Telescope Will Have Images 10X Sharper Than Hubble 315
jangobongo writes "After a 20 year struggle, the University of Arizona's $120 million Large Binocular Telescope was dedicated last week. This unique telescope will have twin 8.4-meter (27.6 foot) mirrors that sit on a single mount. Using methods similar to a medical CAT scan, a technique of "tomographic" image reconstruction will be used to produce pictures 10 times sharper (example) than the Hubble Space Telescope for a fraction of its $2 billion dollar cost."
Hubble Comparison? (Score:4, Insightful)
Re:Hubble Comparison? (Score:5, Insightful)
Adaptive optics makes putting telescopes above the atmosphere unnecessary (or less necessary, AO is still in it's infancy).
If you can build a superior instrument for the cost of a single Hubble reservicing mission, why is it unfair to compare the price/performance to Hubble? No it doesn't have the same "coolness" factor that Hubble has, but as an astronomer, I don't really care about that.
Doug
Re:Hubble Comparison? (Score:5, Informative)
sooooo.... (Score:5, Funny)
so, you took up space in college eh?
Re:Hubble Comparison? (Score:4, Insightful)
How do you plan on doing high-quality UV and IR observations from ground-based telescopes?
Re:Hubble Comparison? (Score:5, Informative)
Will the LBT kick astronomical ass? Almost certainly.
Will Hubble still be able to do things LBT can't? Yes, indeed.
Will the LBT be able to do things Hubble can't? Of course.
The Hubble cost-analysis is way more complex than these simple comparisons on slashdot always seem to apply. At this point, the appropriate questions are things like, is Hubble worth the cost of maintaining? Does it still provide a unique capability? What is the value of that unique capability? When can a bigger, better replacement fly? Etc.
Re:Hubble Comparison? (Score:3, Insightful)
However, exactly like the firsat posts I was imediatly pissed by the "tone" of the aricle, implying that Hubble was wasted. No, it is not literally written there. But ending a sentence (the whole article even) with "for a fraction of its costs" implies the author wants to play down Hubble.
That said: AO was not available, no idea if it was even thought about it, when Hubble was planned and crafted (early 80s).
Hubble anyway excells in the bearly invisible spectrums
Re:Hubble Comparison? (Score:5, Funny)
Re:Hubble Comparison? (Score:5, Funny)
As we all know that is only the first part of its mission, the second is to be a large object burning up in the Earth's atmosphere.
Re:Hubble Comparison? (Score:4, Informative)
Re:Hubble Comparison? (Score:4, Interesting)
Re:Hubble Comparison? (Score:3, Interesting)
Re:Hubble Comparison? (Score:4, Informative)
Re:Hubble Comparison? (Score:3, Insightful)
Because unfortunately there are those who are completely uncompromising, and in this case the fact that the telescope complex takes up a fairly large amount of space and would alter as-of-yet unaltered land was probably what set them off. Personally I find this to be stupid to the largest extent, as it is as short sighted as groups who would completely annhilate
Re:Hubble Comparison? (Score:3, Informative)
OK, I agree with you that the telescopes on Graham should be built, but your characterization of the opposition is wrong. There were two main reasons why the telescopes were opposed: 1) Mt. Graham is the home of the endangered red squirrel. 2) Mt. Graham is the sacred
Re:Hubble Comparison? (Score:5, Insightful)
now lets see how long till we can get one of thee airborne
Re:Hubble Comparison? (Score:4, Funny)
Why dost thou wish to get one of me airborne?
Re:Hubble Comparison? (Score:3, Funny)
New technology generates better and cheaper results than 20 year-old equipment!
Must be a slow news day I guess.
Re:Hubble Comparison? (Score:5, Insightful)
Sorry, you are missing the point about the HST. It is doing things that no earth based scope can ever do. Because its above the atmosphere, there are NO artifacts of atmospheric band limiting it has to deal with. That effectively continuous broadband spectrum, extending from the near ultraviolet to the far infrared allows it to take in and process light that is 100% absorbed by the moisture and other contaminants in our atmosphere.
