Your search keyword '"Kalyan Radhakrishnan"' showing total 10 results

1. Design and development of the SOXS calibration unit

Author

Anna Brucalassi, Sergio Campana, P. Schipani, Maximilian Stritzinger, Seppo Mattila, José Antonio Araiza-Duran, Andrea Baruffolo, Jari Kotilainen, Stephen Smartt, Fabrizio Vitali, Rosario Di Benedetto, Hanindyo Kuncarayakti, Massimo Della Valle, Rachel Bruch, Marco Landoni, Hector Ventura, Ricardo Zanmar Sanchez, O. Hershko, J. Achrén, D. R. Young, Rosario Cosentino, Matteo Aliverti, Salvatore Scuderi, Riccardo Claudi, Giuliano Pignata, Kalyan Radhakrishnan, Michael Rappaport, Matteo Munari, Sergio D'Orsi, Francesco D'Alessio, Mirko Colapietro, Matteo Genoni, Marco Riva, Davide Ricci, Avishay Gal-Yam, Bernardo Salasnich, Enrico Cappellaro, Adam Rubin, Marco De Pascale, P. D'Avanzo, Giulio Capasso, Federico Biondi, Gianluca Li Causi, Iair Arcavi, Marcos Hernandez, Sagi Ben-Ami, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Subjects

Physics, Point source, business.industry, FOS: Physical sciences, Linear stage, 01 natural sciences, law.invention, 010309 optics, Telescope, Transients, Integrating sphere, Optics, law, 0103 physical sciences, Calibration, Pinhole (optics), Transient (oscillation), business, Astrophysics - Instrumentation and Methods for Astrophysics, 010303 astronomy & astrophysics, Spectrograph, Instrumentation and Methods for Astrophysics (astro-ph.IM), Spectroscopy

Abstract

SOXS is a new spectrograph for the New Technology Telescope (NTT), optimized for transient and variable objects, covering a wide wavelength range from 350 to 2000 nm. SOXS is equipped with a calibration unit that will be used to remove the instrument signatures and to provide wavelength calibration to the data. The calibration unit will employ seven calibration lamps: a quartz-tungsten-halogen and a deuterium lamp for the flat-field correction, a ThAr lamp and four pencil-style rare-gas lamps for the wavelength calibration. The light from the calibration lamps is injected into the spectrograph mimicking the f/11 input beam of the NTT, by using an integrating sphere and a custom doublet. The oversized illumination patch covers the length of the spectrograph slit homogeneously, with $< 1\%$ variation. The optics also supports the second mode of the unit, the star-simulator mode that emulates a point source by utilizing a pinhole mask. Switching between the direct illumination and pinhole modes is performed by a linear stage. A safety interlock switches off the main power when the lamp box cover is removed, preventing accidental UV exposure to the service personnel. All power supplies and control modules are located in an electronic rack at a distance from the telescope platform. In this presentation we describe the optical, mechanical, and electrical designs of the SOXS calibration unit, and report the status of development in which the unit is currently in the test and verification stage., 7 pages, 7 figures

Published

2020

2. The development status of the NIR Arm of the new SoXS instrument at the ESO/NTT telescope

Author

Sergio Campana, R. Zanmar Sanchez, Giuliano Pignata, Matteo Genoni, P. Schipani, Daniela Fantinel, Michael Rappaport, Seppo Mattila, Adam Rubin, Fabrizio Vitali, E. Ventura, P. D'Avanzo, Rosario Cosentino, José Antonio Araiza-Duran, Salvatore Scuderi, Sagi Ben-Ami, Marco Riva, Matteo Munari, M. Della Valle, Iair Arcavi, Jari Kotilainen, M. P. De Pascale, Maximilian Stritzinger, Sergio D'Orsi, Riccardo Claudi, Andrea Baruffolo, Davide Ricci, D. R. Young, Mirko Colapietro, Andrea Bianco, Enrico Cappellaro, M. Hernandez, R. Di Benedetto, Giulio Capasso, Federico Biondi, Stephen Smartt, Rachel Bruch, Hanindyo Kuncarayakti, Matteo Aliverti, G. Li Causi, Avishay Gal-Yam, Francesco D'Alessio, Bernardo Salasnich, Marco Landoni, Kalyan Radhakrishnan, O. Hershko, A. Brucalassi, J. Achrén, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Subjects

