PSY101_CHAPTER4_upload.pptx

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Psychology:
From Inquiry to Understanding 2/e
Scott O. Lilienfeld
Steven Jay Lynn
Laura Namy
Nancy J. Woolf
Prepared by Caleb W. Lack
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LECTURE PREVIEW


Sensation and perception



The visual system



The auditory system



The sensual sense



Our body senses

2

Chapter 4
SENSATION AND PERCEPTION:
HOW WE SENSE & CONCEPTUALIZE
THE WORLD

SENSATION & PERCEPTION:
TWO SIDES OF THE COIN
o

Sensation: the detection of physical energy by sense organs
(e.g. eye, nose, skin etc.)

o

Perception: is the brain’s interpretation of raw sensory data.

o

Sensation  pick up signals in environment,
Perception  assembles these signals into stg. meaningful.
(illusions!)

o

4

SENSATION & PERCEPTION:
TWO SIDES OF THE COIN
o

How do signals that make contact with our sense-organs become
translated into info. that our brains can interpret & act?

Sensory systems  physical signals to neural activity.
Brain  interpretation of neural activity.
o

Transduction: The external stimulus converted by sense
receptor into neural activity.
Light, sound  electrical signals

5

SENSATION & PERCEPTION:
TWO SIDES OF THE COIN


Sensory activation greatest when we first detect a stimulus



Sensory adaptation: Sense receptor reacts strongly at first
& then tamps down its level of responding to conserve
energy & attentional resources
Ex: you longer notice that you are sitting on a chair.



Psychophysics (Gustav Fechner,1860): the study of how
we perceive sensory stimuli based on their physical
characteristics

6

SENSATION & PERCEPTION:
TWO SIDES OF THE COIN
o

Absolute threshold: the lowest level of a stimulus that can
be detected when no other that type of stimuli is present
(how sensative our sensory systems are).
• A single candle 48 kms away
• 50 odorant molecules

o

Just Noticeable Difference (JND): the smallest amount of
stimulus change that we can detect.
(How much difference in a stimulus makes a change)
(stronger from weaker)

o

Weber’s Law; the stronger the stimulus, the greater change
needed to detect.
7

8

SENSATION & PERCEPTION:
TWO SİDES OF THE COİN
o

Signal detection theory (Green & Swets, 1966): How we detect
stimuli under uncertain conditions?
Ex: (you need to increase the signal(shout) over the static connection
(background noise) while talking on the phone.

o

Signal-to-Noise Ratio: It becomes harder to detect a signal as
background noise increases.

o

The sensation is determined by the nature of sense-receptor, not
the stimulus

o

Phosphenes- vivid sense of light (sparks) caused by pressure on your
eye’s receptor cells.
( no matter touch or light activated the sense receptor).

Cross-Modal Senses : Phosphenes, the McGurk effect, the rubber hand
illusion)
9

SENSATION & PERCEPTION:
TWO SİDES OF THE COİN
o

McGurk Effect: integration of visual & auditory info.
(our brain automatically calculate the most probable sound given
by the info. from two sources.
(ba-hearing, ga-video; experience of da).
http://www.youtube.com/watch?v=jtsfidRq2tw

o

Rubber-Hand Illusion: how our senses of touch & sight interact to
create a false experience.
http://www.youtube.com/watch?v=sxwn1w7MJvk

o

This may help to explain synesthesia—hearing sounds when one
sees colors or tasting colors; people experience cross-modal
sensations.
10

PERCEPTION:WHEN SENSES MEET THE BRAIN
o

Our brains do not rely on what’s in our sensory field.
 What’s in our sensory field; but also
 What was there a moment ago
 What we remember from our past

o

Parallel Processing: We attend to multiple senses at once
(Bottom-up & Top-down )


Bottom-Up Processing: construction a whole stimuli from its parts
(e.g. perceiving an object from its parts)



raw stimuli
primary visual cortex



synthesizing into meaningful concept.
association cortex.

