Discovering Psychology: The Science of Mind (2022) - PDF

Summary

This book, Discovering Psychology: The Science of Mind (2022), explores the concepts of sensation and perception. It delves into how the human mind constructs its model of reality through sensory input and examines individual differences in perception, influenced by experience and culture.

Full Transcript

5
The Perceiving Mind
SENSATION AND PERCEPTION

LEARNING OBJECTIVES
1. Explain the basic 2. Identify the process 4. Describe the process by 5. Explain the mechanisms by
concepts of sensation by which the physical which physical structures which the somatosensory
and perception, structures of the eye of the ear transduce and chemical sense systems
including transduction transduce light waves sound waves into neural produce perception of
of stimuli into neural into neural signals, signals, producing body position, touch, skin
signals, distinctions producing the sense of perception of pitch, temperature, pain, smell,
between bottom-up vision. loudness, and spatial and taste.
and top-down location in hearing.
perceptual processing, 3. Summarize the 6. Analyze the causes
thresholds, and processes responsible of various individual
measurement. for color vision, object differences in perception,
recognition, and depth including development and
perception. culture, in terms of biology,
experience, and their
interaction.

WE LIKE TO THINK WE UNDERSTAND REALITY. After all, we can see, hear, touch, smell, and taste it.
We don’t live in some science fiction universe where things are not how they appear. Or do we?

The human eye can see many different colors, but what does it mean to “see” a color? Is color something
that is a fixed quality of an object? Is the sky really blue? Is an apple really red? Or does the human mind
construct these colors from the light reflected from these objects into the eye? Consider the image of the
blue/black or white/gold dress that became an Internet sensation in February 2015. A friend of a Scottish
bride posted the dress worn by the bride’s mother on her Tumblr blog, leading to a discussion that engaged
everyone from Justin Bieber to esteemed neuroscientists. Why do people see this photo so differently?

Neuroscientists disagree about why the dress produced such different responses. The Journal of Vision
prepared an entire issue (“A Dress Rehearsal for Vision Science”) devoted to explaining the dress
phenomenon. A survey of 1,400 people found that 57% described the dress as blue/black (which is
Laura Freberg

correct), 30% as white/gold, 11% as blue/brown, and 2% as something else (Lafer-Sousa et al., 2015).
Older individuals and women were more likely to choose white/gold. These researchers believe that
people choose dress colors based on their expectations regarding the lighting. If you think the dress is
seen in daylight, you make different conclusions than if you think the dress is seen under artificial light. “The Dress” became an Internet
phenomenon as people debated its true
Other scientists believe there is something special about the color blue due to our considerable colors. Do you see it as black and blue?
experience with natural lighting (Winkler et al., 2015). Because indirect lighting and shadows are usually White and gold? Something else?

149

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 blue, participants are more likely to confuse blue objects with blue
lighting. If you assume the light falling on the dress is somewhat blue, you
will probably see it as white.

Would having a color vision deficiency change the way a person sees the
dress? See for yourself. We can reconstruct how the image would look to a
person with a rare type of blue-yellow color vision deficiency. Surprisingly,
this has little effect, although the blue looks somewhat gray. Is the reality
seen by a person with a color vision deficiency different from your reality?
We’re going to argue that it is not reality that changes but rather the way
the brain views that reality.

Laura Freberg
As you’ll see in this chapter, we construct models of reality from the
information obtained through our senses. We like to think that we are
aware of the world around us, and it is unsettling to realize that the world
might be different from the representations of reality formed by the human mind. You will learn how
“Tritanopes” have a rare type of
blue-yellow color vision deficiency. the models built by the human mind have promoted our survival over many generations. Our models of
We can simulate how the mysterious reality are distinct from those built by the minds of other animals, whose survival depends on obtaining
dress would look to a tritanope. The different types of information from their environments.
differences are surprisingly subtle,
which explains why we use the term
“color vision deficiency” rather than
“colorblindness.” This example also
reminds us that a single reality (the
How Does Sensation Lead to
dress) can be sensed and perceived
very differently by individual minds. Perception?
Our bodies are bombarded with information during wakefulness and sleep. This information
takes many forms, from the electromagnetic energy of the sun to vibrations in the air to mol-
ecules dissolved in saliva on our tongues. The process of sensation brings information to the
brain that arises in the reality outside our bodies, like a beautiful sunset, or originates from
within, like an upset stomach.
Sensory systems have been shaped by natural selection, described in Chapter 3, to provide
information that enhances survival within a particular niche. We sense a uniquely human
reality, and one that is not shared by other animals. Your dog howls seconds before you hear
the siren from an approaching ambulance because the dog’s hearing is better than yours for
high-pitched sounds. Horses bolt at the slightest provocation, but they may be reacting to the
vibration of an approaching car or an animal that they sense through their front hooves, a
source of information that is not available to the rider. Some animals sense light energy out-
side the human visible spectrum. Insects can see ultraviolet light, and some snakes use infrared
energy to detect their prey.
Differences in sensation do occur from person to person, such as the need to wear cor-
rective glasses or not, but they are relatively subtle. However, once we move from the process
sensation The process of detecting of sensation to that of perception, or the interpretation of sensory input, individual differ-
environmental stimuli or stimuli arising ences become more evident. For example, friends voting for different presidential candidates
from the body.
will come to different conclusions about who won a debate. Everyone watching the exchange
perception The process of interpreting
sensed similar information, but each person’s perceptions are unique.
sensory information.

