Dr. Markus Plattner Profile

Dr. Markus Plattner

Project Manager, System Engineer, Designer at Max-Planck-Institut für extraterrestrische Physik

SPIE Involvement:

Author

Publications (29)

SPIE Journal Paper | 6 April 2023 Open Access

Open Access

Design and acoustic tests of the ATHENA WFI filter wheel assembly development model towards TRL5

Szymon Polak, Jacek Musiał, Robert Pietrzak, Adam Sikorski, Mateusz Dumin, Adam Dacko, Mirosiław Rataj, Tomasz Barciński, Tadeusz Kamisiński, Adam Pilch, Wojciech Binek, Grzegorz Woźniak, Monika Zuchniak, Agata Różańska, Norbert Meidinger, Marcus Plattner, Jintin Frank, Rafael Strecker, Andreas von Kienlin, Marco Barbera, Fabio D’Anca, Daniele Gulli, Ugo Lo Cicero, Nicola Montinaro, Giancarlo Parodi, Enrico Bozzo, Stephane Paltani

JATIS, Vol. 9, Issue 02, 024002, (April 2023) https://doi.org/10.1117/12.10.1117/1.JATIS.9.2.024002

KEYWORDS: Tunable filters, Design and modelling, Acoustics, Scanning probe lithography, Optical filters, Baffles, Equipment, Breadboards, Vibration, Sensors

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Proceedings Article | 13 December 2020 Poster + Paper

Poster + Paper

Structural analysis of Athena WFI Large Detector Array

Jintin Frank, Christian Beitler, Daniel Pietschner, Rafael Strecker, Valeria Antonelli, Markus Plattner, Norbert Meidinger

Proceedings Volume 11444, 114443W (2020) https://doi.org/10.1117/12.2560668

KEYWORDS: Structural design, Space operations, Imaging systems, High energy astrophysics, Galaxy groups and clusters, X-ray imaging, Imaging spectroscopy, Spectroscopes, Cameras, Interfaces

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Proceedings Article | 13 December 2020 Paper

Paper

Development status of the wide field imager instrument for Athena

Norbert Meidinger, Sebastian Albrecht, Christian Beitler, Michael Bonholzer, Valentin Emberger, Jintin Frank, Andreas Lederhuber, Johannes Müller-Seidlitz, Kirpal Nandra, Julian Oser, Sabine Ott, Markus Plattner, Rafael Strecker

Proceedings Volume 11444, 114440T (2020) https://doi.org/10.1117/12.2560507

KEYWORDS: Sensors, Imaging systems, Imaging spectroscopy, Silicon, Cameras, X-ray imaging, X-rays, Spectroscopes, Cryogenics, Image resolution

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The Wide Field Imager (WFI) instrument for ESA’s next large X-ray mission Athena is designed for imaging and spectroscopy over a large field of view, and high count rate observations up to and beyond 1 Crab source intensity. The other focal plane instrument, the cryogenic X-IFU camera, is designed for high-spectral resolution imaging. Both cameras share alternately a mirror system based on silicon pore optics with a focal length of 12 m and unprecedented large effective area of about 1.4 m² at 1keV. The WFI instrument employs DEPFET active pixel sensors, which are fully depleted, back-illuminated silicon devices of 450 μm thickness. The detectors provide high quantum efficiency and state-of-the art energy resolution in the 0.2 keV to 15 keV energy range with extremely fast readout speeds compared to previous generations of Si detectors for X-ray astronomy. The focal plane comprises a Large Detector Array (LDA) and a Fast Detector (FD). The LDA comprises about 1 million pixels and a time resolution in full frame mode of 5 ms. The FD optimized for bright point source observations permits a time resolution of even 80 μs with about 4000 pixels. Both detectors have a pixel size of 130 μm × 130 μm, providing oversampling of the PSF by a factor >2. The instrument development is in phase B of the project after a successful Preliminary Requirements Review and endorsement of the both instrument consortia by ESA. Critical technology developments for the WFI focal plane camera are currently investigated and finally experimentally verified with breadboard models: the detector function and performance, the real-time capability of onboard event pre-processing and the integrity of the large-area and ultra-thin optical blocking filter after environmental tests. Flight-size sensors have been produced and a flight-like detector assembly has been developed. First test results of a flight-size detector are expected in near future. Based on the thermal design and model for the camera head (CH), thermal interface requirements have been estimated.

