Color Scheme
New vision theory states perception of color depends on neural 'reflexes'
Friday, November 10, 2000
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In the latest in a series of papers proposing that visual
perception is an intricate collection of reflexes similar to the
familiar 'knee jerk' response, Duke University Medical Center
neurobiologists outline evidence on the perception of color that
they say supports their theory.Proceedings of the
National Academy of Sciences
The study reported in the PNAS is based on the well-known illusion
that the color of a surface can appear quite different, depending
on its context.
In experiments that explore the basis of color contrast and
constancy, Lotto and Purves presented volunteer subjects with
images displayed on a computer screen in which pairs of colored
targets were shown in the context of two differently colored
surroundings. The subjects were then asked to use onscreen
"buttons" to adjust the apparent color of one target until it
matched the perceived color of the other target.
By measuring the subjects' adjustments, the researchers could
determine how the colors of the surroundings affected perceptions
of the target color. They found that by changing the context so
that the identical targets were more likely to have been generated
by differently reflective objects under different illuminants, the
perceived color difference between the physically identical targets
was increased. However, if the context was changed such that the
targets were more likely to signify similar objects under similar
illumination, the perceived color difference between the targets
decreased.
"This finding is what one would expect if the illusion of color
contrast represents the experience of the visual system with the
physical laws that govern how reflectance and illumination combine
in generating the ambiguous light that hits the eye," Purves
said.
The rationale for this kind of explanation, according to Lotto and
Purves, is that the light that enters the eye does not carry
unambiguous data about the visual world.
"Since photons don't carry any information about their history,
there's no direct way to disentangle what has actually given rise
to the light falling on the retina," Purves said. "The light that
reaches the eye is always a product of both the quality of the
object's surface and the quality of its illumination. So it's
impossible to know the extent to which the stimulus coming from an
object is determined by the object's reflectance properties or the
conditions of its illumination.
"Therefore, the basic problem in vision is that the meaning of a
light stimulus is inevitably ambiguous," he said.
According to the argument presented in the PNAS paper, the only way
observers can sort out the "meaning" - or more appropriately, the
behavioral significance - of such ambiguous stimuli is to use trial
and error to indicate what they should perceive. Thus, humans
gradually evolved the reflexive visual circuitry that enables them
to see, not the actual properties of the light falling on the
retina, but the sources in the physical world that typically would
have generated that type of stimulus in the past.
Despite its simplicity, this wholly empirical theory remains highly
controversial, Purves said.
"The idea of empirical influences on vision has been around for a
long time, but to a large extent has been ignored by people doing
neurobiology, or considered as a way of modulating basic visual
processing machinery under the rubric of 'top-down' influences on
'bottom-up' mechanisms," said Purves. "The reason is that
neurobiologists have made great progress using conventional
techniques of anatomy and physiology to map the brain's visual
circuitry, and this work has proven enormously valuable.
"Given that kind of success, you really don't need to think about
whether some arcane aspects of visual perception provide a better
framework for understanding vision," he said. "The peculiar
phenomena we have been concerned with can easily be ignored as
anomalies that don't have much importance.
"The problem is that, after 50 years of work, neurobiologists still
can't explain in terms of visual circuitry any aspect of visual
perception, no matter how simple," Purves said. "This evidence
about how color is perceived, together with what we have recently
discovered about the perception of luminance [black and white
stimuli], orientation and motion argue pretty strongly that all
these visual percepts arise on the same empirical footing. This way
of thinking rationalizes a long list of phenomena that are
otherwise very hard to explain."
In related papers published over the past three years, Purves and
his colleagues have reported other experiments using visual
illusions to explore perception of brightness, shading, color and
geometry (See Web site at http://www.adm.duke.edu/alumni/purvesfor examples).
According to the neurobiologists, the empirical theory of vision,
if supported by further experiments, could yield a far more
productive approach to understanding the brain, as well as
practical applications such as computers that more realistically
employ the strategies used by the brain.
"The visual part of the brain - and presumably the rest of the
brain as well - seems to work like a computer that doesn't
'understand' the rules of the game it's playing," said Purves.
"Nevertheless, it's already clear a computer can develop a pretty
good game of, say, checkers simply by changing its connectivity
according to feedback about the moves that worked well in the past.
Getting computers to see things, however, has been a difficult
problem that remains largely unsolved,"said Purves.
"Humans have had millions of years as a species, and a fair number
of years as individuals, to perfect the neural networks triggered
by visual stimuli. This very long process of shaping connections by
trial and error is apparently what has made us so good at
visualizing the world we live in, even though we never really see
what's there."