Sensory Information Travels to the Brain
Sensation begins with the interaction between a physical stimulus and our biological sensory
systems. A stimulus is anything that elicits a reaction from our sensory systems. For example,
we react to light energy that falls within our visual range, as we will see later in this chapter,
but we cannot see light energy that falls outside that range, such as the microwaves that cook
our dinner or the ultraviolet waves that harm our skin (see Figure 5.1).

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 FIGURE 5.1
All Species Experience an Adaptive
Reality. Humans see only a small
part of the electromagnetic energy
emitted from the Sun. Some animals
see even less. Dogs apparently do
fine seeing blues, yellows, and grays,
whereas humans have evolved to see
a more colorful world. The dog’s view

Leah Warkentin/AGE Fotostock
of the world is simulated in the photo
on the right.

Wavelength in meters
10–15 10–14 10–13 10–12 10–11 10–10 10–9 10–8 10–7 10–6 10–5 10–4 10–3 10–2 10–1 101 102 103
Visible
Cosmic rays Gamma X-rays Ultraviolet Infrared Microwaves Radar TV FM AM Short
rays Radio waves waves

VISIBLE RANGE

Human’s
view
400 450 500 550 600 650 700 750
Wavelength in nanometers

Dog’s
view

Before you can use information from your senses, it must be translated into a
form the nervous system can understand. This process of translation from stimulus
to neural signal is known as transduction. You might think of sensory transduc-
tion as being similar to the processing of information by your computer. Modern
computers transduce a variety of inputs, including voice, photos, keyboard, mouse
clicks, and touch, into a programming language for further processing.

The Brain Constructs Perceptions From
Ted Kinsman/Science Source

Sensory Information
Once information from the sensory systems has been transduced into neural sig-
nals and sent to the brain, the process of perception, or the interpretation of the
sensory information, begins. Perception allows us to organize, recognize, and use
the information provided by the senses.
An important gateway to perception is the process of attention, defined as a narrow focus of Some types of snakes (vipers, boas,
consciousness. As we discuss in Chapters 6, 9, and 10, attention often determines which features and pythons) can locate prey by
of the environment influence our subsequent thoughts and behaviors. Which stimuli are likely to sensing infrared energy.
grab our attention? Unfamiliar, changing, or high-intensity stimuli often affect our survival and
have a high priority for our attention. Unfamiliar stimuli in our ancestors’ environment might
have meant a new source of danger (an unknown predator) or a new source of food (an unfamil-
transduction The translation of incom-
iar fruit) that warranted additional investigation. Our sensory systems are particularly sensitive ing sensory information into neural signals.
to change in the environment. Notice how you pay attention to the sound of your heating system