Proceedings Article | 13 December 2020 Poster + Presentation + Paper

Poster + Presentation + Paper

On-the-fly data pipeline for image processing enabling real-time persistence correction

Christopher Mandla, Muhammad Subhan Hameed, Viseslav Aracic, Sabine Ott, Markus Plattner, Andreas Herkersdorf, Thomas Wild

Proceedings Volume 11454, 114542V (2020) https://doi.org/10.1117/12.2560641

KEYWORDS: Sensors, Data processing, Image processing, Infrared sensors, CMOS sensors, Infrared detectors, Real time image processing, Data modeling, Telescopes, Analog electronics

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Proceedings Article | 13 December 2020 Poster + Paper

Poster + Paper

Technology development of Athena WFI frame processor electronics and verification of its real-time performance

Markus Plattner, Sebastian Albrecht, Olaf Hälker, Andreas Lederhuber, Norbert Meidinger, Sabine Ott, Samuel Pliego, Jonas Reiffers, Thomas Schanz, Jan-Christoph Tenzer

Proceedings Volume 11444, 1144447 (2020) https://doi.org/10.1117/12.2562200

KEYWORDS: Electronics, Sensors, Field programmable gate arrays, Failure analysis, Imaging systems, X-ray detectors, X-rays, Observatories, Field effect transistors, Data processing

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Proceedings Article | 9 September 2019 Paper

Paper

Status of the wide field imager instrument for Athena

Norbert Meidinger, Sebastian Albrecht, Michael Bonholzer, Johannes Müller-Seidlitz, Kirpal Nandra, Sabine Ott, Markus Plattner, Wolfgang Treberspurg

Proceedings Volume 11118, 111180Y (2019) https://doi.org/10.1117/12.2528109

KEYWORDS: Sensors, Field effect transistors, Optical filters, Cameras, Imaging systems, X-rays, Interfaces, Silicon, Photons

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Proceedings Article | 30 July 2018 Open Access

Open Access

Paper

The MICADO first light imager for the ELT: overview, operation, simulation

R. Davies, J. Alves, Y. Clénet, F. Lang-Bardl, H. Nicklas, J.-U. Pott, R. Ragazzoni, E. Tolstoy, P. Amico, H. Anwand-Heerwart, S. Barboza, L. Barl, P. Baudoz, R. Bender, N. Bezawada, P. Bizenberger, W. Boland, P. Bonifacio, B. Borgo, T. Buey, F. Chapron, F. Chemla, M. Cohen, O. Czoske, V. Déo, K. Disseau, S. Dreizler, O. Dupuis, M. Fabricius, R. Falomo, P. Fedou, N. Förster Schreiber, V. Garrel, N. Geis, H. Gemperlein, E. Gendron, R. Genzel, S. Gillessen, M. Glück, F. Grupp, M. Hartl, M. Häuser, H.-J. Hess, R. Hofferbert, U. Hopp, V. Hörmann, Z. Hubert, E. Huby, J.-M. Huet, V. Hutterer, D. Ives, A. Janssen, W. Jellema, W. Kausch, F. Kerber, H. Kravcar, B. Le Ruyet, K. Leschinski, C. Mandla, M. Manhart, D. Massari, S. Mei, F. Merlin, L. Mohr, A. Monna, N. Muench, F. Müller, G. Musters, R. Navarro, U. Neumann, N. Neumayer, J. Niebsch, M. Plattner, N. Przybilla, S. Rabien, R. Ramlau, J. Ramos, S. Ramsay, P. Rhode, A. Richter, J. Richter, H.-W. Rix, G. Rodeghiero, R.-R. Rohloff, M. Rosensteiner, G. Rousset, J. Schlichter, J. Schubert, A. Sevin, R. Stuik, E. Sturm, J. Thomas, N. Tromp, G. Verdoes-Kleijn, F. Vidal, R. Wagner, M. Wegner, W. Zeilinger, J. Ziegleder, B. Ziegler, G. Zins

Proceedings Volume 10702, 107021S (2018) https://doi.org/10.1117/12.2311483

KEYWORDS: Adaptive optics, Distortion, Planets

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Proceedings Article | 16 July 2018 Open Access

Open Access

Paper

ERIS: revitalising an adaptive optics instrument for the VLT

R. Davies, S. Esposito, H.-M. Schmid, W. Taylor, G. Agapito, A. Agudo Berbel, A. Baruffolo, V. Biliotti, B. Biller, M. Black, A. Boehle, B. Briguglio, A. Buron, L. Carbonaro, A. Cortes, G. Cresci, M. Deysenroth, A. Di Cianno, G. Di Rico, D. Doelman, M. Dolci, R. Dorn, F. Eisenhauer, D. Fantinel, D. Ferruzzi, H. Feuchtgruber, N. Förster Schreiber, X. Gao, H. Gemperlein, R. Genzel, E. George, S. Gillessen, C. Giordano, A. Glauser, A. Glindemann, P. Grani, M. Hartl, J. Heijmans, D. Henry, H. Huber, M. Kasper, C. Keller, M. Kenworthy, J. Kühn, H. Kuntschner, J. Lightfoot, D. Lunney, M. MacIntosh, F. Mannucci, S. March, M. Neeser, P. Patapis, D. Pearson, M. Plattner, A. Puglisi, S. Quanz, C. Rau, A. Riccardi, B. Salasnich, J. Schubert, F. Snik, E. Sturm, A. Valentini, C. Waring, E. Wiezorrek, M. Xompero

Proceedings Volume 10702, 1070209 (2018) https://doi.org/10.1117/12.2311480

KEYWORDS: Adaptive optics, Calibration, Mirrors, Galactic astronomy, Wavefront sensors, Control systems, L band

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Proceedings Article | 9 July 2018 Open Access

Open Access

Presentation + Paper

Learnings from the use of fiber optics in GRAVITY

Magdalena Lippa, Stefan Gillessen, Nicolas Blind, Yitping Kok, Karine Perraut, Laurent Jocou, Frank Eisenhauer, Oliver Pfuhl, Marcus Haug, Stefan Kellner, Frank Haußmann, Markus Plattner, Christian Rau, Oliver Hans, Ekkehard Wieprecht, Thomas Ott, Erich Wiezorrek, Eckhard Sturm, Alexander Buron, Sylvestre Lacour, Reinhard Genzel, Guy Perrin, Wolfgang Brandner, Christian Straubmeier, Antonio Amorim

Proceedings Volume 10701, 107011Y (2018) https://doi.org/10.1117/12.2312477

KEYWORDS: Metrology, Connectors, Polarization, Backscatter, Fiber lasers, Raman scattering, Laser metrology, Luminescence, Fiber optics, Glasses

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Proceedings Article | 6 July 2018 Paper

Paper

Development of the Wide Field Imager instrument for ATHENA

Norbert Meidinger, Kirpal Nandra, Markus Plattner

Proceedings Volume 10699, 106991F (2018) https://doi.org/10.1117/12.2310141

KEYWORDS: Sensors, Field effect transistors, Optical filters, Electronics, Photons, X-rays, Mirrors, Transistors, Imaging systems, Silicon

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The Wide Field Imager (WFI) instrument for ESA’s next large X-ray mission Athena is designed for imaging and spectroscopy over a large field of view, and high count rate observations up to and beyond 1 Crab source intensity. The other focal plane instrument, the cryogenic X-IFU camera, is designed for high spectral resolution imaging. Both cameras share alternately a mirror system based on silicon pore optics with a focal length of 12 m and unprecedented large effective area. The here described WFI instrument employs DEPFET active pixel sensors together with readout and control ASICs tailored for this project. The WFI DEPFETs are 450 μm thick, fully depleted, back-illuminated silicon active pixel sensors. They provide high quantum efficiency over the 0.2 keV to 15 keV range with state-of-the art spectral resolution and extremely high time resolution compared to previous generations of silicon detectors for Xray astronomy. The focal plane comprises a 'Large Detector Array' (LDA) with over 1 million pixels of 130 um · 130 um size, permitting oversampling of the PSF by a factor >2. The LDA spans a 40 amin · 40 amin large field of view and is complemented by a small 'Fast Detector' (FD) optimized for high count rate applications. In the present phase A of the project, the conceptual design of WFI is defined and the necessary development of technology is performed. Critical subsystems with respect to the development are the detector function and performance, the real-time capability of the on-board signal processing chain, and the ultra-thin large-area optical blocking filter, which has to withstand the acoustic noise loads during launch. Various prototype detectors of smaller size than the LDA detector have been developed and successfully tested for this purpose. The results determine the preliminary design of the detector system for the upcoming engineering model of the camera. With a breadboard of the signal processing chain, the necessary steps for signal correction and filtering are presently tested in particular to evaluate the time needed for this. The modular design of the breadboard is based on the Microsemi RTG4 FPGA as key component for the frame processor. An on-board data reduction is necessary because of the high frame rate and large number of pixels per frame. Otherwise, the signal rate would exceed the available telemetry rate to ground. Tests in acoustic noise facilities, complemented by vibration tests, shall prove that the 17 cm · 17 cm large and 0.18 μm thin optical blocking filter survives the satellite launch without a vacuum enclosure. The filter foil is supported by a mesh made of stainless steel and protected by a filter wheel design that minimizes the loads to the optical blocking filter inside the assembly. Furthermore, the overall design of the instrument and its various subsystems has been further developed. Tradeoffs have been performed to obtain an architecture of the instrument compliant with the requirements to the instrument, especially with respect to energy, time and spatial resolution, quantum efficiency, instrumental background as well as technical budgets like mass, volume, power consumption and radiator area. After completion of the current breadboarding phase, an engineering model of the WFI instrument will be developed and tested. According to the WFI model philosophy, a structural and thermal model as well as a qualification model will be developed and tested before the flight model shall be launched in 2031 to the Lagrangian point L2 in 1.5 million km distance from Earth. The mission lifetime is planned to be four years with a possible five-year extension.

Proceedings Article | 21 November 2017 Open Access

Open Access

Paper

A versatile fibre optic sensor interrogation system for the Ariane Launcher based on an electro-optically tuneable laser diode

M. Plattner, F. Hirth, M. Müller, L. Hoffmann, T. Buck, A. Koch

Proceedings Volume 10566, 105661D (2017) https://doi.org/10.1117/12.2308218

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Proceedings Article | 20 November 2017 Open Access

Open Access

Paper

Development of fiber optic sensing interrogators for launchers

M. Plattner, T. Buck, B. Eder, A. Reutlinger, I. McKenzie

Proceedings Volume 10565, 1056518 (2017) https://doi.org/10.1117/12.2309165

KEYWORDS: Sensors, Fiber Bragg gratings, Fiber optics sensors, Astronomical imaging, Digital signal processing, Temperature metrology, Aerospace engineering, Semiconductor lasers, Signal processing, Space telescopes

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We present our work about the development of two complementary interrogation schemes based on fiber optic sensing for the use of structural and thermal monitoring of Ariane launchers. The advantages of fiber optic sensing in particular light-weight, immunity to electromagnetic interferences and the possibility of sensor distribution along optical fibers are driving factors for utilization of this technology in space crafts [1]. The edge-filter (EF) and scanning-laser (SL) interrogators for determination of the mean wavelength of fiber Bragg grating (FBG) sensors have been implemented as two separate demonstrators. Within this paper we describe the functional principles of both interrogators. Furthermore we present test results where the developed systems have been used for readout of FBG sensors which are implemented in an Ariane structural demonstrator during thermal, thermal-vacuum and vibration tests. Functionality of both systems is demonstrated and their potential for further development towards space qualified systems is shown.

Since the performance characteristics of the two systems are different from each other, they are dedicated for different sensing applications on a launcher. The EF sensor interrogator provides a sample rate of 20 kHz at a number of 4 connected sensors and supports parallel readout and aliasing free operation. Therefore it is best suited for high priority measurement. Structural monitoring which requires the acquisition of real time sensor information in order to support control of the launcher is one operation area for a future EF system. The SL interrogator provides an overall measurement rate of 1 kHz at a number of 24 connected sensors distributed on three sensor channels. It can be adapted to any sensors that have design wavelengths lying within the output spectrum of the laser diode. Furthermore the number of overall sensors to be read out with this system can be adapted easily. Thermal mapping of satellite panels is one possible future application for the SL interrogator.

Proceedings Article | 20 November 2017 Open Access

Open Access

Paper

Design of a fiber-optic interrogator module for telecommunication satellites

Philipp Putzer, Alexander Koch, Markus Plattner, Andreas Hurni, Markus Manhart

Proceedings Volume 10564, 105641F (2017) https://doi.org/10.1117/12.2309040

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Proceedings Article | 29 August 2017 Presentation + Paper

Presentation + Paper

The Wide Field Imager instrument for Athena

Norbert Meidinger, Marco Barbera, Valentin Emberger, Maria Fürmetz, Markus Manhart, Johannes Müller-Seidlitz, Kirpal Nandra, Markus Plattner, Arne Rau, Wolfgang Treberspurg

Proceedings Volume 10397, 103970V (2017) https://doi.org/10.1117/12.2271844

KEYWORDS: Sensors, Imaging systems, Cameras, X-rays, Field effect transistors, Image resolution, Active sensors, Electronics, Optical filters, X-ray detectors, X-ray telescopes

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Proceedings Article | 9 August 2016 Open Access

Open Access

Paper

MICADO: first light imager for the E-ELT

R. Davies, J. Schubert, M. Hartl, J. Alves, Y. Clénet, F. Lang-Bardl, H. Nicklas, J.-U. Pott, R. Ragazzoni, E. Tolstoy, T. Agocs, H. Anwand-Heerwart, S. Barboza, P. Baudoz, R. Bender, P. Bizenberger, A. Boccaletti, W. Boland, P. Bonifacio, F. Briegel, T. Buey, F. Chapron, M. Cohen, O. Czoske, S. Dreizler, R. Falomo, P. Feautrier, N. Förster Schreiber, E. Gendron, R. Genzel, M. Glück, D. Gratadour, R. Greimel, F. Grupp, M. Häuser, M. Haug, J. Hennawi, H. J. Hess, V. Hörmann, R. Hofferbert, U. Hopp, Z. Hubert, D. Ives, W. Kausch, F. Kerber, H. Kravcar, K. Kuijken, M. Leitzinger, K. Leschinski, D. Massari, S. Mei, F. Merlin, L. Mohr, A. Monna, F. Müller, R. Navarro, M. Plattner, N. Przybilla, R. Ramlau, S. Ramsay, T. Ratzka, P. Rhode, J. Richter, H.-W. Rix, G. Rodeghiero, R.-R. Rohloff, G. Rousset, R. Ruddenklau, V. Schaffenroth, J. Schlichter, A. Sevin, R. Stuik, E. Sturm, J. Thomas, N. Tromp, M. Turatto, G. Verdoes-Kleijn, F. Vidal, R. Wagner, M. Wegner, W. Zeilinger, B. Ziegler, G. Zins