All things considered, that effect alone is worth, and I'm making a SWAG here, at least half an F-Stop over the whole operating bandwidth, and many F-Stops of increased sensitivity at some frequencies.
No, the HST is not doing what the Webb can do when and if it gets up, but then the Webb cannot do much of the HST's job either, each being designed for completely different objectives.
And if your congress critter doesn't understand that difference, work to elect one that does, its all valuable science.
Cheers, Gene
Re:Hubble Comparison? (Score:5, Insightful)
While I agree that it's important that those in U.S. Congress understand the difference, that doesn't mean that they'd automatically vote for continuing support of Hubble or replacing it. Even those who recognize Hubble as a great science machine must recognize that it isn't free. If Webb and ground based adaptive optics can do, say 80% of what Hubble is used for (not what it can do, but what it does do) plus a bunch of things Hubble can't, is it worth the billions of dollars to maintain or get back that 20%? To many astronomers and scientists the answer is probably yes. To social activists begging for money for homeless, medicare, etc., the answer is probably no. To the average Joe Taxpayer the answer is "Huh, what's a Hubble?". To those who must make the decisions it's a nightmare. There is no right answer. It's all a balance of meeting needs and not everybody's needs can be met.
"Seeing Limited"? (Score:3, Interesting)
Re:"Seeing Limited"? (Score:5, Informative)
And yes, IAAA (I am an astronomer).
Re:"Seeing Limited"? (Score:4, Informative)
Oh for heaven's sakes, this would have taken you maybe five seconds to check online.
The NRAO's headquarters are in Charlottesville, Virginia, and have been for a very long time.
The NRAO has facilities [nrao.edu] in a variety of locations, of which Green Bank is one.
Re:"Seeing Limited"? (Score:5, Informative)
Now, in the past few years something called adaptive optics has become popular. It consists of techniques to correct for the twinkling and make the big, ground based telescopes, see more clearly (in some sense) than HST. The problem is that this only works in the infrared -- not in the optical bands. So we can now do better in some ways from the ground than in space, but not at all wavelengths.
The claim that the LBT is x times better than Hubble is somewhat misleading. Again, this only applies to the infrared -- NOT the optical. And even in the infrared the story isn't really that simple -- with adaptive optics (at least) you tend to get a narrow core that is really, really well defined, much better than Hubble, but then there is a large skirt of less corrected light around the sharply defined core. So for some purposes adaptive optics isn't really better -- like if you need to measure all of the light. This is (naturally) being worked on.
Another problem is that for most adaptive optics systems you need to have a pretty bright star right next to what you are looking at -- which isn't true for most parts of the sky. People are bulding laser systems that create artificial bright stars wherever they want to look, but they aren't as common, don't work as well, and are difficult to use -- among other things you have to file an observing plan with the FAA to make sure you don't accidentally shine the thing at a plane flying by.
You shouldn't have this problem with the LBT, but I don't know about the previous one. And, as far as I can tell, it also only works in the infrared.
More info and not everybody like this... (Score:5, Informative)
Here is a particularly good description of the LBT (Large Binocular Telescope) from an article in the Eastern Arizona Courier [eacourier.com].
The LBT is made up of two 8.4-meter mirrors, which, when in place, will bring together the light, creating sharper images of faint objects in space. One mirror is in place at the Mount Graham International Observatory, and the other will arrive next spring. Each mirror is designed in a manner that allows it to reach the same temperature as the outside air up to two hours faster than any other mirror design. Under the solid glass surface are openings in a honeycomb pattern. Cold air is pushed up through those openings, cooling the glass to the desired temperature. The sooner the glass cools, the more science can get done, which is good from a business standpoint, assistant project director for LBT Jim Slagle said.
Not everbody is happy about this, though. The Apache people are protesting the use of the site for the telescope.
