Disparity, Convergence, and Depth (Visual Depth Perception 10)
Disparity, Convergence, and Depth (Visual Depth Perception 10)
This Demonstration shows binocular disparity together with the convergence angle required for the eyes to fix on F. The angles and together determine the depth of objects on the axis.
δ
κ
y
Details
Details
Binocular disparity has been studied since Euclid, but was popularized by Wheatstone about 150 years ago with the invention of the stereoscope. A stereoscope shows two slightly different images to the separate eyes and gives the scene the appearance of depth. However, disparity alone does not determine depth, as shown in the Demonstration "Binocular Disparity versus Depth (Visual Depth Perception 9)" (see Related Links). To simplify derivations for this Demonstration we take no aim offset and set the nodePercent equal to zero, that is, nodes are (unrealistically) at the center of the eye.
The exact formula for depth when the fixate and distraction are on the axis (including sign) from (in radians) for a given fixate distance is given by the following formula with interocular distance :
y
B.D.=δ
f
i
d=ftan(δ/2)
4+
2
i
f
2-2tan(δ/2)
i
f
Binocular disparity does not determine depth since it requires the absolute fixate distance . The value of could come from a convergence cue since the convergence angle of the eyes is related to fixate distance by
f
f
κ
f=
i
2tan(κ/2)
so (after simplification) depth from static cues is
d=
i
2
sin
δ
2
sinsin
κ
2
κ-δ
2
External Links
External Links
Permanent Citation
Permanent Citation
Keith Stroyan
"Disparity, Convergence, and Depth (Visual Depth Perception 10)"
http://demonstrations.wolfram.com/DisparityConvergenceAndDepthVisualDepthPerception10/
Wolfram Demonstrations Project
Published: March 7, 2011