Physics, NTT, Cryogenics, Spectrograph, Transient, business.industry, Near infrared, Near-infrared spectroscopy, law.invention, SOXS, Telescope, Optics, law, Advanced phase, H2RG, business

Abstract

We present here the development status of the NIR spectrograph of the Son Of X-Shooter (SOXS) instrument, for the ESO/NTT telescope at La Silla (Chile). SOXS is a R~4,500 mean resolution spectrograph, with a simultaneously coverage from about 0.35 to 2.00 μm. It will be mounted at the Nasmyth focus of the NTT. The two UV-VIS-NIR wavelength ranges will be covered by two separated arms. The NIR spectrograph is a fully cryogenic echelle-dispersed spectrograph, working in the range 0.80-2.00 μm, equipped with a Hawaii H2RG IR array from Teledyne. The whole spectrograph will be cooled down to about 150 K (but the array at 40 K), to lower the thermal background, and equipped with a thermal filter to block any thermal radiation above 2.0 μm. In this work, we will show the advanced phase of integration of the NIR spectrograph.

Published

2020

3. MAVIS adaptive optics module optical design

Author

Valentina Viotto, Demetrio Magrin, Guido Agapito, Simone Di Filippo, Thierry Fusco, Matteo Aliverti, Benoit Neichel, Kalyan Radhakrishnan, Bernard Delabre, Francois Rigaut, Marco Bonaglia, Maria Bergomi, Nicholas Herrald, Davide Greggio, Luca Marafatto, Stefan Ströbele, Enrico Pinna, and Christian Schwab

Subjects

Wavefront, Scientific instrument, Very Large Telescope, Computer science, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Field of view, law.invention, Telescope, Optics, law, Angular resolution, Adaptive optics, business, Spectrograph

Abstract

The MCAO Assisted Visible Imager and Spectrograph (MAVIS), is a new instrument for ESO’s Very Large Telescope. The instrument will be installed at the Nasmyth focus of the UT4 telescope and is comprised of an imager and a spectrograph which will take advantage of the unprecedented angular resolution and sky coverage provided by LGS assisted MCAO correction at visible wavelengths. The Adaptive Optics Module (AOM) is the core engine of MAVIS, devoted to multi-conjugate wavefront sensing and correction, and designed to deliver a 30×30 arcsec2 corrected field of view to the scientific instruments. In this paper we focus on the optical design of the AOM, which has been optimized to perform several tasks including field de-rotation, atmospheric dispersion correction, and adaptive optics closed-loop operations. To maximize sky coverage, the system is designed to deliver a 2 arcmin field of view for the selection of up to 3 NGS for measurement of tip-tilt. The AOM module also includes a multiple LGS WFS for high-order wavefront measurements and two post-focal DMs for wide field turbulence compensation. The proposed design is the result of a trade-off study in which particular care has been devoted to satisfy performance and operational requirements, as well as modularity. We present here a complete description of the selected optical configuration with a summary of the performance analyses.

