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1. Analysis of collision avoidance manoeuvres using aerodynamic drag for the Flying Laptop satellite

Author

Turco, Fabrizio, Traub, Constantin, Gaißer, Steffen, Burgdorf, Jonas, Klinkner, Sabine, and Fasoulas, Stefanos

Subjects
Physics - Space Physics
Abstract

Collision avoidance is a topic of growing importance for any satellite orbiting Earth. Especially those satellites without thrusting capabilities face the problem of not being able to perform impulsive collision avoidance manoeuvres. For satellites in Low Earth Orbits, though, perturbing accelerations due to aerodynamic drag may be used to influence their trajectories, thus offering a possibility to avoid collisions without consuming propellant. Here, this manoeuvring option is investigated for the satellite Flying Laptop of the University of Stuttgart, which orbits the Earth at approximately 600 km. In a first step, the satellite is aerodynamically analysed making use of the tool ADBSat. By employing an analytic equation from literature, in-track separation distances can then be derived following a variation of the ballistic coefficient through a change in attitude. A further examination of the achievable separation distances proves the feasibility of aerodynamic collision avoidance manoeuvres for the Flying Laptop for moderate and high solar and geomagnetic activity. The predicted separation distances are further compared to flight data, where the principle effect of the manoeuvre on the satellite trajectory becomes visible. The results suggest an applicability of collision avoidance manoeuvres for all satellites in comparable and especially in lower orbits than the Flying Laptop, which are able to vary their ballistic coefficient., Comment: 12 pages, 13 figures. arXiv admin note: text overlap with arXiv:2302.06893

Published
2023

3. Stratospheric Balloons as a Complement to the Next Generation of Astronomy Missions

Author

Maier, Philipp, Ångerman, Maria, Barnstedt, Jürgen, Bougueroua, Sarah, Colin, Angel, Conti, Lauro, Duffard, Rene, Hanke, Lars, Janson, Olle, Kalkuhl, Christoph, Kappelmann, Norbert, Keilig, Thomas, Klinkner, Sabine, Krabbe, Alfred, Lengowski, Michael, Lockowandt, Christian, Müller, Thomas, Ortiz, Jose-Luis, Pahler, Andreas, Rauch, Thomas, Schanz, Thomas, Stelzer, Beate, Taheran, Mahsa, Vaerneus, Alf, Werner, Klaus, and Wolf, Jürgen

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

Observations that require large physical instrument dimensions and/or a considerable amount of cryogens, as it is for example the case for high spatial resolution far infrared astronomy, currently still face technological limits for their execution from space. The high cost and finality of space missions furthermore call for a very low risk approach and entail long development times. For certain spectral regions, prominently including the mid- to far-infrared as well as parts of the ultraviolet, stratospheric balloons offer a flexible and affordable complement to space telescopes, with short development times and comparatively good observing conditions. Yet, the entry burden to use balloon-borne telescopes is high, with research groups typically having to shoulder part of the infrastructure development as well. Aiming to ease access to balloon-based observations, we present the efforts towards a community-accessible balloon-based observatory, the European Stratospheric Balloon Observatory (ESBO). ESBO aims at complementing space-based and airborne capabilities over the next 10-15 years and at adding to the current landscape of scientific ballooning activities by providing a service-centered infrastructure for broader astronomical use, performing regular flights and offering an operations concept that provides researchers with a similar proposal-based access to observation time as practiced on ground-based observatories. We present details on the activities planned towards the goal of ESBO, the current status of the STUDIO (Stratospheric UV Demonstrator of an Imaging Observatory) prototype platform and mission, as well as selected technology developments with extensibility potential to space missions undertaken for STUDIO., Comment: Proc. 71st International Astronautical Congress, 12-14 October 2020. arXiv admin note: text overlap with arXiv:2012.14215, arXiv:2202.04580

Published
2022

4. Stratospheric balloons as a platform for the next large far infrared observatory

Author

Maier, Philipp, Wolf, Jürgen, Krabbe, Alfred, Keilig, Thomas, Pahler, Andreas, Bougueroua, Sarah, Müller, Thomas, Duffard, Rene, Ortiz, Jose-Luis, Klinkner, Sabine, Lengowski, Michael, Krokstedt, Christian, Lockowandt, Christian, Kappelmann, Norbert, Stelzer, Beate, Werner, Klaus, Geier, Stephan, Kalkuhl, Christof, Rauch, Thomas, Schanz, Thomas, Barnstedt, Jürgen, Conti, Lauro, Hanke, Lars, and Kaźmierczak-Barthel, Maja

