Folded Newtonian Telescope 164
johanneswilm writes "Michael Fallwell has figured out a way to overcome many of the problems of traditional telescope construction - making it way more compact and economical. And the whole thing is completely portable and achieves accuracy down to one or two millionths of an inch across an 18 inch surface!"
Woohoo! (Score:3, Funny)
Re:Woohoo! (Score:4, Funny)
Re:Woohoo! (Score:1)
Re:Woohoo! (Score:2, Funny)
Re:Woohoo! (Score:2)
Re:Woohoo! (Score:1)
different? (Score:4, Interesting)
how is this fundamentally different?
(to me, the picture looks basically like a standard newtonian)
Secondary mirror angle (Score:5, Informative)
Usually, the secondary mirror is elliptical and at a 45 degrees angle. In this case, it's a circular mirror at a 15 degrees angle. This puts the eyepiece closer to the main mirror, making it easier to mount a long focal distance telescope. Notice the eyepiece position spec. A circular secondary mirror is easier to make than the usual elliptical that's required if you mount it at 45 degrees. A larger secondary mirror has a lot of advantages (listed in the article) at the cost of more obstruction.
Re:different? (Score:5, Interesting)
Re:different? (Score:2, Funny)
I gotta say though; she doesn't look too happy in the picture. Maybe you should have gone for the 18 inch DOB after all? ;-)
Seriously though, nice pictures.
Faster link (Score:3, Informative)
http://www.heffernans.org/gifs/scope6.jpg [heffernans.org]
It's a bit slow to load the whole page, and the picture is the last one on the page. I'm sure his bandwidth will thank you.
Re:different? (Score:4, Interesting)
Re:different? (Score:3, Informative)
Instead of going straight out the side of the tube (normal to the tube's surface, that is), the path from the secondary mirror goes back in the general direction of the primary, but canted a bit so that you don't need a hole in the primary. The idea is to bring t
what would waterhouse say?! (Score:4, Funny)
The only problem with my knowledge of Newton these days is that 70% of it involves Waterhouse and other Neal Stephenson creations.
I mean I could regale you with tales of Newton deforming his eye with a knitting needle but it could be complete fiction...
Re:what would waterhouse say?! (Score:4, Informative)
Re:what would waterhouse say?! (Score:1)
Re:what would waterhouse say?! (Score:2)
Total is over $10,000.00 (Score:4, Interesting)
Probably hell of a lot cheaper than University telescopes!
Re:Total is over $10,000.00 (Score:5, Insightful)
And I know any number of hobbiests who spent far more on bicycle racing, or a kart, or golf, or their stamp collection, or modifying their car, etc. Fairly lower middle class income types among them.
Not to mention what the computer geeks/gamers I know have spent. The flight sim folks can get downright silly at times. God bless 'em; and I'd love a full motion cockpit myself.
Call it passionate hobbiest rather than extreme, and I'd say anybody setting out to grind their own mirrors rather than drive to the mall and pick up a Meade is, by definition, passionate about telescopes.
KFG
Re:Total is over $10,000.00 (Score:2)
Re:Total is over $10,000.00 (Score:2)
Re:Total is over $10,000.00 (Score:1)
Re:Total is over $10,000.00 (Score:2)
Prices (Score:4, Informative)
Focusers
1.25" $49
2" $69
4" $140
Equatorial Table $275
Mirror Grinder
10" $250
20" $475
40" $1800
80mm Binocular Holder $250
16" DOB $1800
18" DOB $2200
16" Mirror $900
2" Adapter $30
Led Colimator $30
Silvering Kit $50
Encoder $30
Guide Scope $40
Interferometer 10" $160
10" Folded Schmidt Camera $4500
I wouldn't call $13298 Very Low Cost...
(Assuming all of this stuff is needed of course.)
Re:Prices (Score:5, Funny)
Focusers
1.25" $49
2" $69
4" $140
I wouldn't call $13298 Very Low Cost...
You must be new around here. The correct take off of a Ma$tercard add is:
18" DOB $2200
Mirror Grinder 40" $1800
10" Folded Schmidt Camera $4500
Finding out you spent ALL your money on glass and plastic and are getting kicked out of your apartment. Priceless.
For some things in life there is Slashdot, for everything else there is Google.
Re: (Score:2, Funny)
Re:Prices (Score:2)
AND the MOST BIZARRE thing about those PRICES (Score:5, Informative)
$250 for a binoviewer will get you crap! The good ones are about $900 - $1500 for a Denkmeier [denkmeier.com] or for a Baader Planetarium [astro-physics.com] model.