Published

2020

4. Development status of the SOXS spectrograph for the ESO-NTT telescope

Author

Avishay Gal-Yam, Federico Biondi, Bernardo Salasnich, G. Li Causi, Matteo Accardo, J. A. Araiza-Duran, M. Hernandez, O. Hershko, Riccardo Claudi, Seppo Mattila, Matteo Munari, Francesco D'Alessio, Leander Mehrgan, Mirko Colapietro, Rosario Cosentino, Michael Rappaport, M. Della Valle, M. De Pascale, Maximilian Stritzinger, Adam Rubin, Fabrizio Vitali, E. Pompei, Stephen Smartt, Davide Ricci, Marco Landoni, H. U. Käufl, Sagi Ben-Ami, Kalyan Radhakrishnan, Iair Arcavi, D. R. Young, Jari Kotilainen, P. D'Avanzo, M. Schöller, Salvatore Scuderi, S. Savarese, Giuliano Pignata, P. Schipani, Andrea Baruffolo, Rachel Bruch, Sergio D'Orsi, Enrico Cappellaro, R. Di Benedetto, Giulio Capasso, Marco Riva, A. Brucalassi, J. Achrén, Sergio Campana, Hanindyo Kuncarayakti, Matteo Aliverti, Luca Pasquini, R. Zanmar Sanchez, Matteo Genoni, Hector Ventura, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Subjects

Spectrograph, Computer science, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, New Technology Telescope, Exoplanet, law.invention, Transients, Telescope, Observatory, law, Target of opportunity, Astrophysics::Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Blazar, Instrumentation and Methods for Astrophysics (astro-ph.IM), Instrumentation, Astrophysics::Galaxy Astrophysics, Minor planet

Abstract

SOXS (Son Of X-Shooter) is a single object spectrograph, characterized by offering a wide simultaneous spectral coverage from U- to H-band, built by an international consortium for the 3.6-m ESO New Technology Telescope at the La Silla Observatory, in the Southern part of the Chilean Atacama Desert. The consortium is focussed on a clear scientific goal: the spectrograph will observe all kind of transient and variable sources discovered by different surveys with a highly flexible schedule, updated daily, based on the Target of Opportunity concept. It will provide a key spectroscopic partner to any kind of imaging survey, becoming one of the premier transient follow-up instruments in the Southern hemisphere. SOXS will study a mixture of transients encompassing all distance scales and branches of astronomy, including fast alerts (such as gamma-ray bursts and gravitational waves), mid-term alerts (such as supernovae and X-ray transients), and fixed-time events (such as the close-by passage of a minor planet or exoplanets). It will also have the scope to observe active galactic nuclei and blazars, tidal disruption events, fast radio bursts, and more. Besides of the consortium programs on guaranteed time, the instrument is offered to the ESO community for any kind of astrophysical target. The project has passed the Final Design Review and is currently in manufacturing and integration phase. This paper describes the development status of the project., Proc SPIE Volume 11447, Ground-based and Airborne Instrumentation for Astronomy VIII, 1144709,2020

Published

2020

5. MAVIS: The adaptive optics module feasibility study

Author

Maria Bergomi, Annino Vaccarella, Olivier Beltramo-Martin, Stefan Ströbele, Simonetta Chinellato, Cedric Plantet, Thierry Fusco, Lorenzo Busoni, Matteo Aliverti, Jacopo Farinato, Carmelo Arcidiacono, Daniele Vassallo, Damien Gratadour, Jesse Cranney, Elena Carolo, Marco Bonaglia, Francois Rigaut, Enrico Pinna, Davide Greggio, Luca Marafatto, Simone Esposito, Pierre Haguenauer, Roberto Ragazzoni, Kalyan Radhakrishnan, Guido Agapito, David Brodrick, Demetrio Magrin, Gaston Gausachs, Valentina Viotto, Benoit Neichel, ITA, FRA, DEU, and AUS

Subjects

Scheme (programming language), Scientific instrument, Computer science, Phase (waves), law.invention, Telescope, law, Control system, Electronic engineering, Upstream (networking), Secondary mirror, Adaptive optics, computer, computer.programming_language

Abstract

The Adaptive Optics Module of MAVIS is a self-contained MCAO module, which delivers a corrected FoV to the postfocal scientific instruments, in the visible. The module aims to exploit the full potential of the ESO VLT UT4 Adaptive Optics Facility, which is composed of the high spatial frequency deformable secondary mirror and the laser guide stars launching and control systems. During the MAVIS Phase A, we evaluated, with the support of simulations and analysis at different levels, the main terms of the error budgets aiming at estimating the realistic AOM performance. After introducing the current opto-mechanical design and AO scheme of the AOM, we here present the standard wavefront error budget and the other budgets, including manufacturing, alignment of the module, thermal behavior and noncommon path aberrations, together with the contribution of the upstream telescope system.