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

Observations that require large physical instrument dimensions and/or a considerable amount of cryogens, as it is the case for high spatial resolution far infrared (FIR) astronomy, currently still face technological limits for their execution from space. Angular resolution and available observational capabilities are particularly affected. Balloon-based platforms promise to complement the existing observational capabilities by offering means to deploy comparatively large telescopes with comparatively little effort, including other advantages such as the possibility to regularly refill cryogens and to change and/or update instruments. The planned European Stratospheric Balloon Observatory (ESBO) aims at providing these additional large aperture FIR capabilities, exceeding the spatial resolution of Herschel, in the long term. The plans focus on reusable platforms performing regular flights and an operations concept that provides researchers with proposal-based access to observations. It thereby aims at offering a complement to other airborne, ground-based and space-based observatories in terms of access to wavelength regions, spatial resolution capability, and photometric stability. While the FIR capabilities are a main long-term objective, ESBO will offer benefits in other wavelength regimes along the way. Within the ESBO Design Study (ESBO DS), a prototype platform carrying a 0.5 m telescope for ultraviolet and visible light observations is being built and a platform concept for a next-generation FIR telescope is being studied. A flight of the UV/VIS prototype platform is estimated for 2021. In this paper we will outline the scientific and technical motivation for a large aperture balloon-based FIR observatory and the ESBO DS approach towards such an infrastructure. Secondly, we will present the technical motivation, science case, and instrumentation of the 0.5 m UV/VIS platform., Comment: Proc. 69th International Astronautical Congress, 1-5 October 2018. arXiv admin note: text overlap with arXiv:2111.11068

Published
2022

7. Towards a European Stratospheric Balloon Observatory -- The ESBO Design Study

Author

Maier, Philipp, Wolf, Jürgen, Keilig, Thomas, Krabbe, Alfred, Duffard, Rene, Ortiz, Jose-Luis, Klinkner, Sabine, Lengowski, Michael, Müller, Thomas, Lockowandt, Christian, Krockstedt, Christian, Kappelmann, Norbert, Stelzer, Beate, Werner, Klaus, Geier, Stephan, Kalkuhl, Christoph, Rauch, Thomas, Schanz, Thomas, Barnstedt, Jürgen, Conti, Lauro, and Hanke, Lars

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

This paper presents the concept of a community-accessible stratospheric balloon-based observatory that is currently under preparation by a consortium of European research institutes and industry. The planned European Stratospheric Balloon Observatory (ESBO) aims at complementing the current landscape of scientific ballooning activities by providing a service-centered infrastructure tailored towards broad astronomical use. In particular, the concept focuses on reusable platforms with exchangeable instruments and telescopes performing regular flights and an operations concept that provides researchers with options to test and operate own instruments, but later on also a proposal-based access to observations. It thereby aims at providing a complement to ground-, space-based, and airborne observatories in terms of access to wavelength regimes - particularly the ultraviolet (UV) and far infrared (FIR) regimes -, spatial resolution capability, and photometric stability. Within the currently ongoing ESBO Design Study (ESBO DS), financed within the European Union's Horizon 2020 Programme, a prototype platform carrying a 0.5-m telescope for UV and visible light observations is being built and concepts for larger following platforms, leading up to a next-generation FIR telescope are being studied. A flight of the UV/visible prototype platform is currently foreseen for 2021. We present the technical motivation, science case, instrumentation, and a two-stage image stabilization approach of the 0.5-m UV/visible platform. In addition, we briefly describe the novel mid-sized stabilized balloon gondola under design to carry telescopes in the 0.5 to 0.6 m range as well as the currently considered flight option for this platform. Secondly, we outline the scientific and technical motivation for a large balloon-based FIR telescope and the ESBO DS approach towards such an infrastructure., Comment: Proc. SPIE Conf., Astronomical Telescopes and Instrumentation, 10-15 June 2018