Focusers for $49... to $140 for a 4" model? puh-lease! Superb Feathertouch focusers [buytelescopes.com] are going to run you $300 at least for a 2" model. Clement Focusers [clementfocuser.com] are going to be around $400. AP [astro-physics.com] focusers are going to be $400 - $700.
And the biggest problem of all. 16" mirror for $900?? 18" DOB for $2200?? Go fish! Some crackpipe dreams here. Superbly figured mirrors, which focus light superbly well, in well built dob structures, are going to run you into bucks. A quality 18" dobsonian telescope like a Starmaster [starmastertelescopes.com] is going to run you $6,400 without any options, a far cry above $2200.
I'll put my refractor up against this guys mirrors any day!
Re:AND the MOST BIZARRE thing about those PRICES (Score:4, Interesting)
If you grind your own mirror, you can make an 18" scope for under $2200. And an amateur can grid an excellent mirror - it doesn't take exotic equipment to do it.
A quality 18" dobsonian telescope like a Starmaster is going to run you $6,400 without any options
I'm surprized that they are now over $1K more than an Obsession Telescope.
I'll put my refractor up against this guys mirrors any day! ;)
Even an 8" AP refractor is toast against a 18" dob with a very good mirror on most objects. The slight advantage on planets is demolished by the dobs better reach on Deep Space Objects. And how much for a 206 Starfire EDF, with mount? $25K to $50K? (used, of course).
-MDL
Re:AND the MOST BIZARRE thing about those PRICES (Score:1)
Re:AND the MOST BIZARRE thing about those PRICES (Score:2)
Re:Prices (Score:4, Informative)
You don't add all of that together. If you did, you would have about 3 full telescopes and another 16" mirror for a 4th. Plus, you would have mirror making equipment. It is quite possible to build that 18" scope you see for probably $1100 to $1500. With about 90% of the cost always being the mirror (pre-made).
cb
Re:Prices (Score:1)
In comparison to...? (Score:3, Interesting)
Wow, that sounds really cool and accurate. But current telescopes are obviously also very very accurate too. So this doesn't really say much. I wonder how good this one is compared to current ones, made for the same purpose. Is there a noticeable loss of quality?
Re:In comparison to...? (Score:2)
Re:In comparison to...? (Score:1)
Re:In comparison to...? (Score:2)
Re:In comparison to...? (Score:4, Interesting)
His construction doesn't look very stable. (Score:1)
Comment removed (Score:5, Interesting)
Great chick magnet at parties (Score:3, Funny)
# 30% reduction in tube length
# 50% reduction in eye piece height
# 4x more back focus
Compared to, of course, smaller secondaries...
It's a semi interesting page but frankly doesn't do it for me. Great for telescope geeks no doubt. But the key question he surely missed... if you point it at some interesting bedroom or bathroom windows... is it able to see better through slightly opaque curtains?
Re:Great chick magnet at parties (Score:1)
Doubtfully, but if you are going to spy on people don't you think something less conspicuous then an 18" f/8 might be in order?
Re:Great chick magnet at parties (Score:2)
-aiabx
New? (Score:1)
I wonder... (Score:2)
Does this qualify as an invention? Is it patentable?
If so, I hope a big corporation doesn't manage to scoop it behind his back. Any time you radically reduce the cost of something there's a big risk of that.
Re:I wonder... (Score:2, Offtopic)
If so, I hope a big corporation doesn't manage to scoop it behind his back. Any time you radically reduce the cost of something there's a big risk of that.
We look through the telescope and we wonder...
why Darl McBride is staring back.
Isn't it great the way modern patent and copyright law frees us all to concentrate on creativity and innovation, rather than legal minutia and protecting our work from overbroad and stealth patents?
No Patents here... Move along (Score:1)
Prior Art - I know Captain Ahab had a folding telescope when he was looking for Moby Dick. Unfortunately he was looking straight down when from the depths of hell he stabbed at it...
Portable is in the eye of the beholder (Score:5, Funny)
Weight 70lb
Eyepiece Ht. at Zenith 5'4"
33% Obstruction
3 Min: Setup - Ultra Portable
I assume the guy doesn't live in an appartment. My 12' Schmidt Cassegrain telescope however, while less interesting that this project, can be moved with a bicycle trailer to go stargazing on the high hill near my place, and doubles as a handy tool to watch my neighbours' boobs in the appt complex down the street.
Dont you wish... (Score:1)
You neighbour had installed "full length windows"?
Re:Portable is in the eye of the beholder (Score:2, Informative)
The thing colapses and would easily fit in the back of a honda. With a bit of care you could probably get it into your bicycle trailer.