Published

2020

6. SOXS End-to-End simulator: development and applications for pipeline design

Author

Sagi Ben-Ami, Giorgio Pariani, M. Hernandez Diaz, A. Brucalassi, G. Li Causi, Jari Kotilainen, Hanindyo Kuncarayakti, Matteo Aliverti, Sergio Campana, J. A. Araiza-Duran, Iair Arcavi, O. Hershko, Andrea Baruffolo, Seppo Mattila, J. Achrén, Marco Landoni, P. D'Avanzo, Stephen Smartt, M. De Pascale, Rosario Cosentino, Kalyan Radhakrishnan, Federico Biondi, Marco Riva, Maximilian Stritzinger, M. Della Valle, Rachel Bruch, Avishay Gal-Yam, Sergio D'Orsi, D. R. Young, Fabrizio Vitali, Francesco D'Alessio, Bernardo Salasnich, Giuliano Pignata, Adam Rubin, Davide Ricci, R. Di Benedetto, Giulio Capasso, Enrico Cappellaro, P. Schipani, H. Perez Ventura, Matteo Munari, R. Zanmar Sanchez, Matteo Genoni, Michael Rappaport, Riccardo Claudi, Mirko Colapietro, Salvatore Scuderi, Angeli, George Z., and Dierickx, Philippe

Subjects

Flexibility (engineering), Computer science, Pipeline (computing), Detector, Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Echelle cross-dispersed spectrograph, Modularity, law.invention, Telescope, SOXS, End-to-End simulations, law, Calibration, ESO-NTT telescope, Astrophysics::Solar and Stellar Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Spectrograph, Instrumentation and Methods for Astrophysics (astro-ph.IM), Simulation, Astrophysics::Galaxy Astrophysics

Abstract

We present the development of the End-to-End simulator for the SOXS instrument at the ESO-NTT 3.5-m telescope. SOXS will be a spectroscopic facility, made by two arms high efficiency spectrographs, able to cover the spectral range 350-2000 nm with resolving power R˜4500. The E2E model allows to simulate the propagation of photons starting from the scientific target of interest up to the detectors. The outputs of the simulator are synthetic frames, which will be mainly exploited for optimizing the pipeline development and possibly assisting for proper alignment and integration phases in laboratory and at the telescope. In this paper, we will detail the architecture of the simulator and the computational model, which are strongly characterized by modularity and flexibility. Synthetic spectral formats, related to different seeing and observing conditions, and calibration frames to be ingested by the pipeline are also presented.

Published

2020

7. Development status of the UV-VIS detector system of SOXS for the ESO-NTT telescope

Author

Marco De Pascale, Matteo Accardo, Adam Rubin, Stephen Smartt, Sergio Campana, Rosario Di Benedetto, Leander Mehrgan, Hanindyo Kuncarayakti, José Antonio Araiza-Duran, D. R. Young, Matteo Aliverti, Marco Landoni, Fabrizio Vitali, Sergio D'Orsi, Giulio Capasso, Maximilian Stritzinger, Sagi Ben-Ami, Rosario Cosentino, Iair Arcavi, Michael Rappaport, Ricardo Zanmar Sanchez, Kalyan Radhakrishnan, Anna Brucalassi, Jari Kotilainen, P. D'Avanzo, Marcos Hernandez, O. Hershko, Josh Hopgood, Seppo Mattila, Federico Biondi, Matteo Munari, Gianluca Li Causi, Avishay Gal-Yam, Rachel Bruch, Bernardo Salasnich, P. Schipani, Massimo Della Valle, Andrea Baruffolo, Davide Ricci, Derek Ives, Enrico Cappellaro, Francesco D'Alessio, J. Achrén, Giuliano Pignata, Marco Riva, Hector Ventura, Matteo Genoni, Riccardo Claudi, Mirko Colapietro, Salvatore Scuderi, ITA, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Subjects