HOW DOES SENSATION LEAD TO PERCEPTION? 151

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 cycling on or off but pay little attention to the noise it makes while running. This reduced re-
sensory adaptation The tendency to
pay less attention to a nonchanging source
sponse to an unchanging stimulus is known as sensory adaptation. High-intensity stimuli, such
of stimulation. as bright lights and loud noises, draw our attention because the situations that produce these
bottom-up processing Perception stimuli, such as a nearby explosion, can have obvious consequences for our safety.
based on building simple input into more We rarely have the luxury of paying attention to any single stimulus. In most cases, we
complex perceptions. experience divided attention, in which we attempt to process multiple sources of sensory in-
top-down processing A perceptual formation. Students walk to class without getting run over by a car while texting. These divided
process in which memory and other cogni- attention abilities are limited. We simply cannot process all the information converging simulta-
tive processes are required for interpreting neously on our sensory systems. To prioritize input, we use selective attention, or the ability to
incoming sensory information.
focus on a subset of available information and exclude the rest. These abilities may be disrupted
in cases of attention deficit hyperactivity disorder (ADHD; Wimmer et al.,
If you think about the most memorable 2015; also see Chapter 14).
advertisements you have seen lately on television We refer to the brain’s use of incoming signals to construct perceptions as
or online, it is likely that they share the features of bottom-up processing. For example, we construct our visual reality from infor-
mation about light that is sent from the eye to the brain. However, the brain also
attention-getting stimuli: novelty (we don’t see
imposes a structure on the incoming information, a type of processing known
talking geckos every day), change (rapid movement, as top-down. In top-down processing, we use knowledge gained from prior
use of changing colors, and the dreaded pop-up), experience with stimuli to perceive them. For example, a skilled reader has no
and intensity (the sound is often louder than the trouble reading the following sentences, even though the words are jumbled:
program you’re watching). All you hvae to do to mkae a snetnece raedalbe is to mkae srue taht the fisrt and lsat letrtes
of ecah wrod saty the smae. Wtih prcatcie, tihs porcses becoems mcuh fsater and esaeir.
How can we explain our abil-
We have all had the experience ity to read these sentences? First,
of watching events with others we require bottom-up processing to
(sensation) and then being shocked by bring the sensations of the letter
the different interpretations we hear shapes to our brain. From there,
of what just happened (perception). however, we use knowledge and
experience to recognize individual
words. Many students have learned
the hard way that term papers must
AP Images/Roberto Pfeil

be proofread carefully. As in our ex-
ample, if the brain expects to see a
particular word, you are likely to see
that word, even if it is misspelled, a

metamorworks/Shutterstock.com

Divided attention abilities are limited.
Some people believe that heads-up
displays for cars assist drivers with
divided attention, while others believe
the displays are too distracting.

152 Chapter 5 THE PERCEIVING MIND: SENSATION AND PERCEPTION

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Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it.
 mistake that is unlikely to be made by the
literal, bottom-up processing of a com- Selective attention, or our focus on a
puter spell-checker. subset of input, prioritizes incoming
Can we predict when the mind will information. However, we can
use bottom-up or top-down processing? sometimes be so focused that we miss
There are no hard and fast rules. Ob- important information. An astonishing
viously, we always use bottom-up pro- 20 out of 24 expert radiologists

skyhawk x/Shutterstock.com
cessing, or the information would not be completely missed the image of a
perceived. It is possible that bottom-up gorilla superimposed on scans of lungs
processing alone allows us to respond while scanning for signs of cancer.
appropriately to simple stimuli, like in- Source: T. Drew et al. (2013). “The
dicating whether you saw a flash of light, Invisible Gorilla Strikes Again:
or stimuli that are unfamiliar to us. As Sustained Inattentional Blindness
stimuli become more complicated or familiar, like reading a sentence or recognizing a in Expert Observers,” Psychological
friend in a crowd, we are more likely to engage in top-down processing in addition to Science, 24(9), 1848–1853, doi:
bottom-up processing. 10.1177/0956797613479386

Measuring Perception Gustav Fechner (1801–1887) developed methods, which he
called psychophysics, for studying the relationships between stimuli (the physics part) and
perception of those stimuli (the psyche or mind part) (see Figure 5.2). Fechner’s careful psychophysics The study of relationships
methods not only contributed to the establishment of psychology as a true science but are still between the physical qualities of stimuli
used in research today. and the subjective responses they produce.
The methods of psychophysics allow us to establish the limits of awareness, or thresholds, absolute threshold The smallest
for each of our sensory systems. The smallest possible stimulus that can be detected at least amount of stimulus that can be detected.
50% of the time is known as the absolute threshold. Under ideal circumstances, our senses difference threshold The smallest de-
tectable difference between two stimuli.
are surprisingly sensitive (see Figure 5.3). For example, you can see the equivalent of a
candle flame 30 miles (about 48 kilometers) away on a moonless night. We can also establish
a difference threshold, or the smallest difference between two stimuli that can be detected at
least 50% of the time. The amount of difference that can be detected depends on the size of
the stimuli being compared. As stimuli get larger, differences must also become larger to be
detected by an observer.

