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cue approach to depth perception

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Figure 8.16 The two images of a stereoscopic photograph. ... D movies are filmed with a stereoscopic camera that records video much like how ... – PowerPoint PPT presentation

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Title: cue approach to depth perception


1
Chapter 8
  • ?????

2
?????????(cue approach to depth perception)
  • ??????(proximal stimulus)???????(distal
    stimulus)???????(cues ),???????????????????????,??
    ??????

3
??????(Oculomotor cues)
  • ?????????????????????,????????
  • ??????(????)
  • Convergence
  • ??????,???????
  • ????convergence ??,????????
  • ????

4
  • Accommodation
  • ???????,????????????
  • ?????,??????
  • ????

5
Albertis window
6
???? (monocular cues)
  • ????(pictorial cues)
  • Albertis window

7
  • ??(occlusion)
  • ????????
  • ??????
  • ????
  • ???????????
  • ??,??????????,?????????

8
Fig. 8-3, p. 170
9
  • ????
  • ????? (demo-monster)
  • ????(perspective convergence)
  • ?????

10
  • ?????
  • ??????????
  • ???????????

11
  • ????(atmosphere perspective)
  • ???????

12
Fig. 8-5, p. 171
13
  • ????
  • ????

14
  • ??
  • ??????????????????

???????????????
15
  • ????(movement-produced cues)
  • ?????????????(??)

16
  • ????(motion parallax)
  • ???????,???????link
  • ????????,??????????????????,??????????

17
  • Deletion accretion

18
Fig. 8-10a, p. 173
19
Fig. 8-10b, p. 173
20
  • Table 8.1 Range of effectiveness of different
    depth cues

21
??????
  • ????(Binocular disparity)
  • ????????

22
  • Figure 8.11 Location of images on the retina for
    the Two Eyes Two Viewpoints demonstration.
    (a) Both images are on the fovea when the left
    eye is open. (b) The images are on different
    places on the retina when the right eye is open.

23
  • ???(stereopsis)
  • ???(corresponding retinal points)
  • ???????????????

24
  • horopter
  • ???????,?????,???????????????????
  • Figure 8.13 (a) When the lifeguard looks at
    Frieda, the image of Frieda, Susan, and Harry
    fall on corresponding points on the lifeguards
    retinas, and the images of the other swimmers
    fall on noncorresponding points. (b) The
    locations of the images of Susan, Frieda, and
    Harry on the lifeguards retina.

25
  • ??horopter????,????????????(noncorresponding
    points),??????(angle of disparity)
  • C?X???
  • ?horopter??,?????
  • L?Y???

26
  • ?????(crossed disparity) ?? horopter????????????,
    ?????horopter?
  • ??????(uncrossed disparity)?? horopter???????????
    ??(????????) ,?????horopter?

27
  • Stereoscope (1800s)

28
  • Figure 8.16 The two images of a stereoscopic
    photograph. The difference between the two
    images, such as the distances between the front
    cactus and the window in the two views, creates
    retinal disparity. This creates a perception of
    depth when (a) the left image is viewed by the
    left eye and (b) the right image is viewed by the
    right eye.

29
Fig. 8-18, p. 176
30
  • 3-D movies
  • A polarized filter allows only light travelling
    in one position to pass through. It is made of
    parallel micro-sized slits that block out all but
    one position of wave.
  • A wave in the vertical planepasses through a
    verticalpolarized filter.A wave in the
    horizontal planepasses through a
    horizontalpolarized filter, but would not
    beable to pass through a verticalpolarized
    filter.

31
  • There are two types of filters in 3-D glasses
    (i.e. vertical and horizontal). So, one side
    allows only light travelling in one position to
    pass through while the other side allows light of
    the opposite position to pass.
  • 3-D movies are filmed with a stereoscopic camera
    that records video much like how the Pathfinder
    IMP above records images. When a 3-D movie is
    played, two projectors are used to display both
    perceptions. Each projects a video polarized
    (with a filter) onto the screen. Wearing the 3-D
    glasses, each eye can only take in light from one
    of the projectors. Therefore, each eye receives a
    different image. Your brain interprets these two
    separate images and combines them into one 3-D
    picture.
  • Next time you view a 3-D movie, take two set of
    glasses. Place the right-eye filter and place it
    over the left-eye filter. It's dark. That because
    the vertical and horizontal filters are combined
    and no light can enter. They cancel each other.

