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Laser-guided adaptive optics are all the rage for telescopes nowadays. A laser guide star helps the software that processes telescope data figure out how to compensate for the shimmer of Earth’s atmosphere. And besides, it can make for a cool “Star Wars” special effect, as seen in this composite image of the European Southern Observatory’s Very Large Telescope in Chile.
ESO astronomer Yuri Beletsky set up the picture while his colleagues were pointing the guide-star system at the dense core of our own Milky Way galaxy, hanging in the clear skies above Chile's Atacama Desert. The Very Large Telescope is actually four separate telescope units, working together in an array. This particular unit is named Yepun, which is the word for the star Sirius in the language of the region's indigenous people.
Yepun's laser guide system energizes sodium atoms at an altitude of 56 miles (90 kilometers). The telescope system's software uses that artificial "star" to determine how light is blurred as it shines down through the atmosphere. Those readings can in turn be factored into astronomical observations, to add sharpness to what otherwise would be blurry images. This is the process that's known as adaptive optics, and it's being used more and more to produce images from ground-based telescopes that can rival the Hubble Space Telescope's sharpest stunners.
In an e-mail, Beletsky explains how he blended two frames to create the picture you see here.
"The image was taken with a Canon 5D Mark II camera + Canon 15/2.8 Fisheye lens. The image is actually a mosaic of two frames, where each one was taken with 30-second exposure. Due to the very small focal length (15 mm) the stars are not trailed (because of Earth's rotation — the longer the focal length, the shorter should the exposure in order to avoid trailing). Then those images were carefully aligned in data reduction software.
"Now, regarding the colors. At night, human eyes are not sensitive to colors. Therefore, in reality, the Milky Way looks colorless (while on the image it does have a color). In contrast, the laser beam is bright enough to see its color with our eyes. The only issue is that on the image the laser beam looks really bright (due to long exposure time), while in reality it has a very deep and dim orange color."
Beletsky's image is the current "Picture of the Week" from the ESO, as well as Monday's "Astronomy Picture of the Day" at NASA and today's top candidate for enlasenation at Phil Plait's Bad Astronomy blog (and that's good!). For still more stunning views of the cosmos, check out the latest installment of "Month in Space Pictures," our long-running series of slideshows. And for stunning views, period, graze through our Photoblog to your heart's content.
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Leave a Comment:
WOW! This is a spectacular image!! There are many reasons that I love the photo, but the main reason I enjoy this photo soo much is because I've always wanted to have a picture that basically says "this is the center" of the galaxy. And this photo does it beautifully!
Adaptive optics is such a great technique and technology, it's great to see all the new types of tricks today's astronomers are using.
Wonderful article and a supremely great photo!
Adaptive optics were also used in Star Wars (the technology, not the movies) to focus ground-based high-powered laser arrays on various low-altitude targets using orbital reflector arrays. This required correction for two atmospheric transits (up and down). The instantiation described in the article here represents "de-weaponization" of the technology developed over 10 years ago... Swords into plowshares, anyone?
It's amazing, what they have done in the last thirty years since my Astronomy classes
oh, god... it really HAS been that long...
when i was in high school they were still teaching the univers was the milky way...
sad, but true...
apod and pow? nice picture, deserves the recognition. Guide lasers are becoming more and more common, of all things I have found a couple of DIY's and yes, I want one too!!....but I am hesitant, astronomers, and others, are always complaining of light pollution, I for one recommend thier sparse use. For instance the long exposures above could very well look the same if the laser was only on for a microsecond, sparsly pulsed, or on continously (not that I am suggesting the duty cycle of that laser is 100%, god forbid)...after all, they have few aviators to contend with at their location but here on the east coast I could see it get to a point where pilots would have to where polarizers and wavelength selective glasses to look down for positional land-marks...after all, we would not want them pointing lasers down at us to find thier position. Still I want one, I will try to make the cheap one first from the daisy bb gun 12.00 laser pointer off the "toy" shelves (as soon as I find it)...and use a momentary contact switch on it for the guide.....If any of you are trying the DIY route, research the web for info on defective cheap green laser pointers to avoid bouncing a lot of UV around. Kudus on the equipment list, wonder if he used reg stacker for the image alignment bit.