-Peter
Re:Portable is in the eye of the beholder (Score:2)
Re:Portable is in the eye of the beholder (Score:3, Funny)
``Ultra Portable'' (Score:4, Funny)
Not much information (Score:5, Interesting)
The figure itself is stabilized by a trick developed years ago for stabilizing glass lasers eliminitaing any need for Pyrex at least for mirrors of this size.
The reason for using Pyrex is thermal stability (ordinary glass expands, changing the carefully-worked shape in the process). What's this trick then? How does it work? Being able to use plate glass effectively would make amateur telescope making much easier, yet I've never heard of this method. Some references would be nice.
Would you trust a computer review which said something like "this machine is cooled using a trick developed years ago for cooling nuclear reactors, eleminating the need for fans for a processor of this speed" without some kind of additional information? That's what this article sounds like to me.
These kind of statements and the lack of, say, an optical diagram, make it very hard to judge the article. Theres a photo of a guy with a telescope, so I guess he built it, but I'd prefer to see some more concrete information and proper test results (diffraction rings, spot diagrams, whatever).
The price list is strange - an encoder? There's no drive on that thing. A $4500 Schmidt camera? that has nothing to do with this telescope (its a kind of telescope in itself, used for very wide fields). 40" mirror grinder? 16" mirror? The article talks about an 18" mirror telscope. The only thing I can think of is that this an attempt at a price comparison with other technology.
In short, interesting, but strange.
Re:Not much information (Score:5, Informative)
Last year I finished my first, an 8" f6.6 and the figuring was rather hard. I think my next attempt should be better, but something like this at f8 is much easier to figure!
I'll show the article to my ATM mentor and see what he thinks about it. Especially some of those contentious sentences.
Re:Not much information (Score:3, Insightful)
Quite true. A particularly nice example exists on the old 74" telescope at the David Dunlap Observatory [utoronto.ca]. The encoders feed into a computer which displays not the absolute position but the difference between the current position and where you want to point to. All you have to do is move
Serious cash flow problems? (Score:2)
Wow dude - you must have serious cash flow problems if you have somebody mentoring your ATM activities.
Seriously, aside from a machine where I can get cash, what is an ATM in this context?
OT: Transit Information Packages [my new project] (Score:2)
A while ago, you asked to be posted about a transit project. [slashdot.org] Well, I finally got the rough draft of the web site started. The project is called, TIPs [Transit Information Packages] [geocities.com]. This is a project to create customized transit information. The web site elaborates a bit more.
I look forward to hearing from you.
I remember a saying.... (Score:3, Funny)
The world will beat a path to the door of the man who builds a better mousetrap
Now it should read: Slashdot will burn a hole in the server of the man who builds a better telescopeRe:I remember a saying.... (Score:2)
My favorite Homebrew 'Scopes (Score:5, Informative)
As homebrew telescopes go, this one isn't terribly refined. It uses a unique optical arrangement, but not all that unique. Check out this folded refractor [aol.com], or this set of 22-inch newtonian binoculars [foothill.net] for some real jaw-droppers. (Also check out that last guy's all-metal 14-1/2" Alt-Az telescope... truly a beautiful instrument, even if it's a conventional design.)
There are a ton of exotic telescope designs out there being crafted by enthusiastic hobbyists, many of them on-par with deleriously expensive research-grade instruments. Most of them aren't made out of cheap plywood and bed rails. (I plan on building a 12" off-axis newtonian this summer.)
SoupIsGood Food
Re:My favorite Homebrew 'Scopes (Score:1)
Re:My favorite Homebrew 'Scopes (Score:2)
SoupIsGood Food
Huge central obstruction (Score:5, Informative)
I would imagine that it must have been a bitch to figure (shape) the mirror - it's not a simple parabola, and would require much more effort than a conventional mirror the same diameter. Kudos to Mike Fallwell for doing something different!
-MDL
16" f5 (Score:5, Informative)
Re:16" f5 (Score:5, Informative)
Re:16" f5 (Score:5, Interesting)
We're accustomed to think of large f numbers as "slow" because of cameras. I don't know much about cameras, but I suppose because there is a fixed area in the focal plane you are exposing; this translates to different clear diameters through which the film is "looking". You could have a long focal length lens with a huge diameter, but since the image it would create would be bigger than the film there's no point: you're stuck with smaller useful aperatures for longer f numbers. With telescopes the area of the focal plane you are examining is dependent upon the eyepiece you use: its focal length and FOV. That is to say that if I choose eyepieces to provide the same magnification, objects should look equally bright in two scopes with the same aperature and different focal lengths.