Signal Detection Many perceptions involve some uncertainty. Perhaps you think you
recognize the person coming toward you on the sidewalk. Do you wave right away? Or do
you wait until the person is close enough that you know for sure it’s your friend? How do your
personal feelings about making mistakes affect your decision? How embarrassed would you
be if you waved at a stranger? FIGURE 5.2
This type of decision making can have serious implications, such as in the case of deci-
sions made by radiologists examining the results of mammograms for signs of cancer or by Connecting the Physical
intelligence officers assessing the possibility of an attack. Is there reason for concern or not? World and the Mind. “Golden”
rectangles, named for their
proportions rather than color,
appear in art and architecture
dating back to ancient Greece,
but why are they attractive?
Gustav Fechner (1801–1887) made
40 many attempts to link physical
35
Percent of choices

realities with human psychological
30
responses. He asked people to
25
Photo Researchers, Inc/Alamy Stock Photo

choose which rectangles are most
20
15
pleasing or least pleasing. His
10 results indicated that the most
5 pleasing rectangle was fourth
0 from the right. This rectangle
is the closest to having golden
Most pleasing The proportions (1:1.618). Its sides have
Least pleasing Golden Rectangle a ratio of 13:21.

HOW DOES SENSATION LEAD TO PERCEPTION? 153

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FIGURE 5.3
Absolute Sensory Thresholds. An absolute
threshold is the smallest amount of sensation that
can be processed by our sensory systems under ideal
conditions. Moving from left to right in this image,
we see that the absolute threshold for touch is the
equivalent of feeling the wing of a fly fall on your cheek
from a distance of 0.4 inches (about 1 centimeter), the
absolute threshold for olfaction is a drop of perfume
in the air filling a six-room apartment, the absolute
threshold for sweetness is the equivalent of one
teaspoon (about 5 grams) of sugar in two gallons (about A drop of perfume diffused
into the entire volume of air
7.5 liters) of water (the absolute threshold for bitter
The wing of a fly falling in a six-room apartment
tastes is even more sensitive), the absolute threshold
on you from a distance of
for hearing is the equivalent of the sound of a mosquito 0.4 inches (about 1 centimeter)
10 feet (about 3 meters) away, and the absolute Photos, left to right: Gladskikh Tatiana/Shutterstock.com; Kuttelvaserova Stuchelova/Shutterstock.com;
Christopher Elwell/Shutterstock.com; AlexRoz/Shutterstock.com.
threshold for vision is seeing a candle flame 30 miles
(about 48 kilometers) away on a dark, clear night.

This situation is different from the thresholds described earlier because it adds the cognitive
signal detection The analysis of sensory
process of decision making to the process of sensation. In other words, signal detection is a
and decision-making processes in the de-
tection of faint, uncertain stimuli. two-step process involving (a) the actual intensity of the stimulus, which influences the ob-
server’s belief that the stimulus did occur, and (b) the individual observer’s criteria for decid-
ing whether the stimulus occurred.
Experiments on signal detection provide insight into this type
Another example of signal detection is a jury’s of decision making. In these experiments, trials with a single, faint
decision about whether a person is guilty. Based stimulus and trials with no stimulus are presented randomly. The
on frequently uncertain and conflicting evidence, participant states whether a stimulus was present on each trial. The pos-
jurors must weigh their concerns about convicting sible outcomes of this experiment are shown in Table 5.1. In the case
of reading mammograms, we can use such experiments to help us
an innocent person (false alarm) or letting a real
understand why two people might respond differently, even if they
criminal go (miss). were sensing the same information. Ideally, a radiologist would identify
100% of all tumors without any false alarms, but mammograms are not that easy to evalu-
ate. A radiologist afraid of missing a tumor might identify anything that looks remotely
like a tumor as the basis
for more testing. Few
cases of cancer would be
missed (high hit rate), but
many healthy patients
would go through unnec-
essary procedures (high
false alarm rate). In con-
trast, another radiologist
According to Fechner’s work on the might need a higher
difference threshold, British Olympian level of certainty about
YURI CORTEZ/AFP/Getty Images/Newscom

Zoe Smith would be more likely to the presence of a tumor
notice the difference between 1 and before asking for fur-
2 kilogram (about 2- and 4-pound) ther tests. This would
dumbbells than the difference reduce the number of
between her new record of 121 false alarms, but it would
kilograms (266.76 pounds) in the clean also run a higher risk of
and jerk event and the former record overlooking tumors (high
of 120 kilograms (264.56 pounds). miss rate).