The U of A is finally dedicating it's Large Binocular Telescope (LBT), formerly called the Columbus Project, after years legal and money problems and at least a year before actual completion. (The U of A changed the name of the project after realizing it wasn't such a popular idea to name it the Columbus project and then, against the wills of the Apache people, place it on their most sacred site on top of the mountain.) The LBT is mainstay of the project. Investors will be wined and dined on Fri. at the La Paloma resort in the Catalina foothills and bused up to the mountain on Sat. to tour the scope site. Our job is to show the investors how controversial and unpopular this project is... and has been for decades.
Re:More info and not everybody like this... (Score:3, Insightful)
It seems rather poetic in my opinion - this mountain is used to peer into the heavens, where their ancestors used to commune and/or communicate with the heavens. (I'm not up on Apache religion, enlighten me if I'm way off.)
I'm assuming they aren't levelling the whole thing and putting a McDonalds up there or something like this. The objection to the use of the name Columbus sou
Re:More info and not everybody like this... (Score:5, Interesting)
But not everyone is proud of the achievement. Controversy has swirled around plans for the Mount Graham International Observatory since it got its start 20 years ago atop the 10,700-foot mountain. Opponents contended the observatory would cause the demise of the endangered Mount Graham red squirrel. And the San Carlos Apache Tribe said development would desecrate a sacred mountain. Environmentalists and members of the tribe filed some 40 lawsuits - eight of which ended up before a federal appeals court - but the University of Arizona prevailed. The telescope and mountain observatory, about 125 miles northeast of Tucson, also survived two major forest fires in eight years, the most recent one this summer. "It's a sad day for anyone who believes that the University of Arizona cares about ethics, biology, cultural protection and religious freedom," said longtime project foe Robin Silver, conservation chairman for the Center for Biological Diversity. [miami.com]
Re:More info and not everybody like this... (Score:5, Interesting)
Unless there's a burial ground at the top, the term "sacred mountain" doesn't mean much to me.
Re:More info and not everybody like this... (Score:5, Informative)
I want to add some other comments. The LBT is not the only telescope on Mt. Graham. The Vatican Observatory and the Hienrich Hertz telescopes have been there for years already (I once observed at the Heinrich Hertz).
The squirrel population has been doing very well with the telescopes there. They suffered a setback a couple of years ago from a tree disease that hurt their habitat, but that wasn't telescope related in any way. Moreover, last summer the forest fires came close to destroying the observatories...and the squirrels. I have little doubt that the squirrels would have been wiped out if the telescopes weren't there. Firefighters battled the blaze like crazy to save the $200 million dollar facility. Would they have fought so hard, in so many numbers, at that location, if not for the LBT?
Re:More info and not everybody like this... (Score:3, Funny)
Hmm. With the increased number of websites showing this thing's pictures, you'd think they'd be happy there'll be more use of their web server!
Re:More info and not everybody like this... (Score:3, Funny)
Re:More info and not everybody like this... (Score:3, Insightful)
"Yes, I think that scientific progress should not be held back - at any cost. I think that nothing is sacred in the light of science - so long as it's justifiable."
Huh? You have a contradiction right there. "Science should not be held back at any cost" and "as long as it's justifiable". So what is
Does this effectively obsolete Hubble? (Score:2, Insightful)
-S
Re:Does this effectively obsolete Hubble? (Score:2)
It is another question of whether that extra capability is worth the extra cost.
Re:Does this effectively obsolete Hubble? (Score:5, Informative)
With that TWENTY YEAR OLD technology, we have gotten absolutely amazing results, as you have seen. After two decades of advancement, we can do even better from the ground, but that doesn't invalidate the science we have already done. (like that huge meteor strike on Jupiter; because of the Hubble, we practically had front-row seats). The money involved to keep Hubble running isn't that large, relatively speaking; the initial build and launch were very expensive, but we have already paid for those. Fixing the Hubble just needs to be cheaper than building a ground-based 'scope of similar quality, and I don't think there's any argument about that. And even if the Arizona telescope is better, that hardly makes the Hubble useless. There's never enough observation time for everyone on the really big instruments, and having several available would be good.
