Sola Virtus Observatory
Tutorials
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Sola Virtus Observatory Tutorials |
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Astrophotography
Basics Stepping into the realm of astrophotography can be daunting. Astro imaging
can be both expensive and complex, leaving your head spinning faster then a Neutron star. Well relax, it can also be relatively
simple and easy on your wallet. Astro imaging will test your patience, tax your mind and challenge your endurance. But this
is what makes astrophotography such a great hobby. At the end of a session to have captured an image of a Nebula or Galaxy
that is millions of years old can be quite thrilling. "So how do I get started?", you ask. Well, expensive telescopes, mounts
or cameras are not always needed to take great images. If you already own a telescope, a cheap web camera can be had
with software for less than $100.00. Quality DSLR cameras start at around $500.00 and are employed by amateur and professional
astrophotographers alike. A DSLR camera unlike a web cam, may be used alone, on a tripod, at prime focus or piggybacked
on a telescope with a tracking mount. The use of a T- Adapter, T- Ring and Tele-
Extender allows a DSLR camera to be attached to the back of the telescope for Prime Focus and high magnification Eyepiece
Projection astrophotography. At the SVObservatory (Sola Virus Observatory), I use digital SLRs for both deep-sky and planetary imaging and a NexImage camera for Solar System imaging only. Among DSLRs I prefer the Canon Rebel XT (350D). It is
reasonably priced, are easily modded and the Canon Digital Rebel XT(EOS 350D) works surprisingly well as a deep-sky astro
camera without any cooling devices, particularly when exposures are kept under 10 minutes and dark frames are subtracted.
Colder weather goes along way in extending those exposure times to the 10 minute mark and beyond. The Canon 350D also has
low noise, can take Pentax and Nikon mounts (with adapters), works well in light polluted skies and can be completely computer
controlled. My basic imaging setup is a Canon 350D attached to the scope
via a T-Ring adapter along with a ScopeStuff TA2P which contains a f/6.3focal reducer and connects the camera to the microfocuser
on the C11 telescope.
Beginning astro-imagers, myself included, expect our first imaging session
to be a "Super Terrific Happy Hour" full of Super Galactic images. Obtaining quality images rarely happens by
accident. Next we will discuss proper DSLR camera settings and a few techniques that will have you one step closer to successful
imaging. Basic DSLR Camera Settings for Astrophotography You will find the settings menus like the one above within the camera program and/or
the camera controls on the camera body. Consult the manual supplied with the camera for more detailed information.
Instead of listing the many parameters and settings here, you can find them in this article by Jerry Lodriguss. For the most part these settings are very accurate, however the ISO speed settings
and White Balance settings are not set in stone. I have imaged deep space targets at ISO 200. The generic White Balance
set to daylight is not always appropriate. Experiment and see what works for you. Are We Ready To Image Yet? There are just a few more basics to discuss. Equipment:
DSLR or Film Camera, Web Cam ( telescope required) You can take the list from here, for the sky's the limit. But with this basic equipment
list you can begin to capture our own Luna Moon or the wonders of the universe from your own backyard.
Polar Alignment If you will be using your camera with a telescope, then not enough can be said about polar
alignment. Having a good polar alignment or drift alignment (the most accurate method) is a must for successful astro imaging. A
rough polar alignment will suffice for viewing but not for astro imaging. Also important is to make sure your mount or
tripod is level. |
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Focusing Without critical focus your images will be a bit of a disappointment. Focusing
the DSLR camera especially when attached to the telescope can be a challenge and a true test of patience. Focusing by eye
thru the viewfinder is awkward to say the least, making you wish your body moved like Gumby. Right
angle attachments can make things somewhat easier but the view of faint objects has now become more dim. A Hartmann Mask is a nice simple tool that can assist you in achieving critical focus and are easy
to make. Many of today's DSLR cameras have an Auto Focus feature and when used with auto focus lenses can achieve some amount
of critical focus. Knife edge focusers and focusing on Diffraction Spikes work for some astro imagers.
Using a Flip Mirror in your imaging train
may help also, however I'm not a big fan. While there are many other methods of achieving focus, the two I use most
often at SVObservatory is focusing software and a Slider Microfocus. I use Images Plus, DSLR Focus or DSLRlite focusing
software. Most focusing software take the many variables of critical focus into account including the effects
of temperature on the imaging train. On the downside there is the added cost, the learning curve of the software
and portability as focusing software requires a PC next to the scope. What about Flats, Darks, Lights, Noise Reduction, Color Space, RAW, Mirror Lock and
so many other terms. Do we need to know all of these? Well of course, but for basic astrophototography we will focus(
did you get that) on a few for now.
Raw Mode or JPEG, which one should I choose? JPEG is easier for beginners. No worrying
with dark and light frames, flats or too many parameters. If you have too many hot pixels or noise on your images, just resample
your image to 25% of the original image. RAW mode is the best format to image in and allows the greatest manipulation
of your images during processing. RAW mode saves the data recorded by the CMOS or CCD sensor in a high bit format. Noise reduction
technology reduces the amount of errant thermal signal. Most DSLRs have in-camera long exposure noise reduction built in.
Using in-camera noise reduction will increase your imaging time due to the fact that the camera will be taking dark frames
automatically after each image, but it is one less thing for the beginning astro imager to worry with. Mirror Lock, if you
have it on your camera, great, if not it is not the end of the world. Normally for long exposures on a good mount it is not
needed.
The way I usually go about imaging at SVObservatory is to begin with taking flats sometime
around dusk when the sky is evenly illuminated. I also use a light box panel and even the dome wall. Taking flats help you detect any contaminates
on the sensor or optics that can be subtracted later as well as determining the amount of vignetting or dark edges. After
imaging I will take all my dark frames. I average the dark frames from my shortest and longest exposure
times. Take your darks in odd quantities like 3, 6, 9 etc. When combining later during processing the software picks
up on the odd numbered choices. *Quick Tip, for anyone who wants to do their own darks and their cameras are not controlled
by software, just leave the lens cap on, turn in-camera noise reduction off. Be sure to cover the view finder window,
you could get errrant light leaking onto the sensor and take a minimum of 3 dark frames. Do this under the same condtions
and at the same length of your longest image, i.e. 5 minute image, take a 5 minute dark frame.*
For deep-sky imaging I usually image in sets or subs, taking multiple frames of varying
exposure times. For example: 30: 30 second subs, 3: 4 minute subs etc. Don't be afraid to mix it up either.
I have occasionally taken long single exposures of 5 minutes or more. Taking multiple exposures however will increase
your success and later during processing you will stack and align these frames using software such as Registax. Image Processing Now you have your images and you think you are done.....
Next you have to process those hard earned bits of data into something you can show off
to friends, family or maybe here at MidAtlantic Astronomy.
Registax, Gimp or IRIS are all good programs and they are all free. I use Registax, K3CCDTOOLS and
IRIS for processing images at SVObservatory.
The many facets of image processing are too much for me to cover here. But you
will find a decent tutorial on the web site of fellow astronomer David Nash from the U.K. Mr. Nash takes you thru the
steps of processing an image he captured using K3CCDTOOLS and Gimp. Any questions? Why of course you do. The journey has just begun..... SVO |
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