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 The sound of a mosquito
flying about 10 feet
(about 3 meters) away A candle flame seen at
30 miles (about 48 kilometers)
on a clear night

Photos, left to right: fotomak/Shutterstock.com; seeyou/Shutterstock.com;
taedong/Shutterstock.com; Karen H. Ilagan/Shutterstock.com.
A teaspoon of sugar (about 5 grams) in two
gallons (about 7.5 liters) of water

Does this mammogram indicate the
woman has cancer or not? Many
decisions we make are based on
ambiguous stimuli. Signal detection
theory helps us understand how an
individual doctor balances the risks
of missing a cancer and those of
alarming a healthy patient.
BSIP/Contributor/Universal Images Group/Getty Images

TABLE 5.1
Possible Outcomes in Signal Detection
Participant Response Stimulus Present Stimulus Absent
Yes Hit False alarm
No Miss Correct rejection

HOW DOES SENSATION LEAD TO PERCEPTION? 155

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Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it.
SUMMARY 5.1 Assessing Perception
Concept Definition Example

Absolute threshold The smallest amount of stimulation that is Seeing light from a candle flame
detectable. 30 miles away on a dark night.

Difference threshold The smallest difference between two Being able to detect the difference between
stimuli that can be detected. two different weights.

Signal detection Correctly identifying when a faint stimulus A radiologist correctly detecting cancer from
is or is not present. a mammogram.

Credits: Top row—Karen H. Ilagan/Shutterstock.com; Second row—YURI CORTEZ/AFP/Getty Images/Newscom; Bottom row—BSIP/Contributor/Universal Images Group/Getty Images.

vision The sense that allows us to process
reflected light. How Do We See?
Vision, the processing of light reflected from objects, is one of the most important sensory
systems in humans. Approximately 50% of our cerebral cortex processes visual information,
in comparison to only 3% for hearing and 11% for touch and pain (Kandel & Wurtz, 2000;
Sereno & Tootell, 2005). We will begin our exploration of vision with a description of the
visual stimulus, and then we will follow the processing of that stimulus by the mind into a
meaningful perception.

The Visual Stimulus
Visible light, or the energy within the electromagnetic spectrum to which our visual systems
respond, is a type of radiation emitted by the Sun, other stars, and artificial sources such as a
lightbulb. As shown in Figure 5.4, light energy moves in waves, like the waves in the ocean.
Wavelength, or the distance between successive peaks of waves, is decoded by our visual
FIGURE 5.4 system as color or shades of gray. The height, or amplitude, of the waves is translated by the
visual system into brightness. Large-amplitude waves appear bright, and low-amplitude waves
Light Travels in Waves. The distance appear dim.
between two peaks in a light wave The human visual world involves only a small part of this light spectrum (review
(wavelength) is decoded by the visual Figure 5.1). Gamma rays, x-rays, ultraviolet rays, infrared rays, microwaves, and radio waves
system as color and the height, or lie outside the capacities of the human eye.
amplitude, of the wave as brightness.

Wavelength
Amplitude
Baseline

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 The Biology of Vision
Human vision begins with the eye. The eye is roughly sphere shaped and about the size of a
ping-pong ball. Its hard outer covering helps the fluid-filled eyeball retain its shape. Toward
the front of the eye, the outer covering becomes clear and forms the cornea. The cornea begins
the process of bending light to form an image on the back of the eye. Traveling light next en-
ters the pupil, which is actually an opening formed by the muscles of the iris (see Figure 5.5).
The iris, which means “rainbow” in Greek, adjusts the opening of the pupil in response to
the amount of light present in the environment and to signals from the autonomic nervous
system, described in Chapter 4. Arousal is associated with dilated pupils, while relaxation is
associated with more constricted pupils.
Directly behind the pupil and iris is the main optical instrument of the eye, the lens.
Muscles attached to the lens can change its shape, allowing us to accommodate, or adjust our
focus to see near or distant objects. Behind the lens is the main chamber of the eye, and lo- cornea The clear surface at the front of
the eye that begins the process of directing
cated on the rear surface of this chamber is the retina, a thin but complex network of neurons
light to the retina.
specialized for the processing of light.
pupil An opening formed by the iris.
Located in the deepest layer of the retina are specialized receptors, the rods and cones,
iris The brightly colored circular muscle
that transduce the light information. However, before light reaches these receptors, it must
surrounding the pupil of the eye.
pass through layers of blood vessels and neurons. We normally do not see the blood vessels
lens The clear structure behind the pupil
and neural layers because of sensory adaptation. As we mentioned previously in this chapter, that bends light toward the retina.
adaptation occurs when sensory systems tune out stimuli that never change. Because the
retina Layers of visual processing cells in
blood vessels and neural layers are always in the same place, we see them only under unusual the back of the eye.
circumstances, such as during certain ophthalmology (eye) tests.

