Lines and Shapes-from-shadows Juan Bai Purpose: Where do lines fail in vision? What is its...
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Transcript of Lines and Shapes-from-shadows Juan Bai Purpose: Where do lines fail in vision? What is its...
Lines and Shapes-from-shadows
Juan Bai
Purpose: Where do lines fail in vision? What is its implication for the function of lines in
touch?
2
We see objects by means of their surfaces, and source of illumination.
Lines and Surfaces
We touch objects by means of their surfaces, i.e., no brightness information is involved.
For example, touch can often accurately discern this line drawing as depicting a cup.
3Lines, Surfaces, and ShadowsLines copying surface edges give us surface edge impressions (e.g., roof, hill, etc. in the image below).
However, lines copying shadow borders do not give us the impression of the darkness of shadow (e.g., the shadow on the ground; from Kennedy, 1993).
shadow border
surface borders
4
Contour = reflectance/emission change on a surface. A line has two contours, one on each side.
Contour, Line, and Outline
Lines copying surface edges can be called ‘outlines.’
shadow border
surface borders
The image below shows that outlines cannot show shadows (Kennedy, 1993).
5Hering’s ‘Outlined’ Shadow
Hering (1874) might contend that for the cup’s cast shadow in (a), shadow perception fails in (b) because the penumbra is lost to the dark line (after Goldstein, 2002).
a b
umbra
penumbrapenumbra
umbra
6Outlined Sharp-contoured
Shadow
But shadows without penumbras (a, adapted from Mooney, 1957) convey information about a girl’s face, and dark lines in (b) impair percept of the same face.
a b
Note that shadowed areas in (b) are darker than illuminated areas (Cavanagh & Leclerc, 1989), yet shape-from-shadow perception is diminished.
7Shape-from-Shadow: Figure-
Ground?Here is another shape-from-shadowed face (adapted from Mooney, 1957), shown with a color image.
8Lines, Contours, and Kinds of
BordersHere are different kinds of figure-ground segregations along borders (Kennedy, Juricevic, & Bai, 2003):
figure-figure along a line
figure-figure along a contour figure-ground along a contour
ground-figure-ground along a line
figure-ground-figure along a line
9
c
Theory of Dark Lines and Shadows
Line version (a), negative (c), and Hering-dark-line version (d) all have negative contours (light-to-dark from shadow to non-shadow), and all three fail to show the face in (b).
So it may be the dark line’s negative contour bordering the shadow in (d) that diminishes shape-from-shadow perception – a ‘border-polarity’ hypothesis.
dba
10
Alternatively, dark lines in (a) and (b) may impair shape-from-shadow perception because a line has two contours rather than one (c) – a ‘number-of-contours’ account.
Alternative Theory
a b c
The number-of-contours account is based on an ‘axis’ theory of a line (Kennedy, 1993).
11
a b c
Kennedy & Bai (2000): Polarity vs. Number-of-contours
Border-polarity predicts the face in (a) should be easy to see, but number-of-contours predicts otherwise.Results = (a) and (c) were equally easy, only (b) difficult, supporting border-polarity.
12
An arm-and-hand is relatively easy to see in gray-line version (a) but not in black-line version (b). It is evident in no-line version (c). So only dark line fails.
Demonstrations for K & B (2000)
arm-and-hand (adapted from Kennedy, 1988)
a b c
13
figure
ground
Kennedy & Bai (2004): Testing Belongingness
wire or
crack
ground
figure
ba c
A ‘belongingness’ hypothesis may propose that a dark-to-light shadow border has to belong to both the shadowed and the illuminated areas to allow perception of a continuous face bearing the shadow.
The purpose of K & B (2004) is to test this hypothesis.
14
Result = the dot-grating figure showed the face, possibly because on average the border polarity is positive, despite negative polarity along the final dots.
K & B (2004)’s Dotted Shadow for Belongingness Test
final dots
15
When two areas share a common border, it is said that the common border belongs to the closer area – the figure; it does not belong to the area that is farther away – the ground (e.g., Nakayama et al., 1989).
If so, when stereo depth indicates that the bordering elements belong only to a closer, shadow area or a closer, non-shadow area, the inappropriate belongingness should impair shape-from-shadow perception.
Rationale for K & B (2004) Stereo Test
16Stereo Stimuli
Only right eye sees
smaller dots
unpaired dotsmost shadow
17
Only left eye sees smaller dots
unpaired dotsmost shadow
Stereo Stimuli (Continued)
18
Both eyes see smaller dots
at the shadow border
binocular percept
same stereo depth
Stereo Stimuli (Control)
19
Results = in binocular percept, positive images showed the face in shadow, even when stereo depth signaled different belongingness of the border.
The results rejected predictions from belongingness, but supported border-polarity.
Negatives did not show the face.
Stereo Stimuli (Negative Control)
20ConclusionsA Hering line added along a shadow border may have impaired shape-from-shadow perception because of negative polarity of its contour bordering the shadow.
There are 8 kinds of borders in a visual display that can cause perception of surfaces. These include luminance/spectral, monocular/binocular, and static/moving borders (Kennedy et al., 2003). Among these 8 combinations, only luminance matters for shape-from-shadow: From shadow to non-shadow the border has to be from darker to lighter to allow perception of shapes from shadows.