11

WHEN SENSES MEET THE BRAIN


Top-Down Processing: processing the whole stimuli & by
analyzing ends up with processing the smaller parts.
association cortex  primary visual cortex.
(work hand in hand ; e.g. ambigous figures).

Depending on our expectations & beliefs
we typically percieve these figures differently.
o
o

(jazz musician)
(woman face)

Perceptual sets
We form a perceptual set when our expectations influence what we
perceive.
12

CAN YOU FIND THE DOG?

13

WHEN SENSES MEET THE BRAIN
.

H or A?

B or 13?

Old or young?

14

WHEN SENSES MEET THE BRAIN
o

Perceptual constancy: we perceive a stimulus consistently
across varied conditions (adaptive!)



Shape constancy: we see a door as a door when shut, barely open or
fully open.



Size constancy: percieve objects as the same size no matter how far
away they are.



Color constancy: our ability to perceive color across different levels of
lightening.

o

Color perception in particular derives from context!
15

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17

http://www.youtube.com/watch?v=z9Sen1HTu5o
18

19

THE ROLE OF ATTENTION
o

Flexible attention ! (adaptive!)

• Selective attention: allows us to choose which sensory inputs to focus
on and which to “turn down” (RAS & the frontal lobe)
• Pay attention to some aspects of the stimulus/environment & ignore
others

• Cocktail Party Effect: we don’t typically notice what other people are
saying at a party unless it’s relevant to us.
(Experiment conducted by Simons & Chabris, 1999)

o

http://www.youtube.com/watch?v=vJG698U2Mvo
Change-blindness- failure to detect obvious changes in the environment.
20

SEEING: THE VISUAL SYSTEM
o

Light (electromagnetic energy)!

o

Visible light  wavelenght in the
hundreds of nanometers.
(btw. ultraviolet & infrared)

o

Other animals may have a more
restricted or greater spectrum;
(e.g.; reindeer, butterflies; some birds
& fish, bees)

21

SEEING: THE VISUAL SYSTEM
o

o

When light reaches an object, some of that
light gets reflected & some of gets
absorbed.
Brightness  intensity of the reflected light.
White  reflect

black  absorb

Hue  the color of light.
o

Primary colors; red, green & blue  white
(additive color mixing)

o

Primary colors; yellow, cyan, magenta black
(subtractive color mixing )
22

STRUCTURE OF THE EYE
o




Different parts of our eye
The Sclera: the white portion; protective layer
The Iris: colored part of the eye (e.g. blue, brown, green/ hazel)
•
•



two pigments (melanin/ brown & lipochrome/ yellowish brown)
controls amount of the light

The Pupil: the hole where light enters the eye.


Pupil contradiction  the amount of light

Pupil dilation  the amount of light 
 Psychological significance  complex info.,
arousal & excitement & attractiveness


belladonna

23

24

STRUCTURE OF THE EYE


The Cornea: transparent cells ; focus/bends light on the back of
the eye (retina).
•

•


Fixed

The Lens: changes curvature (accommodation) to focus light
onto back of eye (retina).
•
•

o

Curved, transparent layer

Consists of cells completely transparent.
Bends the light, changes (adaptation to distance)

The lens  flat (distant objects)
fat (nearby objects)

 accomodation

25

26

STRUCTURE OF THE EYE


Glasses change the way light enters the eye to help correct
myopia or hyperopia;












Myopia (nearsightedness)- ability to see near objects &
inability to see distant objects.
results when images are focused in front of the eye (retina), or
our eyes are too long.
Hyperopia (far-sightedness)- ability to see distant objects &
inability to see near objects.
results when images are focused behind the eye (retina), or
our eyes are too short.

Age  Vision 
https://www.youtube.com/watch?v=YcedXDN6a88
27

STRUCTURE OF THE EYE


The retina: thin membrane at the back of the eye.





Rods- basic shapes & forms of the objects low (dim light)






cell-receptors for vision & neurons
The fovea; for acuity or sharpness of vision (fine detail).

