Resolution is determined by aperture. The larger the aperture, the greater the resolution. Engineers have made a device similar to what you describe, called an interferometer. Imagine two small telescopes, say 3" aperture, seperated by ten feet. If you combine the light paths of the two scopes, you have a telescope with the resolution of a ten-foot aperutre, although the image is not as bright as that of a true ten-foot aperture. The trick is that in order for it to work properly, the wavefronts of the two light paths must be perfectly synchronized to arrive at the eye (or detector) at precisely the same instant. This is incredibly difficult to do mechanically. Exactly as you describe, if the eye (or detector) gets 2X the light half as often, the net result is no gain. The MMT, in it's original configuration, was a true interferometer. A segmented mirror such as the Keck telescopes are funtioning interferometers. --- "Lambert, Aaron" <Aaron.Lambert@Williams.com> wrote:
I will start this off with another disclaimer. It has been several years since I took physics and I have not done much with the art of telescope making except for one small project that Chuck helped me with.
On my way into work this morning (I ride the bus, so I get plenty of time to think), I came up with an idea. Again, this is based on ignorance, but hear me out and then shoot me down. :)
I was pondering a way to increase the light-to-eye value for telescopes, ideally allowing a small scope to show the same detail only visible in a larger scope. I had thought previously about using some kind of device that captures light (like a CCD) and then duplicates it to enhance the image, but I do not think that would work, or it would be just like staring at a screen instead of letting the photons hit your eye.
But let's say you could take a small tube (perhaps the size of a Barlow) and put a one-way light valve (mirror of some kind?) at the end coming from your scope and then have a reflective shutter at the eyepiece end which opened and closed several times per second. The light would enter the tube and have a 50% chance of reflecting twice before entering the eyepiece. The result (in my mind) would be that you would have alternating periods of no light reaching your eye and then double light. This would give an effect similar to watching a movie (one frame at a time) or looking through the slats of a fence while driving - your mind can still stitch the image together so it is cohesive. The question is, would it provide the desired effect of increasing the detail of what you can see?
Is there anyone out there that can shed some light (pun intended) on this?
Thanks, Aaron
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