Binocular system with asymmetric eyes

Jacek Turski

doi:10.1364/JOSAA.35.001180

Journal of the Optical Society of America A
Vol. 35,
Issue 7,
pp. 1180-1191
(2018)
•https://doi.org/10.1364/JOSAA.35.001180

Binocular system with asymmetric eyes

Jacek Turski

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
Jacek Turski, "Binocular system with asymmetric eyes," J. Opt. Soc. Am. A 35, 1180-1191 (2018)

Export Citation
- BibTex
- Endnote (RIS)
- HTML
- Plain Text
Citation alert
Save article
Editors' Pick

Check for updates

Abstract

I elaborate binocular geometry with a novel eye model that incorporates the fovea’s temporalward displacement and the cornea and the lens’ misalignment. The formulated binocular correspondence results in longitudinal horopters that are conic sections resembling empirical horopters. When the eye model’s asymmetry parameters’ range is that which is observed in healthy eyes, abathic distance also falls within its experimentally observed range. This range in abathic distance is similar to that of the vergence resting position distance. Further, the conic’s orientation is specified by the eyes’ version angle, integrating binocular geometry with eye movement. This integration presents the possibility for modeling 3D perceptual stability during physiological eye movements.

Full Article | PDF Article

Corrections

Jacek Turski, "Binocular system with asymmetric eyes: erratum," J. Opt. Soc. Am. A 36, 1161-1161 (2019)
https://opg.optica.org/josaa/abstract.cfm?uri=josaa-36-7-1161

More Like This

Cyclopean geometry of binocular vision

Miles Hansard and Radu Horaud
J. Opt. Soc. Am. A 25(9) 2357-2369 (2008)

Functional division of the retina and binocular correspondence

Lei Liu and Clifton M. Schor
J. Opt. Soc. Am. A 15(7) 1740-1755 (1998)

Analysis of Eye Movements during Monocular and Binocular Fixation*

John Krauskopf, T. N. Cornsweet, and L. A. Riggs
J. Opt. Soc. Am. 50(6) 572-578 (1960)

Previous Article Next Article

Cited By

You do not have subscription access to this journal. Cited by links are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Figures (10)

You do not have subscription access to this journal. Figure files are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Tables (2)

You do not have subscription access to this journal. Article tables are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Equations (46)

You do not have subscription access to this journal. Equations are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

$F^{1} : ϕ_{l} = 10 °$ , $ϕ_{r} = 9 °$	$F^{2} : ϕ_{l} = - 15 °$ , $ϕ_{r} = - 13 °$
Horopter Points
$F^{1} (- 22.028, 131.552)$	$F^{2} (15.358, 61.434)$
$P_{1}^{1} (- 27.319, 129.821)$	$P_{1}^{2} (12.931, 62.623)$
$Q_{1}^{1} (- 16.688, 133.458)$	$Q_{1}^{2} (17.708, 60.141)$
$P_{2}^{1} (- 37.836, 126.863)$	$P_{2}^{2} (7.919, 64.936)$
$Q_{2}^{1} (- 5.784, 137.828$	$Q_{2}^{2} (22.164, 57.395)$
$P_{3}^{1} (- 48.396, 124.550)$	$P_{3}^{2} (2.7280, 66.919)$
$Q_{3}^{1} (5.5630, 143.009)$	$Q_{3}^{2} (26.244, 54.469)$
$P_{4}^{1} (- 115.781, 123.674)$	$P_{4}^{2} (- 25.598, 72.291)$
$Q_{4}^{1} (86.374, 192.830)$	$Q_{4}^{2} (40.601, 37.244)$
Nodal Points
$N_{l}^{1} (- 3.388, 0.584)$	$N_{l}^{2} (- 3.128, 0.588)$
$N_{r}^{1} (3.190, 0.597)$	$N_{r}^{2} (3.418, 0.576)$

$F^{3} : ϕ_{l} = ϕ_{r} = 9.5 °$	$F^{4} : ϕ_{l} = ϕ_{r} = - 14 °$
Horopter Points
$F^{3} (16.236, 96.916)$	$F^{4} (23.419, 93.821)$
$P_{1}^{3} (- 27.713, 92.943)$	$P_{1}^{4} (12.101, 99.702)$
$Q_{1}^{3} (- 4.259, 100.973)$	$Q_{1}^{4} (34.016, 88.121)$
$P_{2}^{3} (- 35.086, 90.340)$	$P_{2}^{4} (4.156, 103.722)$
$Q_{2}^{3} (4.003, 103.724)$	$Q_{2}^{4} (40.680, 84.420)$

$F^{1} : ϕ_{l} = 10 °$ , $ϕ_{r} = 9 °$	$F^{2} : ϕ_{l} = - 15 °$ , $ϕ_{r} = - 13 °$
Horopter Points
$F^{1} (- 22.028, 131.552)$	$F^{2} (15.358, 61.434)$
$P_{1}^{1} (- 27.319, 129.821)$	$P_{1}^{2} (12.931, 62.623)$
$Q_{1}^{1} (- 16.688, 133.458)$	$Q_{1}^{2} (17.708, 60.141)$
$P_{2}^{1} (- 37.836, 126.863)$	$P_{2}^{2} (7.919, 64.936)$
$Q_{2}^{1} (- 5.784, 137.828$	$Q_{2}^{2} (22.164, 57.395)$
$P_{3}^{1} (- 48.396, 124.550)$	$P_{3}^{2} (2.7280, 66.919)$
$Q_{3}^{1} (5.5630, 143.009)$	$Q_{3}^{2} (26.244, 54.469)$
$P_{4}^{1} (- 115.781, 123.674)$	$P_{4}^{2} (- 25.598, 72.291)$
$Q_{4}^{1} (86.374, 192.830)$	$Q_{4}^{2} (40.601, 37.244)$
Nodal Points
$N_{l}^{1} (- 3.388, 0.584)$	$N_{l}^{2} (- 3.128, 0.588)$
$N_{r}^{1} (3.190, 0.597)$	$N_{r}^{2} (3.418, 0.576)$

$F^{3} : ϕ_{l} = ϕ_{r} = 9.5 °$	$F^{4} : ϕ_{l} = ϕ_{r} = - 14 °$
Horopter Points
$F^{3} (16.236, 96.916)$	$F^{4} (23.419, 93.821)$
$P_{1}^{3} (- 27.713, 92.943)$	$P_{1}^{4} (12.101, 99.702)$
$Q_{1}^{3} (- 4.259, 100.973)$	$Q_{1}^{4} (34.016, 88.121)$
$P_{2}^{3} (- 35.086, 90.340)$	$P_{2}^{4} (4.156, 103.722)$
$Q_{2}^{3} (4.003, 103.724)$	$Q_{2}^{4} (40.680, 84.420)$

Abstract

Corrections

Cited By

Figures (10)

Tables (2)

Equations (46)

Journal of the Optical Society of America A