chapter 2
DESCRIPTION
TRANSCRIPT
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Understanding Color:
An Introduction for Designers
Chapter 2: A Little Light on the Subject
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Part 1
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Light
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Only light generates color.
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Light is visible energy that is emitted by alight source.
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A light source can be:
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the sun...
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a luminous panel...
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a neon sign...
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a light bulb...
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or a monitor screen.
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The eye is uniquely adapted to receive
light.
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The retina of the eye receives a stimulus - the energy signal - and
transmits it to the brain, where it is identified as color.
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Light sources emit this visible energy in pulses, or waves.
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All light travels at the same speed, but waves of light energy are emitted at
different distances apart or frequencies.
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The distance between the peaks of these energy emissions is called
wavelength. Wavelengths of light are measured in nanometers (nm).
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The human eye is able to sense wavelengths of light ranging from about 380
nm to about 720 nm.
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Individual wavelengths are sensed as discrete colors, or hues.
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Red is the longest visible wavelength at 720 nm.
Violet is the shortest visible wavelength at 380 nm.
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The wavelength of visible light goes in order from longest to shortest:
REDORANGEYELLOWGREENBLUEINDIGOVIOLET
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“ROYGBIV” is an acronym for these wavelengths, which are the colors of the visible spectrum.
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“ROYGBIV” is an acronym for these wavelengths, which are the colors of the visible spectrum.
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Here is an easy way to remember the order:
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Different types of light sources emit the various wavelengths (colors) at different levels of energy. One light may give off a particular wavelength at
such a low level of energy that it is barely visible...
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...while another emits it so strongly that it is seen as a brilliant color.
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Although the color is the same, the intensity of the color experience is very
different.
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The human eye is most sensitive to light in the middle range of the visible spectrum and sees
these colors, the yellow-green range, most easily.
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Yellow-green light can be sensed at a
lower level of energy than other colors.
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There is visible light and color beyond the range of human vision.
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Some animals and insects can sense colors that are
beyond the range of human vision.
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For instance, jumping spiders and bees can sense ultraviolet light.
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Colors on the edges of human vision can also be sensed with special optical equipment.
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For instance, there are special filters and lenses that you can attach to a camera to take photos using only infrared light.
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Additive Color:Mixing Light
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Sunlight is sensed as white, or colorless, but it is actually made up of a mixture of colors (wavelengths) that are emitted in a continuous band. Individual colors can be seen when sunlight is passed through a prism.
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The glass of the prism bends, or refracts, each wavelength at a slightly different angle so that each color emerges as a separate beam.
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Under the right atmospheric conditions water droplets will form natural prisms, and the
compoenent colors of sunlight can be seen as a rainbow.
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Other light
sources, like light
bulbs, emit light
perceived as
white.
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But light sources do not have to emit all of the visible wavelengths for white light to
result.
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White light is produced as long as a source emits the red, green, and
blue wavelengths in roughly equal proportions.
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Red, green, and blueare the primary colors of light.
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Mixing two of the primary colors of light produces a new color.
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Cyan, magenta, and yellow are the secondary colors of light.
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Wavelengths can be combined in
unequal proportions to create additional
colors.
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Two parts green light and one part red at equal levels of
energy provide yellow-green.
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Two parts red light and one part green at equal levels of energy
provide orange.
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All hues, including violets and browns that are not found as wavelengths in the visible
spectrum, can be produced in light by mixing the light primaries in different
proportions.
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White or colored light seen as a result of a combination of wavelengths is called anadditive mixture or additive color.
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Lamps
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Lamps are the principle man-made light sources.
“Lamp” is the correct term for a light bulb.
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The fixture that holds the lamp is a luminaire.
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A general light source is a lamp that produces light that is white.
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General light sources provide ambient light, which is general area
lighting.
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A lamp that is missing one or more of the primary colors gives off colored
light.
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It is NOT a general light source.
