Stereoscopic Vision
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Transcript of Stereoscopic Vision
![Page 1: Stereoscopic Vision](https://reader033.fdocuments.net/reader033/viewer/2022042615/55a71e581a28ab3f4a8b46f8/html5/thumbnails/1.jpg)
Stereoscopic Vision
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Humans are extremely good a judging the relative distances of objects and can very easily judge which objects are closer and which are further away.
This ability to perceive depth information within a visual scene is greatly improved by having two eyes that are spatially separated.
However, depth perception is not solely a binocular phenomenon there are a number of monocular cues that can also give information about depth:
1.Motion Parallax2.Relative size of known objects3.Light and shade4.Geometric Perspective5.Surface texture6.Overlapping contours
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Perspective
Overlapping Contours
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Relative size of known objects
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Texture
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Binocular Depth Cues & Stereopsis
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F
F F
Uncrossed retinal disparity
Crossed retinal disparity
Corresponding points
Retinal Disparity
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In a binocular subject the eyes are separated horizontally and hence receive slightly different views of objects at different distances.
The disparity information combined with information derived from the vergence system provides precise quantitative information about object distance.
The perception of depth that is produced by binocular retinal disparity is called STEREOPSIS.
Stereopsis is important for producing finely tuned depth perception at near distances (particularly within arms length) when other depth cues are absent.
Stereopsis is specified as an angle at the eye (unit = min arc or sec arc)
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The Vieth-Müller Circle
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F
Left Eye Right Eye
fl fr
αP
P
p1pr
θ l θ r
ClCr
Vieth-Müller Circle
αF
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αP
The point P, unlike point F, is not fixated but lies on the V-M circle.
Rays from this point strike the retina at points pl & pr.
The convergence angle of this point = αP
since it lies on the circumference of the V-M circle :
αP=αF,
Since Cl & Cr fall on the same
circle the angles θ l & θ r are equal.
Therefore the displacements pl &
pr are equal and are
corresponding points.
F
P
Left Eye Right Eye
flfr
p1pr
θ lθ r
Cl Cr
Vieth-Müller Circle
αF
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Panum’s Fusional Areas
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Binocular disparity produces stereopsis only if the retinal disparity is not too great.
If retinal disparity does not exceed a certain limit, then retinal images are fused with the resultant perception of depth – stereopsis.
The area on the retina that corresponds to this area of binocular fusion is referred to as Panum’s Fusional Area.
If retinal disparity is too great, binocular fusion does not occur. The images fall on retinal positions that signal very different positions and results in physiological diplopia.
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F
F FCorresponding points
Retinal Disparity
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F F
Horopter
Panum’s Fusional Area
Diplopia
DiplopiaDiplopia
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The Vieth-Müller Circle describes in very geometrical terms how stereopsis might come about.
A more physiologically based concept for describing stereopsis is the HOROPTER.
The horopter can be simply described as the locus of all points in the binocular field that are seen as single.
As shown in the previous slide diagram below it can be thought of as a curved line that passes through the fixation point that plots corresponding points.
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F F
Horopter
Panum’s Fusional Area Diplopia
DiplopiaDiplopia
Objects that fall close to the horopter are also fused.
For these stimuli the retinal disparity falls within Panum’s Fusional Area and the result is stereopsis.
For those objects located at greater distances from the horopter the disparity is too great for the images to be fused and the result is physiological diplopia.
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The Neurophysiological Basis of Stereopsis
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The Physiological Basis of Stereopsis
There is evidence that stereopsis is coded by neurons in the primary visual cortex (V1).
Up to this point in the visual pathway information from each eye is largely segregated.
LGN
Layers 2, 3, 5 ipsilateral
Layers 1, 4 6 contralateral
12 & 3
4A4B4C{5A5B6
αβ
V1
MAGNO (1 & 2)
12
3 4 5 6
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Certain cells in V1 however receive inputs from two eyes and are known as binocular neurons.
The pioneering work on the binocularity of cells in the brain was carried out by Hubel & Wiesel in the 1960s.
They found that approximately 80% of the neurons in the primary visual cortex of the cat were driven by both eyes.
In the monkey approximately 60% of neurons are binocular.
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0
10
20
30
40
50
60
1 2 3 4 5 6 7
Ocular Dominance
No
. o
f C
ell
s
Contralateral Equal Ipsilateral
Ocular dominance distribution of 233 cellsfrom the striate cortex of the cat. Each cellis assigned to an ocular dominance group 1-7according to the relative response weighting from the two eyes.
(Wiesel & Hubel 1963)
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Binocular neurons may act as disparity detectors and such cells are responsive to stimuli at a specific distance – a simple scheme as to how a binocular neuron might signal disparity is illustrated below: