Dr. Pablo Gustavo Redondo Caicoya Profile

Dr. Pablo Gustavo Redondo Caicoya

SPIE Involvement:

Author

Publications (19)

Proceedings Article | 26 August 2024 Poster + Paper

Innovative solution for upgrading commercial bearings for use in cryogenic instruments

Alejandro Luján, Elvio Hernández, Pablo Fuerte, Pablo Redondo, Alberto Hernández-González

Proceedings Volume 13100, 1310073 (2024) https://doi.org/10.1117/12.3018038

KEYWORDS: Cryogenics, Equipment, Design, Liquids, Manufacturing, Metals, Vacuum, Nitrogen, Infrared radiation, Data modeling

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Proceedings Article | 18 July 2014 Paper

The optical AIV of the infrared multi-slit spectrophotometer for GTC, EMIR

Roberto López, Patricia Fernández, Angel Mato, Pablo Redondo

Proceedings Volume 9151, 91513M (2014) https://doi.org/10.1117/12.2056076

KEYWORDS: Optical benches, Telescopes, Optical alignment, Sensors, Mirrors, Content addressable memory, Cryogenics, Optics manufacturing, Optical fabrication, Cameras

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Proceedings Article | 10 July 2014 Paper

CARMENES instrument overview

A. Quirrenbach, P. Amado, J. Caballero, R. Mundt, A. Reiners, I. Ribas, W. Seifert, M. Abril, J. Aceituno, F. J. Alonso-Floriano, M. Ammler-von Eiff, R. Antona Jiménez, H. Anwand-Heerwart, M. Azzaro, F. Bauer, D. Barrado, S. Becerril, V. J. Béjar, D. Benítez, Z. Berdiñas, M. Cárdenas, E. Casal, A. Claret, J. Colomé, M. Cortés-Contreras, S. Czesla, M. Doellinger, S. Dreizler, C. Feiz, M. Fernández, D. Galadí, M. Gálvez-Ortiz, A. García-Piquer, M. García-Vargas, R. Garrido, L. Gesa, V. Gómez Galera, E. González Álvarez, J. González Hernández, U. Grözinger, J. Guàrdia, E. Guenther, E. de Guindos, J. Gutiérrez-Soto, H.-J. Hagen, A. Hatzes, P. Hauschildt, J. Helmling, T. Henning, D. Hermann, L. Hernández Castaño, E. Herrero, D. Hidalgo, G. Holgado, A. Huber, K. Huber, S. Jeffers, V. Joergens, E. de Juan, M. Kehr, R. Klein, M. Kürster, A. Lamert, S. Lalitha, W. Laun, U. Lemke, R. Lenzen, Mauro López del Fresno, B. López Martí, J. López-Santiago, U. Mall, H. Mandel, E. Martín, S. Martín-Ruiz, H. Martínez-Rodríguez, C. Marvin, R. Mathar, E. Mirabet, D. Montes, R. Morales Muñoz, A. Moya, V. Naranjo, A. Ofir, R. Oreiro, E. Pallé, J. Panduro, V.-M. Passegger, A. Pérez-Calpena, D. Pérez Medialdea, M. Perger, M. Pluto, A. Ramón, R. Rebolo, P. Redondo, S. Reffert, S. Reinhardt, P. Rhode, H.-W. Rix, F. Rodler, E. Rodríguez, C. Rodríguez-López, E. Rodríguez-Pérez, R.-R. Rohloff, A. Rosich, E. Sánchez-Blanco, M. Sánchez Carrasco, J. Sanz-Forcada, L. Sarmiento, S. Schäfer, J. Schiller, C. Schmidt, J. H. M. M. Schmitt, E. Solano, O. Stahl, C. Storz, J. Stürmer, J. Suárez, R. Ulbrich, G. Veredas, K. Wagner, J. Winkler, M. Zapatero Osorio, M. Zechmeister, F. Abellán de Paco, G. Anglada-Escudé, C. del Burgo, A. Klutsch, J. Lizon, M. López-Morales, J. Morales, M. A. C. Perryman, S. Tulloch, W. Xu

Proceedings Volume 9147, 91471F (2014) https://doi.org/10.1117/12.2056453

KEYWORDS: Spectrographs, Optical fibers, Lamps, Stars, Telescopes, Calibration, Planets, Sensors, Visible radiation, Exoplanets

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This paper gives an overview of the CARMENES instrument and of the survey that will be carried out with it during the first years of operation. CARMENES (Calar Alto high-Resolution search for M dwarfs with Exoearths with Near-infrared and optical Echelle Spectrographs) is a next-generation radial-velocity instrument under construction for the 3.5m telescope at the Calar Alto Observatory by a consortium of eleven Spanish and German institutions. The scientific goal of the project is conducting a 600-night exoplanet survey targeting ~ 300 M dwarfs with the completed instrument. The CARMENES instrument consists of two separate echelle spectrographs covering the wavelength range from 0.55 to 1.7 μm at a spectral resolution of R = 82,000, fed by fibers from the Cassegrain focus of the telescope. The spectrographs are housed in vacuum tanks providing the temperature-stabilized environments necessary to enable a 1 m/s radial velocity precision employing a simultaneous calibration with an emission-line lamp or with a Fabry-Perot etalon. For mid-M to late-M spectral types, the wavelength range around 1.0 μm (Y band) is the most important wavelength region for radial velocity work. Therefore, the efficiency of CARMENES has been optimized in this range. The CARMENES instrument consists of two spectrographs, one equipped with a 4k x 4k pixel CCD for the range 0.55 - 1.05 μm, and one with two 2k x 2k pixel HgCdTe detectors for the range from 0.95 - 1.7μm. Each spectrograph will be coupled to the 3.5m telescope with two optical fibers, one for the target, and one for calibration light. The front end contains a dichroic beam splitter and an atmospheric dispersion corrector, to feed the light into the fibers leading to the spectrographs. Guiding is performed with a separate camera; on-axis as well as off-axis guiding modes are implemented. Fibers with octagonal cross-section are employed to ensure good stability of the output in the presence of residual guiding errors. The fibers are continually actuated to reduce modal noise. The spectrographs are mounted on benches inside vacuum tanks located in the coud´e laboratory of the 3.5m dome. Each vacuum tank is equipped with a temperature stabilization system capable of keeping the temperature constant to within ±0.01°C over 24 hours. The visible-light spectrograph will be operated near room temperature, while the near-IR spectrograph will be cooled to ~ 140 K. The CARMENES instrument passed its final design review in February 2013. The MAIV phase is currently ongoing. First tests at the telescope are scheduled for early 2015. Completion of the full instrument is planned for the fall of 2015. At least 600 useable nights have been allocated at the Calar Alto 3.5m Telescope for the CARMENES survey in the time frame until 2018. A data base of M stars (dubbed CARMENCITA) has been compiled from which the CARMENES sample can be selected. CARMENCITA contains information on all relevant properties of the potential targets. Dedicated imaging, photometric, and spectroscopic observations are underway to provide crucial data on these stars that are not available in the literature.

Proceedings Article | 8 July 2014 Paper

Results of the verification of the NIR MOS EMIR

F. Garzón, N. Castro-Rodríguez, M. Insausti, L. López-Martín, Peter Hammersley, M. Barreto, P. Fernández, E. Joven, P. López, A. Mato, H. Moreno, M. Núñez, J. Patrón, J. Rasilla, P. Redondo, J. Rosich, S. Pascual, R. Grange

Proceedings Volume 9147, 91470U (2014) https://doi.org/10.1117/12.2054804

KEYWORDS: Sensors, Imaging spectroscopy, Telescopes, Astronomical imaging, Multiplexers, Infrared sensors, Near infrared, Molybdenum, Image filtering, Spectroscopy

