Binocular OverlapBinocular overlap refers to the visible overlapping portion between the two eyes of a stereoscopic vision system. In other words, it describes how much of the viewed scene can be seen by both eyes as opposed to by just one of the eyes.
Source: David Johnson, University of Utah
The visual field varies from person to person, but typically extends 60 inward (toward the nose) and 100 degrees outwards, and typically 60 degrees above and 75 below the horizontal meridian. As such, the binocular overlap region is 120 degrees horizontally (-60 to +60 degrees for each eye). Since each eye can see about 160 degrees, the binocular overlap is 120/160 = 75%.
Binocular overlap is particularly important for depth perception. When the brain sees an object with both eyes, the relative angles in which this object is visible gives an estimate of how far this object is located. If the object is far, far away, the angle in which it is seen by both eyes is practically the same. If the object is very close, the angles are much different.
Binocular overlap in goggles
|Independent images of the left and right eyepieces, each at 60 degree diagonal field of view|
|100% overlap, 60 degree binocular field of view|
|Partial (75%) overlap, 70 degree total diagonal field of view made of individual 60 degree eyepieces|
Advantages of partial overlap
- Wider field of view, and thus greater immersion. In the example above, we created an HMD with 70-degree field of view using 60-degree eyepieces.
- Improved aspect ratio. The aspect ratio of the eyepieces in our example was 4:3 = 1.333. The aspect ratio over using 75% overlap became 60:36, or 5:3 = 1.666. This aspect ratio is between the 16:9 HD1080 (1920x1080) standard and the 16:10 WUXGA (1920x1200) standard, making the result more suitable for viewing wide screen content, assuming the wide screen content is correctly divided between the two screens (more on that below).
Disadvantages of partial overlap
- Binocular rivalry. Consider the a green circle that is shown in the eyepieces. Because of the location of the circle, it will be fully shown in the left eyepiece but cut off in the right eyepiece. In fact, when a person looks through both eyepieces at the same time, that person might notice the leftmost border of the right eye and this might look unusual or distracting. The image in the binocular view continues more to the left, but the right eyepiece no longer shows the object. Some people may find this distracting because of binocular rivalry. Instead of seeing a summation of the two images, our perception switches from one image to the other. If the field of view is larger than in our example, say 100 degrees in each eye, this is less of a problem because the discontinuity of the image is outside the central vision area.
|Binocular rivalry caused by a partial-overlapping visual system|
- Compatibility challenges with non-3D content. One of the nice things in a fully-overlapped system is that you can view standard content - a computer desktop, Microsoft Word, a YouTube video or live video from a Web cam - without much effort. The same content is presented on both eyes. The application does not need to know that is is viewed in a goggle as opposed to a computer monitor In the case of partial-overlap, that is not the case. If the same exact image is presented in both eyes, eye strain will result because the eyes will try to merge the two images even though they are shown in different angles. In most cases, applications need to be aware that they are being viewed in a partial-overlap system. The exception is hardware that automatically splits a wide screen image into two left and right images (see the description of the zSight electronics below), but that is often not available.
What's the exact math?
Can you have it both ways (a bit promotional)?
|Left: zSight in full overlap mode; Right: zSight in partial-overlap mode|
Expert interviews and tutorials can also be found on the Sensics Insight page here