Visual Imaging and the Electronic Age Color Science

Transcription

1 Visual Imaging and the Electronic Age Color Science Grassman s Experiments & Trichromacy Lecture #5 September 5, 2017 Prof. Donald P. Greenberg

2 Light as Rays

3 Light as Waves

4 Light as Photons

5 What is Color Science? Quantifying the physical energy which reaches the eye (physical) Determining the information which is sent from the retina (rods and cones) through the optic nerve to the human visual system (physiological stimuli) How does the brain interpret this information? (cognitive)

6 What is Color Science? Quantifying the physical energy which reaches the eye (physical) Determining the information which is sent from the retina (rods and cones) through the optic nerve to the human visual system (physiological stimuli) How does the brain interpret this information? (cognitive)

7 Color Rainbow over London.

8 Color

9 Visible Light Spectrum

10 Frequency Spectrum

11 Spectral Distributions of Natural Outdoor Light Sources CIE standard D 55 : typical sunlight D 65 : typical average daylight D 75 : typical north-sky light Power 400 Wavelength (nm) 700

12 Indoor Light Source Goniometric Diagram

13 Spectral Distribution Fluorescent Light

14 Spectral Distribution Incandescent Light

15 Additive & Subtractive Color Spaces RGB CMY

16 Printer Inks Black Cyan Magenta Yellow

17 Subtractive Reflection Processes

18 Spectral Distributions of Reflective Colors

19 Reflected Light P P P = = λ E λ = E ρ λ λ (EmittedLight) λ P = EE λλ ρρρρ dddd energy reaching the eye at all wavelengths E λ = ρ = λ emitted light energy at each wavelength reflected light energy at each wavelength

20 Reflected Light E λ ρ λ E ρ λ λ Roy S. Berns. Billmeyer and Saltzman s Principles of Color Technology, 3 rd Ed. 2000, John Wiley & Sons, Inc. p. 15.

21 Transparency

22 Transmitted Light PP = PP = PP = EE λλ dd λλ EE λλ pp λλ dd λλ EE λλ tt λλ dd λλ

23 What is Color Science? Quantifying the physical energy which reaches the eye (physical) Determining the information which is sent from the retina (rods and cones) through the optic nerve to the human visual system (physiological stimuli) How does the brain interpret this information? (cognitive)

24 Cross Section of Eye & Retina

25 Rods & Cones Comparison of a rod cell (right) and cone cell (left). This shows how each cell acquired its name from its shape.

26 Visible Light Spectrum S M L Dominant wavelengths of the cones of the human receptor system

27 Rods and Cones

28 Receptor Distribution fovea Adapted from Levine, Vision in Man and Machine McGraw-Hill, 1985.

29 Receptor Distribution

30 Receptor Distribution fovea parafovea periphery far periphery Cone Rod Adapted from Levine, Vision in Man and Machine McGraw-Hill, 1985.

31 Cone Responses S,M,L cones have broadband spectral sensitivity S,M,L neural response is integrated with respect to λ results in a trichromatic visual system

32 Question? How can a TV display reproduce (almost) every color sensation that we can experience using only 3 color phosphors? R,G,B?

33 Question? How can a printer reproduce (almost) every color sensation that we can experience using only 3 color inks? CMY?

34 Question? How can we reproduce such a vast range of color using two completely different sets of three primary colors? R G B vs C M Y

35 Grassmann s Color Matching Experiments (1853) Roy. S. Berns. Billmeyer and Saltzman s PRINCIPLES OF COLOR TECHNOLOGY, 2000 John Wiley & Sons, Inc.

36 Matching a Test Lamp with 3 Primary Lights We can match a color sensation from any spectrum using only 3 primary colors (R,G,B) spectral test lamp 700 nm 546 nm 436 nm observer

37 Matching a Test Lamp with 3 Primary Colors

38 Matching a Test Lamp with 3 Primary Lights Need to allow negative light Can t match a bright yellow (Y) light with R,G,B. But can match Y + B with R + G. spectral test lamp 436 nm 700 nm 546 nm observer

39 Matching a Test Color (Lamp) with 3 Primary Colors

40 Experiment to Determine the Response Matching Functions of the Average Human Observer 400 nm 700 nm 700 nm 546 nm 436 nm observer Individually match the RGB primary lights to the unit values of each of the spectral lamps.

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42 Response Matching Functions of the Average Human Observer These are the response matching functions of the average human observer for these three primary lights.

43 Trichromatic Generalization Many colors can be matched by additive mixtures of suitable amounts of three fixed primary colors. Others have to be mixed with a suitable amount of one before it can be matched by the other two. All the colors can be matched in one of these two ways: The restriction is that none of the primary colors can be matched by an additive mixture of the other two.

44 Trichromatic Generalization Proportionality and additivity are valid over a large range of observing conditions. Proportionality - If A=B, then ka=kb Additivity- If A=B, and C=D, the A+C=B+D

45 Observer Response x = x = Response Matching Functions Roy S. Berns. Billmeyer and Saltzman s Principles of Color Technology, 3 rd Ed. 2000, John Wiley & Sons, Inc. p. 46.

46 Computing Tristimulus Values with the Response Matching Functions For each test lamp we can compute the equivalent RGB tristimulus values using the color matching functions = = = λ λ λ λ λ λ λ λ λ d b P B d g P G d r P R ) ( ) ( ) ( ) ( ) ( ) (

47 Comments on Response Matching Functions Note that knowing the spectral distributions of the primary light sources and the response matching functions of the average human observer, we can then represent a large range of colors with any three primary light sources. (Monitors, cell phones, and printers). Perhaps most important, is the fact that these are perceptual spaces because a human observer is within the experimental testing loop. All of these tests have been conducted in a dark room and thus do not consider the effect of the illumination within the external environment.

48 Metamer A metamer is a phenomenon in which two spectrally different stimuli match to a given observer.

49 Metamers P P Physically different λ λ Perceptual filter R,G,B R,G,B Perceptually equal

50 Metamers Trichromacy, perhaps the most important property of the visual system, leads to metamerism. (Grassman 1853) Metamerism is a phenomenon in which spectrally different stimuli match to a given observer. Because of metamerism, color reproduction is possible. Stimuli do not have to have identical spectral properties in order to have a perceptual color match.

51 Typical LCD spectral radiance distribution Figure #3 --

52 Taking Advantage of Metamers P watts/m λ wavelength (nm) R,G,B = R,G,B Visual match

53 End...