Fovea

Optic disk

James P. Gilman, C.R.A./Medical Images.com
(blind spot)

Blood
vessels

Retina

Fovea
FIGURE 5.5
Optic disk
Cornea
The Human Eye. Light entering the
eye travels through the cornea, the
pupil, and the lens before reaching
Pupil the retina. Among the landmarks
on the retina are the fovea, which is
Iris
specialized for seeing fine detail, and
Lens the optic disk, where blood vessels
Blood vessels enter the eye and the optic nerve exits
the eye.
Source: Argosy Publishing, Inc.

HOW DO WE SEE? 157

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FIGURE 5.6
Now You See It—Now You
Don’t. There are no photoreceptors in
the optic disk, producing a blind spot in We can identify several landmarks on the surface of the retina. The blood vessels serv-
each eye. We do not see our blind spots ing the eye and the axons that leave the retina to form the optic nerve exit at the optic disk.
with both eyes open because our brain Because there are no rods and cones in the optic disk, each eye has a blind spot. Normally, we
fills in the hole. You can demonstrate are unaware of our blind spots because perception fills in the missing details. However, if you
your blind spot by holding your follow the directions in Figure 5.6, you should be able to experience your own blind spot.
textbook at arm’s length, closing one Toward the middle of the retina is the fovea, which is specialized for seeing fine detail. When
eye, focusing your other eye on the dot, we stare directly at an object, the image of that object is projected onto the fovea. The fovea
and moving the book toward you until is responsible for central vision, as opposed to peripheral vision, which is the ability to see
the stack of money disappears. objects off to the side while looking straight ahead.
The image projected on the retina is upside down and reversed relative to the actual
FIGURE 5.7 orientation of the object being viewed (see Figure 5.7). You can duplicate this process by
looking at both sides of a shiny spoon. In the convex (or outwardly curving) side, you see your
What the Retina “Sees.” The image image normally. In the concave (or inwardly curving) side, you see your image as your retina
projected on the retina is upside down sees it. Fortunately, the visual system easily decodes this image and provides realistic percep-
and reversed, but the brain is able to tions of the actual orientations of objects.
interpret the image to perceive the
correct orientation of an object. Photoreceptors The human retina contains three types of photoreceptors: rods, cones,
Source: Argosy Publishing, Inc.
and a group of specialized ganglion cells that respond to brightness. Rods and cones are
named after their shapes. Each human eye contains over
Retina
110 million rods and about 6 million cones. There are only
Light about 50,000 of the specialized ganglion cells.
These photoreceptors are responsible for different as-
pects of vision. Rods are more sensitive to light than cones,
and they excel at seeing dim light. As we observed previ-
ously, under ideal circumstances, the absolute threshold
Ariwasabi/Shutterstock.com

for human vision is the equivalent of a single candle flame
from a distance of 30 miles (about 48 kilometers; see Hecht
et al., 1942). Rods become more common as we move from
the fovea to the periphery of the retina, so your peripheral
vision does a better job of viewing dim light than your
central vision does (see Figure 5.8). Before the develop-
Cornea Optic nerve
ment of night goggles, soldiers patrolling in the dark were
Lens trained to look to the side of a suspected enemy position
fovea An area of the retina that is special-
ized for highly detailed vision.
rather than directly at their target.
rod A photoreceptor specialized to detect
dim light. Rods
cone A photoreceptor in the retina that
processes color and fine detail.

FIGURE 5.8
Distribution of Rods and Cones
Across the Retina. In humans, cones,
indicated by red, blue, and green
dots, become less frequent as you
move from the fovea to the periphery
of the retina. The colors of the dots
representing cones indicate the colors
to which each shows a maximum
response (see Figure 5.11). Rods
(light brown dots) and cones are
named according to their shapes.
Cones
Source: Argosy Publishing, Inc.

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 This extraordinary sensitivity of rods has costs. Rods do Primary visual cortex (occipital lobe)

not provide information about color, nor do they provide
Midbrain Thalamus
clear, sharp images. Under starlight, normal human vision
is 20/200 rather than the normal daylight 20/20. In other
words, an object seen at night from a distance of 20 feet
would have the same clarity as an object seen in bright Optic chiasm
sunlight from a distance of 200 feet. Cones function best
under bright light and provide the ability to see both sharp
images and color.
The observation that animals lacking rods and cones Retina
still showed some visual responses led to the search for
additional photoreceptors in the retina. A special class of
ganglion cells in the retina turned out to be important for Optic tract

setting our biological clocks (see Chapter 6), maintaining Optic nerve
pupil reflexes, and assessing the brightness of a visual
stimulus (Yamakawa et al., 2019).