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The lamps in neon signs are one example of a light source emitting a narrow range
of wavelengths
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General light sources each produce wavelengths in a characteristic pattern
called a spectral distribution curve or spectral reflectance curve.
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The spectral distribution curve shows which wavelengths are actually present and the strength of each wavelength relative to the others for that
particular type of lamp.
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Spectral distribution determines (and describes) the color quality of a light source.
NeutralWarm Cool
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We think of natural and artificial light as two different entities, but ALL light is visible
energy.
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Light sources can
be differentiated from other
each other in two ways:
•spectral distribution
•apparent whiteness
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Daylight is the standard of whiteness for man-made light sources, and because response to sunlight is part of our genetic makeup, it also helps to determine whether light from a given source will be sensed as more or less natural.
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About 40% of man-made interior lighting is used for domestic purposes.
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The balance is used to illuminate public and commercial spaces.
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Incandescent lamps, like the sun, produce light by burning.
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The light they emit is a small byproduct of heat - only about 5% of the energy used by an
incandescent lamp results in light.
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Candlelight, firelight, and incandescent lamplight are sensed as comforting
because they emit light in the same way the sun does.
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The apparent whiteness of an incandescent lamp depends on the
temperature at which it burns, called its color temperature.
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Color temperature in
lamps is measured in
degrees Kelvin (K).
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A typical incandescent lamp burns at a relatively low temperature, around
2600 - 3000 K.
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Lamps that burn hotter emit bluer light; very white light is hottest of all.
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A halogen lamp is a type of incandescent lamp with a gas inside the glass envelope that causes it to
burn at a high temperature resulting in a bluer white.
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The color temperature of a lamp is used as a measure of whiteness for the color of light
produced by the lamp.It does not help to predict how a light source will
render the colors of objects.
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As a designer, you will need to use mockups in field conditions to make sure that the lamps you use deliver the right quantity and quality of light
for each situation.
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Fluorescent lamps
produce light in a
completely different way.
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The interior of the glass bulb is coated with phosphors, substances that emit light when they are bombarded with electrical energy.
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The color of a fluorescent lamp depends on the particular makeup of
its phosphor coating.
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What is “phosphor?”
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Fluorescent lamps do not burn, so they do not have an actual color
temperature, but they are assigned an “apparent color temperature” to indicate their degree of whiteness.
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Fluorescent lights produce separate bands of energy instead of a continuous spectrum, but will still emit all wavelengths at similar levels of energy. Because of our eye’s sensitivity to yellow-green,
ordinary fluorescent lamps appear yellow-greenish.
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Light that imitates sunlight - continuous spectrum - is sensed as the most comfortable, welcoming
and natural.
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Some lamps are marketed as “full spectrum,” but that doesn’t really tell you anything about the
temperature of the light since it could have various strengths of wavelengths.
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Current emphasis on the environment has led to new sources of light like the LED lamp.
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LED lamps produce light at low operating cost by combining the output of red, green light-
emitting diodes.
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LED lamps produce a white, strong light that is excellent for limited uses like car headlamps, but is
problematic in interior environments because it contains only the three primary colors and does not
have a continuous spectrum.
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Lighting level refers to the quantity of available
light, regardless of its color makeup.
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Lighting level describes the total amount of light coming from the source and is unrelated to its spectral distribution.
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A lamp may give off more or less light, but its spectral distribution - the pattern of energy emitted at the different
wavelengths - is identical for that lamp no matter what quantity of light it gives off.
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Too little available light makes it hard to see colors.
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Excessive and uncontrolled light falling on a surface can also impair color perception.
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Glare is an extreme, physically fatiguing level of general light. Glare obliterates
color perception and can be temporarily blinding.
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Reflectance or luminance is a measure of the amount of light falling on a surface that is reflected
back.
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It is a measure of the total amount of light reflected, not the individual
wavelengths, or colors.