32
  • ????

33
  • ????

34
Fig. 8-17, p. 176
35
Also see demo
36
  • ??????????
  • ??????(Random dot stereogram)(Julez, 1971)
  • ??????????

37
  • ???????match?--????(The correspondence problem)
  • ??????????
  • RDS ??

38
?????????
  • A neuron in the parietal cortex of a monkey
  • Figure 8.20 Top gradient stimuli. Bottom
    response of neurons in the parietal cortex to
    each gradient. This neuron fires to the pattern
    in (c), which the monkey perceives as slanting to
    the left. (From Tsutsui et al., 2002, 2005.)

39
  • ??????(Binocular depth cell)????????(disparity
    selective cell)
  • ??????????????
  • Figure 8.21 Disparity tuning curve for a
    disparity-sensitive neuron. This curve indicates
    the neural response that occurs when stimuli
    presented the left and right eyes create
    different amounts of disparity. (From Uka
    DeAngelis, 2003.)

40
  • ??????,????????????
  • ???(sensitive period)??????

41
???? (size perception)
  • ???????????

42
  • Figure 8.25 (a) The visual angle depends on the
    size of the stimulus (the woman in this example)
    and its distance from the observer. (b) When the
    woman moves closer to the observer, the visual
    angle and the size of the image on the retina
    increases. This example shows how halving the
    distance between the stimulus and observer
    doubles the size of the image on the retina.

43
(No Transcript)
44
  • Figure 8.26 The thumb method of determining the
    visual angle of an object. When the thumb is at
    arms length, whatever it covers has a visual
    angle of about 2 degrees. The womans thumb
    covers half the width of her iPod, so we can
    determine that the visual angle of the iPods
    total width is about 4 degrees.

45
Fig. 8-27, p. 182
46
  • Holway Boring (1941)
  • ???????????,????????????
  • ?????????(?????10ft?)???????????

47
  • 1-????????2-??3-?????4-???????
  • ?????????????,????????

?????????????
48
????? ??????????
  • ?????????????
  • ??????????????

?????
49
  • ?????(size constancy)
  • ??????,????????????
  • ???????????????-??????(size-distance scaling
    mechanism)
  • demo
  • SK(R x D)
  • S-????,K-??, R-??????,D-??

50
  • Emmerts law
  • Familiar size and texture gradient
    information????????????

51
Fig. 8-30, p. 183
52
Emmerts lawK(R x D) S
Fig. 8-31, p. 184
53
Fig. 8-32, p. 184
54
Fig. 8-33, p. 185
55
??
  • Muller-Lyer illusion
  • ??????????? SK(R x D)

56
  • ???????????????

57
  • ??????????????
  • ??????????

58
  • Ponzo illusion
  • ???????????

59
  • Ames room

60
Fig. 8-40, p. 187
61
  • Figure 8.41 The Ames room, showing its true
    shape. The woman on the left is actually almost
    twice as far away from the observer as the woman
    on the right however, when the room is viewed
    through the peephole, this difference in distance
    is not seen. In order for the room to look
    normal when viewed through the peephole, it is
    necessary to enlarge the left side of the room.

62
  • ????(Moon illusion)
  • ??????(apparent distance theory)
  • ??????????????,??????,??????????
  • ????????(angular size contrast theory)
  • ??????,??????,??????

63
2005/6/23
64
  • Figure 8.42 An artists conception of the moon
    illusion showing the moon on the horizon and high
    in the sky simultaneously.

65
  • Figure 8.43 When observers are asked to consider
    that the sky is a surface and are asked to
    compare the distance to the horizon (H) and the
    distance to the top of the sky on a clear
    moonless night, they usually say that the horizon
    appears farther away. This results in the
    flattened heavens shown above.

66
  • ????(apparent distance)??
  • ?????,??????
  • ??????
  • ????
  • ????
  • ??
  • ????

67
  • ?????????????????

68
  • ?????????????????
  • Figure 8.44 Results of Witt et al.s (2004)
    experiment. For each of the conditions, larger
    distance estimates were associated with greater
    effort.
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