Midterm 2: Color Vision

Question 1

What color cone was the first to evolve?

Answer 1

Blue cones were the first to evolve

Question 2

What is the relationship between the opsin molecules of red and green cones?

Answer 2

The red and green cones are very similar. There are only a few differences in amino acids between the two. This is what causes the green and red to be located closely to one another on a spectral sensitivity graph.

Question 3

What is the Principle of Univariance?

Answer 3

The absorption of a long wavelength (low frequency, low energy) quantum has the same effect on a receptor as the absorption of a short wavelength (high frequency, high energy) quantum. Once a quantum of light is absorbed, all information about wavelength is lost.

The probability of absorption changes with wavelength and with photoreceptor class.

Ex. Blue cones absorb short wavelength photons more easily than long ones.

Question 4

Wavelength is a _______ attribute. 
Color is a __________ attribute.

Answer 4

physical; perceptual

Question 5

Color is to __________ as brightness is to _________.

Answer 5

wavelength; intensity

Question 6

Illuminant color is related to the wavelengths of light ________.

Answer 6

emitted

Question 7

Object color is related to the wavelengths of light ________ from an object.

Answer 7

reflected

Question 8

The two main ways colors can be combined. What colors are associated with both? What law does this relate to?

Answer 8

Color addition- Red, Green Blue (RGB)

Color Subtraction- Cyan, magenta, yellow ( CMYK) K=whiteness?

Relates to Abneys Law- “total luminance of light composed of several wavelengths is equal to the sum of the luminances of its monochromatic components.”

Question 9

Describe color subtraction

Answer 9

Start with yellow, cyan, and magenta. When subtracting colors, you take away what they don’t have in common. What’s left is what they have in common.

Example, yellow (R+G) and magenta (R+B) have a Red in common. Take away what they don’t have in common (G and B) and you are left with red.

Question 10

How is spectral color obtained?

Answer 10

By prismatic decomposition of sunlight

Question 11

How is non-spectral color obtained? What color is non-spectral?

Answer 11

ONLY by mixing spectral colors. Not present in sunlight.

-purples are non spectral colors

Question 12

What are metamers?

Answer 12

Two or more stimuli that have the same color but have different wavelengths.

Question 13

Describe the 3 Grassman Laws

Answer 13

Scalar Property of Metamers:
If you increase the intensity of two metamers, they will still be metamers.

Additive Property of Metamers:
Add same wavelength to two metamers and the results will still be metamers.

Associative Property of Metamers:
If a 3rd metamer is created for one of a pair of metamers, all three will be metamers.

Question 14

Describe Newton’s color circle and the information you can get from it.

Answer 14

Newton had 3 points on a circle that were equally separated and labeled them blue, green, and red with lines connecting them. If you were to add 2 of the colors along the line, the resulting color would be desaturated. As you move that desaturated color to the outside of the circle, the saturation would increase.

• Provides qualitative description of color matches.
• Shows why there needs to be more than 2 colors to make all the color matches.
• Shows the need to use negative colors.
• To saturate the color, add red (color not used for initial mixture)

Question 15

__________ colors are any two colors that, when added together, produce a “neutral” (i.e. black-gray-white) color.

Answer 15

Complementary

Question 16

On a color circle, complementary colors always lie on _________ sides of “white”. Where is white?

Answer 16

opposite

White is in the center of the circle

Question 17

Perceptual color attributes associated with wavelength

Answer 17

Hue

Question 18

Perceptual color attribute that gives perceived intensity of the color

Answer 18

Brightness (Munsell “value”)

Question 19

Perceptual color attribute that gives degree to which a color appears to differ from an equally bright gray.

Answer 19

Saturation (Munsell “chroma”)

Question 20

What gives perceptual attribute gives a color’s perceived colorimetric purity?

Answer 20

Saturation

Question 21

What are the tree types of cones? What color is associated with each?

Answer 21

S: Blue
M: Green
L: Red

Question 22

How do each cone type respond to a given wavelength?

Answer 22

Each cone type responds to a wide range of wavelengths. Depending on the wavelength, some cones overlap and the intensity of each response is different depending on the wavelength.

Question 23

Describe the Relative Cone Sensitivity Function graph. (also x and y axis)

Answer 23

This graph shows the sensitivity to a given wavelength by each cone (S,M and L)

On the x-axis, you have the wavelength in nanometers.
On the y-axis, you have relative excitation level

Question 24

What is colorimetric purity? What does it describe? What is the equation?

Answer 24

Colormetric purity is the physical correlate of saturation.
It describes the proportion of pure, dominant spectral wavelength energy relative to the amount of achromatic (white/gray) luminance objectively present in a color sample.

cp = Lλ / (Lλ + Lw)

Lw= luminance of white

Question 25

What are MacAdam Ellipses?