Proceedings Volume 9908, 99081Z (2016) https://doi.org/10.1117/12.2233047

KEYWORDS: Adaptive optics, Cameras, Adaptive optics, Cameras, Stars, Mirrors, Galactic astronomy, Imaging spectroscopy, Interfaces, Spectroscopy, Zoom lenses, Sensors

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Proceedings Article | 4 August 2016 Open Access

Open Access

Paper

The metrology system of the VLTI instrument GRAVITY

Magdalena Lippa, Stefan Gillessen, Nicolas Blind, Yitping Kok, Şenol Yazıcı, Johannes Weber, Oliver Pfuhl, Marcus Haug, Stefan Kellner, Ekkehard Wieprecht, Frank Eisenhauer, Reinhard Genzel, Oliver Hans, Frank Haußmann, David Huber, Tobias Kratschmann, Thomas Ott, Markus Plattner, Christian Rau, Eckhard Sturm, Idel Waisberg, Erich Wiezorrek, Guy Perrin, Karine Perraut, Wolfgang Brandner, Christian Straubmeier, Antonio Amorim

Proceedings Volume 9907, 990722 (2016) https://doi.org/10.1117/12.2232272

KEYWORDS: Metrology, Telescopes, Signal detection, Laser metrology, Sensors, Beam splitters, Phase shifts, Phase measurement, Receivers, Diodes

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Proceedings Article | 3 August 2016 Open Access

Open Access

Paper

Making SPIFFI SPIFFIER: upgrade of the SPIFFI instrument for use in ERIS and performance analysis from re-commissioning

E. George, D. Gräff, H. Feuchtgruber, M. Hartl, F. Eisenhauer, A. Buron, R. Davies, R. Genzel, H. Huber, C. Rau, M. Plattner, E. Wiezorrek, H. Weisz, P. Amico, A. Glindemann, G. Hau, H. Kuntschner

Proceedings Volume 9908, 99080G (2016) https://doi.org/10.1117/12.2231285

KEYWORDS: Adaptive optics, Mirrors, Sensors, Collimators, Cameras, Wavefronts, K band, Calibration, Point spread functions, Spectral resolution

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Proceedings Article | 18 July 2016 Paper

Paper

The wide field imager instrument for Athena

Norbert Meidinger, Josef Eder, Tanja Eraerds, Kirpal Nandra, Daniel Pietschner, Markus Plattner, Arne Rau, Rafael Strecker

Proceedings Volume 9905, 99052A (2016) https://doi.org/10.1117/12.2231604

KEYWORDS: Sensors, Field effect transistors, Cameras, Head, Electronics, Thermal modeling, Connectors, Interfaces, Instrument modeling, Aluminum

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The WFI (Wide Field Imager) instrument is planned to be one of two complementary focal plane cameras on ESA’s next X-ray observatory Athena. It combines unprecedented survey power through its large field of view of 40 amin x 40 amin together with excellent count rate capability (≥ 1 Crab). The energy resolution of the silicon sensor is state-of-the-art in the energy band of interest from 0.2 keV to 15 keV, e.g. the full width at half maximum of a line at 7 keV will be ≤ 170 eV until the end of the nominal mission phase. This performance is accomplished by using DEPFET active pixel sensors with a pixel size of 130 μm x 130 μm well suited to the on-axis angular resolution of 5 arcsec half energy width (HEW) of the mirror system. Each DEPFET pixel is a combined sensor-amplifier structure with a MOSFET integrated onto a fully depleted 450 μm thick silicon bulk. Two detectors are planned for the WFI instrument: A large-area detector comprising four sensors with a total of 1024 x 1024 pixels and a fast detector optimized for high count rate observations. This high count rate capable detector permits for bright point sources with an intensity of 1 Crab a throughput of more than 80% and a pile-up of less than 1%. The fast readout of the DEPFET pixel matrices is facilitated by an ASIC development, called VERITAS-2. Together with the Switcher-A, a control ASIC that allows for operation of the DEPFET in rolling shutter mode, these elements form the key components of the WFI detectors. The detectors are surrounded by a graded-Z shield, which has in particular the purpose to avoid fluorescence lines that would contribute to the instrument background. Together with ultra-thin coating of the sensor and particle identification by the detector itself, the particle induced background shall be minimized in order to achieve the scientific requirement of a total instrumental background value smaller than 5 x 10^-3 cts/cm²/s/keV. Each detector has its dedicated detector electronics (DE) for supply and data acquisition. Due to the high frame rate in combination with the large pixel array, signal correction and event filtering have to be done on-board and in real-time as the raw data rate would by far exceed the feasible telemetry rate. The data streams are merged and compressed in the Instrument Control and Power distribution Unit (ICPU). The ICPU is the data, control and power interface of the WFI to the Athena spacecraft. The WFI instrument comprises in addition a filter wheel (FW) in front of the camera as well as an optical stray-light baffle. In the current phase A of the Athena project, the technology development is performed. At its end, breadboard models will be developed and tested to demonstrate a technical readiness level (TRL) of at least 5 for the various WFI subsystems before mission adoption in 2020.