Generally speaking, things get optically better the longer the f number you choose, but mechanically worse. For example, any eyepiece will work quite well in an f6 scope, but for f4 you need a pretty good eyepiece to get a good view. An f15 reflector mirror could be figured spherically and perform well, but an f5 must be parabolic. An f15 refractor's objective lens focuses all colors in the same place, but an f4 requries exotic materials to get close to the same peformance. The list goes on and on. If convenience is no object, then longer is better.
The problem with long focal length scopes is that, in conventional designs, they are mechanically impractical. Eyepieces have to go to two inches, then higher for adequate fields of view; mounts have to become larger, and heavier; you have to climb ladders to look through them etc.
What this guy is doing is exploiting another optical advantage of long focal lengths to mitigate their mechanical inconveniences. To wit: he's exploiting off axis performance to acheive a comfortable viewing position. In a fast (f4.5) scope, the stars in the center are sharp, but at the edge they tend to be spread out like a comet. This effect is not noticeable in long focal lengths like f8. By folding the optical path, the observer can stand on the ground and look through the eyepiece; he is viewing the entire image off axis, but it probably is not too bad given the relatively long focal length. Where the sweet spot is is probably hard to say. He could have gone with a 12" f12 and had an optically superior system with the same mechanical advantages, but I suspect you aren't going to gain much ATM mojo with anything smaller than 18". Over 18" then you're back to the stepladder.
This guy is not the first person to think of this. I've seen references to this approach in ATM books, and I think I even remember an ad for a commercially produced scope, of smaller aperature.It's probably not popular because it doesn't meet most people's needs. A scope involves so man tradeoffs between optical performacnes under certain conditions and convenience, that what makes a scope "good" is surprisingly subjective. For example, this design is not going to be good for astrophotography; it might not work well with wide field eyepieces; it may be great for planetary work; who knows?
Re:16" f5 (Score:2)
Yes, I was thinking about cameras and assumed it's similar for telescopes. In cameras, the f-stop number determines the amount of light let in, controlled (usually) by an iris aperature. The lower the f number, the larger the aperature of
No disrespect to the builder (Score:2)
Re:No disrespect to the builder (Score:2)
-aiabx
Wow! Can you imagine.... (Score:3, Funny)
Comment removed (Score:5, Interesting)
I don't know telescopes, but I do know crackpots (Score:3, Insightful)
+2: frequent spelling mistakes
+4: train of thought derailments
+5: extraneous figures
+7: grandious claims not backed up by facts
+6: derision towards common theories/devices
-5: cool picture of finished product
crack-point total: 19
crackpot category: eccentric
Re-running the scan after callibrating for your input, we get:
+2: frequent spelling mistakes
+4: train of thought derailments
+5: extraneous figures
+7: grandious claims not backed up by facts
+6: derision towar
Best /. post this year (Score:1)
I gotta get me one of those crackpot-o-meters. Does James Randi have the local distributorship for this octant of the galaxy?
Re:Folded Newtonians are nothing new. (Score:2, Insightful)
targets like the moon, planets, or double stars where contrast matters. It shouldn't be too bad on faint fuzzies (galaxies, nebulae etc) and that 18" aperature doesn't hurt.
He also complains that collimation in on an SCT
is critical. It is critical but not particularly hard t
Re: (Score:3, Insightful)
Not much to see here... (Score:5, Informative)
There isn't much to see here. This is an old concept, one with advantages and disadvantages.
The main issue is that a folded design allows for a lower eyepiece height when you have a long focal length.
A long focal length mirror is faster to make (less grinding) and easier to figure (making a high quality mirror is easier when it is shallower).
The problem with a long focal length is you end up needing a ladder. You also lose the ability to get the brightest images (exit pupils of 7mm) when you go over an f/6.
The folding also introduces loss of contrast... from both the big secondary and the MAJOR baffling problem. You run the risk of extra star light entering the eyepiece and washing out the image when the eyepiece is pointed up.
So this design is nothing more than what this designer wanted for trade offs. There is no major design advances that lets an ATM do something they couldn't do before.
For more designs, check out:
http://members.efn.org/~mbartels/tm/ul-dobs
(scroll to the bottom)
and specifically another folded design...
http://www.irony.com/Ed/astro/18inch/
-Jeff
Re:Not much to see here... (Score:2, Informative)
I forgot to mention... a longer focal length also gets you lower coma, which is an off axis abberation. It makes stars on the edge of the field look like seagulls.
-Jeff
Re:Not much to see here... (Score:2)
Thanks for that explanation. I can stop taking those meds, now. *whew*
emplies (Score:1, Informative)
His neighbours must live pretty far away.... (Score:4, Funny)
Re:His neighbours must live pretty far away.... (Score:2)
Does anyone have a picture of the optical diagram? (Score:3, Insightful)
New chatup line (Score:1, Funny)
Her: "Is that a Folded Newtonian Telescope in your pocket, or are you just pleased to see me?"
