23 research outputs found
Raman LIDARs for the atmospheric calibrationalong the line-of-sight of CTA
The Cherenkov Telescope Array (CTA) is the next generation ground-based observatory forgamma-ray astronomy at very-high energies. Employing more than 100 Imaging AtmosphericCherenkov Telescopes in the northern and southern hemispheres, it was designed to reach un-precedented sensitivity and energy resolution. Understanding and correcting for systematic bi-ases on the absolute energy scale and instrument response functions will be a crucial issue forthe performance of CTA. The LUPM group and the Spanish/Italian/Slovenian collaboration arecurrently building two Raman LIDAR prototypes for the online atmospheric calibration alongthe line-of-sight of the CTA. Requirements for such a solution include the ability to characterizeaerosol extinction at two wavelengths to distances of 30 km with an accuracy better than 5%,within time scales of about a minute, steering capabilities and close interaction with the CTAarray control and data acquisition system as well as other auxiliary instruments. Our Raman LI-DARs have design features that make them different from those used in atmospheric science andare characterized by large collecting mirrors (âŒ2.5 m2), liquid light-guides that collect the light atthe focal plane and transport it to the readout system, reduced acquisition time and highly preciseRaman spectrometers. The Raman LIDARs will participate in a cross-calibration and character-ization campaign of the atmosphere at the CTA North site at La Palma, together with other sitecharacterization instruments. After a one-year test period there, an in-depth evaluation of the so-lutions adopted by the two projects will lead to a final Raman LIDAR design proposal for bothCTA sites
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Status of the Dark Energy Survey Camera (DECam) Project
The Dark Energy Survey Collaboration has completed construction of the Dark Energy Camera (DECam), a 3 square degree, 570 Megapixel CCD camera which will be mounted on the Blanco 4-meter telescope at CTIO. DECam will be used to perform the 5000 sq. deg. Dark Energy Survey with 30% of the telescope time over a 5 year period. During the remainder of the time, and after the survey, DECam will be available as a community instrument. All components of DECam have been shipped to Chile and post-shipping checkout finished in Jan. 2012. Installation is in progress. A summary of lessons learned and an update of the performance of DECam and the status of the DECam installation and commissioning will be presented
Raman LIDARs for the atmospheric calibration along the line-of-sight of the Cherenkov Telescope Array
International audienceThe Cherenkov Telescope Array (CTA) is the next generation ground-based observatory for gamma-ray astronomy at very-high energies. Employing more than 100 (north and south sites) Imaging Atmospheric Cherenkov Telescopes in the northern and southern hemispheres, it was designed to reach unprecedented sensitivity and energy resolution. Understanding and correcting for systematic biases on the absolute energy scale and instrument response functions will be a cru- cial issue for the performance of CTA. The Montpellier group and the Spanish/Italian/Slovenian collaboration are currently building two Raman LIDAR prototypes for the online atmospheric cal- ibration along the line-of-sight of the CTA. Requirements for such a solution include the ability to characterize aerosol extinction at two wavelengths to distances up to 30 km with an accuracy better than 5%, within exposure time scales of about a minute, steering capabilities and close interaction with the CTA array control and data acquisition system as well as other auxiliary in- struments. Our Raman LIDARs have design features that make them different from those used in atmospheric science and are characterized by large collecting mirrors (âŒ2.5 m2), liquid light- guides that collect the light at the focal plane and transport it to the readout system, reduced acquisition time and highly precise Raman spectrometers. The Raman LIDARs will participate in a cross-calibration and characterization campaign of the atmosphere at the CTA North site at La Palma, together with other site characterization instruments. After a one-year test period there, an in-depth evaluation of the solutions adopted by the two projects will lead to a final Raman LIDAR design proposal for both CTA sites
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System Architecture of the Dark Energy Survey Camera Readout Electronics
The Dark Energy Survey makes use of a new camera, the Dark Energy Camera (DECam). DECam will be installed in the Blanco 4M telescope at Cerro Tololo Inter-American Observatory (CTIO). DECam is presently under construction and is expected to be ready for observations in the fall of 2011. The focal plane will make use of 62 2Kx4K and 12 2kx2k fully depleted Charge-Coupled Devices (CCDs) for guiding, alignment and focus. This paper will describe design considerations of the system; including, the entire signal path used to read out the CCDs, the development of a custom crate and backplane, the overall grounding scheme and early results of system tests
Raman LIDARs for the atmospheric calibration along the line-of-sight of CTA
The Cherenkov Telescope Array (CTA) is the next generation ground based
observatory for gamma ray astronomy at very high energies. Employing more than
100 Imaging Atmospheric Cherenkov Telescopes in the northern and southern
hemispheres, it was designed to reach unprecedented sensitivity and energy
resolution. Understanding and correcting for systematic biases on the absolute
energy scale and instrument response functions will be a crucial issue for the
performance of CTA. The LUPM group and the Spanish/Italian/Slovenian
collaboration are currently building two Raman LIDAR prototypes for the online
atmospheric calibration along the line of sight of the CTA. Requirements for
such a solution include the ability to characterize aerosol extinction at two
wavelengths to distances of 30 km with an accuracy better than 5%, within time
scales of about a minute, steering capabilities and close interaction with the
CTA array control and data acquisition system as well as other auxiliary
instruments. Our Raman LIDARs have design features that make them different
from those used in atmospheric science and are characterized by large
collecting mirrors (2.5 m2), liquid light guides that collect the light at the
focal plane and transport it to the readout system, reduced acquisition time
and highly precise Raman spectrometers. The Raman LIDARs will participate in a
cross calibration and characterization campaign of the atmosphere at the CTA
North site at La Palma, together with other site characterization instruments.
After a one year test period there, an in depth evaluation of the solutions
adopted by the two projects will lead to a final Raman LIDAR design proposal
for both CTA sites