Proceedings Article | 11 July 2016 Paper

Paper

WFI electronics and on-board data processing

Markus Plattner, Sebastian Albrecht, Jörg Bayer, Soeren Brandt, Paul Drumm, Olaf Hälker, Franz Kerschbaum, Anna Koch, Irfan Kuvvetli, Norbert Meidinger, Sabine Ott, Roland Ottensamer, Jonas Reiffers, Thomas Schanz, Konrad Skup, Manfred Steller, Chris Tenzer, Chris Thomas

Proceedings Volume 9905, 99052D (2016) https://doi.org/10.1117/12.2235375

KEYWORDS: Electronics, Sensors, Field effect transistors, X-rays, Imaging systems, Transistors, Amplifiers, Capacitance, Signal detection, Electroluminescent displays

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Proceedings Article | 11 July 2016 Paper

Paper

The filter and calibration wheel for the ATHENA wide field imager

M. Rataj, S. Polak, T. Palgan, T. Kamisiński, A. Pilch, J. Eder, N. Meidinger, M. Plattner, M. Barbera, G. Parodi, Fabio D'Anca

Proceedings Volume 9905, 990568 (2016) https://doi.org/10.1117/12.2235411

KEYWORDS: Optical filters, Imaging systems, Acoustics, Finite element methods, Optical filters, Sensors, Calibration, Imaging systems, Acoustics, Image filtering, Adhesives, Aluminum, Polishing

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Proceedings Article | 24 August 2015 Paper

Paper

Development of the wide field imager for Athena

Norbert Meidinger, Josef Eder, Maria Fürmetz, Kirpal Nandra, Daniel Pietschner, Markus Plattner, Arne Rau, Jonas Reiffers, Rafael Strecker, Marco Barbera, Thorsten Brand, Jörn Wilms

Proceedings Volume 9601, 96010H (2015) https://doi.org/10.1117/12.2187012

KEYWORDS: Sensors, Field effect transistors, Electronics, Optical filters, Cameras, Photons, Quantum efficiency, X-rays, Imaging systems, Visible radiation

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SPIE Journal Paper | 30 December 2014 Open Access

Open Access

Wide field imager instrument for the Advanced Telescope for High Energy Astrophysics

Norbert Meidinger, Kirpal Nandra, Markus Plattner, Matteo Porro, Arne Rau, Andrea Santangelo, Chris Tenzer, Jörn Wilms

JATIS, Vol. 1, Issue 01, 014006, (December 2014) https://doi.org/10.1117/12.10.1117/1.JATIS.1.1.014006

KEYWORDS: Sensors, Field effect transistors, Imaging systems, Cameras, Electronics, Optical filters, Photons, Mirrors, High energy astrophysics, Telescopes

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Proceedings Article | 24 July 2014 Paper

Paper

The wide field imager instrument for Athena

Norbert Meidinger, Kirpal Nandra, Markus Plattner, Matteo Porro, Arne Rau, Andrea Santangelo, Chris Tenzer, Jörn Wilms

Proceedings Volume 9144, 91442J (2014) https://doi.org/10.1117/12.2054490

KEYWORDS: Sensors, Field effect transistors, Optical filters, Cameras, X-rays, Signal processing, Mirrors, Analog electronics, Control systems, Imaging systems

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The "Hot and Energetic Universe" has been selected as the science theme for ESA's L2 mission, scheduled for launch in 2028. The proposed Athena X-ray observatory provides the necessary capabilities to achieve the ambitious goals of the science theme. The X-ray mirrors are based on silicon pore optics technology and will have a 12 m focal length. Two complementary camera systems are foreseen which can be moved in and out of the focal plane by an interchange mechanism. These instruments are the actively shielded micro-calorimeter spectrometer X-IFU and the Wide Field Imager (WFI). The WFI will combine an unprecedented survey power through its large field of view of 40 arcmin with a high countrate capability (approx. 1 Crab). It permits a state-of-the-art energy resolution in the energy band of 0.1 keV to 15 keV during the entire mission lifetime (e.g. FWHM ≤ 150 eV at 6 keV). This performance is accomplished by a set of DEPFET active pixel sensor matrices with a pixel size matching the angular resolution of 5 arcsec (on-axis) of the mirror system. Each DEPFET pixel is a combined detector-amplifier structure with a MOSFET integrated onto a fully depleted 450 micron thick silicon bulk. The signal electrons generated by an X-ray photon are collected in a so-called internal gate below the transistor channel. The resulting change of the conductivity of the transistor channel is proportional to the number of electrons and thus a measure for the photon energy. DEPFETs have already been developed for the "Mercury Imaging X-ray Spectrometer" on-board of ESA’s BepiColombo mission. For Athena we develop enhanced sensors with integrated electronic shutter and an additional analog storage area in each pixel. These features improve the peak-to-background ratio of the spectra and minimize dead time. The sensor will be read out with a new, fast, low-noise multi-channel analog signal processor with integrated sequencer and serial analog output. The architecture of sensor and readout ASIC allows readout in full frame mode and window mode as well by addressing selectively arbitrary sub-areas of the sensor allowing time resolution in the order of 10 μs. The further detector electronics has mainly the following tasks: digitization, pre-processing and telemetry of event data as well as supply and control of the detector system. Although the sensor will already be equipped with an on-chip light blocking filter, a filter wheel is necessary to provide an additional external filter, an on-board calibration source, an open position for outgassing, and a closed position for protection of the sensor. The sensor concept provides high quantum efficiency over the entire energy band and we intend to keep the instrumental background as low as possible by designing a graded Z-shield around the sensor. All these properties make the WFI a very powerful survey instrument, significantly surpassing currently existing observatories and in addition allow high-time resolution of the brightest X-ray sources with low pile-up and high efficiency. This manuscript will summarize the current instrument concept and design, the status of the technology development, and the envisaged baseline performance.

