Difference between revisions of "Stereo Vision"
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*Set stereo display to SideBySide (VMD Main → Display → Stereo → SideBySide) | *Set stereo display to SideBySide (VMD Main → Display → Stereo → SideBySide) | ||
*Resize the window, until two equivalent points on the protein are the same distance on the screen, as your eyes are apart (this is usually about 6 cm). Don't just guess, measure, and get this right to within better than half a centimetre. | *Resize the window, until two equivalent points on the protein are the same distance on the screen, as your eyes are apart (this is usually about 6 cm). Don't just guess, measure, and get this right to within better than half a centimetre. | ||
− | *Touch your nose to the screen and look right at the two images. Make sure you see the right image with your right eye, the left with your left eye. Of course, since you are so close, the images will be blurred and out of focus. Nevertheless, you should see one solid, three dimensional shape in the centre, two peripheral images of the same on the sides. <small>Thus you actually see three copies of the same scene, but only the fused, centre scene appears three-dimensional; the other two become less noticeable as you practice more, your brain simply begins editing them out.</small> Slowly rotating the protein helps | + | *Touch your nose to the screen and look right at the two images. Make sure you see the right image with your right eye, the left with your left eye. Of course, since you are so close, the images will be blurred and out of focus. Nevertheless, you should see one solid, three dimensional shape in the centre, two peripheral images of the same on the sides. <small>Thus you actually see three copies of the same scene, but only the fused, centre scene appears three-dimensional; the other two become less noticeable as you practice more, your brain simply begins editing them out.</small> Slowly rotating the protein helps generate the impression of a 3-D object floating before you. |
*Once you see the object in 3-D, try to move your head backwards slowly, until the structure comes into focus by itself. Do not voluntarily try to focus, since this will induce your eyes to converge and you will lose the 3-D effect. After a short while, you will probably lose the 3-D effect. Once you lose the 3-D effect, pause, look somewhere else and start over. | *Once you see the object in 3-D, try to move your head backwards slowly, until the structure comes into focus by itself. Do not voluntarily try to focus, since this will induce your eyes to converge and you will lose the 3-D effect. After a short while, you will probably lose the 3-D effect. Once you lose the 3-D effect, pause, look somewhere else and start over. | ||
*Practice this patiently, two times daily for some 3 to 5 minutes. Stop, when your head feels funny. Don't force yourself. | *Practice this patiently, two times daily for some 3 to 5 minutes. Stop, when your head feels funny. Don't force yourself. |
Revision as of 04:38, 14 September 2007
Contents
Introduction
Being able to visualize and experience strucutre in 3-D is an essential skill, if you are at all serious about understanding the molecules of molecular biology.
Even though hardware devices exist that help in the three-dimensional perception of computer graphics images, for the serious structural biologist there is really no alternative to being able to fuse stereo pair images by looking at them. VMD is an excellent tool to practice stereo vision and develop the skill. Stereo images consist of a left-eye and a right-eye view of the same object, with a slight rotation around the vertical axis (about 5 degrees). Your brain can accurately calculate depth from these two images, if they are presented to the right and left eye separately. This means you need to look at the two images and then fuse them into a single image - this happens when the left eye looks directly at the left image and the right eye at the right image.
Some people find convergent (cross-eyed) stereo viewing easier to learn. I recommend the divergent (wall-eyed) viewing - not only because it is much more comfortable in my experience, but also because it is the default way in which stereo images in books and manuscripts are presented. The method explained below will only work for learning to view divergent stero pairs.
Physiology
In order to visually fuse stereo image pairs, you need to override a vision reflex that couples divergence and focussing, this is something that needs to be practiced for a while. Usually 5 to 10 minutes of practice twice daily for a week should be quite sufficient. It is not as hard as learning to ride a bicycle, but you need to practice regularily for some time, maybe 10 or 20 sessions of 3 to 5 minute over a period of a week or two. Once you have acquired the skill, it is really very comfortable and can be done effortlessly and for extended periods. You will enter a new world of molecular wonders !
Instructions
Here are step by step instructions of how to practice stereo-viewing with VMD.
- Load a small protein into VMD and display this as a simple backbone model. (VMD Main → Representations → Drawing Method: Tube)
- Set stereo display to SideBySide (VMD Main → Display → Stereo → SideBySide)
- Resize the window, until two equivalent points on the protein are the same distance on the screen, as your eyes are apart (this is usually about 6 cm). Don't just guess, measure, and get this right to within better than half a centimetre.
- Touch your nose to the screen and look right at the two images. Make sure you see the right image with your right eye, the left with your left eye. Of course, since you are so close, the images will be blurred and out of focus. Nevertheless, you should see one solid, three dimensional shape in the centre, two peripheral images of the same on the sides. Thus you actually see three copies of the same scene, but only the fused, centre scene appears three-dimensional; the other two become less noticeable as you practice more, your brain simply begins editing them out. Slowly rotating the protein helps generate the impression of a 3-D object floating before you.
- Once you see the object in 3-D, try to move your head backwards slowly, until the structure comes into focus by itself. Do not voluntarily try to focus, since this will induce your eyes to converge and you will lose the 3-D effect. After a short while, you will probably lose the 3-D effect. Once you lose the 3-D effect, pause, look somewhere else and start over.
- Practice this patiently, two times daily for some 3 to 5 minutes. Stop, when your head feels funny. Don't force yourself.
It should take you about a week to master this, with regular training it will become very easy. And, the best thing is, you do not easily forget this skill. It is like riding a bicycle, equalizing pressure in your eustachian tubes while scuba diving, or circular breathing to play the didgeridoo: once you teach your body what to do, it remembers. And it expands your horizon.
Examples
Below, there is a script to set up a stereo-view of 2IMM. Simply copy the script from the textarea and paste it into the VMD command line window. The commands get executed line by line and it is easy to change parameters and arguments and see what effect this has.
Trouble shooting
[TBC]
Resources and References
- Stereopsis - Wikipedia article on why we see in three dimesions
- Stereoscopy - Wikipedia article on the techniques for stereo images