1. Physics of Color

2. Mixing Colored Light the lower-frequency red end
The frequencies of white light can be divided into three regions:
the lower-frequency red end
the middle-frequency green part
the higher-frequency blue end
Low and middle frequencies combine to form yellow to the human eye. The middle and high frequencies appear greenish blue (cyan). The low and high frequencies appear bluish red (magenta).

3. Mixing Colored Light
The low-frequency, middle-frequency, and high-frequency parts of white light appear red, green, and blue.
To the human eye, red + green = yellow; red + blue = magenta; green + blue = cyan.

4. Mixing Colored Light
This amazing phenomenon is due to the way the human eye works.
The three colors do not have to be red, green, and blue, although those three produce the highest number of different colors.
For this reason, red, green, and blue are called the additive primary colors.

5. Spectrum of Visible Light

6. Simple Trichromatic Theory
Yellow, Green &
Cyan
photons excite me
Yellow &
Red
photons excite me
Cyan &
Blue
photons excite me
MOE
LARRY
CURLY
Inside your eye there are three receptors called
Cones

7. Trichromatic: Seeing Yellow
Yellow, Green &
Cyan photons excite me.
I’M EXCITED
Yellow &
Red
photons excite me. I’M EXCITED
Cyan & Blue
photons excite me.
Yawn.
CURLY OR
MOE
LARRY
Yellow seen when Curly and Larry excited, either by yellow photons or red & green photons.

8. Trichromatic: Seeing Magenta
Yellow &
Red
photons excite me. I’M EXCITED
Cyan & Blue
photons excite me.
I’M EXCITED
Yellow, Green &
Cyan photons excite me.
Yawn.
CURLY
MOE
LARRY
Magenta is seen by eye when Moe and Larry excited, which no single type of photon can achieve.

9. Maxwell Color Disk
Disk painted half red, half blue looks magenta when rapidly spinning.

10. Trichromatic: Seeing White
Yellow &
Red
photons excite me. I’M EXCITED
Cyan & Blue
photons excite me.
I’M EXCITED
Yellow, Green &
Cyan photons excite me.
I’M EXCITED
CURLY
MOE
LARRY
White seen when all three very excited
Gray seen when all three less excited

11. Trichromatic: Color Blindness
Red , Yellow, Green &
Cyan photons excite me.
I’M EXCITED
Cyan & Blue
photons excite me.
Yawn.
Color blindness occurs if the eye is missing one of the three receptors. Other receptors try to compensate but cannot distinguish some colors.
CURLY OR
MOE
LARRY
Do I see red or green?

12. Color Blindness
Weakness or absence of one of the three types of cones is the cause of color blindness, leading to a reduced ability to distinguish colors.
Classification
Incidence (%)
Males
Females
Anomalous Trichromacy
6.3
0.37
Protanomaly (Red-cone weak)
1.3
0.02
Deuteranomaly (Green-cone weak)
5.0
0.35
Tritanomaly (Blue-cone weak)
0.0001
Dichromacy
2.4
0.03
Protanopia (Red-cone absent)
Deuteranopia (Green-cone absent)
1.2
0.01
Tritanopia (Blue-cone absent)
0.001
Rod Monochromacy (no cones)
21 or 74?
29 or 70?
Those with a red/green deficiency will see a 21
Those red/green deficient will see a 70

13. Trichromatic: After-Image
First stare at RED
I’M EXCITED!
Yawn.
MOE
CURLY
LARRY
Me too, but tired.
ME TOO!
I’M EXCITED!
MOE
CURLY
LARRY
Then stare at WHITE
Moe and Curly are excited so what color is seen?
CYAN (light blue-green)

14. Negative After-image
Stare, unfocused, at the red cross for 10 seconds

15. Negative After-image
Cyan

16. Negative After-image
Stare, unfocused, at the flag for 10 seconds

17. Negative After-image
Cyan
Magenta
Yellow

18. Additive Complements
LARRY
After-image of red is cyan because Larry gets tired so when white light excites all three Stooges, Moe & Curly stronger than Larry. R
MOE
CURLY C
Cyan = White - Red

20. Trichromatic: Opponency
Yellow, Green &
Cyan photons excite me.
I’M EXCITED
Yellow &
Red
photons excite me. I’M EXCITED
Oh, Shut The Up!
CURLY
MOE
LARRY
Shine Red & Green photons (or Yellow photons)
Yellow seen when Curly and Larry excited, which can annoy Moe, who then opposes them.

21. Simultaneous Contrast
Does the gray bar look slightly bluish?
Are the two gray bars the same shade of gray?
Yes, the presence of a nearby color affects perception of both hue and value, shifting both towards complement