green lie along the line shown Where along the line is the color of the mixture?

26. Chromaticity: Color Mixtures This depends on the relative intensities of the 700 nm red and the 500 nm green. Much more green than red gives a green Much more red than green gives an orange-red Slightly more red than green gives a yellow This also works for mixing colors not at the edges

27. Concept Question: Chromaticity What color would a mixture of these two colors (green and blue), equal amounts of each, look like? A.Yellow B.Red C.Pink D.Cyan E.Green

28. Chromaticity: Complementary Colors Recall that a color combined with its complement produces white If mixtures lie on the line between the two colors, then we can find the complement by drawing a line through white to the other side

29. Chromaticity: Complementary Colors Using this diagram, we can see that the complement of 700 nm red is 490 nm cyan And the complement of 520 nm green is magenta (a non-wavelength color)

30. Concept Question: Chromaticity What is the complementary color of blue, shown by the black dot? A.Yellow B.Red C.Pink D.Cyan E.Green

31. Chromaticity: Dominant Hues Unsaturated colors are related to their saturated counterparts by the additive mixture with white Ex: Pink (unsaturated) = red (saturated) + white

32. Chromaticity: Dominant Hues To find the dominant hue of the color indicated by the black dot Draw straight line from white through the point to get dominant wavelength, and hence, hue (547 nm green)

33. Chromaticity: Dominant Hues If hue is in the non- wavelength purples, find the complementary dominant wavelength by extending backwards through white (get 495 nm cyan) There is no dominant wavelength color for magentas and purples

34. Concept Question: Chromaticity What is the dominant hue of the color shown by the black dot? A.Yellow B.Red C.Pink D.Cyan E.Green

35. Chromaticity: Color Gamuts The gamut of colors which can be reproduced by an additive mixture of red, green and blue light is inside the triangle we now draw at right. 530-nm green 460-nm blue 650-nm red

36. Chromaticity: Color Gamuts Other gamuts are generally even smaller Say we picked red blue and yellow, the artists primaries: We would not be able to make cyans or greens

37. Concept Question: Color Gamuts If we selected our primaries as the three black dots shown, which colors would we NOT be able to make by combining them? In other words, which color is OUTSIDE the color gamut generated by these three primaries? A C D B E

38. Color Gamut of Flat Panel Displays The intensity distribution of the primary colors used in an LED backlit display The color gamuts of LED vs. CCFL backlit displays

39. Display Pixels: Partitive Mixing In additive mixing, we assume that the different wavelength colors reaching your eye are all coming from the same place:

40. Display Pixels: Partitive Mixing What it instead, we make the different colors coming from separate, very small, very closely spaced points You eye cannot see them as separate sources, so the colors mix and you see the same color. This is called partitive mixing

41. Partitive Mixing: Pointillism

42. Partitive Mixing: Pixels