1 / 26

Interaction of light with paint

Interaction of light with paint. Review of some color ideas Histories of light rays coming to our eyes Index of refraction 1—Front surface of painting 2—Thick white paint 3—Thick red paint. “Perfect” R, G and B.

fjonell
Download Presentation

Interaction of light with paint

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Interaction of light with paint • Review of some color ideas • Histories of light rays coming to our eyes • Index of refraction • 1—Front surface of painting • 2—Thick white paint • 3—Thick red paint

  2. “Perfect” R, G and B • Suppose we could find sources which excite either ONLY the R, only the G or only the B cones. (Hard to see how, but let’s suppose!)

  3. A “perfect”color space y = “perfect” green 1.0 0.9 “perfect” blue x = “perfect” red 0.8 0.9 1.0

  4. Coordinates of the CIE plot y = “perfect” green 1.0 0.9 “perfect” blue x = “perfect” red 0.8 0.9 1.0

  5. Mixing spectral color with white • Hue • Which spectral color • Saturation • How little white • Brightness • How much of everything

  6. ****Hue, saturation, brightness**** • I have a color A with source intensities (R,G,B) = (128, 64, 64), i.e., 128 units of R, 64 units of G and B. • I make another color B with (R,G,B) = (64,128,64). • I make another color C with (R,G,B) = (116,70,70). • I make another color D with (R,G,B) = (140,70,70). • I make another color E with (R,G,B) = (120,120,100). • Comparing each of B, C, D and E with A, fill in the table giving the change in hue, saturation and brightness using the code L = less, D = different, M = more, S= same. • hue saturation brightness • B D S S • C S L S • D S S M • E D L M

  7. Hue, saturation and brightness brightness saturation

  8. Saturation of color • Can make any color in chromaticity diagram by mixing a spectral color with white • Highly saturated means mostly spectral • Unsaturated means mostly white

  9. Cross-section of painting varnish binder pigment ground substrate • What do we see?? • How many different things can happen?? • Critical properties — index of refraction, particle size, transmission spectra

  10. Index of refraction Speed of light fast slow n1 n2 > n1 • Light bends (refracts) as goes from air to water (or glass, or …) • Velocity of light in medium • s = c/n c = 3 x 108 m/s • n = index of refraction • typically 1 < n < 2 • sin q1/sin q2 = n2/n1 • Bending ~ (n2 - n1) • More refraction if n’s are very different q2 q1

  11. Reflection Speed of light fast slow n1 n2 > n1 • Light is reflected as goes from air to water (or glass, or …) • Velocity of light in medium • s = c/n c = 3 x 108 m/s • n = index of refraction • typically 1 < n < 2 • specular reflection qi = qr • Reflected intensity ~ (n2 - n1)2/ (n2 + n1)2 • More reflection if n’s are very different qi qr

  12. *****Reflection***** • I have a painting with a varnish overcoat. The varnish has an index of refraction n = 1.6 and the paint (assume it to b a flat, smooth surface) has n = 2.0. Will the front surface reflection for this painting be dominantly from the air/varnish interface or the varnish/paint interface? air/varnish interface

  13. Surface finish—physics • Varnish • Flat, smooth surface • Specular reflection • Reflected beams—single direction—(and “white”) • Raw paint • Rough, uneven surface • Diffuse reflection • Reflected beams—random directions—(and “white”) • (Two-step index change alsoreduces reflection—see T&M)

  14. Surface finish—what do we see • Consequences • Specular • Annoying reflections from lamps, windows • Diffuse • Avoids annoying reflection problem by killing specular reflection • But get weak reflection of white light at all angles—“light fog,” i.e., colors less saturated • Specular • Avoids reduction of color saturation • Most museums: lights and windows, if any, will be high • Examples • Raw paint versus varnish on paintings • Matte versus glossy finish on photos • Anti-reflection versus normal glass • Unfinished versus polished (or wet) stone

  15. White paint • White paint made of transparent pigment and binder • Why is it white? • Why is it not transparent? • Clouds made of transparent water • Why are clouds white? • Why are cloudy days dark?

  16. Scattering of light • Parallel light beam incident on sphere • Refracted as enters the sphere • Refracted again as leave the sphere • Typical scattering angle q ~ (n1 - n2) • (scattering by reflection as well!) Q

  17. Multiple scattering D • L = “mean free path” = typical distance before directional memory is lost • Transmission (fraction that gets through) T = L/D • Fraction diffusely reflected = R = (1 - L/D) • Color reflected = color incident (usually = white)

  18. Effect of binder index of refraction D Smaller (n2 - n1) implies: smaller q more scatterings to randomize direction longer mean free path L deeper penetration

  19. Effect of binder index of refraction Smaller (n2 - n1) implies: smaller q more scatterings to randomize direction longer mean free path L deeper penetration glass/air glass/linseed oil

  20. Colored pigment • Key new property of pigment— selective absorption • Each pigment particle like a filter • Subtractive combination of filtering by number of particles • Multiply transmission spectra • What are the consequences?

  21. Filtering by multiple particles 400 500 600 700 Suppose light passes through n = 1, 2, …, 64 particles transmission 1 1 2 4 8 0.5 16 32 64 0

  22. Change of hue with particle number 400 500 600 700 transmission 1 1 0.5 2 4 0 8

  23. Index of refraction difference(for fixed particle size) • Binder and pigment—large (n1 - n2) • Short mean free path L • Typical ray gets out very quickly • Total pathlength is small • Color unsaturated and bright • Binder and pigment better “index matched” • Long mean free path L • Typical ray penetrates deeply • Total pathlength is long • Saturated color but less bright • Possible change of hue

  24. *****miscellaneous***** • We didn’t talk about thin paint layers, but you should be able to answer these anyway!!!! Think about two cases, one with a white ground (reflecting any light that reaches it), the other (unconventional, but I’m a physicist) with a black one (absorbing all of the light that reaches it). • A) Each has a thin layer of red paint on it. (Thin means some of the light reaches the ground.) Which will show the brighter color? • B) Each has a thin layer of red paint on it. See if you argue why the one with the white ground will show the greater saturation? (If anyone asks, the answer will appear in the FAQs later in the week/) • C) If a binder contains a mixture of two different pigments, do we need to combine the colors of the two pigments additively or subtractively? • D) I’m mixing my own paints and find that a paint I have made gives a rather pale washed out color. Should I try to add more binder to allow the light to penetrate more deeply? Should I try to use less binder so that the light has to go through more pigment? Should I use a binder with an index of refraction closer to that of the pigment? • A) The one with the white ground • C) Subtractively • D) no, no, yes

  25. Light, paint and color • A few basic ideas: • Hue, saturation and brightness • Index of refraction—refraction/reflection • Front surface of painting—diffuse/specular • Thick white paint—clear pigment/white paint • Thick red paint—many-filter model • The subtleties: ????

More Related