Dark adaptation; from bright  to dark environment.
Rods should regain their maximum sensitivity to light.
No rods in the fovea; we can see the star better by not looking
directly

Cones- gives the color vision & sensitive to detail



(also active in reading)
require more light
28

29

STRUCTURE OF THE EYE


The optic nerve: retina cells bundle all axons together &
depart the eye to reach the brain (back of the eye)



From retina to the rest of the brain.


optic chiasm; half of the axons cross optic chiasm & other half stays
on the same side.



Most of the axons go to the thalamus and then the visual cortex, but
some go to midbrain (play a key role in reflexes)



Blind spot; the place where optic nerve connects to retina
https://www.youtube.com/watch?v=JRxdFuPSp98
30

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32

33

Thalamus  occipital lobe  assoc. cortex of the pariatal lobe
assoc.cortex of the temporal lobe.
(visual form, motion, position)
34

GESTALT PRINCIPLES
o

o

o

Rules that govern how we perceive objects as wholes within their
overall context.
Gestalt principles why we see much of our world as consisting of
unified figures or forms
Formulated by Wertheimer, Kohler & Koffka in the early 20th
century.

35

DEPTH PERCEPTION
o

o

Depth perception; ability to see spatial relations in three
dimensions.
Depth perception  idea of how close & far the objects.

o

Two kinds of cues;




Monocular depth cues: one eye
 Relative size, texture gradient, interposition, linear perspective,
height in plane, light & shadow.
Binocular depth cues: both eyes
 Binocular disparity & binocular convergence.

DEPTH PERCEPTION
o

Monocular depth cues: pictorial cues

o

Relative Size: more distant objects look smaller.
Texture Gradient: The texture of objects become less apperent as
objects move farther away.
Interposition: When one object blocks our view of an object, we
understand which object is closer / farther away.
Linear Perspective: The outline of rooms & buildings converge as
distance increases.
Two parallel lines (vanishing point) !
Height in Plane: Distance objects seem higher & nearer objects lower.
Light & Shadow: Objects cast shadows a sense of their three
dimensional form.

o

o

o

o
o
o

o

Motion Parallax; the ability to judge the distance of objects from their
speed

38

DEPTH PERCEPTION
o

o

o

o

o

Binocular depth cues: we can view each of our two visual
fields with both eyes.
info. sent from both sides compared 
binocular depth perception.
Binocular Disparity: our right & left eyes  different info. for near
objects but see distant objects similarly. Each eye sees the world a bit
differently & brain uses this info to judge the depth & place of the
objects.
Binocular Convergence: nearby objects eye muscles turn eyes
inward; our brains are aware of how much our eyes are converging
(estimates distance).

Depth Perception begins in infancy (6-14 months) when we
learn to crawl (Visual cliff studies).

WHEN PERCEPTION DECEIVES US
o

We often misperceive information around us

o

Moon illusion: the moon appears larger on the
horizon than high in the sky.
o

Ames Room illusion: a distorted room
(trapezodial) .
- Relative size & the height
of the ceiling
- L.O.T.R.
- Charlie & the Chocolate
Factory

WHEN PERCEPTION DECEIVES US
o

Muller-Lyer illusion:
line with arrowheads pointing inward >
line with arrowheads pointing outward.

o

Ponzo illusion: when converging lines
enclose two objects of identical size
the object closer to the
converging line > the
object far way to the
converging line

.

WHEN PERCEPTION DECEIVES US
o

Horizontal-vertical illusions:
vertical part of > horizontal part,

o

Ebbinghaus-Titchner illusions:
circle when surrounded by small
circles > circle when surrounded
by bigcircles.

