Title: Chapter 4: Sensation and Perception
1Chapter 4 Sensation and Perception
2What are they?
- Sensation
- Process in which the sense organs receptor cells
are stimulated and relay initial information to
the brain for further processing - Sensation requires transduction which is the
change of physical energy to neural energy - Perception
- Process by which organism selects and interprets
sensory input so that it acquires meaning (Do
something about it) - How do you study it?
- Bottom Up Stimuli to concept
- Top Down Concept to stimuli
3The Perceptual Process
The steps in this process are arranged in a
circle to emphasize the fact that the process is
dynamic and continually changing. Blue arrows
point to stimuli green to processing red to
perceptual responses. Arrows A, B, and C
indicate three important relationships that
researchers measure.
4The Senses
- Vision
- Hearing
- Touch
- Taste
- Smell
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7Vision The Stimulus
- Light electromagnetic radiation
- Amplitude perception of brightness
- Wavelength perception of color
- Purity mix of wavelengths
- perception of saturation, or richness of colors.
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9The EyeA Living Optical Instrument
- The eye housing and channeling
- Components
- Cornea where light enters the eye
- Lens focuses the light rays on the retina
- Iris colored ring of muscle, constricts or
dilates via amount of light - Pupil regulates amount of light
10The Retina The Brains Envoy in the Eye
- Retina absorbs light, processes images
- Optic disk optic nerve connection/blind spot
- Receptor cells
- Rods black and white/low light vision
- Cones color and daylight vision
- Adaptation becoming more or less sensitive to
light as needed
11Retinal Processing
- Differences between rods and cones
- Shape
- Rods - large and cylindrical
- Cones - small and tapered
- Distribution on retina
- Fovea consists solely of cones
- Peripheral retina has both rods and cones
- More rods than cones in periphery
12Figure 4.4 The retina
13Figure 4.6 Receptive fields in the retina
14Adaptation
- Progressive loss of response when stimulation is
maintained - Form of information suppression that prevents the
nervous system from becoming overwhelmed by
stimuli that offer very little news about the
world.
15Vision and the Brain
- Light ? rods and cones ? neural signals ? optic
nerve ? optic chiasm ? opposite half brain - dorsal where
- ventral what
16Figure 4.7 Visual pathways through the brain
17Figure 4.9 The what and where pathways from the
primary visual cortex
18Information Processing in the Visual Cortex
- Early 1960s Hubel and Wiesel
- Microelectrode recording of axons in primary
visual cortex of animals - Discovered feature detectors neurons that
respond selectively to lines, edges, etc. - Groundbreaking research Nobel Prize in 1981
- Later research cells specific to faces in the
temporal lobes of monkeys and humans
19Theories of Color Vision
- Trichromatic theory - Young and Helmholtz
- Receptors for red, green, blue color mixing
- Opponent Process theory Hering
- 3 pairs of antagonistic colors
- red/green, blue/yellow, black/white
- Current perspective both theories necessary
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22Perceiving Forms, Patterns, and Objects
- Reversible figures
- Perceptual sets
- Inattentional blindness
- Feature detection theory - bottom-up processing
- Form perception - top-down processing
- Gestalt psychologists the whole is more than
the sum of its parts - Reversible figures and perceptual sets
demonstrate that the same visual stimulus can
result in very different perceptions - Video!
23Figure 4.16 Feature analysis in form perception
24Figure 4.17 Bottom-up versus top-down processing
25Principles of Perception
- Gestalt principles of form perception
- figure-ground
- Proximity
- closure
- similarity
- simplicity
- and continuity
26Figure 4.18 The principle of figure and ground
27Figure 4.21 A famous reversible figure
28Figure 4.22 The Necker cube
29Perceptual Constancies in Vision
- Perceptual constancies stable perceptions amid
changing stimuli - Size
- Shape
- Brightness
- Hue
- Location in space
30Pictorial Cues and Depth Perception
- Or - figuring out where things are in space
31- A scene in Tucson, Arizona containing a number of
depth cues occlusion (the cactus occludes the
hill, which occludes the mountain) perspective
convergence (the sides of the road converge in
the distance) relative size (the far motorcycle
is smaller than the near one) and relative
height (the far motorcycle is higher in the field
of view the far cloud is lower).
32- Atmospheric perspective - distance objects are
fuzzy and have a blue tint
- A scene along the coast of California that
illustrates atmospheric perspective.
33- Figure 8.6 A texture gradient in Death Valley,
California.
- Texture gradient - elements are more closely
packed as distance increases
34Shadows - indicate where objects are located
- (a) Occlusion indicates that the tapered glass is
in front of the round glass and vase. (b)
Overlap now indicates that the vase is in front
of the tapered glass, but there is something
strange about this picture. (c) The cast shadow
under the vase provides additional information
about its position in space, which helps clear up
the confusion.
35The Power of Misleading CuesVisual Illusions
- Optical Illusions - discrepancy between visual
appearance and physical reality - Famous optical illusions Muller-Lyer Illusion
and Impossible Figures
36Figure 4.28 The Muller-Lyer illusion
37Figure 4.29 Explaining the Muller-Lyer Illusion
38Figure 4.32 Three classic impossible figures
39Hearing The Auditory System
- Stimulus sound waves (vibrations of molecules
traveling in air) - Amplitude (loudness)
- Wavelength (pitch)
- Purity (timbre)
- Wavelength described in terms of frequency
measured in cycles per second (Hz) - Frequency increase pitch increase
40Sensory Processing in the Ear
- External ear (pinna) collects sound
- Middle ear the ossicles (hammer, anvil, stirrup)
- Inner ear the cochlea
- a fluid-filled, coiled tunnel
- contains the hair cells which are auditory
receptors - lined up on the basilar membrane
Figure 4.35 The human ear
41Figure 4.36 The basilar membrane
42How do we hear?
1. The pinna (outer ear) catches sound waves 2.
Sound waves are amplified and transduced from
air pressure into mechanical energy by
cochlea 4. The vibration causes the
basilar membrane to move and subsequently causes
the cilia of the outer hair cells to bend
converting mechanical energy into neural energy
43Theories of Hearing Place or Frequency?
- Hermann von Helmholtz (1863)
- Place theory where on the basilar membrane
- Other researchers (Rutherford, 1886)
- Frequency theory how quickly the basilar
membrane vibrates - Georg von Bekesy (1947)
- Traveling wave theory
44The Chemical Senses Taste
- Taste (gustation)
- Physical stimulus soluble chemical substances
- Receptor cells found in taste buds
- Pathway taste buds - neural impulse - thalamus
- cortex - Four primary tastes sweet, sour, bitter, and
salty
The tongue is most sensitive to these basic
tastes in certain regions
45The Chemical Senses Smell
- Smell (Olfaction)
- Physical stimuli substances carried in the air
- dissolved in fluid, the mucus in the nose
- Olfactory receptors olfactory cilia
- Pathway Olfactory cilia - neural impulse -
olfactory nerve - olfactory bulb (brain) - Does not go through thalamus
46Sensory HomunculusLatin for "little man"
47Skin Senses Touch
- Physical stimuli mechanical and thermal energy
impinging on the skin. - Receptive fields
- Pain receptors free nerve endings in skin
- Two pain pathways fast vs. slow
- Gate-control theory
48Slow Throbbing
Fast Sharp
Figure 4.40 Pathways for pain signals