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Reflectance is so important to some
products, like interior and
exterior paints, that the
percentage of light reflected back from
each color, called its LRV (light-
reflecting value), is part of the basic information the
manufacturer provides.
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Lighting level affects our ability to see value, and to make sense of what we see,
but the color of the light does not.
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Vision is the sense that detects the environment and objects in it through the eyes, and is the only way in which color is
perceived.
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Color vision is experienced in two different ways: either as
light directly from a light source, or as light reflected from an
object.
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In the illuminant mode of vision, colors are experienced as direct light reaching
the eye, like the colors of a monitor screen or a neon sign.
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In the object mode of vision, colors are seen indirectly as reflected light.
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The tangible things of the real world - objects and the environment - are seen in the object mode of
vision.
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The illuminant mode of vision has two variables:
•the characteristics of the light source
•and the characteristics of the viewer.
![Page 104: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/104.jpg)
In the illuminant mode of vision, colors are relatively stable.
![Page 105: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/105.jpg)
But every viewer brings their own personal sense
and interpretation to the perception
of color.
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Part 2
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In the object mode of vision, color is seen as light
reflected from a surface.
![Page 108: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/108.jpg)
Color perception in the object mode of vision has three
variables:•the characteristics of the light
source,
•the individual viewer’s visual acuity for color and interpretation of it, and
•the light-modifying characteristics of the object.
![Page 109: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/109.jpg)
Light leaving a light source is the incident beam.
The reflected beam is light that leaves a surface and
reaches the eye.
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The material an object is made of modifies light in one of three
ways:
•Transmission
•Absorption
•Reflection or scattering
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Transmission: the material allows light to pass through, as through
glass.
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Absorption: the material soaks up light reaching it like a
sponge, and the light is lost as visible. It can no longer be seen.
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Reflection or scattering: Light reaching the material bounces off it,
changing direction
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Colorants are special materials that modify light by absorbing some
wavelengths and reflecting others.
![Page 115: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/115.jpg)
A colorant can be integrated into the substance of a material, like a color-
through plastic...
![Page 116: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/116.jpg)
...or applied to a surface as a coating.
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Colorants are also called color agents, dyes, pigments, and dyestuffs,
depending on their makeup or end use.
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A white colorant reflects, or scatters, all wavelengths of light, and a black
colorant absorbs all of the wavelengths of light.
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Other colorants modify light selectively.
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Here the colorant in bananas absorbs all colors except yellow which is reflected.
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In order for an object to be seen as a color, the wavelengths that its colorant
reflects must be present in the light surface.
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A red dress seen under green light is a black dress. In a parking lot illuminated by the light of yellow
sodium lamps, red, green and blue cars are indistinguishable from each other. Only yellow cars
can be located by their color.
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Colorants don’t absorb and reflect individual wavelengths perfectly. They may absorb part of a wavelength and reflect part of it, or reflect more than one wavelength. So many possibilities exist that the range of visible colors is nearly infinite.
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Colors seen as the result of the absorption of light are subtractive mixtures.
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A Macbeth lamp has a spectral distribution similar to sunlight and is
often used under laboratory conditions to measure color.
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However, such a lamp has little use for artists since their products are
seen under all types of light, and by all types of people.
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Two objects that appear to match
under one light source but not under another
exhibit metamerism. The objects are
called a metameric
pair.
![Page 128: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/128.jpg)
Because materials differ in their ability to absorb colorants or accept them as coatings, it is
virtually impossible to color match two very different materials.
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It is really only possible to reach an acceptable match, one that is
pleasing to the eye.
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If your colors are an acceptable match under both fluorescent and
incandescent lights, they will probably be acceptable under
nearly all conditions.
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A sample submitted for color matching is a standard.
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A match that is perfect under any light conditions is possible only
when the original standard and the new product are identical in all
ways.
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Surface is the outermost layer of a thing,
its “skin.”
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Different surfaces - rough, smooth, or in between - have an impact on the
way that colors are perceived.