Non-story (Score:5, Informative)
You wanna run a story about amateur telescopes, that's a good one. Or I could point you to the story of the three guys who ground their own 30" mirror and built a telescope from that. There's a lot of cool stuff being done by amateurs. Sorry, but this isn't that cool compared to most of it.
It would probably be useful (Score:2)
Not that this has any impact on his telescopes or importance (I've built one of his scopes myself) but for years I had a rather incorrect mental image of what he looked like.
TLAs? (Score:3, Interesting)
Re:TLAs? (Score:5, Informative)
Junkyard wars? (Score:2)
Slashdot: Taking the NEW out of NEWS (Score:1, Interesting)
Hmm, so it's good for wide fie
Can anyone explain to me? (Score:2)
Re:Can anyone explain to me? (Score:2)
-aiabx
Re:Can anyone explain to me? (Score:4, Insightful)
A newtonian can be easily tested by looking into the focuser w/out an eyepiece. If all you see is black and the mirror, the scope is adequately baffled, and no shroud or tube will improve it.
Why build your own telescope? (Score:4, Insightful)
It is quite within the range of any reasonbly competent person to grind and figuer a telescope mirror so that it is diffraction limited. This means that the surface has been shaped close enough to the ideal parabola (for a newtonian design) that the limiting factor for resolution is the wavelength of light you are interested in. In other words, the mirror is opticaly perfect.
The larger you go, the more difficult it is to do this, however.
unfortunatly, the design presented in the article seems to have been optimized solely for a lower eyepiece height, and all the rest of the choices made will result in a less than optimal image. eyepiece height.
the plate glass will make in very sensitive to temperature changes.
the large central obstruction will reduce contrast
the spray on mirror coating will almost certainly change the effective shape of the figure.
I could go on. There is not much to recommend this design other than eyepiece height.
But hey, the guy built his own telescope, and it works!
Can you mod down an article? (Score:2)
building as telescope (Score:2, Informative)
Bad Idea (Score:3, Funny)
I really should have known not to search the comments of this story for "mirror".
Interesting idea, but there are optical flaws. (Score:4, Interesting)
One thing that's important to realize is that any telescope is a compromise. However, this design makes some compromises that I don't know I would be willing to make.
The obvious benefit of such a design is to get a large aperture and a long focal-length without having to balance on a ladder. In general, if you want an 18" newtonian scope, you'd have to go down to a focal ratio of 4.25 or less to stay on the ground (that corresponds to a focal length of (4.25 x 18") = 76.5"). The problem with short focal length scopes is that they have to be much more accurate for their aperture...basically, it's easier to get a really good figure for a long focal length mirror. Long focal length scopes also have less coma (a certain kind of aberration), so kudos to him for this design with a focal ratio of 8.
However, I see three serious problems with this design:
1) Secondary size. In order to pack a greater percentage of that long focal length into the beam after reflection from the secondary, you have to make your secondary significantly bigger. This, to me, is unacceptable. He's using a 6" secondary, which is covering fully 33% of the main mirror's aperture. Not only does this cut down on the total light you see, but also reduces the minimum angular resolution...as long focal length scopes excel at high-res viewing, you're essentially shooting yourself in the foot right after you bought a really excellent foot. To give you a basis for comparison, my scope has only 21.6% of the primary covered by the secondary (mine also has a focal ratio of 7.5).
2) That 15 degree angle has got to be killer. When constructing scopes, it's plenty easy (er, well, easier, anyway) to make a perpendicular angle from your secondary. It seems like lining up that 15 degree angle correctly (known as collimation) every time you set up the scope is going to be difficult at best, especially when you have to line the "eyepiece tube" up at a 30 degree angle every time, as well. A couple degrees off and you're already introducing significant aberration.
3) Viewing angle. How do I look through an eyepiece that's only 30 degrees off the optical axis? With difficulty, at best. One of the main purposes of the scope - viewing comfort - is compromised by this. The obvious solution is to use a mirror diagonal, but that, again, is then only cutting more into the amount of light you see (no surface reflects 100% of the light), as well as presenting the potential for more surface defects.
Re:Michael Fallwell? (Score:1)
Ob Cassegrain Rant (Score:3, Informative)
on consumer products. Maks and
Schmidts are not subtypes, they are are Cadioptics based on the Cassegrain design which have
a corrector plate at the front. A cassegrain
(note no prefix) has no corrector plate. Spoken
as one who has worked with several cassegrain telescopes.