Visual Pathways When rods and cones absorb
light, they trigger responses in four additional
layers of neurons within the retina. Axons from
the final layer of cells, the ganglion cells,
leave the back of the eye to form the
optic nerve. The optic nerves cross the
midline at the optic chiasm (named
after its X shape, or the Greek letter
chi). At the optic chiasm, the FIGURE 5.9
axons closest to the nose cross
over to the other hemisphere, Visual Pathways. Visual information
while the axons to the outside from the retina travels to the thalamus
proceed to the same hemisphere. and then to the primary visual cortex
This partial crossing means in the occipital lobe. While looking
that if you focus straight ahead, straight ahead, visual stimuli to the
everything to the left of center in right of center are processed by the
the visual field is processed by the left hemisphere, while visual stimuli to
Visual field the left of center are processed by the
right hemisphere, while everything of right eye
to the right of center is processed by right hemisphere.
the left hemisphere. This organization Source: Argosy Publishing, Inc.
Visual field
provides us with significant advantages of left eye

when sensing depth, which we discuss later in
the chapter.
Beyond the optic chiasm, the visual pathways are known as optic tracts (see Figure 5.9).
About 90% of the axons in the optic tracts synapse in the thalamus. The thalamus sends
information about vision to the amygdala and the primary visual cortex in the occipital
lobe. The amygdala uses visual information to make quick emotional judgments, especially
about potentially harmful stimuli. The remaining optic tract fibers connect with the hypo-
thalamus, where their input provides information about light needed to regulate sleep–wake
cycles, discussed in Chapter 6, or with the superior colliculi of the midbrain, which manage
a number of visually guided reflexes, such as changing the size of the pupil in response to
light conditions.
The primary visual cortex begins, but by no means finishes, the processing of visual input.
The primary visual cortex responds to object shape, location, movement, and color (Hubel &
Wiesel, 1959; Livingstone & Hubel, 1984; Hubel & Livingstone, 1987). Two major pathways optic nerve The nerve exiting the retina
of the eye.
radiating from the occipital cortex into the adjacent temporal and parietal lobes continue the
analysis of visual input. The parietal pathway helps us process movement in the visual envi- optic tracts Nerve pathways traveling
from the optic chiasm to the thalamus, hy-
ronment. The temporal pathway responds to shape and color and contributes to our ability to pothalamus, and midbrain.
recognize objects and faces.

HOW DO WE SEE? 159

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Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it.
 Visual Perception and Cognition
To see something requires the brain to interpret the information gathered
by the eyes. How do you know your sweater is red or green, based on the
information sent from the retina to the brain? How do you recognize your
grandmother at your front door?

Color Vision Most of us think about colors in terms of the paints and
crayons we used in elementary school. Any kindergartner can tell you
that mixtures of red and yellow make orange, red and blue make purple,
and yellow and blue make green. Mixing them all together produces a
lovely muddy brown. Colored lights, however, work somewhat differently
(see Figure 5.10). The primary colors of light are red, green, and blue, and
mixing them together produces white light, like sunlight. If you have ever
adjusted the color on your computer monitor or television, you know that
these devices also use red, green, and blue as primary colors. Observations supporting the
FIGURE 5.10 existence of three primary colors of light gave rise to a trichromatic theory of color vision.
Trichromatic theory is consistent with the existence of three types of cones in the retina
Mixing Colored Lights. The primary
that respond best to short (blue), medium (green), or long (red) wavelengths. Our ultimate
colors of paint might be red, yellow,
experience of color comes not from the response of one type of cone but from comparisons
and blue, but in the world of light, the
among the responses of all three types of cones (see Figure 5.11).
primary colors are red, green, and blue.
Color vision deficiency occurs when a person has fewer than the typical three types of cones.
Mixed together, they produce white.
We no longer use the term colorblind, as this is not accurate. Most people with color vision defi-
ciencies see color differently than someone with all three cone types. Very rarely, individuals have
either one type of cone or none. To these people, the world appears to be black, white, and gray.
trichromatic theory A theory of color
vision based on the existence of different
Trichromatic theory does a good job of explaining color vision deficiency, but it is less
types of cones for the detection of short, successful in accounting for other color vision phenomena, such as color afterimages. For
medium, and long wavelengths. example, if you stare at the yellow, green, and black flag in Figure 5.12 and then focus on the
opponent process theory A theory dot within the white rectangle to the right, you will see an afterimage of the American flag in
of color vision that suggests we have a its more traditional colors of red, white, and blue.
red–green color channel and a blue–yellow An opponent process theory of color vision does a better job than the trichromatic
color channel in which activation of one
theory in explaining these color afterimages. This theory proposes the existence of color
color in each pair inhibits the other color.

