Now, if you could assemble the thing in space, then everything could be less massive. You might make the mirror and some of the struts on the moon, and then launch them from there to somewhere in space where they can be assembled. The final stages of the optics would come from earth.

Anyhow, thinking is cheap: stuffing up a space station or trying to set a man on Mars without doing the thinking is what eats the resources. There is no rush to sort out a moon telescope anyway. We will have to see if the OWL can be built first, and that ought to happen on Earth (on the Antarctica dome if we are allowed). We see how that goes before we try making one where we can't repair it.

I referred to spin like a concrete mixer, (which is quite small no matter how you look at it)- this along with molds instead of one gigantic fabricator. And I'm saying small since you can have the machines run for any length of time.

14 out of 28 days is plenty, either have panels on both sides of the moon, a back up storage unit, or simply build two telescopes with the equipment at hand.

And size is of no matter where it be micro meters, feet, kilo meters, just let machines run for any indefinite amount of time and readjust the molds. Lastly I was joking about the manpower- but it is doable, maybe with a smaller scale mirror for testing the idea first on the moon before implicating it.

Why is every1 thing about large machinery? All you need are small ones which run for a longer period of time, like ion engines, small amounts at a time but effective

I'm not quite sure if the scientists are suggesting to produce a 50-metre diameter mirror that could then be spun inside a ~ 50-metre diameter spinning-type machine as this would require huge, huge amounts of machinery (so I agree with you on that count). Before I go on, just a note about your corrected calculations which seem, I think, to suggest you' re looking at 50 foot diameter mirrors, but as far as I know they're talking about ~ 50-metre diameter mirrors (and upwards). This would then make the overall area using πr^2 as ~ 1963 sq. metres not 1963 sq. feet (1963 sq. metres is much, much greater than 1963 sq. feet).

I think, however, that the scientists may not be be looking at producing just one huge 50-metre diamter mirror as a whole, but rather a mirror made up of several smaller, segmented mirrors, say, a metre across, which would then be conjoined together to produce the larger 50-metre diameter mirror. These segemented type mirrors have been made on Earth (e.g.the Hobby-Eberly telescope made up of 91segmented mirrors each a ~ metre in diameter across), and so it would be possible to produce the mirror sizes they suggest. Just imagine, therefore, an astronaut spinning smaller 1-metre-diameter mirrors at a future lunar base, where the euipment used to do so wouldn't be that much big, and as the moon's gravity is 1/6 that of Earth's, assembling them together would be somewhat easier. However, I do agree that trying to do such work in those awkward, confining suits that astronauts have to wear isn't going to be a walk in the park. Still, they've [the astronauts] have tackled far more difficult jobs in the past in space, and on the Moon, so, it's as well to remain optimistic to someday see them building these huge 50-metre diameter telescopes that they are proposing.

John — http://www.moonposter.ie

Who are the ones smoking crack?

Think before you open your pie holes.

Peace

Man power for dust collection?! What a waste! Consider how big a 50' mirror is. That's 150 square feet of surface area. Imagine collecting enough sand to cover 150 square feet to a depth of a couple inches. Now do that on the Moon wearing a suit with limited air, limited time, and multiple priorities. Would you really spend valuable time sending astronauts out on errands to collect dust in buckets?!

I was ignoring power production (except for a few select places like the rim of Shackleton Crater, solar power on the Moon only works 14 out of 28 earth-days) because the power requirements are moot – operating the telescope and support equipment will require power, so some sort of electrical power generation on the Moon must occur regardless of where the telescope is assembled.

A machine to spin the mirror in assembly may be less mass than the 50' mirror itself, but it must be at least 50' in diameter to hold a 50' mirror without allowing material to slough off the sides when spun and to maintain a uniform surface across the mirror. Forget _fitting_ it on a rocket (who said anything about the Shuttle? Shuttle can't get to the Moon anyway, and I made no mention of actual payload size requirements for launch vehicles). My point is that when you add up all the equipment required to build a mirror on the Moon versus assemble a mirror from components manufactured on Earth, it is more energy efficient (launch vehicle, not power generation on the Moon) and thus cost effective to manufacture it on Earth and assemble it on the Moon than to manufacture a single solid mirror on the Moon.

However, lunar manufacturing may have an advantage over terrestrial manufacturing when considering economies of scale. If more than one mirror is to be produced with little or no transport over the lunar surface, it may be more efficient to manufacture it on the Moon.

Peace

But why just optical? I would like to see multi layered inputs from the telescope seeing how so much time will be put into it.

Think about it. You'd have to send up the machines to collect the lunar regolith. You'd have to send up the machines to hold the regolith in place. You'd have to send up the epoxy. You'd have to send up a machine to pour the epoxy. You'd have to send up a machine to spin the whole assembly. You'd have to send up a machine that could heat aluminum to the melting point, and you'd have to do it in a controlled thermal/atmospheric environment. Then you'd still have to transport it to the assembly it needs to be mounted on. Why not skip all that and just send up segments and assemble them in-situ?

Peace,
Drew