light the human perception of color. color : what to learn in this lesson color isn’t “real”,...
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Light
The Human Perception of Color
Color: what to learn in this lesson
• Color isn’t “real”, it is a figment of our imagination
• Color only “exists” in the human mind
• Energy is the real characteristic of every light particle
• Our eyes can detect only a small range of the possible energies
• Goal today is to understand this . . .
Description of LIGHT
• Called the Electromagnetic spectrum
• Based on the energy of the photons
The EM spectrum
• LIGHT comes in two “flavors”:
1. VISIBLE LIGHT: the very small range of energies of
light which our eyes can detect.
2. There is MUCH, MUCH more light which is not “visible” to human eyes.
HIGHER ENERGY than visible light:
• EXAMPLES:
cosmic rays gamma rays X rays ultraviolet
HIGHER ENERGY
LOWER ENERGYEnergies too high for human
vision
The ELECTROMAGNETIC SPECTRUM
•
Energy is too HIGH for human eyes, normal vision
HIGH f Short
LOWER ENERGY than visible light:
• EXAMPLES:
infrared (heat) microwaves radio & TV waves
HIGHER ENERGY
LOWER ENERGYEnergies too low for human
vision
The ELECTROMAGNETIC SPECTRUM
•
Energy is too LOW for human eyes, normal vision LOW f Long
The VISIBLE LIGHT spectrum• the portion of the electromagnetic
spectrum we can sense with our EYES.
• Our skin can detect other portions as well . . . Leading to sunburn, cancer . . .
• Both UV and IR are invisible to our eyes, but are sensed by the skin.
• Some of the energies, “colors of light”, which are invisible to humans
are visible to other species.
The VISIBLE LIGHT spectrum
Red
LOW energy
LOW frequency
LONG wavelength
Blue
HIGH energy
HIGH frequency
SHORT wavelength
R O Y G B I V
SUMMARY: EM spectrum
Radio & TV micro IR visible UV X rays rays
low ENERGY high
low FREQUENCY high
long WAVELENGTH short
low DANGER to LIFE high
Know this table and “ROY G BIV”
See page 521 in your text
Where does light come from?
• Photons are emitted when electrons lose energy:
• All atoms are surrounded by electrons• CHEMISTRY CONNECTION: these
electrons “live” in certain energy levels• Electrons can change energy states in
an atom: if they Absorb light: gain energyLoose energy: emit light
OUTCOME• Atoms of each element have a unique,
characteristic electron configuration.• Each element has a
unique, characteristic light spectrum.• A specific element can only emit and
absorb particular energies of light.• We can only “see” some of those
“colors .
Atomic emission spectra
Atomic sources• Hydrogen
• Helium• Neon• Argon
• Krypton• Mercury
Compound sources
• H2O
• CO2
SOURCES of light: In order, from left to right
Our eyes “see” a collection of different energies . . . .
• We normally “see” a lot of different colors SIMULTANEOUSLY.
• To see what colors are really there, we have to use a diffraction grating.
• Notice the differences when we look at each light, one at a time:
Hydrogen
Helium
Neon
Argon
Krypton
Mercury
H2O
CO2
How do we see colors ?
• We see when light enters the eye.
• No light: DON’T SEE ANYTHING.
• Our brain processes light information two ways:1) in the “where” system2) in the “what” system
• The following examples of visual stimuli demonstrate some of the things we experience because of our color vision.
Example #1
The twinkling black spots do not actually exist in the intersections of the gray lines on the next slide.
You can discover this by focusing on one particular intersection.
The spots appear because of the way the cones and rods in your eyes respond to light.
This is easy to read, so you can decide to ignore it very rapidly
Very low contrast text is read by the part of the brain which locates objects, the “where” system.
As long as the words are easy to recognize, you can read rather rapidly, but recondite or infrequently encountered words seem unfamiliar and have to be read letter-by-letter.
This is also hard to read. It jumps around and seems unstable because the “where” system has trouble seeing it. Advertisers use this trick to make you pay attention because you have to slow down and read each individual word.
This is also hard to read. It jumps around and seems unstable because the “where” system has trouble seeing it. Advertisers use this trick to make you pay attention because you have to slow down and read each individual word.
Changing the color of the letters helps a lot
This is also hard to read. It jumps around and seems unstable because the “where” system has trouble seeing it. Advertisers use this trick to make you pay attention because you have to slow down and read each individual word.
Changing the background color also helps a lot
This is hard to read even though each individual letter is easy to see, so you have to pay a lot of attention in order to read it.
Why do things like this happen ?
When light enters the eye . .
• Light from some source strikes the eye• Passes through the CORNEA• Amount let in controlled by the IRIS
which adjusts the opening of the PUPIL• The light is focused by the LENS,• passes through some “transparent stuff”
and strikes the RETINA.• It is absorbed, creating an electrical signal
which is sent by the optic nerve to the brainwhere it is perceived as an image.
COLOR VISION ONLY EXISTS IN THE BRAIN
• Biology connection:• Color is not something “real” or
“special” about the visible spectrum.• Most species do not see color.