100
Percentage of maximum response

Rods
Cones

75
Green

FIGURE 5.11
50
Red
Responses by Cones to Colored Light. Our perception
of color results from a comparison of the responses of
25 Blue
the red, green, and blue cones to light. A 580-nanometer
light is perceived as yellow and produces a strong
response in green cones, a moderate response in red
cones, and little response in blue cones. 400 450 500 550 600 650 700 750
Wavelength (nm)

FIGURE 5.12
Afterimages Demonstrate Opponent Process
Theory. If you stare at the dot in the center of the
yellow, green, and black flag for a minute and then
shift your gaze to the dot in the white space on the
right, you should see the flag in its traditional red,
white, and blue.

160 Chapter 5 THE PERCEIVING MIND: SENSATION AND PERCEPTION

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Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it.
 channels: a red–green channel and a blue–yellow channel. We cannot
see a color like reddish green or bluish yellow because the two colors
share the same channel. The channels are “opponent” or competing.
Activity in one color group in a channel inhibits activity in the other
color group.
Returning to our green, yellow, and black flag, how can we use

Dan Tuffs/Contributor/Getty Images Entertainment/Getty Images
opponent process theory to explain our experience of the red, white,
and blue afterimage? By staring at the flag, you fatigue some of your
visual neurons. Because the color channels compete, reducing activ-
ity in one color group in a channel, such as green, increases activity
in the other group, which is red. Fatiguing green, black, and yellow
causes a rebound effect in each color channel, and your afterimage
looks red, white, and blue. (Black and white also share a channel.) If
you stare at an image of a real red, white, and blue flag and then look
at a white piece of paper, your afterimage looks like our green, black,
and yellow illustration.
Which of these two theories of color vision, trichromatic theory
or opponent process theory, is correct? The trichromatic theory pro-
vides a helpful framework for the functioning of the three types of
Monty Roberts, known as the Horse Whisperer, attributes his
cones in the retina. However, as we move from the retina to higher
abilities to observe horse behavior to his complete lack of color
levels of visual analysis, the opponent process theory seems to fit
vision. This condition is quite rare, occurring in only 1 person out
observed phenomena neatly. Both theories help us understand color
of every 30,000.
vision but at different levels of the visual system.

PSYCHOLOGY AS A HUB SCIENCE
Color and Accessible Web Design
NOW THAT YOU HAVE AN UNDERSTANDING of color perception, we can consider one
of the practical problems associated with individual differences in color vision. Between 7%
and 10% of males and about 0.4% of females have a form of red–green color vision deficiency
(see Figure 5.13). Males are more affected than females because the genes for the pigments
used by red and green cones are located on the X chromosome, making red–green color de-
ficiency a sex-linked condition (see Chapter 3). Smaller numbers of people lack blue cones
(0.0011%) or cones altogether (0.00001%). Given the frequency of color vision deficiency,
making visual materials accessible to people with all types of color vision is a serious concern.
Color can be an effective tool for designing exciting and engaging websites, but many
graphic web designers, who typically have excellent vision, fail to consider how the site might
look to a person with a color vision deficiency. One clue for designing an accessible site can
be found in other systems based on color, such as traffic lights. Although most of us rely on
the color information from the red, yellow, or green
lights, the lights also vary in location. In other words,
color should never be the only basis for extracting FIGURE 5.13
meaning. A second major concern is contrast, which
we discuss in the next section. The strong contrast Detecting Color Vision
between black letters on the white pages makes text Deficiency. The Ishihara Color Test,
PRISMA ARCHIVO/Alamy Stock Photo

easy to read for most people. Colored text against a designed by Shinobu Ishihara in 1917,
colored background might add interest, but it runs is a standard method for detecting
the risk of being harder to read, especially when reds color vision deficiency. The test
and greens are used. As shown in Figure 5.14, online is printed on special paper, so the
resources simulate how a web page looks to a person recreated image here would not be
with color vision deficiency, which helps designers considered a valid basis for diagnosing
maximize accessibility. color deficiency.

HOW DO WE SEE? 161

Copyright 202