Physics, Cryostat, Spectrograph, business.industry, Controller (computing), Detector, Programmable logic controller, FOS: Physical sciences, UV-VIS, law.invention, Telescope, Optics, law, Control system, Electronics, Astrophysics - Instrumentation and Methods for Astrophysics, business, Instrumentation and Methods for Astrophysics (astro-ph.IM), CCD

Abstract

SOXS will be the new spectroscopic facility for the ESO NTT telescope able to cover the optical and NIR bands by using two different arms: the UV-VIS (350-850 nm), and the NIR (800-2000 nm). In this article, we describe the development status of the visible camera cryostat, the architecture of the acquisition system and the progress in the electronic design. The UV-VIS detector system is based on a CCD detector 44-82 from e2v, a custom detector head, coupled with the ESO continuous flow cryostats (CFC), a custom cooling system, based on a Programmable Logic Controller (PLC), and the New General Controller (NGC) developed by ESO. This paper outlines the development status of the system, describes the design of the different parts that make up the UV-VIS arm and is accompanied by a series of information describing the SOXS design solutions in the mechanics and in the electronics parts. The first tests of the detector system with the UV-VIS camera will be shown., 10 pager, 13 figures

Published

2020

8. Final integration and alignment of LINC-NIRVANA

Author

Thomas Bertram, Peter Bizenberger, Kalyan Radhakrishnan, Lars Mohr, Tom Herbst, J. Moreno-Ventas, Harald Baumeister, Luca Marafatto, Frank Kittmann, ITA, and DEU

Subjects

Physics, business.industry, Collimator, Field of view, Large Binocular Telescope, 02 engineering and technology, Wavefront sensor, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, 010309 optics, Telescope, Interferometry, Optical path, law, 0103 physical sciences, 0210 nano-technology, Adaptive optics, business, Simulation, Computer hardware

Abstract

The LBT (Large Binocular Telescope), located at about 3200m on Mount Graham (Tucson, Arizona) is an innovative project undertaken by institutions from Europe and USA. LINC-NIRVANA is an instrument which provides MCAO (Multi-Conjugate Adaptive Optics) and interferometry, combining the light from the two 8.4m telescopes coherently. This configuration offers 23m-baseline optical resolution and the sensitivity of a 12m mirror, with a 2 arc-minute diffraction limited field of view. The integration, alignment and testing of such a big instrument requires a well-organized choreography and AIV planning which has been developed in a hierarchical way. The instrument is divided in largely independent systems, and all of them consist of various subsystems. Every subsystem integration ends with a verification test and an acceptance procedure. When a certain number of systems are finished and accepted, the instrument AIV phase starts. This hierarchical approach allows testing at early stages with simple setups. The philosophy is to have internally aligned subsystems to be integrated in the instrument optical path, and extrapolate to finally align the instrument to the Gregorian bent foci of the telescope. The alignment plan was successfully executed in Heidelberg at MPIA facilities, and now the instrument is being re-integrated at the LBT over a series of 11 campaigns along the year 2016. After its commissioning, the instrument will offer MCAO sensing with the LBT telescope. The interferometric mode will be implemented in a future update of the instrument. This paper focuses on the alignment done in the clean room at the LBT facilities for the collimator, camera, and High-layer Wavefront Sensor (HWS) during March and April 2016. It also summarizes the previous work done in preparation for shipping and arrival of the instrument to the telescope. Results are presented for every step, and a final section outlines the future work to be done in next runs until its final commissioning....

