Monocular vision explained

Monocular vision is vision using only one eye. It is seen in two distinct categories: either a species moves its eyes independently, or a species typically uses two eyes for vision, but is unable to use one due to circumstances such as injury.[1]

Monocular vision can occur in both humans and animals (such as hammerhead sharks). Humans can benefit from several monocular cues when using only one eye, such as motion parallax and perspective. There are also some mythological creatures with only one eye, such as the cyclops.

In human species

Monocular vision vision is known as seeing and using only one eye in the human species. Depth perception in monocular vision is reduced compared to binocular vision, but still is active primarily due to accommodation of the eye and motion parallax. The word monocular comes from the Greek root, mono for single, and the Latin root, oculus for eye.

Bimonocular vision, also named two-eyed monocular vision, is known as seeing and using both eyes in a monocular way independently of each other without fusion over the entire field of view without visual field loss in the human species and was discovered in 2018. The word monocular comes from the Greek root, mono for single, and the Latin root, oculus for eye.

In animals

The eyes of an animal with monocular vision are positioned on opposite sides of the animal's head, giving it the ability to see two objects at once. This is usually most commonly seen with prey animals, as the reason why their eyes are placed on either side of their head is to make it easier for them to look out for predators, which usually have forward-facing eyes to make it easier to find prey. However, there are some exceptions to this rule, usually if the predator is an animal that is often preyed upon by a greater predator (because of this, apex predators usually tend to have forward-facing eyes) or sport an anatomy that makes it very difficult for it to see straight, such as a short, stiff neck that would limit its head movement, and therefore would require its eyes to be on either side (this is often seen with marine predators such as sharks and killer whales).

Notably, hammerhead sharks have some binocular vision as well as some amount of monocular vision.

Related medical conditions

Monocular vision impairment refers to having no vision in one eye with adequate vision in the other.[2]

Monopsia is a medical condition in humans who cannot perceive depth even though their two eyes are medically normal, healthy, and spaced apart in a normal way. Vision that perceives three-dimensional depth requires more than parallax. In addition, the resolution of the two disparate images, though highly similar, must be simultaneous, subconscious, and complete. (After-images and "phantom" images are symptoms of incomplete visual resolution, even though the eyes themselves exhibit remarkable acuity.) A feature article in The New Yorker magazine published in early 2006 dealt with one individual in particular, who, learning to cope with her disability, eventually learned how to see three-dimensional depth in her daily life. Medical tests are available for determining monoptic conditions in humans.[3]

Monocular cues

Monocular cues provide depth information when viewing a scene with one eye.

Recent advances in computational machine learning now allow monocular depth for an entire scene to be algorithmically estimated from a single digital image by implicitly using one or more of these cues.[6] [7]

Balance

Vision has been known to play an important role in balance and postural control in humans, along with proprioception and vestibular function. Monocular vision affects how the brain perceives its surroundings by decreasing the available visual field, impairing peripheral vision on one side of the body, and compromising depth perception, all three of which are major contributors to the role of vision in balance.[8] [9] Studies comparing monocular vision to binocular (two eyes) vision in cataract patients (pre and post surgery),[10] glaucoma patients (compared with healthy age matched controls),[11] and in healthy adults and children (in both binocular and monocular conditions)[8] have all shown to negatively impact balance and postural control than when both eyes are available. Each of the studied populations still displayed better balance when having only one eye compared to having both eyes closed.

In popular culture

There are many examples of mythological creatures that have one eye, and thereby monocular vision.

A popular mythical beast with monocular vision is a cyclops.

External links

Notes and References

  1. Web site: 2019-10-07 . Monocular vision . 2023-09-22 . Biology Articles, Tutorials & Dictionary Online . en-US.
  2. Web site: Monocular Vision Impairment (MVI). www.guidedogsqld.com.au . https://web.archive.org/web/20061208095213/http://www.guidedogsqld.com.au/cgi-bin/index.cgi/monocular/mvi . December 8, 2006.
  3. Monocular individuals face increased challenges with driving. These specifically relate to depth perception and peripheral vision. Keeney, et al., state, "nationwide, monocularly impaired individuals have seven times more accidents than the general population with which they were compared." He recommends monocularly impaired drivers be denied class 1 licenses, (commercial driver license for transport of people), and that they be warned by their doctors regarding increased risk of accident with driving
  4. Ferris, S. H. (1972). Motion parallax and absolute distance. Journal of experimental psychology, 95(2), 258--63.
  5. O’Shea, R. P., Blackburn, S. G., & Ono, H. (1994). Contrast as a depth cue. Vision Research, 34, 1595-1604.
  6. Book: Godard, C., Mac Aodha, O., Brostow, G.J.. Unsupervised monocular depth estimation with left-right consistency. Proc. Computer Vision and Pattern Recognition. 2017. 2. 6. 7. http://openaccess.thecvf.com/content_cvpr_2017/papers/Godard_Unsupervised_Monocular_Depth_CVPR_2017_paper.pdf.
  7. Book: Atapour-Abarghouei, A., Breckon, T.P.. Real-Time Monocular Depth Estimation using Synthetic Data with Domain Adaptation. Proc. Computer Vision and Pattern Recognition. 2018. 1–8. IEEE. http://community.dur.ac.uk/toby.breckon/publications/papers/abarghouei18monocular.pdf. 9 August 2018.
  8. Berela, J. et al. (2011) Use of monocular and binocular visual cues for postural control in children. Journal of Vision. 11(12):10, 1-8
  9. Wade, M. and Jones, G. (1997) The role of vision and spatial orientation in the maintenance of posture. Physical Therapy. 77, 619-628
  10. Schwartz, S. et al. (2005) The effect of cataract surgery on postural control. Investigative Ophthalmology and Visual Science. 46(3), 920-924
  11. Shabana, N, et al. (2005) Postural Stability in primary open angle glaucoma. Clinical and Experimental Ophthalmology. 33, 264-273