Proceedings Article | 8 July 2014 Paper

Paper

ERIS: preliminary design phase overview

Harald Kuntschner, Lieselotte Jochum, Paola Amico, Johannes Dekker, Florian Kerber, Enrico Marchetti, Matteo Accardo, Roland Brast, Martin Brinkmann, Ralf Conzelmann, Bernard Delabre, Michel Duchateau, Enrico Fedrigo, Gert Finger, Christoph Frank, Fernando Rodriguez, Barbara Klein, Jens Knudstrup, Miska Le Louarn, Lars Lundin, Andrea Modigliani, Michael Müller, Mark Neeser, Sebastien Tordo, Elena Valenti, Frank Eisenhauer, Eckhard Sturm, Helmut Feuchtgruber, Elisabeth George, Michael Hartl, Reiner Hofmann, Heinrich Huber, Markus Plattner, Josef Schubert, Karl Tarantik, Erich Wiezorrek, Michael Meyer, Sascha Quanz, Adrian Glauser, Harald Weisz, Simone Esposito, Marco Xompero, Guido Agapito, Jacopo Antichi, Valdemaro Biliotti, Marco Bonaglia, Runa Briguglio, Luca Carbonaro, Giovanni Cresci, Luca Fini, Enrico Pinna, Alfio Puglisi, Fernando Quirós-Pacheco, Armando Riccardi, Gianluca Di Rico, Carmelo Arcidiacono, Mauro Dolci

Proceedings Volume 9147, 91471U (2014) https://doi.org/10.1117/12.2055140

KEYWORDS: Adaptive optics, Sensors, Calibration, Mirrors, Stars, Spectrographs, Cameras, Wavefront sensors, Infrared sensors, Telescopes

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The Enhanced Resolution Imager and Spectrograph (ERIS) is the next-generation adaptive optics near-IR imager and spectrograph for the Cassegrain focus of the Very Large Telescope (VLT) Unit Telescope 4, which will soon make full use of the Adaptive Optics Facility (AOF). It is a high-Strehl AO-assisted instrument that will use the Deformable Secondary Mirror (DSM) and the new Laser Guide Star Facility (4LGSF). The project has been approved for construction and has entered its preliminary design phase. ERIS will be constructed in a collaboration including the Max- Planck Institut für Extraterrestrische Physik, the Eidgenössische Technische Hochschule Zürich and the Osservatorio Astrofisico di Arcetri and will offer 1 - 5 μm imaging and 1 - 2.5 μm integral field spectroscopic capabilities with a high Strehl performance. Wavefront sensing can be carried out with an optical high-order NGS Pyramid wavefront sensor, or with a single laser in either an optical low-order NGS mode, or with a near-IR low-order mode sensor. Due to its highly sensitive visible wavefront sensor, and separate near-IR low-order mode, ERIS provides a large sky coverage with its 1’ patrol field radius that can even include AO stars embedded in dust-enshrouded environments. As such it will replace, with a much improved single conjugated AO correction, the most scientifically important imaging modes offered by NACO (diffraction limited imaging in the J to M bands, Sparse Aperture Masking and Apodizing Phase Plate (APP) coronagraphy) and the integral field spectroscopy modes of SINFONI, whose instrumental module, SPIFFI, will be upgraded and re-used in ERIS. As part of the SPIFFI upgrade a new higher resolution grating and a science detector replacement are envisaged, as well as PLC driven motors. To accommodate ERIS at the Cassegrain focus, an extension of the telescope back focal length is required, with modifications of the guider arm assembly. In this paper we report on the status of the baseline design. We will also report on the main science goals of the instrument, ranging from exoplanet detection and characterization to high redshift galaxy observations. We will also briefly describe the SINFONI-SPIFFI upgrade strategy, which is part of the ERIS development plan and the overall project timeline.

