Your search keyword '"Marijn Franx"' showing total 3 results

1. MUSE: a second-generation integral-field spectrograph for the VLT

Author

Thierry Contini, C. M. Carollo, Florence Laurent, Antonio Manescau, Martin M. Roth, E. Popow, Andreas Kelz, L. Capoani, P. Caillier, Christian Monstein, Lutz Wisotzki, N. Champavert, C. Koehler, Stefan Dreizler, P. Boehm, Roland Bacon, Peter M. Weilbacher, Simon J. Lilly, Cyril Petit, P. T. de Zeeuw, Aurélien Jarno, Joop Schaye, Julien Devriendt, D. Hofmann, Stefan Stroebele, Jean-Pierre Dubois, Magali Loupias, Luca Pasquini, G. Soucail, Roland Reiss, R. Pello, Eric Emsellem, J. Gerssen, Herve Wozniak, G. Gallou, Matthias Steinmetz, L. Parès, Svend M. Bauer, S. Brau-Nogué, Harald Nicklas, Richard M. McDermid, Bernard Delabre, Didier Boudon, Emmanuel Pecontal, Eric Daguisé, M. Dupieux, Johan Kosmalski, Andreas Quirrenbach, Edgard Renault, J. P. Dupin, Wolfram Kollatschny, Marijn Franx, B. Guiderdoni, J.-P. Picat, T. Hahn, Arlette Pécontal-Rousset, J.-L. Lizon, Remko Stuik, and Pierre Ferruit

Subjects

Very Large Telescope, Pixel, Galactic astronomy, Computer science, business.industry, Astronomy, Multi Unit Spectroscopic Explorer, Data cube, Integral field spectrograph, Optics, Observatory, Guide star, business, Adaptive optics, Spectrograph

Abstract

The Multi Unit Spectroscopic Explorer (MUSE) is a second-generation instrument in development for the Very Large Telescope (VLT) of the European Southern Observatory (ESO), due to begin operation in 2011/12. MUSE will be an extremely powerful integral-field spectrograph fed by a new multiple-laser adaptive optics system on the VLT. In its usual operating mode, MUSE will, in a single observation, produce a 3-dimensional data cube consisting of 90,000 R 3000 spectra, each covering a full spectral octave (480-930 nm), and fully sampling a contiguous 1×1 arcmin2 field with 0.2×0.2 arcsec2 apertures. A high-resolution mode will increase the spatial sampling to 0.025 arcsec per pixel. MUSE is built around a novel arrangement of 24 identical spectrographs (each comparable to a 1st generation VLT instrument), which are fed by a set of 24 precision image slicers. MUSE is designed for stability, with only 2 modes, and virtually no moving parts, allowing very long exposures to be accumulated. Together with high throughput, this ensures that MUSE will have extreme sensitivity for observing faint objects. We overview the technical and scientific aspects of MUSE, highlighting the key challenges for dealing with the unprecedented quantity and complexity of the data, and the integration with the VLT adaptive optics facility (AOF) - a key development on the path to extremely large telescopes (ELTs). © 2008 Springer-Verlag Berlin Heidelberg.

Published

2003

2. Overview of the Advanced Camera for Surveys on-orbit performance

Author

John P. Blakeslee, Randy A. Kimble, Marco Sirianni, John Krist, Edward S. Cheng, Paul D. Feldman, William B. Sparks, Rychard Bouwens, Marc D. Rafal, Robert A. Woodruff, David A. Golimowski, Michael Lesser, Marc Postman, Narcisco Benitez, Caryl Gronwall, Robert A. Brown, Garth D. Illingworth, Tom Broadhurst, F. Bartko, William Jon McCann, Mark Clampin, Richard L. White, Zlatan Tsvetanov, Holland C. Ford, George K. Miley, André R. Martel, Dan Magee, George F. Hartig, Douglas Campbell, Paul Volmer, Gerhardt R. Meurer, Christopher J. Burrows, Pamela C. Sullivan, Marijn Franx, Hien D. Tran, and Piero Rosati

Subjects

Physics, business.industry, Orbital mechanics, Encircled energy, Advanced Camera for Surveys, law.invention, Grism, Wavelength, Optics, law, Calibration, business, Coronagraph, Dark current

Abstract

We present an overview of the ACS on-orbit performance based on the calibration observations taken during the first three months of ACS operations. The ACS meets or exceeds all of its important performance specifications. The WFC and HRC FWHM and 50% encircled energy diameters at 555 nm are 0.088" and 0.14", and 0.050" and 0.10". The average rms WFC and HRC read noises are 5.0 e- and 4.7 e-. The WFC and HRC average dark currents are ~ 7.5 and ~ 9.1 e-/pixel/hour at their operating temperatures of - 76°C and - 80°C. The SBC + HST throughput is 0.0476 and 0.0292 through the F125LP and F150LP filters. The lower than expected SBC operating temperature of 15 to 27°C gives a dark current of 0.038 e-/pix/hour. The SBC just misses its image specification with an observed 50% encircled energy diameter of 0.24" at 121.6 nm. The ACS HRC coronagraph provides a 6 to 16 direct reduction of a stellar PSF, and a ~1000 to ~9000 PSF-subtracted reduction, depending on the size of the coronagraphic spot and the wavelength. The ACS grism has a position dependent dispersion with an average value of 3.95 nm/pixel. The average resolution λ/Δλ for stellar sources is 65, 87, and 78 at wavelengths of 594 nm, 802 nm, and 978 nm.

Published

2003

3. Advanced camera for surveys

Author

Tom Broadhurst, F. Bartko, Michael Lesser, Marc Postman, Pierre Y. Bely, David A. Golimowski, Mark Clampin, Marc D. Rafal, Holland C. Ford, Pamela C. Sullivan, Tom Lajeunesse, Richard L. White, Paul D. Feldman, Paul Volmer, William B. Sparks, Christopher J. Burrows, Marijn Franx, George F. Hartig, James H. Crocker, Piero Rosati, Zlatan Tsvetanov, Randy A. Kimble, Edward S. Cheng, Garth D. Illingworth, and George H. Miley

Subjects

Physics, Astrophysics::Instrumentation and Methods for Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Polarizer, Advanced Camera for Surveys, Third generation, law.invention, Band-pass filter, law, Hubble space telescope, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Near ultraviolet, Optical filter, Astrophysics::Galaxy Astrophysics, Remote sensing

Abstract

The Advanced Camera for Surveys (ACS) is a third generation instrument for the Hubble Space Telescope (HST). It is currently planned for installation in HST during the fourth servicing mission in Summer 2001. The ACS will have three cameras.

Published

2000