1. Chapter 5: Spatial Vision & Form Perception
Detection
Discrimination
Identification
Objects & Forms
Light can vary by intensity, color, pattern.

2. Analysis of Form Titchener & Analytic Introspection
Campbell & Robson’s Analysis by Scale (a.k.a. the multi-channel model)

3. Gratings (Gabors)

5. Grating (Gabors)
Spatial Frequency
Contrast
Orientation
Spatial Phase

6. Orientation

7. Spatial Phase

8. Spatial Phase

9. An analogy between lens and vision
The Transfer function (the lens)
The context sensitivity function (vision)

10. Gratings and the Transfer Function

13. The transfer function vs. the contrast sensitivity function
In both cases, we can have gratings as targets.
In the eye, we don’t want the retinal image, but some perceptual fact. That is, we want both to analyze a perceptual function.
So, we go for contrast thresholds

15. Contrast thresholds
At some levels of contrast, humans can see a grating.
At other levels of contrast, humans cannot see a grating.
We want to plot the line that separates the two.

17. TF & CSF Both have a high end cut-off.
CSF has a low-end cut-off; TF does not.
CSF: There is a maximal spatial frequency for contrast sensitivity.

19. CSF and night vision
High spatial frequency fade first with decreasing light.
So, at night, people can see big things, but not small things.

20. How does this fit in with the “convergence trade-off?”

21. How does this fit in with the “convergence trade-off?”
What is the convergence trade off?
The lower the convergence, the greater the resolution.
The higher the convergence, the greater the light sensitivty.

22. We can understand why fine details disappear first
We can understand why fine details disappear first. The ability to see fine details is bought at the expense of light sensitivity.

23. The CSF is species specific
Different species have different CSFs.
CSFs have been measured in over a dozen different species.

31. Evidence for spatial frequency channels
Selective adaptation

33. Evidence for spatial frequency channels
Selective adaptation
People respond more quickly to low frequency information that to high frequency information.
In short presentations, only low-frequency information is perceived; high-frequency information is “blotchy.”

37. Metamers
Metamers are objects that are physically different, but are perceptually indistinguishable from each other.

38. Whether or not two objects are metamers depends on viewing conditions.
(See Figure 5.28 on p. 20).
For example,
Lighting
Distance

42. Form Defined by Contrast
Form Defined by Texture

46. Gestalt Principles
Proximity
Similarity
Closure
(Good) continuation

63. Gestalt principles interact
In the window, proximity indicates grouping of the face with the bars. Texture and luminance (similarity) indicate non-grouping.
Proximity promotes perceptual grouping.

65. Why do the Gestalt Principles work?
They embody cues that help identification in the natural world. So, they are fostered by natural selection.

66. Reinforcement between hypercolumns
Bill Geisler, et al., at University of Texas studied many natural scenes.
In short, similarity of orientation is proportional to separation.

67. In other words:
Adjacent segments of any single natural contour tend to have very similar orientations.
Distant segments of any single natural contour tend to have dissimilar orientations.

68. Perception of Symmetry (Sometimes Classified as a Gestalt Principle)
Faces are approximately bilaterally symmetric.
Human body is approximately bilaterally symmetric.
Symmetry is widely thought to contribute to attractiveness.

71. Rentsler, et al. People prefer more symmetry.
People prefer greater simplicity.
But, simplicity is a function of experience, where symmetry is not.