color 1.selective reflection most objects "reflect" rather than emit light. radiations...
TRANSCRIPT
Color
1. SELECTIVE REFLECTION
• Most objects "reflect" rather than emit light.
• Radiations that match the resonant frequencies of the atoms are absorbed.
• Frequencies of the radiations on either side of the resonant frequencies are “reflected.”
• Objects can only reflect the light that is in
the source illuminating the object.
2. SELECTIVE TRANSMISSION
• As light passes through materials some frequencies of light are removed (absorbed) while other frequencies are transmitted.
• The degree of transmission depends on how transparent the material happens to be.
• Color filters are good examples of selective
transmission.
• Demo – Color Filters and White LightDemo – Color Filters and White Light
3. MIXING COLORED LIGHT
• All visible frequencies make up white light.
• Example: The sun emits all frequencies and its
light is white.
• (Actually it is slightly yellowish to us on Earth,
which possibly explains why we are more
sensitive to light in the middle of the spectrum.)
• RED, GREEN, and BLUE when added also produce white.
• Demo - Color Addition and Colored ShadowsDemo - Color Addition and Colored Shadows• Color Addition Schematic
• Red, green, and blue are
called the additive primaries.
Color Addition
Through color addition you are able to see a wide
range of colors from a color TV or color projector
which actually only emit three different colors.
These colors are red, green, and blue.
They are called the additive primaries.
Your vision system “adds” these together to see a
single color from a single location illuminated by
more than one color.
You even see colors that don’t appear in the
continuous emission spectrum of the sun.
Red, green, and blue are used as the additive
primaries because this set of three will produce the
widest range of colors that you visually
experience.
On the next slide you will see what happens as you add colors to produce other colors.
Note that cyan is the addition of green and blue.
Note that yellow is the addition of red and green.
White
Red
Green
Blue
Yellow
Cyan
Magenta
Colors in White Light
Note that magenta is the addition of red and blue.
You can see that these three add to give white.
4. MIXING COLORED PIGMENTS
• Subtractive primaries - YELLOW,
CYAN, and MAGENTA
• Example - Mixing paints, zip-lock
sandwich bags, color printing
• Demo - Color SubtractionDemo - Color Subtraction
Color Subtraction
Through color subtraction you are able to see a
variety of colors from printings, paintings, etc.
If you have ever bought printer inks, you will
notice that the ones used to provide a variety of
colors in printing are yellow, cyan, and magenta.
They are called the subtractive primaries.
In subtraction, colors are eliminated by the
absorption of colors that were in the original
illuminating source.
This particular set of three colors, yellow, cyan,
and magenta, will produce the widest range of
colors that you visually experience.
White
Yellow
Take away yellow and what is left?
You get blue.
Blue
Colors in White Light
WhiteRed
Take away cyan and what is left?
Cyan
You get red.
Colors in White Light
Magenta
White
Take away magenta and what is left?
You get green.
Green
Colors in White Light
What you are about to see is what you would get with three partially overlapping transparencies on an overhead projector.
Color Subtraction Circles
Red
Green
Blue
YellowCyan
Magenta
• It should be noted from the previous that objects that reflect a particular color are themselves good absorbers of the complimentary color of that particular color.
• For examples:
• A red object is a good absorber of cyan and vice versa.
• A blue object is a good absorber of yellow and vice versa.
• A green object is a good absorber of magenta (blues and reds) and vice versa.
5. WHY THE SKY IS BLUE
• Just as resonating tuning forks scatter sound, so do particles in our atmosphere scatter light.
• N2 and O2 scatter high frequencies which are near natural frequencies of N2 and O2.
• (Natural frequencies are in the UV.)• This scattering produces the bluish sky.• The blue end of the spectrum is scattered ten times
better that the red end.
6. WHY SUNSETS ARE RED
• If the atmosphere becomes thicker or the paths
of light through the atmosphere become longer,
more of the longer wavelengths of light will be
scattered.
Sunset
Sun
Sun
Earth
• Because of scattering of blue light the sun
appears more yellowish at noon than it really is.
7. WHY CLOUDS ARE WHITE
• Droplet size dictates which colors are
scattered best.
• Low frequencies scatter from larger particles.
• High frequencies scatter from small particles.
• Electrons close to one another in a cluster
vibrate together and in step, which results in a
greater intensity of scattered light than from the
same number of electrons vibrating separately.
• Large drops absorb more and scatter less.
8. WHY WATER IS GREENISH BLUE
• Water quite often looks bluish.
• This is due to reflected “sky light.”
• A white object looks greenish blue when
viewed through deep water.
• Water is a strong absorber in IR and a little in
red.
• Remove some of the red and cyan is left.
• Crabs and other sea creatures appear black in
deep water.
9.9. COLOR VISION ANDCOLOR VISION ANDCOLOR DEFICIENCYCOLOR DEFICIENCY
• Colorblindness (color deficiency) affects
about 10% of population
• Red-green is predominant• Yellow-blue - a few
• Total – some
• Colorblindness Tests – Colorblindness Tests – URL
10. AFTER IMAGES
• Slides - After Images - After Images
• After images are due to conal fatigue.
• Cones that have been “firing” for a while
will not “fire” as well as “rested” cones
when all are exposed to white light.
Chapter 27 Review Questions
Most of the light that we see has undergone(a) selective interference
(b) selective transmission
(c) selective reflection
(d) selective refraction
A mixture of magenta and green lights give white light. These two colors are
(a) additive primaries
(b) secondary colors
(c) complementary colors
(d) fluorescent colors
(e) interference colors
Mixing yellow paint and magenta paint gives what color? (a) red
(b) green
(c) blue
(d) cyan
What color would red cloth appear if it were illuminated by cyan light?
(a) cyan
(b) red
(c) yellow
(d) green
(e) black
The sky is blue because air molecules in the sky act as tiny
(a) mirrors which reflect only blue light
(b) resonators which scatter blue light
(c) sources of white light
(d) prisms
(e) none of these
When you stare at a red object for a long time without moving your head and eyes and then suddenly look away at a white screen, you will see a image of the object.
(a) red
(b) blue
(c) cyan
(d) green
(e) white