Published

2016

9. Optical integration and verification of LINC-NIRVANA

Author

Davide Greggio, J. Moreno-Ventas, Thomas Bertram, Peter Bizenberger, Florian Briegel, Luca Marafatto, Kalyan Radhakrishnan, Frank Kittmann, H. Schray, Harald Baumeister, and Lars Mohr

Subjects

Fizeau interferometer, Instrumentation, integration, LINC-NIRVANA, law.invention, Telescope, LBT, Optics, law, Electronic, Optical and Magnetic Materials, Electrical and Electronic Engineering, AIV, alignment, interferometry, Applied Mathematics, Electronic, Optical and Magnetic Materials, Condensed Matter Physics, Optical path length, Wavefront, Physics, business.industry, Large Binocular Telescope, Mount, Interferometry, business, Computer hardware

Abstract

The LBT (Large Binocular Telescope) located in Mount Graham near Tucson/Arizona at an altitude of about 3200m, is an innovative project being undertaken by institutions from Europe and USA. The structure of the telescope incorporates two 8.4-meter telescopes on a 14.4 center-to-center common mount. This configuration provides the equivalent collecting area of a 12m single-dish telescope. LINC-NIRVANA is an instrument to combine the light from both LBT primary mirrors in an imaging Fizeau interferometer. Many requirements must be fulfilled in order to get a good interferometric combination of the beams, being among the most important plane wavefronts, parallel input beams, homotheticity and zero optical path difference (OPD) required for interferometry. The philosophy is to have an internally aligned instrument first, and then align the telescope to match the instrument. The sum of different subsystems leads to a quite ambitious system, which requires a well-defined strategy for alignment and testing. In this paper I introduce and describe the followed strategy, as well as the different solutions, procedures and tools used during integration. Results are presented at every step.

Published

2014

10. Pathfinder first light: alignment, calibration, and commissioning of the LINC-NIRVANA ground-layer adaptive optics subsystem

Author

Roberto Ragazzoni, Kalyan Radhakrishnan, Derek Kopon, Ralph Hofferbert, Jürgen Berwein, Luca Marafatto, Lars Mohr, Maria Bergomi, Florian Briegel, Carmelo Arcidiacono, Martin Kürster, Thomas Bertram, Tom Herbst, Al Conrad, Valentina Viotto, Jacopo Farinato, Frank Kittmann, and Harald Baumeister

Subjects

Wavefront, business.industry, Computer science, FOS: Physical sciences, First light, Wavefront sensor, Pupil, law.invention, Telescope, Optical axis, Interferometry, Optics, Pathfinder, law, Guide star, business, Adaptive optics, Secondary mirror, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)

Abstract

We present descriptions of the alignment and calibration tests of the Pathfinder, which achieved first light during our 2013 commissioning campaign at the LBT. The full LINC-NIRVANA instrument is a Fizeau interferometric imager with fringe tracking and 2-layer natural guide star multi-conjugate adaptive optics (MCAO) systems on each eye of the LBT. The MCAO correction for each side is achieved using a ground layer wavefront sensor that drives the LBT adaptive secondary mirror and a mid-high layer wavefront sensor that drives a Xinetics 349 actuator DM conjugated to an altitude of 7.1 km. When the LINC-NIRVANA MCAO system is commissioned, it will be one of only two such systems on an 8-meter telescope and the only such system in the northern hemisphere. In order to mitigate risk, we take a modular approach to commissioning by decoupling and testing the LINC-NIRVANA subsystems individually. The Pathfinder is the ground-layer wavefront sensor for the DX eye of the LBT. It uses 12 pyramid wavefront sensors to optically co-add light from natural guide stars in order to make four pupil images that sense ground layer turbulence. Pathfinder is now the first LINC-NIRVANA subsystem to be fully integrated with the telescope and commissioned on sky. Our 2013 commissioning campaign consisted of 7 runs at the LBT with the tasks of assembly, integration and communication with the LBT telescope control system, alignment to the telescope optical axis, off-sky closed loop AO calibration, and finally closed loop on-sky AO. We present the programmatics of this campaign, along with the novel designs of our alignment scheme and our off-sky calibration test, which lead to the Pathfinder’s first on-sky closed loop images.

Published

2014