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COLOR
TELEVISION
Suggested Texts:
Television Engineering
Handbook, Benson Rev Ed. Mc
Graw Hill ISBN: 0-07-004788-X
Video Demystified,
K. Jack (Brooktree's Guru) Hightext, Brooktree ISBN: 1-878707-09-4
Basic Television and
Video Systems, Grob, Bernard Mc
Graw Hill ISBN: 0-07-024933-4 |
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| The light that lights up our world and allows us to see
that world is solar energy in what is known as the visible region of the
Spectrum. This visible region is a very narrow segment of this spectrum
extending from ~ 440nm in the extreme blue (near ultra violet) to ~ 690
nm in the red region--with green in the middle @ ~ 555 nm.
| Human vision is such that what appears as white
light is really composed of weighted amounts of a continuum of so-called
Black Body energy. Tungsten lamps have a similar spectral distribution.
Sodium, Mercury vapor, fluorescent (a variant of Mercury), etc., on
the other hand, do not have this continuum of spectral energy, but are
composed of several discrete wavelengths in proportions that "fool" the
eye. There is mounting evidence that this is an unhealthy environment.
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An ideal transfer function in this overlapping selectivity would be
such that as one filter's selectivity increases the adjacent filter's selectivity
decreases having a total gain of unity throughout this continuum.
On the display side of this arrangement is a display device capable
of producing only three narrow nearly discreet wavelengths of Red, Green,
and Blue light. This is a result of electron bombardment of certain selected
phosphors inside the CRT, each releasing a quanta of photons which are
essentially "Monochromatic. "The wavelength of which is a function of each's
atomic structure.
This all works because human vision can be easily fooled when it comes
to absolute color discrimination. Within reason, the actual color or hue
of each of these three colors is not critical.
Each phosphor is formulated as a compromise between its quantum efficiency
and desired hue or color. An example of this is the fact that red phosphor
requires more energy to cause it to "appear" equally bright to the human
observer. Evidence of this can be seen when a CRT is over driven, the first
color to bloom, is red.
By now it may be obvious that an imaging system for people is different
than one for machines. Machine vision is not weighted to complement a second
vision system--the human eye. |
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| This all works because human vision can be easily fooled when it comes
to absolute color discrimination. Within reason, the actual color or hue
of each of these three colors is not critical.
| For example, in order to produce "White" light
to the human observer there needs to be 11 % blue, 30 % red and 59% green
(=100%). However, if you shifted, say the red light source to a longer
wavelength, the white light would appear more toward cyan. White balance
could be restored by changing the three color's weights, i.e. other than
the original 11, 30, 59 percent ratios.
One point should be made: the human observer is very discriminating
when it comes to flesh or skin tones. |
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By now it may be obvious that an imaging system for people is different
than one for machines. Machine vision is not weighted to complement a second
vision system--the human eye. |
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The addition of colors in the correct proportion creates white; unlike
paint which darkens, e.g., black is the addition of Yellow, Cyan and Magenta
pigments. |
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Frequency Interleaving: "one
way of putting two pounds of picture in a one pound spectrum."
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Under Construction in
Perpetuity
Suggestions are Solicited, P l e a s e !
.raFor
the Reading Challenged