• We see color because of the way our eyes are built . . . . . and the way our brain interprets what we see.
How do we see the different colors?
• Occurs because of the construction of the retina.
• The retina is composed of millions of photoreceptor cells
called “rods” and “cones”.
rods• Can not distinguish energies (see color)
• Can only sense brightness.• Extremely sensitive to dim light.
• Are use to identify object location using the “where” portion of the brain perceptual processing centers.
• The way rods work are behind the checker board pattern illusion.
rods
• Do not detect “edges” well: so are not very useful in reading. ( Large pixels)
• Used to see at night. Helpful in looking at stars.
• Quite sensitive to peripheral motion.
Testing rods . . .
ZA
M
GN
Q
S WT
RH
O
Y
JG
V
AP
L
B
M
K
FQ
U
D
WT
P
Y
C
B
cones
• Function only under bright light conditions (takes a lot of photons).
• Cones can distinguish different photon energies.
• Very sensitive to edges; good focus. VERY Small pixels
• About 3 million packed in fovea, center part of the retina.
• Fovea is where image is formed when we look at something.
How does color vision work?• Three kinds of cones:
about 3 million in the fovea.
• “Blue” cones = about 1 %
• The rest are “Green” and “Red”
• Each type of cone is sensitive to a range of energies (what we call “colors”)
BLUE cones
GREEN cones
RED cones
The VISIBLE LIGHT spectrum
Basic understanding
All of the “colors” of the rainbow actually exist in an energy sense.
But because of the way our eyes work :1. we can see yellow when we see
yellow or2. we can “see yellow” when only the
colors red and green are both present at the same time . . . .
At night, we see the higher energy photons much better that during the daytime
What are the PRIMARY COLORS ?
• Based on the way the human eye workswe synthesize “colors” in our brain.
• The human mind creates our color palate.• In practice, it only takes three colors:
BLUEGREENRED
to “see” all of the colors known to humans.
Primary colors of light
Examples of 3 color process:• Called “color by addition”: adding colors
of light.
• Television sets and computer monitors: all are “RGB”
• Works for all SOURCES OF LIGHT.
• Remember that each type of cone “SEES” more than a single shade of color.
Primary colors of light
BLUE
GREEN RED
Secondary colors are formed by addition of
primary colors BLUE
GREEN RED
MAGENTA
YELLOW
CYAN
White formed by addition of all three primary colors
BLUE
RED GREEN
WHITE
White also formed by addition of all three
secondary colors
MAGENTA CYAN
YELLOW
WHITE
Color of light relationships
BLUE
GREEN RED
MAGENTA
YELLOW
CYAN
WHITE
PRIMARY and SECONDARY colors for
pigments
Works for all materials which control color by absorption
Seeing REFLECTED light.
Seeing TRANSMITTED light.
Pigments (paint, ink, filters)
• DEFINE: Primary colors of pigment • Absorb only one primary color of
light.
• YELLOW absorbs only BLUE• CYAN absorbs only RED• MAGENTA absorbs only
GREEN
Pigments (paint, ink, filters)
• DEFINE: Secondary colors of pigment • Absorb two primary colors of light.
• BLUE absorbs both RED and GREEN
• RED absorbs both BLUE and GREEN• GREEN absorbs both RED and BLUE
What is IMPORTANT:
• ASK: What colors are eliminated from the light source ?
• When any light hits a page, some of the light is absorbed.
• The rest is reflected into your eye.
• The color you see is based on the reflected
colors that enter your eye.
Comparison of PRIMARY colors
• EMISSION
BLUERED
GREEN
• REFLECTION or TRANSMISSION
YELLOWMAGENTA
CYAN
Comparison of SECONDARY colors
• REFLECTION OR TRANSMISSION
BLUERED
GREEN
• EMISSION
YELLOWMAGENTA
CYAN
Filters and slides• Theater filters are used to
eliminate colors from white.• Slide projectors and movie film is
designed to eliminate colors from white.
• Some glasses are designed to eliminate colors from white.
• Colored glass also eliminates colors from white.
EXAMPLES of color by subtraction
• COLOR SLIDES• Photographic printing,
magazines, computer printers, newspapers.
Three basic ways to see color:
• Color by emission : the object emits colors of light.
• Color by transmission: a filter absorbs some colors
while letting others pass through
• Color by reflection: pigment absorbs some colors
while letting others reflect off.
In order to observe all “human” colors, you must have a “white light source”.
IMPORTANT CONCLUSION
What you THINK you see vs.
what is REALLY THERE
EXAMPLE: You can “see” yellow two different ways:
1. When only YELLOW LIGHT is present: it stimulates both red and green cones.
• ONLY YELLOW LIGHT is really present.
2. When the RIGHT AMOUNT of both RED and GREEN are present
• It APPEARS to be YELLOW but only RED and GREEN are actually being seen.
Key question:• What color(s) of light are actually
entering your eye?
• To see a particular color, the right colors of light have to (1) be present and (2) entering the eye to stimulate the cones by the right amount.
• You CAN NOT see a color that isn’t present in the light SOURCE.
One More Reason Why Physics is Better Than Drugs
Sunset on Maui