Answer 25

MacAdam Ellipses are regions on the CIE chromaticity diagram that show the normal just noticeable differences regions. They are not uniform in shape. Some regions have larger ellipses than others.

Question 26

Describe wavelength discrimination. What wavelengths provide the best discrimination from other wavelengths?

Answer 26

The ability to distinguish differences in the hue of two spectral (mono-chromatic) lights that differ ONLY in wavelength.

The best discrimination is at 495 nm and 590 nm.

Question 27

What color is both the least saturated and and has the poorest saturation discrimination?

Answer 27

Yellow (570 nm)

Question 28

Describe the Bezold-Bruke Effect. What wavelengths do not follow this effect. What are they called?

Answer 28

Changing the value (intensity) also changes the hue for most wavelengths.

The wavelengths that don’t follow this are called invariant wavelengths and have unique(invariant) hues. They are wavelengths 478 nm, 503 nm, and 578 nm.

Question 29

Describe the graph the Bezold-Burke Effect uses.

Answer 29

On x-axis, you have wavelength.
On y-axis, you have Log luminance.

Used different intensities of monochromatic light and plotted the results. The lines are called “hue contour lines”. The lines for wavelengths 478, 503, and 578 were straight vertical while all other values were bent.

Question 30

What is Benham’s disk? What does it indicate?

Answer 30

Benham’s disk is a disk made up of black lines of different lengths. When you spin it, you can see colors like red, green, and blue. The colors are referred to as Fechner colors.

It indicates that the different wavelength-opponent neural channels have different temporal response and recovery characteristics.

Question 31

The value and hue of most lights are
_____ entirely independent

Answer 31

not

Question 32

Describe simultaneous color contrast

Answer 32

Hue is influenced by its surround in complementary fashion.

Differs from an aftereffect by in that, here, the inducing and illusory colors are visible simultaneously.

Question 33

Describe the McCollough Effect

Answer 33

Complementary hues perceived, but the McCollough Effect is not due to simple receptor adaptation.
It exhibits “binocular transfer” (requires cortical processing).
It lasts (way) too long!

Question 34

What is color assimilation?

Answer 34

lighter pattern elements cause the background colors to appear brighter.
Differs from an simultaneous contrast by the similar (rather than complementary) influence of context.

Question 35

What is color constancy?

Answer 35

Color constancy refers to the tendency of objects to retain the same color appearance despite changes in the spectral composition of their illumination.

Allows a color to be a stable property of an object despite changes of the object’s illumination

Question 36

Describe Ed Land’s demo of color constancy by looking at a Mondrian Pattern

Answer 36

1) 3 light sources: red, green, blue.
2) Measure the amounts of red, green, and blue light reflected by
a green rectangle.
3) Adjust each of the red, green, and blue illuminants so that a blue rectangle now reflects the same amounts of red, green, and blue light as the green rectangle reflected before.

The blue rectangle still looks blue even though it now reflects the same light that made the green rectangle appear green.

Question 37

How do rainbows work?

Answer 37

The light hits water droplets in the sky. Each beam of light is refracted into a prismatic effect. Depending on where you stand, the refracted beams will present you with different colors for the different angles at which the beam was refracted.

Question 38

How does lightning work?

Answer 38

Specific atoms in gas present a vapor or a gas when excited, which have their electrons raised into higher energy levels by a variety of excitations; light is then emitted when the excess energy is released as photons.

Question 39

Why is water blue?

Answer 39

The absorption that gives water its color is in the red end of the visible spectrum, one sees blue (the complementary color of orange) when observing light that has passed through several meters of water.

Question 40

How are Auroras formed?

Answer 40

The light is emitted when charged particles from the sun are guided by the earth’s magnetic field into the atmosphere near the poles. When the particles contact atmospheric molecules, primarily oxygen and nitrogen, at altitudes from 300 down to 100 km, a part of the energy of the collisions transforms to visible light.

Question 41

Describe the Munsell Color System

Answer 41

Has 3 values: Hue, Chroma (saturation), Value (brightness/lightness)

Hue:

• has 10 sectors (R, YR, Y, GY, G, BG, B, PB, P, RP)
• each sector broken down into 10 more values labeled 1-10

Chroma (saturation):

• Visually uniform scale
• 0-30+
• Increases as fluorescent colors are added

Value (Lightness/ Brightness)

• scale 0-10
• black > white

Question 42

Explain the RGB color matching function

Answer 42

A person can add the 3 different primary colors to match any color. The proportion of tristimulus values are plotted on a graph.
Y- value on graph = proportion of primary
X-value on graph = wavelength of sample color

Question 43

What are the real primary wavelengths

Answer 43

435. 8 nm (blue)

436. 1 nm (green)

437. 0 nm (red)

Question 44

Explain XYZ color matching function

Answer 44

Y-Axis = tristimulus value
X-axis = wavelength of given

Uses imaginary primaries.
XYZ (RGB) tristimulus values are plotted instead of proportions. To find tristimulus value, divide the tristimulus value
or each primary by the sum of the 3 tristimulus values.