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Value refers to the relative lightness or darkness of a hue.
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Only the perception of value is affected by surface texture.
![Page 137: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/137.jpg)
Surface texture has no effect on hue, but a rough surface will look darker than a smooth surface of the same
color.
![Page 138: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/138.jpg)
The smoother the surface, the greater the amount of light that is reflected
back directly.
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A specular surface is glossy, or mirror-like.
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Light leaving a specular surface is reflected so immediately, and so
directionally, that most or all of it is seen as white light.
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When a specular surface is viewed from an angle that is not the same as the
angle of the incident beam, some light reaching the underlying colorant can be
seen.
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The color of a sequined garment is only visible when the sequins are viewed at
an angle that allows the color to be visible.
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A matte surface is a smooth surface that is very slightly, even
microscopically, roughened.
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Colors on a matte surface have a flatness and unifsormity under nearly
all lighting conditions.
![Page 146: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/146.jpg)
Textured surfaces are dynamic and lively.
![Page 147: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/147.jpg)
Incident light scatters in random directions producing a surface with
both light and dark patches.
![Page 148: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/148.jpg)
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Texture is most apparent under point light sources, like sunlight or
incandescent lamps.
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Light from a point source originates from a single location, or point, and
the beams of light emitted are parallel.
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Fluorescent lights are linear light sources. Linear light sources emit a broad-spread light that is essentially
non-directional
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Light from a linear source does not reach the surface at an angle in the same way as a point light source.
![Page 154: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/154.jpg)
Even heavily textured surfaces tend to appear flat and uniform under
fluorescent (or other linear) lighting.
![Page 155: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/155.jpg)
Point Linear
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LED lamps are currently offered as
both linear and point sources, but LED lamps are an
emerging technology and
their rendition of color and surface is difficult to evaluate
at this time.
![Page 157: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/157.jpg)
The sharper the angle of incident light, the more directional
the reflected beam will be.
![Page 158: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/158.jpg)
Raking light describes light from a source that is positioned at an acute
angle relative to a surface.
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Specular surfaces appear more glossy, and textured surfaces dramatically
rougher, under raking light.
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Varying the textures of a surface allows designers to create a an effect of two or more colors (or more accurately, lighter and darker
variants of a single hue) using only one material.
![Page 161: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/161.jpg)
A piece of yarn, seen on its long side, is relatively smooth. Cut ends of the same yarn ( a pile, or nap)
reflect the identical wavelength but scatter light more widely and appear darker.
![Page 162: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/162.jpg)
A small amount of light is lost each time that light travels from a source to a surface, and when light reaches a surface, a very small
amount reflects back immediately.
![Page 163: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/163.jpg)
The sum of this light loss can be so slight that as a practical matter it is unimportant.
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The light that remains is reflected, absorbed, transmitted, or a combination of these.
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If all of the light reaching an object is either reflected or absorbed, the object is opaque.
If all (or nearly all) of the light reaching an object or material is transmitted, that object is
transparent.
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When some of the light reaching an object or material is transmitted and some is reflected,
the object is translucent.
![Page 167: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/167.jpg)
A translucent material can be white or a color, depending on its selective transmission and
reflection of various wavelengths
![Page 168: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/168.jpg)
Translucent materials may allow a great deal of light to pass through (and be very translucent) or transmit very little light (and be barely translucent).
![Page 169: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/169.jpg)
The terms transparent and translucent are not interchangeable. A truly transparent material is like window glass: for all practical purposes, it is
invisible.
![Page 170: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/170.jpg)
A translucent material is detectably present, no matter how sheer it may be.
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Iridescence is an attribute of surfaces on which the hue changes as the observer’s angle
of view changes.
![Page 172: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/172.jpg)
The changes from blue to green that are seen in a butterfly’s wings as it flies...
![Page 173: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/173.jpg)
the flashes of red, purple, and green in the black feathers of a Grackle...