The Hubble's successor should be as far past its ground-based competition as the Hubble was. Like it or not, that atmosphere is annoying: we can correct for its presence to some degree (which we couldn't twenty years ago), but it's even better to not have it in the way. We're trying to look unbelievably far away, and if we're not spending a great deal of time correcting for the atmosphere, we can spend time correcting for much smaller problems.... ultimately giving us far better pictures.
Reemember the Hubble Deep Field -- in the darkest part of the sky, in an area about as large as a grain of sand held at arm's length, we saw at least 1,500 GALAXIES.
There's a lot to see out there.
Re:Does this effectively obsolete Hubble? (Score:3, Informative)
Some of it has been upgrade by shuttle service missions.
Re:Does this effectively obsolete Hubble? (Score:3, Informative)
Estimates I have heard (and IANAA) have put the cost for further service missions at around have a billion dollars, which would be around 4 times the cost of building this telescope. And remember that mission will only keep the Hubble out for a limited time. Afterwards more missions will be required to keep it up longer. And money isn't the only problem.
Re:Does this effectively obsolete Hubble? (Score:3, Insightful)
I don't think the risk to the astronauts, however, is a particularly compelling argument. They know the risks in going up, maybe better than anyone. Perfect safety is appallingly expensive; if we can just do 'good safe
Re:Does this effectively obsolete Hubble? (Score:5, Interesting)
A requirement on all observing proposals to Hubble is that the observation can't be done by any ground based telescope. This is so we don't waste the expensive telescope time on something that can be done by the chearper telescopes. So when LBT starts operation, there may be some observations that would have been done on Hubble going to LBT instead. But certainly not all of them.
In any case, the way things are going at NASA HQ, it'll be lucky if Hubble is still operating by the time LBT starts observing with both mirrors.
Re:Does this effectively obsolete Hubble? (Score:3, Informative)
Doug
Re:Does this effectively obsolete Hubble? (Score:4, Interesting)
You forgot Spitzer (Link) [caltech.edu], which is up there today. There have already been more than a few collaborative projects between this space telescope and Hubble.
And on the subject of space telescopes that can see places Earth-based telescopes will never be able to see because of the blocking effects of the atmosphere: Chandra (Link) [harvard.edu], which can see X-ray sources. This one is my favorite Chandra picture. [harvard.edu]
Re:Does this effectively obsolete Hubble? (Score:3, Insightful)
Almost no telescopes in space do quite the same thing, and moreover, no telescopes on the ground, including the LBT, can do some of the things that space-based telescopes can do. It's way too simple to say x is better than y, and cheaper than y, so why do x? "Better" is a very slippery word. Are apples "better" than organges?
Terrestrial limitation (Score:5, Interesting)
A space-based telescope (like the Hubble) can be rotated and aimed at almost any object out there. In that sense, a Hubble is still superior in some aspects.
On the other hand, just the fact that adaptive optics and interferometry can clean up the images so spectacularly is simply amazing!
I wonder how long before I can get a consumer-grade version, to take pictures of the coeds^H^H^H^H <ahem> natural "scenery"... ;-)
Re:Terrestrial limitation (Score:2)
Re:Terrestrial limitation (Score:4, Insightful)
Re:Terrestrial limitation (Score:3, Informative)
The practical viewing area is even smaller, because objects near the horizon are obscured by atmospheric effects...so there's plenty of advantage to being in space.
rj
Re:Terrestrial limitation (Score:5, Informative)
However, although you can only observe 1/3 of the sky at a given moment, the motion of the stars through the night and year means you can observe much more of the sky if you're prepared to wait. Furthermore, if the telescope costs a small fraction of the cost of a space telescope, you can build many of them in different parts of the world, to overcome these limitations.
There are other reasons for going into space - atmospheric bluring, absorption and emission.