MOTION PERCEPTION

43

MOTION PERCEPTION
o To determine motion, the brain
compares visual frames of what
is to what was.
o

Phi phenomenon: the optical
illusion of perceiving continuous
motion btw. separate objects
viewed rapidly in succession.

o Defined by Max Wertheimer (1912)
(cinema & animation)

a series of adjacent light
flashed on/ off in succession.
44

45

WHEN WE CAN’T SEE
o
o

Blindness: inability to see
Blind people  heightened sense of touch
(visual cortex  sensitive to touch)

o

Color Blindness: can not see all the colors, results from
the absence or reduced number of one or more types of
cones.

o

Motion blindness—inability to perceive seamless motion.
(damage to occipital cortex & Alzheimer's disease)

o

Visual agnosia—object recognition deficit; damage to
visual cortical areas & parietal lobe.

HEARING
o
o

o
o

Audition; sense of hearing
Sound  vibration (mechanical energy) traveling through a
medium (air).
Vibration of molecules of air  sound waves.
Sound has;


Pitch: wave frequency (Hz);vibration per second
higher frequency  higher pitch ; lower frequency  lower pitch (people
 20 to 20.000 Hz).



Loudness: amplitude or the height of the sound waves (dB).
Loud noise  increased wave amplitude (more disturbance & more
vibrating airborne molecules). ( > 85 Db)





Timbre: complexity& quality of sound. Different musical instruments
have different timbre.

HEARING

48

49

THE EAR
o
o


o
o

o

o

Ear ; sense receptors sound  neural activity.
The outer ear, middle ear & inner ear.
The outer ear: pinna & ear canal.
Funnels sound waves onto the eardrum
The pinna  direct sound through the ear canal to the
tympanic membrane (eardrum).
Eardrum (tympanic membrane): is a thin, coneshaped membrane
Vibrates in response to sound waves & transmits sound to
middle ear.

51

THE EAR


Middle Ear: contains the ossicles (hammer, anvil & stirrup)
vibrate at the frequency of the sound wave
sound middle ear  to the inner ear



Inner ear: sound detection & balance.
cochlea, & vestibular system.
Cochlea; vibration  neural activity
sound pressure  electrochemical impulses  brain
(auditory nerve)
Organ of Corti & Basilar Membrane.






53

54

THE EAR


Organ of Corti & Basilar Membrane



Organ of Corti; transduction of sound vibration pressure
electrochemical impulses  brain via the auditory nerve.





o

Basilar Membrane: hair cells or auditory sensory cells.
respond to fluid-borne vibrations
btw. 15,000-20,000 auditory nerve receptors.

Different tones  different areas of the basilar membrane
&auditory cortex

PITCH PERCEPTION
o

The primary auditory cortex  different tones in different
places (info. from different part of basilar membrane

PITCH PERCEPTION
o

o
o

o

o

Different tones  different areas of the basilar membrane
&auditory cortex
Place theory
Hair cells  base of basilar membrane (high-pitched tones).
Hair cells  the top of the basilar membran (low-pitched tones)
auditory nerve  to thalamus;  to auditory cortex

Vestibular system: balance & movement & spatial
orientation (Semicircular canals) .

https://www.youtube.com/watch?v=PeTriGTENoc

59

WHEN WE CAN’T HEAR
o About 1 in 1000 people are deaf & many others suffer from hard
of hearing.
o Deafness may result from;
o Malfunctioning of ear (eardrum or ossicles)
o Damage to auditory nerve & auditory cortex
o Exposure to lound sounds for a long time (hair cells in the organ of
corti is damaged)

SMELL AND TASTE
o

Olfaction (smell) & gustation (taste): work hand in hand.
(liking/disliking of some foods)

.
o

chemical senses

o

Smell  odors;

o

Animals  tracking preys, establishing territories & recognizing the
opposite sexs.

o

Function of smell & taste  sample our food before
swallowing it (survival!)

taste  flavors

ODORS AND FLAVORS
o

Odors  airborne chemicals (odorant chemicals) int. with
olfactory neurons w/ sense receptors in our nasal passages.