![Page 174: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/174.jpg)
or the brilliant and changing colors of soap bubbles and oil films are iridescence.
![Page 175: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/175.jpg)
Iridescence is an optical phenomenon that occurs with reflected light.
![Page 176: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/176.jpg)
The color is produced by the structure of a surface that amplifies some wavelengths of light and suppresses others, depending on the angle
of the light reaching it.
![Page 177: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/177.jpg)
The amplification
of light makes iridescent
color extremely vivid – the color that
reaches the eyes may be
reflected, but in the absence of a modifying
colorant it is sensed as pure light.
![Page 178: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/178.jpg)
Because no colorant is involved – nothing that absorbs some wavelengths of light
and reflects others – it is sometimes called structural color.
![Page 179: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/179.jpg)
Iridescent textiles are
brilliantly shimmery,
seeming to be one color at one
angle of view and a second
color as the fabric moves.
![Page 180: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/180.jpg)
Iridescence in textiles is
produced in a variety of ways.
There are silk yarns with a
molecular structure that
creates iridescence as
well as synthetic yarns with
similar properties.
![Page 181: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/181.jpg)
Most iridescent textiles, however, are made using special yarns and techniques of weaving. When the
warp and weft are made from differently colored and light-reflective yarns, each color appears, vanishes, and reappears as the viewing angle
shifts.
![Page 182: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/182.jpg)
There are paints and inks with light-reflecting properties that create convincing iridescent effects on a page. As the observer’s position changes, the
color changes.
![Page 183: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/183.jpg)
An impression of iridescence is difficult to create on a screen, because light leaving a screen reaches
the eye directly, no matter what the viewer’s position or movements.
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Luminosity is a word that appears often in color study.
Its real meaning is the attribute of emitting light without heat.
![Page 185: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/185.jpg)
A luminous object is light-reflective, but it does not emit
heat.
![Page 186: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/186.jpg)
The word “luminous” is used often to describe very light-reflecting colors and media with a great deal of light reflectance, like watercolor, dyes, or markers.
![Page 187: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/187.jpg)
Indirect light occurs when light from a light source reaches a broad, light reflective plane
that re-reflects it onto a second surface or object.
![Page 188: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/188.jpg)
In order for this to happen, the light source, the reflective surface, and the target surface or
object must be positioned at similar angles to one another.
![Page 189: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/189.jpg)
Moonlight is a familiar form of indirect light. The moon is luminous: it reflects light but does not emit its own energy. Its surface reflects
the light of the sun to the earth.
![Page 190: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/190.jpg)
Each time light travels, some of it is lost through scattering. Moonlight is weaker than sunlight
because much of the sun’s light has been scattered and lost, first on its way from the sun to the moon,
then again from the moon to the earth.
![Page 191: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/191.jpg)
Indirect light works in the same way that moonlight does. Light reaching a white surface is redirected to a target area. The indirectly lit area appears darker than it would under direct light, but no change in its apparent hue takes place.
![Page 192: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/192.jpg)
Indirect color is a form of indirect light. Indirect color occurs when general light reaches a highly reflective color on a broad plane.
![Page 193: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/193.jpg)
Some of the general light–and a good deal of the strong color–will reflect onto any surface that is positioned to receive it.
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One way to describe the phenomenon of color reflected from one surfact to
another is plane reflection.
![Page 196: Chapter 2](https://reader038.vdocument.in/reader038/viewer/2022103015/54bc31a44a79592a738b4613/html5/thumbnails/196.jpg)
The design applications most vulnerable to this are architecture and interior design, where planes of color on
walls, floors, and ceilings interact with directional light sources to create potential conditions of light and color
reflections.
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Filters are materials that transmit (pass through) some wavelengths of light and absorb others.
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A red filter placed between a light source and an object allows only the red wavelengths to pass
through. Other wavelengths are absorbed.
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Filters are powerful
modifiers of light, so they must be
used with real understanding of
their effects.