I don't know. (Score:4, Insightful)
Furthermore, both hubble and an earth bound telescop would have a somewhat limited view due to their "orbit". Concider a telescope on the equator. It would have a 180 degree field of view at any given time, and over the course of a day, everything would be in it's field of view except a cylinder the width of the earth, centering around the earths rotational axis, and extending to infinity in either direction. If you have telescope further north, it's daily field of view would have a cone shaped blind spot to the south. Hubbles orbital blind spot would be nearly non-existant over its orbit period, slightly better than the observatory at the equator, but that is easily solved by having two observatories - one in each hemisphere.
Concidering how inexpensive these are to build relative to a space based telescope, there is no reason why we can't do this. In fact we have hundreds of observatories across the world, each new or improved one slightly better than the one befores, but only one space based telescope. Improvements in ground telescopes will also be available to many more researchers, than with just one expensive space telescope.
Re:I don't know. (Score:5, Insightful)
Overall, Hubble is less restricted than any ground-based telescopes because it can look closer to the sun than any of them. We used to have all sorts of problems making quasi-simultaneous ground-based observations, because they would schedule Hubble observations a month later/earlier than we'd be able to see a target from our telescope in Texas. That atmospheric scattering hurts in more ways than one.
Re:Terrestrial limitation (Score:5, Insightful)
however, there's a more fundamental reason why this is largely unimportant - the universe doesn't have a special direction, it's pretty much the same everywhere. so while you might not be able to see a certain object from a certain telescope, you can see another one pretty much like it.
there are exceptions, of course. if you're looking at objects in our galaxy then you may need to use a certain telescope, because the position of the galaxy relative to the earth is pretty much fixed. so for "nearby" objects it may be important. also, at the extreme opposite, observations of large scale fluctations in the very early universe (effectively observing *very* distance objects) may require all-sky observations.
but for many interesting objects - other galaxies, quasars, radio galaxies, etc there's no real loss to being restricted to one particular direction.
Re:Terrestrial limitation (Score:3, Informative)
Ugh. (Score:3, Interesting)
Pardon me for asking... (Score:3, Interesting)
Granted, the telescope's location is a plus in this department (there are few locations more suitable) but the potential interference is still a consideration. I've read their page on ground versus space telescopes [arizona.edu] and it touches on this issue, talking about fast computers and adaptive optics that correct atmospheric blurring, but it's not an issue for which you can completely compensate.
Having said that, a ground-based observatory is a heck of a lot cheaper than an orbital one...
Re:Pardon me for asking... (Score:2, Informative)
Re:Pardon me for asking... (Score:2)
Re:Pardon me for asking... (Score:3, Informative)
Concerning Hubble (Score:2, Interesting)
Re:Concerning Hubble (Score:2, Informative)
Re:Concerning Hubble (Score:3, Funny)
I'd suspect it would have something to do with it not being able to focus that close. Just like if you point a camera at something 5 cm in front of the lens, it wouldn't be able to focus on it, and you'd get a really fuzzy picture.
So what you're saying is they forgot to implement a macro mode on Hubble. Silly astronomers--oh wait...
Re:Concerning Hubble (Score:2, Interesting)
Re:Concerning Hubble (Score:2, Informative)
Re:Concerning Hubble (Score:4, Interesting)
But don't worry, the Keyhole scopes the US intelligence community use are basically Hubbles pointing at the earth, with appropriate instruments. Of course they don't let anyone see the pictures or admit they exist, but that's a minor detail.
Don't hate... (Score:2)
they have 4 open positions (Score:3, Informative)
Sadly, I'm not qualified for any of them.
Could this telescope and Hubble be used together? (Score:2)
slug bug! (Score:3, Funny)
something black and vacuous!
Question is (Score:2)
Just a thought
Hubble is not obsolete (Score:5, Informative)
This is an overstatement. There is lots that Hubble can do that no other telescope can, being a unique combination of aperature (light gathering power and resolution), instruments (many wavelengths, imaging and spectroscopic) and being above the atmosphere (no 'seeing', no atmospheric absorption or emission in UV and IR.)