Question 45

True or false:

Chromaticity coordinates are always decimals that add up to one.

Answer 45

true

Question 46

Can tri-stimulus values be greater than 1?

Answer 46

Yes

Question 47

2-dimensional plot of human color space

Answer 47

CIE Chromaticity Diagram

Question 48

What is a spectral locus?

Answer 48

Any point on the outside of the CIE chromaticity diagram

Question 49

What is the planckian locus?

Answer 49

path or locus that the color of an incandescent black body would take in a particular chromaticity space as the blackbody temperature changes.

Question 50

Where are the non-spectral purples on a CIE chromaticity diagram?

Answer 50

On the flat part of the diagram at the bottom between red and violet.
Also called the purple locus

Question 51

Describe excitation purity and how to find it on a CIE chromaticity diagram

Answer 51

Correlates to saturation.
From W (White in center) to a given point on the graph (S) represents the value “a”.
From S to the D (most saturated form of S, located on edge in same direction) represents value “b”

Excitation purity = a / (a+b)

Question 52

What is a color gamut?

Answer 52

All possible outcomes of combining certain colors.

CIE diagram is a color gamut of the primary colors (RGB)

Question 53

X and Y components of CIELUV diagram

Answer 53

Y- axis = v’

X-Axis = u’

Question 54

What is the purpose ff the CIE (u’, v’) diagram?

Answer 54

Attempts to make perceived chromaticity differences more uniform across the whole diagram.

Question 55

What is the color temperature, source, and function of CIE illuminant A?

Answer 55

Color temp = 2856° K

Source = gas-filled coiled-tungsten filament lamp with a fused-quartz envelope or window operating at 2854° K

Function = Serves as standard for illuminants B & C


Question 56

What is the color temperature, source, and function of CIE illuminant B?

Answer 56

Color temp = 4874° K

Source = Illuminant A + 1 cm thick double cell optical glass container (Davis-Gibson filter) filled with liquid chemical solutions B1 and B2

Function = Mimics direct sunlight at noon (poorly).


Question 57

What is the color temperature, source, and function of CIE illuminant C?

Answer 57

Color temp = 6774° K

Source = Illuminant A + 1 cm thick double cell optical glass container (Davis-Gibson filter) filled with liquid chemical solutions C1 and C2

Function = Mimics average direct Northern sunlight but lacks power in near UV range important for fluorescent materials.
-Illuminant C is the illuminant for which nearly all clinical color vision tests were designed.

Question 58

What is illuminant C best approximated by? (name of lamp)

Answer 58

Macbeth Lamp

Question 59

Describe CIE D illuminants. What does it correct for? Source? Which is acceptable for Illuminant C substitute?

Answer 59

• Represent measured spectra under different conditions of natural daylight
• Correct for weaknesses of the other standard illuminants (A, B, & C) in near UV
• no standard source
• Illuminant D65 is an acceptable substitute for Illuminant C for color vision testing.

Question 60

What is the color temperature, source, and function of CIE Illuminant D65? What is recommended for?

Answer 60

-recommended for natural daylight

Color temp: 6500° K , fluorescent sources

Source: No standard source.

Function: Acceptable substitute for Illuminant C in clinical color vision testing.

Question 61

Describe Matching color test (Anomaloscopes)

Answer 61

• based on work by Rayleigh (red+green=yellow)
• most accurate; expensive; difficult to use
• Patient mixes colors to obtain the color of regard
• Traditionally, for red/green defects only
• Sloan Achromatopsia Test

Question 62

Describe the arrangement test for color vision

Answer 62

(testing distance-50cm)
Farnsworth Munsell 100 Hue Test (FM 100)
uses the chromaticity diagram/takes a long time
Farnsworth Dichotomous Test for Color Blindness (Panel D-15). Good screener for congenital and acquired defects
L’Anthony desaturated D-15
Adams desaturated D-15

Question 63

Describe the Pseudoisochromatic plates (color confusion) “PIC Test” for color vision testing. The 2 types and what they are good for.

Answer 63

• Distance 75 cm
• Different strategies on various plates (ex. Vanishing vs. Transformational designs)
• Ishihara. Good screener for congenital defects
• HRR. Acquired and congenital.

Question 64

What test is useful for red/green defects? Describe it.

Answer 64

Nagel Anomaloscope is useful for red/green defects. It distinguishes from proton and Deutan only. Not Tritan.

Bipartite field
670 nm (red) + 546 nm (green) (or 664 & 549, or 679 & 544)
Variable ratio (0 to 73, arbitrary units)
Constant (CIE) luminance
590 nm (yellow) (or 579nm)
Variable radiance

Change radiance until they appear equal.