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adaptiveoptics.org provides news and information for the world-wide adaptive optics community. Contact: webmaster@adaptiveoptics.org. News
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| Garching bei München, Germany – June 18, 2009: The next generation of instruments for ground-based telescopes took a leap forward with the development of a new ultra-fast camera that can take 1500 finely exposed images per second even when observing extremely faint objects. The first 240×240 | ||||
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pixel images with the world's fastest high precision faint light camera
were obtained through a collaborative effort between
ESO
and three French laboratories from the French
Centre National de la Recherche Scientifique/Institut National des Sciences de l'Univers
(CNRS/INSU).
Cameras such as this are key components of the next generation of
adaptive optics instruments of Europe's ground-based astronomy flagship facility,
the
ESO
Very Large Telescope (VLT).
“The performance of this breakthrough camera is without an equivalent anywhere in the world. The camera will enable great leaps forward in many areas of the study of the Universe,” says Norbert Hubin, head of the Adaptive Optics department at ESO. OCam will be part of the second-generation VLT instrument SPHERE. To be installed in 2011, SPHERE will take images of giant exoplanets orbiting nearby stars. |
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A fast camera such as this is needed as an essential component
for the modern adaptive optics instruments used on the largest ground-based telescopes.
Telescopes on the ground suffer from the blurring effect induced by atmospheric turbulence.
This turbulence causes the stars to twinkle in a way that delights poets,
but frustrates astronomers, since it blurs the finest details of the images.
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Adaptive optics techniques overcome this major drawback,
so that ground-based telescopes can produce images that are as sharp as if taken from space.
Adaptive optics is based on real-time corrections computed
from images obtained by a special camera working at very high speeds.
Nowadays, this means many hundreds of times each second.
The new generation instruments require these corrections to be done at an even higher rate,
more than one thousand times a second,
and this is where OCam is essential.
“The quality of the adaptive optics correction strongly depends on the speed of the camera and on its sensitivity,” says Philippe Feautrier from the LAOG, France, who coordinated the whole project. “But these are a priori contradictory requirements, as in general the faster a camera is, the less sensitive it is.” This is why cameras normally used for very high frame-rate movies require extremely powerful illumination, which is of course not an option for astronomical cameras. |
The CCD220 detector at the core of the OCam camera has 240×240 pixels
and has a readout noise ten times smaller than detectors in current use,
making it ideal for the faint light camera systems to be used
on the second generation of Very Large Telescope instruments.
It was developed by the British manufacturer e2v technologies.
Image: P. Balard / INSU-CNRS / ESO
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OCam and its CCD220 detector, developed by the British manufacturer
e2v technologies,
solve this dilemma, by being not only the fastest available, but also very sensitive,
making a significant jump in performance for such cameras.
Because of imperfect operation of any physical electronic devices,
a CCD camera suffers from so-called readout noise.
OCam has a readout noise ten times smaller than the detectors currently used on the
VLT,
making it much more sensitive and able to take pictures of the faintest of sources.
“Thanks to this technology, all the new generation instruments of ESO’s Very Large Telescope will be able to produce the best possible images, with an unequalled sharpness,” declares Jean-Luc Gach, from the Laboratoire d’Astrophysique de Marseille, France, who led the team that built the camera. “Plans are now underway to develop the adaptive optics detectors required for ESO’s planned 42-metre European Extremely Large Telescope, together with our research partners and the industry,” says Hubin. Using sensitive detectors developed in the UK, with a control system developed in France, with German and Spanish participation, OCam is truly an outcome of a European collaboration that will be widely used and commercially produced. About the CCD220 and OCam:
OCam and the CCD220 are the result of five years work,
financed by the European Commission,
ESO
and
CNRS-INSU,
within the
OPTICON
project of the
6th Research and Development Framework Programme
of the European Union.
The development of the CCD220, supervised by
ESO,
was undertaken by the British company
e2v technologies,
one of the world leaders in the manufacture of scientific detectors.
The corresponding
OPTICON
activity was led by the
Laboratoire d'Astrophysique de Grenoble,
France.
The OCam camera was built by a team of French engineers from the
Laboratoire d'Astrophysique de Marseille,
the
Laboratoire d’Astrophysique de Grenoble
and the
Observatoire de Haute Provence.
In order to secure the continuation of this successful project a new
OPTICON
project started in June 2009 as part of the
7th Research and Development Framework Programme
of the European Union with the same partners,
with the aim of developing a detector and camera with
even more powerful functionality for use with an artificial laser star.
This development is necessary to ensure the image quality of the future 42-metre
European Extremely Large Telescope.
About ESO:
ESO,
the
European Southern Observatory,
is the foremost intergovernmental astronomy organisation in Europe
and the world’s most productive astronomical observatory.
It is supported by 14 countries:
Austria, Belgium, the Czech Republic, Denmark, France, Finland, Germany, Italy,
the Netherlands, Portugal, Spain, Sweden, Switzerland and the United Kingdom.
ESO
carries out an ambitious programme focused on the design, construction
and operation of powerful ground-based observing facilities enabling astronomers
to make important scientific discoveries.
ESO
also plays a leading role in promoting and organising cooperation in astronomical research.
ESO
operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor.
At Paranal,
ESO
operates the
Very Large Telescope,
the world’s most advanced visible-light astronomical observatory.
ESO
is the European partner of a revolutionary astronomical telescope
ALMA,
the largest astronomical project in existence.
ESO
is currently planning a 42-metre
European Extremely Large
optical/near-infrared Telescope,
the
E-ELT, which will become “the world’s biggest eye on the sky”.
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Full Press Release
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© 2009 |
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