(This is not to downplay the LBT - doing better than HST in some aspects, and as well but much cheaper in others, is very valuable.)
Having quickly scanned the website for this telescope, I can't see how they are counteracting the bluring of 'seeing' (atmospheric turbulance). It is inconceivable that they have neglected it, but I don't see where. Adaptive optics can help, but have limitations of their own.
Another limitation of the LBT is that the high resolution reconstruction will require 3 observations at different times - so it only works well with non-time-varying targets. This is a minor limitation, however - a large majority of targets for which you want high resolution are non-variable.
(IWAA: I was an astonomer. PhD, but no further.)
No other telescope? Sort of... (Score:3, Informative)
Hubble is one of multiple telescopes in NASA's Great Observatories [nasa.gov] project.
There are currently three space-bound observatories for astronomy.
For instance, Spitzer [caltech.edu] meets the qualifications you gave, the difference being that it operates in the IR range [nasa.gov], while Chandra [nasa.gov] looks at x-rays.
Hubble [stsci.edu] works in the visible range. But that's not to say that it's the only space-based visible spectrum satellite,
Seeing Planets (Score:5, Informative)
It will permit formation of images of sufficient sharpness (diffraction-limited) that the planet could be detected against only a low surface brightness halo of residual scattered light. In this manner, a Jupiter-like planet could be detected, if present, around some fifty of the nearest stars. The interferometric mode will enhance the planet/background contrast even further, thus increasing the number of candidate stars and the sensitivity of the survey. The direct detection of such a planet would surely be counted as one of the major steps forward in determining the likelihood of life existing elsewhere in the Universe and in understanding our place in it.
So, gas giants, but no mention of anything Earth-like. Too bad. I'd definitely be psyched to someday hear about "Earth-sized planet discovered about an AU away from a Sun-sized star."
Re:Seeing Planets (Score:4, Informative)
My questions was "Will this be able to resolve earth-like planets around nearby stars?" To which the answer was "No. Need 2 orders of magnitude better resolution."
In fact, in some rather extended searching, it appears there isn't even anything on the drawing board which would be able to achieve this feat. That's not to say that this is important, or anything, just cool! Who wouldn't take a second look at the first pictures of another "earth" around another star in their morning newspaper?
I keep hearing that (Score:5, Informative)
1. Limited range of sky
2. Frequencies different than hubble, such as only infrared.
3. Only works near bright stars due to "guide-star" anti-blur technology.
Let's see if new techniques get around these.
Why don't they build one of these on the moon? (Score:3, Interesting)
Heck. we could even build a whole telescope _array_ on the moon... just imagine what we would be able to do with that!
Re:Why don't they build one of these on the moon? (Score:3, Interesting)
Future space telescope concepts include deployable mirrors and such.
The moon's only advantage would be if you had a mirror manufacturing facility there, which clearly isn't going to happen anytime soon.
Re:Why don't they build one of these on the moon? (Score:5, Informative)
Well, almost all. There are a couple of difficulties with respect to pointing. Even under a sixth of normal gravity, you still need a much beefier structure to rigidly support a telescope on the Moon, compared to the same object in space. Particularly when the direction of that gravitational force changes as you tilt the telescope to follow objects.
In principle, you could build a space telescope of hundreds of meters in diameter, and it wouldn't sag. You'd have to brace it a bit for aiming motions, but you can do those at a hundredth of a gee, not a sixth--and the stress is off again once you're aimed.
For a really big telescope, that's another advantage of being in space--you don't have to move it while imaging. Point it, and it keeps looking at the same object for as long as you want to integrate. On the Moon, you have to track objects across the sky.
