Light, Color & Human
Color photography, especially color
printing has always been a challenge. Photographers as reknown as AnselAdams
have felt intimidated trying to produce worthy color prints of their work. Many
sought refuge and remained in the safe world of B&W through out their career.
The digital darkroom has given every photographer who so desires the power to
print accurate, easily reproduceable color prints of their images, assuming
of course they possess an understanding of human color vision .
The nature of light:
Light is the basis of all photography.
Without light, we are all left in the dark. But what is light? Light it turns
out is a form of electromagnetic radiation (EMR), fluctuations of electric and
magnetic fields which move through space as waves move over the surface of a
pond. The electromagnetic sprectrum includes radio waves , infrared, visible
light, ultraviolet, xrays and gamma rays.
EMR by its wavelength, the distance between two consecutive crests of a wave.
Human eyes it turns out are only sensitive to EMR in the range that is between
the wavelengths of 780 nanometers and 380 nanometers. A nanometer is one billionth
of a meter, these are very tiny waves! This very special area is called the
visble spectrum or visible light. Most color photography deals only with the
of colors in the visble spectrum
In order to see a color print or
anything for that matter, we must place it under a source of illumination. There
are several common effects that are used to produce this illumination.
Liquids or solids that are heated
to 1000 degrees K in temperature or greater emit light. K is short for Kelvin
the absolute version of Centigrade scale. Water boils at 373 K, so 1000 K is
very hot! The tungsten filament light bulb is the commonest man made source
of light on earth, it glows at about 2854 K. The sun, is a natural incandescent
source whose surface is at about 5800 K.
Phosphors are substances that absorb
energy and re-emit light. The phosphor coating of a common florescent tube emits
visble light when excited by energy released within the tube. An electric arc
between the tubes electrodes creates ultraviolet light which excites the phosphor
causing it to glow.
The problem for color photographers
is, not all light sources are created equal! The spectral energy of these light
sources varies greatly. The color content of the light source is usually described
in terms of the temperature of an incandescent emitter which produces a color
spectrum closest in color to that source. The higher the temperature the bluer
the light. The lower the temperature the redder the light. Tungsten light bulb
illumination is very orange compared to daylight. The color characteristics
of the light source are referred to as its spectral power distribution.
The nature of the the object:
The color we perceive an object to
be is determined by which wavelengths of light are absorbed or reflected by
the object. Only the reflected wavelengths reach our eye and are seen as color.
The leaves of most common plants absorb red, orange, blue & violet . At
the same time they reflect all the green wavelengths and are therefor seen to
be green in color. These characteristics of the object are referred to as its spectral reflectance.
The nature of the human eye:
The human eye is the last link in
the chain of color vision. The human eye has a simple two element lens. The
cornea is the front or outer element and the lens is the back or inner element.
The amount of light entering the eye is controlled by the iris which lies in
between the two. The light passes through a clear gel called the vitreous humor
and creates an inverted image on the retina at the back of the eyeball.
The retina is the light sensitive
part of the eye. Its surface is coated with millions of photoreceptors. These
photoreceptors sense the light and pass electrical signals indicating its presence
through the optic nerve to stimulate the brain. There are two types of photoreceptors,
rods and cones.
The rods are sensitive to very low
levels of light but are monochromatic and cannot see color. That's why at very
low light levels, humans see things in B&W.
The retina contains three types of
cones. Different light sensitive pigments within each of these three types responds
to different wavelengths of light.. Red cones are most stimulated by light in
the red-yellow spectrum. Green cones are most stimulated by light in the yellow-green
spectrum. Blue cones are most stimulated by light in the blue violet spectrum.
This phenomena describes the spectral sensitivity of the eye.
sensitivities of the red, green and blue cones.
To make the eye "see" any
color of the spectrum it is only necessary to stimulate the three types of cones
in a manner similar to the way the actual color would.
It is not necessary to actually produce
the color of light! This is exeactly how a CRT monitor works on a computer or
TV. If you look closely at the face of your TV with a 4x loop you can see the
individual RGB color phosphor stripes glowing. A color TV or computer monitor
is really not a color device at all, its a RGB source of illumination.
When you back off to a normal distance the eye combines the red, green and light
and is fooled into seeing the whole color spectrum. Most color file formats
used on computers, store the individual color data in exactly this way. For
each point of light or pixel in an image a 24 bit binary number is stored describing
the exact amount of red,green and blue making up the pixel.
This representation of color is called
the additive color system. It explains how we see objects that emit their own
light. This system states that all perceivable color hues can be created by
mixing different amounts of red,green and blue light. Equal amounts of red,green
and blue give the sensation of white. The absence of red green and blue gives
the sensation of black.
which are seen because they reflect light from another illuminant source are
explained by the subtractive color system. Color prints fall in this category.
The color perceived by the eye while looking at a color print depends on all
three factors discussed above The spectral power distribution of the light source,
the spectral reflectance of the object and the spectral sensitivity of the eye.
In a color print, you
control the spectral sensitivity of the paper at a given point when you adjust
the color balance while looking at the image in Photoshop.The light source the
print is viewed under is often out of your control and can be a problem. Certain
pigment based inks appear to be identical under light sources of one type, say
2800K tungsten filament sources. The same inks viewed under a different light
source, say 6500K daylight appears very different. This phenomena is called metamerism and is a problem for some printer owners.
When taking a photo,
the spectral power distribution of the illuminant is even a bigger problem.
Standard color films are either balanced for daylight or a tungsten light source.
Anything in between, will require color adjustment in the digital darkroom for
It is quite possible
the artistic effects created by color shifts are highly desirable. Not many
of us would want to trade the warm hues of sunset or sunrise for an accurate
set of whites! Once we understand the nature of color, it is possible to control
it. There are many color tools in Photoshop that allow you to do this, but that
is the topic of yet another tutorial.