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Color. Sources and Resources: Hypergraph Frosty Drew Observatory User-Centered Web Site Development: a Human-Computer Interaction Approach by McCracken and Wolfe. Electromagnetic Spectrum. Visible Spectrum. RGB Color. CMYK. NTSC. HSV. Emotional Response to Color.
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Color Sources and Resources: Hypergraph Frosty Drew Observatory User-Centered Web Site Development: a Human-Computer Interaction Approach by McCracken and Wolfe
Emotional Response to Color • Different colors evoke different reactions in viewers. • Culturally specific.
Beautiful Color Scheme??? • For a given lens curvature, longer wavelengths have a longer focal length • Red is the longest focal length • Blue is the shortest. • Since to have an image focused on the retina, the lens curvature must change with wavelength with red light requiring the greatest curvature and blue light the least curvature.
Beautiful Color Scheme??? • For a given lens curvature, longer wavelengths have a longer focal length • Red is the longest focal length • Blue is the shortest. • Since to have an image focused on the retina, the lens curvature must change with wavelength with red light requiring the greatest curvature and blue light the least curvature.
Chromostereopsis • Pure colors located at the same distance from the eye appear to be at different distances • Reds appear closer • Blues appear more distant • Sometimes pure blues focus in front of the retina and so appear unfocused. • At night a deep blue sign may appear fuzzy while other colors appear sharp.
Lens Absorbs Light • The lens absorbs about twice as much in the blue region as in the red region. • Older eyes have yellowed lens • It absorbs more in the shorter wavelengths. • More sensitive to longer wavelengths (yellows and oranges) than they are to shorter wavelengths (cyan to blue) and this increases with age.
Fluid Absorbs Light • Fluid between the lens and the retina absorb light. • Older fluid absorb MORE light. • The older people get the less sensitive they are to light in general (the apparent brightness level decreases) and especially the sensitivity to blue decreases.
Retina • Contains the photo receptors that • absorb photons • transmit chemical signals to the brain. • Two types • Rods • night-vision receptors • no color dependency • Cones • color sensitivity • require a higher level of light intensity
Retina - Cones • Three types of photopigments in the cones • "blue" with a maximum sensitivity at 430 nm • "green" with a maximum sensitivity at 530 nm • "red" at 560 nm (this wavelength actually corresponds to yellow)
Retina - Cones • The percentage of cones • blue (4%) • green (32%) • red (64%) • Cone and rod distribution • The center of the retina • has a dense concentration of cones but no rods • is primarily green cones, surrounded by red-yellow cones • no blue cones • The periphery • the blue cones • has many rods but few cones.
How we identify objects • By edge detection • Difference in color • Difference in brightness • Difference in both color and brightness
Light intensity and Photoreceptors • Going into or out of a dark room requires some adjustment time. • A required minimum intensity level for the photoreceptors to respond. • Minimum varies with wavelength • Highest sensitivity in the center of the spectrum. • Blues and reds must have a higher intensity than greens or yellows in order to be perceived.
Brain • From the retina the optic nerve (actually a collection of nerves) goes to the brain but before it reaches the brain there is a color processing unit, called the lateral geniculate body. • This recombines the RGB color information into three new channels as follows: • R-G gives red or green color perception • R+G gives the perception of brightness and also yields yellow (Y) • Y-B gives yellow or blue color perception
Brain • From the retina the optic nerve (actually a collection of nerves) goes to the brain but before it reaches the brain there is a color processing unit, called the lateral geniculate body. • This recombines the RGB color information into three new channels as follows: • R-G gives red or green color perception • R+G gives the perception of brightness and also yields yellow (Y) • Y-B gives yellow or blue color perception
Color Blindness • Nine percent of the population has some kind of color perception problem. • The most common is red-green deficiency, which can arise from a deficiency of either the red or the green photopigments. • These people have difficulty distinguishing any color that is dependent upon the red:green ratio. • Test for Color Blindness
Derived Color Guidelines • Avoid the simultaneous display of highly saturated, spectrally extreme colors. • Pure blue should be avoided for text, thin lines, and small shapes. • Avoid adjacent colors that differ only in the amount of blue. • Older operators need higher brightness levels to distinguish colors. • Colors change in appearance as the ambient light level changes.
Derived Color Guidelines • The magnitude of a detectable change in color varies across the spectrum. • It is difficult to focus upon edges created by color alone. • Avoid red and green in the periphery of large displays. • Opponent colors go well together. • For color-deficient observers, avoid single color distinctions.
Color in Web Pages • Go on the Internet and select a color scheme for your homework page. • http://www.coherentwaves.com/bgpanel1.html and there are many other tools on the web. • Write down the 6 digit hexadecimal values for • Background • Text • Links • Visited Links • Active Links