The ESA's Darwin [rl.ac.uk] project proposes a free-flying array of six(!) 1.5 meter telescopes up to five hundred meters apart, with their relative positions controlled to within micrometers to do optical interferometry. They want to be able to do things like 40 day exposures to measure the spectra of extrasolar planets and possibly detect life. I don't mean to suggest that such a facility isn't possible on the Moon, but assembling and reconfiguring it (if necessary) is probably a lot easier in space where you don't have to pour concrete foundations.
The moon's not that great a place for a telescope (Score:4, Interesting)
Heliocentric orbits (e.g. earth trailing) or the Lagrange points (cue ZZ top) are nicer, more stable environments to put your space telescope into.
Re:Why don't they build one of these on the moon? (Score:4, Informative)
This is not a replacement for Hubble (Score:3, Insightful)
They cannot detect EM waves that's not either visible light or in the radio wave to the far infrared range
This is because Earth's atmosphere, contrary to what most people would believe, is not transparent to EM waves of all wavelengths. For example, common sense tells us that it blocks almost all extreme UV light. So if you want to observe an object that emits only extreme UV light with a ground-based telescope, you're not gonna see it.
Another example would be gamma ray bursters. Remember these objects weren't detected until the US sent survillence satellites into space? This is because there's no way you can detect gamma rays that originated from space inside the atmosphere. Granted it's now possible to observe the after-glow of GRBs with ground-based telescopes, GRBs must still be detected from space telescopes beforehand.
Won't work (Score:5, Funny)
Nobody's eyes are that far apart.
Keck? (Score:3, Insightful)
I am only an ameteur astronomer but wouldn't a more valid comparison be to (the slightly lesser known) Keck Telescopes on Mauna Kea? For those of you who are not familiar there are twin 10-meter telescopes on Mauna Kea, which I'd be willing to be has infinitely better seeing (read: atmospheric conditions; the light is distorted less) than New Mexico.
In addition, one can add instrumentation and the like to ground based telescopes and not really to space based onces - hence, Keck would be a much better comparison.
Finally, I don't understand why such a big deal is made of the implied revolutionary methods that are used to combine the images from each scope. If anyone knows, is this different from any other dual telescope setup?
tomographic image reconstruction... (Score:3, Interesting)
the LBT places fringes on each point-like portion of the image. When we combine pictures taken with these fringes at three different angles, the fringes cross and give information about the exact placement of the point of light, distinguishing other points of light close to it. It is the crossings of these fringes that allow us to reconstruct a high resolution image.
So, does this mean that video from 2 cheap webcams pointed at the same subject, can be combined to a single higher quality stream?
The Intel Intel Open Computer Vison library [sourceforge.net] already uses binocular vison to track objects in 3D space. Can it be applied to this application?
Re:Why? (Score:2, Informative)
Re:Why? (Score:2, Insightful)
Re:Why? (Score:3, Interesting)
That being said, if you could use the same technique from space and not have to worry about atmospheric distortion, dispersion, and absorbtion, you could potentially do some really cool things.
Re:Why? $10 million?!?! (Score:2, Funny)
Hell, if you can LAUNCH another Hubble for $10 million...
Cripes, even launch the frickin' MIRROR for $10 million...
How about a box lunch for one of the workers? If you could launch THAT for $10 million, that'd put you into major miracle worker status.
Re:Why? $10 million?!?! (Score:3, Funny)
Re:Why? $10 million?!?! (Score:3, Interesting)
Re:Why? (Score:5, Funny)
But there's an Air in Space Museum?
Re:But (Score:2)
Unfortunately, our society has different priorities...
Doug
Re: I don't get it (Score:5, Insightful)
> This isn't intended to be a troll, but I just don't get space exploration. I mean, there are a lot of good causes that all these dollars could be going to right here on Earth: stopping wars, battling diseases, increasing literacy, fighting pollution.
Better yet, why not use the money we spend on wars for all that good stuff, and maybe we'll have enough left to do some space exploration anyway.
Re: I don't get it (Score:2)
Yes, because if we spent nothing on the military the world would be a happy place full of dancing elves, with no hunger, or wars, or traffic accidents.