Proceedings Article | 13 May 2013 Paper

Paper

A space-borne fiber-optic interrogator module based on narrow-band tunable laser diode for temperature monitoring in telecommunication satellites

P. Putzer, N. Kuhenuri, A. Koch, S. Schweyer, A. Hurni, M. Plattner

Proceedings Volume 8788, 878810 (2013) https://doi.org/10.1117/12.2020495

KEYWORDS: Fiber Bragg gratings, Sensors, Signal to noise ratio, Field programmable gate arrays, Fiber optics, Fiber optics sensors, Computer simulations, Temperature metrology, Convolution, Error analysis

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Proceedings Article | 6 April 2012 Paper

Paper

Concept and design of a fiber-optic and an I2C hybrid sensor bus system for telecommunication satellites

P. Putzer, A. Hurni, M. Manhart, C. Tiefenbeck, M. Plattner, A. Koch

Proceedings Volume 8345, 83453L (2012) https://doi.org/10.1117/12.914787

KEYWORDS: Sensors, Fiber Bragg gratings, Satellites, Fiber optics sensors, Telecommunications, Fiber optics, Optical fibers, Tunable lasers, Field programmable gate arrays, Interfaces

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Proceedings Article | 27 May 2011 Paper

Paper

High temperature sensing with FBGs using a tunable laser interrogation system

B. Eder, M. Plattner, P. Putzer, P. Eckert, A. Reutlinger, T. Zeh

Proceedings Volume 8082, 80823M (2011) https://doi.org/10.1117/12.889650

KEYWORDS: Fiber Bragg gratings, Sensors, Temperature metrology, Semiconductor lasers, Combustion, Optical fibers, Tunable lasers, Reflectors, Laser systems engineering, Stereolithography

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Proceedings Article | 17 June 2009 Paper

Paper

Spectral peak tracking for enhanced fiber optic sensing

Markus Plattner, C. Brand, T. Mair, S. Schupfer, T. Buck, A. Koch

Proceedings Volume 7389, 738923 (2009) https://doi.org/10.1117/12.827668

KEYWORDS: Sensors, Digital signal processing, Fiber optics sensors, Fiber Bragg gratings, Detection and tracking algorithms, Semiconductor lasers, Field programmable gate arrays, Tunable lasers, Time metrology, Modulation

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Within this work, we describe our newly developed interrogation scheme for fiber optic sensing applications. This measurement system will be utilized in Ariane launchers for monitoring temperature and mechanical stress distribution during flight. The acquired sensing data can be used to control propulsion unit an thrusters and thereby adapt the flight path in a way that damage on the launcher is prevented. In order to detect the peak wavelength of e.g. fiber Bragg grating (FBG) sensors, a tunable laser source based on a modulated-grating laser diode is able to scan through a more than 40nm wide spectrum in the infrared region. Several sensors with different spectral answers can be placed inside one sensor fiber and then interrogated sequentially. The magnitudes of the reflected intensities depend on the actual sensor position that is determined by the measurand (e.g. temperature). One single sensor is scanned by a variable number of spectral sampling points and the spectral answer of the sensor is then calculated by centroid algorithms. Depending an the spectral width of one sensor, the number of sensors that shall be interrogated and the required sampling points per sensor, a maximum sampling frequency of 240kHz is achievable with our hardware. Contrary to comparable systems, our interrogator is capable of switching to any available wavelength of its spectrum within a couple of nanoseconds. Therefore standard continuous sweeping through the entire spectrum is not necessary. This results in a new measurement scheme, wherein spectral gaps between consecutive sensors do not need to be scanned and can be skipped. Since most of the spectrum consists of the gaps between the sensors, overall measurement time is thereby reduced significantly. One problem arises from this measurement scheme: Due to the fact that the sensor's spectral answers vary in time, a special algorithm for tracking the spectral movement has to be implemented. The scope of this work is the description, implementation and assessment of this new peak tracking procedure. After describing the measurement setup, we will therefore explain the algorithm behind the peak tracking measurement. Afterwards the simulation process is explained and results are shown. Performance obtained by peak tracking compared to standard continuous wavelength scanning is evaluated in detail and further development steps which are necessary to obtain a fully sophisticated interrogation systems are discussed.

Proceedings Article | 17 June 2009 Paper

Paper

Performance analysis of interrogators for fiber Bragg grating sensors based on arrayed waveguide gratings

Thorbjörn Buck, Mathias Müller, Markus Plattner, Alexander Koch

Proceedings Volume 7389, 738930 (2009) https://doi.org/10.1117/12.827526

KEYWORDS: Fiber Bragg gratings, Sensors, Waveguides, Light sources, Electronics, Optical filters, Resistors, Amplifiers, Refractive index, Photodetectors

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Showing 5 of 29 publications

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