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EMIR is one of the first common user instruments for the GTC, the 10 meter telescope operating at the Roque de los Muchachos Observatory (La Palma, Canary Islands, Spain). EMIR is being built by a Consortium of Spanish and French institutes led by the Instituto de Astrofísica de Canarias (IAC). EMIR is primarily designed to be operated as a MOS in the K band, but offers a wide range of observing modes, including imaging and spectroscopy, both long slit and multiobject, in the wavelength range 0.9 to 2.5 μm. This contribution reports on the results achieved so far during the verification phase at the IAC prior to its shipment to the GTC for being commissioned, which is due by mid 2015. After a long period of design and fabrication, EMIR finally entered into its integration phase by mid 2013. Soon after this, the verification phase at the IAC was initiated aimed at configuring and tuning the EMIR functions, mostly the instrument control system, which includes a sophisticated on line data reduction pipeline, and demonstrating the fulfillment of the top level requirements. We have designed an ambitious verification plan structured along the three kind of detectors at hand: the MUX and the engineering and scientific grade arrays. The EMIR subsystems are being integrated as they are needed for the purposes of the verification plan. In the first stage, using the MUX, the full optical system, but with a single dispersive element out of the three which form the EMIR suite, the two large wheels mounting the filters and the pseudo-grisms, plus the detector translation unit holding the MUX, were mounted. This stage was mainly devoted to learn about the capabilities of the instrument, define different settings for its basic operation modes and test the accuracy, repeatability and reliability of the mechanisms. In the second stage, using the engineering Hawaii2 FPA, the full set of pseudo-grisms and band filters are mounted, which means that the instrument is fully assembled except for the cold slit unit, a robotic reconfigurable multislit mask system capable of forming multislit pattern of 55 different slitlets in the EMIR focal plane. This paper will briefly describe the principal units and features of the EMIR instrument as the main results of the verification performed so far are discussed. The development and fabrication of EMIR is funded by GRANTECAN and the Plan Nacional de Astronomía y Astrofísica (National Plan for Astronomy and Astrophysics, Spain).

Proceedings Article | 6 July 2006 Paper

SMART-MOS: a NIR imager-MOS for the ELT

Francisco Garzón, Eli Atad-Ettedgui, Peter Hammersley, David Henry, Callum Norrie, Pablo Redondo, Frederic Zamkotsian

Proceedings Volume 6273, 62731S (2006) https://doi.org/10.1117/12.671675

KEYWORDS: Telescopes, Sensors, Molybdenum, Diffraction, Cameras, Spectral resolution, Micromirrors, Image quality, Spectroscopes, Near infrared

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Proceedings Article | 29 June 2006 Paper

Development of configurable slit unit for GTC-EMIR

M. Teuwen, H. Janssen, R. Geurink, P. Redondo, J. Díaz-Garcia

Proceedings Volume 6269, 62694B (2006) https://doi.org/10.1117/12.671793

KEYWORDS: Actuators, Sensors, Cryogenics, Prototyping, Ceramics, Nitrogen, Microcontrollers, Signal processing, Spectroscopes, Capacitance

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Proceedings Article | 28 June 2006 Paper

Status of the EMIR mechanical system

V. Sánchez, S. Barrera, S. Becerril, S. Correa, J. Pérez, P. Redondo, R. Restrepo, P. Saavedra, F. Tenegi, J. Patrón, F. Garzón

Proceedings Volume 6269, 626955 (2006) https://doi.org/10.1117/12.671331

KEYWORDS: Prototyping, Sensors, Collimators, Optical benches, Interfaces, Current controlled current source, Cryogenics, Cooling systems, Virtual colonoscopy, Aluminum

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Proceedings Article | 28 June 2006 Paper

EMIR: the GTC NIR multi-object imager-spectrograph

F. Garzón, D. Abreu, S. Barrera, S. Becerril, L. Cairós, J. Díaz, A. Fragoso, F. Gago, R. Grange, C. González, P. López, J. Patrón, J. Pérez, J. Rasilla, P. Redondo, R. Restrepo, P. Saavedra, V. Sánchez, F. Tenegi, M. Vallbé

Proceedings Volume 6269, 626918 (2006) https://doi.org/10.1117/12.671302

KEYWORDS: Imaging spectroscopy, Sensors, Telescopes, Astronomical imaging, Control systems, Near infrared, Astronomy, Cryogenics, Software development, Spectroscopes

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Proceedings Article | 30 August 2005 Paper

Test results: EMIR optomechanics

S. Barrera, C. Gonzalez, A. Manescau, D. Abreu, S. Becerril, S. Correa, A. Fragoso, J. Perez, P. Redondo, R. Restrepo, P. Saavedra, V. Sanchez, F. Tenegi, F. Garzon, J. Patron

Proceedings Volume 5877, 58770Y (2005) https://doi.org/10.1117/12.614899

KEYWORDS: Prototyping, Silica, Aluminum, Cryogenics, Temperature metrology, Collimators, Optomechanical design, Spectrographs, Telescopes, Optical mounts

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