Re:I don't get it (Score:5, Insightful)
First, all "these dollars" are spent right here on earth anyway. The idea that somehow or other money spent on research for space or technology is gone when the space craft is launched seems to be a common fallacy. It is also a faovorite that is often promulgated by parties with an interest in keeping frontiers closed and humanity in bulk pig-ignorant (religious zealots, some political parties, etc.).
Second, I doubt that any amount of spending will "stop" a war. Wars are inherently economic at root. A Cheney or a bin Laden or a Bush, a Haliburton or an Enron is always, always in the background with an "interest" in the objective of any conflict. Ideals and religious rationalizations are used by all sides in a war, but curiously, neither the idealists nor the religious seem to supply more than cannon fodder. The commonest example of this these days are the leaders of Muslim terrortist groups. You don't see THEM with a pound of semtex strapped to their bodies, or out taking lessons in crashing airliners. Nope, its some poor sap with a burning desire to purify the land for his religion or to get even for a real or imagined harm done by some equyally misguided zealot on the other side. What would stop wars is for the "followers" to hand their leaders the bag and say, "O.K. boss, your turn."
Re:I don't get it (Score:5, Insightful)
And would spending the money spent on space actually fix these problems? No. There's enough food in the world, to take one problem, but other issues (politics) interfere with distribution.
This criticism can be reduced to the absurd very easily. In the most extreme case, should we identify the "top priority problem" and spend 100% of our resources to fix it? And then move down some list?
Of course not. That notion is absurd.
The case for space expoloration is exactly the case as for basic research of any kind. You never know what you will discover or its importance until you do it, and supporting basic capability in science and technology is always a good idea for a society. It pays off economically in lots of ways, so it doesn't even cost what it looks like on paper.
Personally, I find it gratifying to live in a culture that values studying the universe and understanding our place within it. That says something noble about humans in a world that is too often filled with the mundane and the tragic.
Re:I don't get it (Score:3, Insightful)
Re:Hubble? Bah! (Score:2)
Re:So the Hubble was a huge waste of taxpayer's $$ (Score:3, Insightful)
Re:down with government programs!! (Score:3, Insightful)
Re:Seeing the moon (Score:3, Interesting)
rj
Re:Resolution not everything (Score:3, Informative)
There is, however, an area of faint astronomy where Hubble is unbeatable. And that is working on concentrated or point source
Re:Multiple Day Exposures (Score:5, Informative)
The LBT therefore collects far more light per unit of time than Hubble does. For many types of imaging the LBT ought to be able to get Hubble-quality or better images in less time than it takes Hubble to get them. A four day exposure from Hubble might only take a single day on the LBT.
This however doesn't necessarily answer the question of how far the LBT can see. Hubble is in an enviable position of being extra atmospheric. It can image in parts of the spectrum that are entirely blocked out by the various gasses floating around here on Earth. Hubble is able to take those deep universe images by imaging mostly in the IR band of the spectrum. Galaxies billions upon billions of lightyears away have enormous amounts of redshift. What they originally emitted in visible light has stretched into infrared as it's traveled to reach us. The pretty images NASA releases are just that, pretty images. They're greyscale images that have been given false colors as to be more appealing to non-astronomers.
Hubble will still be able to peer deeper into space than the LBT. The LBT however will be able to image faint visual objects quicker than Hubble (in many cases) and get far better optical resolution of large cosmological structures. A small telescope on the ground might be able to see M31 (the Andromeda galaxy). Hubble might be able to see fairly large structures like globular clusters, large dust clouds, and larger groups of stars. The LBT however will be able to see even smaller structures than Hubble. With higher resolving power the LBT will be able to produce more detailed visual band images which can be combined with other images or studies (Hubble IR or UV images for example) to provide a ton of information about the structure of that galaxy. The LBT isn't designed so much to replace Hubble or anything else, simply to expand our capability to observe and study objects in the sky.