Our nose  2000-4000 different odors



Few tastes;
 Sweet, salty, sour, bitter, umami (meaty)



Each olfactory neuron contains  a single type of receptor,
(odorant shape, lock & key)



(450 types)

Transduction
Odorants  olfactory receptors  action potentials

SMELL AND TASTE SENSE RECEPTORS

64

ODORS AND FLAVORS


Odors  sense receptors  olfactory bulb  limbic
system (hypothalamus, amygdala, hippocampus) &
olfactory cortex (temporal lobe)  orbitafrontal cortex

66

ODORS AND FLAVORS


Odors  sense receptors  olfactory bulb  limbic
system (hypothalamus, amygdala, hippocampus) &
olfactory cortex (temporal)  orbitafrontal cortex

SMELL AND TASTE
o

o

Humans detect taste with taste buds, the bumps on the tongue
called papillae.
Papillae  numerous taste buds. Taste buds specific to



Sweet
Bitter

Sour
Salty

Umami

ODORS AND FLAVORS
o

o

o

Chemicals bind to taste buds (gustotary cells)
(transduction!)
Taste buds  cranial nerves  thalamus  gustatory
cortex  orbitafrontal cortex (smell & taste converge)
Also  limbic system (amygdala, hypothalamus &
hippocampus) & somatosensory cortex

70

OLFACTORY AND GUSTATORY PERCEPTION
o

Babies →mother’s odor &
siblings → each other on the
basis of odor.

o

Women can tell whether
people just watched a happy
or sad movie from samples of
armpit odor.

o

Supertasters; people
oversensitive to certain tastes
(abundance of taste buds).
http://www.youtube.com/watch?v=8pCSVtwAZpE
http://www.youtube.com/watch?v=WavjbJhiRAE

OUR BODY SENSES
o

Three body systems that work in tandem;


Somatosensory (touch, temperature and pain)



Proprioception (kinesthetic sense); body position sense.



Vestibular sense (equilibrium and balance)

SOMATOSENSORY SYSTEM
o

Somatosensory System: stimuli applied to skin
(pressure, light touch, temperature, & injury that produces pain)

o

o

specialized nerve endings (mechanoreceptors)  temperature,
pressure, light touch
free nerve endings  pain

Free nerve
ending

Light
touch

Skin
stretching

Deep
pressure

SOMATOSENSORY SYSTEM
o Pain → thermal; chemical or mechanical.
o People w/ red hair- more sensitive to pain
women > men

o Phantom limb: the sensation that an amputated or
missing limb is still attached to the body &feeling of pain
or discomfort in the missing limb.
1) Maladaptive changes in the primary somato-sensory cortex
after amputation (maladaptive plasticity)
2) Result of "junk" inputs from the peripheral nervous system

o Pain insensitivity

SOMATOSENSORY PATHWAYS

Somatic nerves carry info to spinal
cord
Connects in brain stem; Spinal
reflexes may be activated
Thalamus

Touch: somatosensory, motor cortex,
association cortex
o Emotions
are also
involved in
pain
perception.

OR
Pain: somatosensory cortex, limbic areas,
frontal cortex

77

BODY POSITION & BALANCE
o Proprioception; our kinesthetic sense, helps us keep track
of where we are and move efficiently
o Proprioceptors (muscles, skin & joints)
o The sense of the relative position of parts of the body &
strength of effort being employed in movement.
(even if our eyes are closed)

BODY POSITION & BALANCE
o

Proprioceptors  spinal cord  brain stem (reflexes) 
thalamus  motor cortex & somatosensory cortex
(parietal lobe)
cerebellum

BODY POSITION & BALANCE
o

Vestibular system: balance & movement & spatial
orientation

o

Semicircular canals  contain fluid & “sensors” that detect
rotational movement of the head.
Each semicircular canal  different movement: up/down/side-to side.

o

BODY POSITION & BALANCE

82

BODY POSITION & BALANCE
Vestibular system: Sensory hair cells  vestibular nerve  brain
o

Sensory hair cells  vestibular nerve  brain stem
(reflexes) & cerebellum (to catch our balance when falling)

o

Awareness occurs only balance is lost or experience dramatic
mismatches btw. visual input & vestibular inputs.
(dizziness & nausa)