Published
2021

8. UPM Satellite Ground Station Data for Borneo NDVI Image Analysis

Author

Tee Jia Jian, Varatharajoo Renuganth, and Klinkner Sabine

Subjects
Environmental sciences, GE1-350
Abstract

Small satellites have been developed and used for earth observations as the remote sensing data can be used to perform analysis such as weather forecasts, vegetation monitorings, climate changes, and disaster monitorings. The Flying Laptop satellite (Flying Laptop) is the first small satellite developed by the University of Stuttgart (Germany), which is mainly used for research and development projects. The raw data obtained from Flying Laptop is used in the data analysis and data processing, which involve the ground tracks and images analysis. The filtered images are used to formulate Normalized Difference Vegetation Index (NDVI) plots, which are broadly used for the vegetation monitor in recent years. Due to the weather influences and the available filter in the Flying Laptop imaging payload, the generated NDVI plot needs to be improved in terms of its contrast and the difference in an identification of landcover type for better monitoring purposes. The ground track analysis and image comparison with respect to the fixed ground were used to identify the location of the image being captured and filtered out for unusable images. The formulation of NDVI is repeated with cloud maskings using Normalized Difference Water Index (NDWI) as references and accordingly normalized the plot in a logarithmic scale. The proposed method of using the cloud masking with references to NDWI improves the contrast of the overall NDVI plots. The usage of automation also helps to improve the efficiency in generating NDVI plots.

Published
2024
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9. Feasibility studies for a dust observatory between earth and the asteroid belt

Author

Srama, Ralf, Klinkner, Sabine, Fugmann, Martin, Lengowski, Michael, Gläser, Jan, Simolka, Jonas, Sommer, Maximilian, Strack, Heiko, Acker, Denis, Barth, Nadine, Eckstein, Sergej, Filatov, Michael, Gutierrez, Elizabeth, Maydali, Aren, Merz, Florian A., Meyer, Tristan, Pippert, Adrian, Starzmann, Dominik, Stucke, Marvin B., and Waizenegger, Kevin

Published
2022
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11. Qualification of the Attitude Control System of the E-band CubeSat EIVE

Author

Eggert, Marius, primary, Bötsch-Zavřel, Lena, additional, Fugmann, Martin, additional, Holeczek, Cedric, additional, Koller, Markus, additional, Kranz, Markus, additional, Lengowski, Michael, additional, Löffler, Thorben, additional, Loidold, Lukas-Maximilian, additional, Maier, Philipp, additional, Meier, Jakob, additional, Mohr, Ulrich, additional, Müller, Robin, additional, Schweigert, Robin, additional, Starzmann, Dominik, additional, Steinert, Michael, additional, Zietz, Martin, additional, Schoch, Benjamin, additional, Haussmann, Simon, additional, Tessmann, Axel, additional, Freese, Jens, additional, and Klinkner, Sabine, additional

Published
2024
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17. Measurement and Analysis of FDM for E-Band Satellite Communication

Author

Haussmann, Simon, primary, Manoliu, Laura, additional, Gebert, Lukas, additional, Schoch, Benjamin, additional, Koller, Markus, additional, Meier, Jakob, additional, Steinmetz, Fabian, additional, Freese, Jens, additional, Henneberger, Ralf, additional, Tessmann, Axel, additional, Klinkner, Sabine, additional, and Kallfass, Ingmar, additional

Published
2023
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18. Simulating asteroid impacts and meteor events by high-power lasers: from the laboratory to spaceborne missions

Author

Ferus, Martin, primary, Knížek, Antonín, additional, Cassone, Giuseppe, additional, Rimmer, Paul B., additional, Changela, Hitesh, additional, Chatzitheodoridis, Elias, additional, Uwarova, Inna, additional, Žabka, Ján, additional, Kabáth, Petr, additional, Saija, Franz, additional, Saeidfirozeh, Homa, additional, Lenža, Libor, additional, Krůs, Miroslav, additional, Petera, Lukáš, additional, Nejdl, Lukáš, additional, Kubelík, Petr, additional, Křivková, Anna, additional, Černý, David, additional, Divoký, Martin, additional, Pisařík, Michael, additional, Kohout, Tomáš, additional, Palamakumbure, Lakshika, additional, Drtinová, Barbora, additional, Hlouchová, Klára, additional, Schmidt, Nikola, additional, Martins, Zita, additional, Yáñez, Jorge, additional, Civiš, Svatopoluk, additional, Pořízka, Pavel, additional, Mocek, Tomáš, additional, Petri, Jona, additional, and Klinkner, Sabine, additional

Published
2023
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21. Comparison of the Low-Cost Sun Sensors of the SOURCE and EIVE CubeSats

Author

Pentke, Nils, Schaefer, Joelle, Schwarz, Timon Karl-Heinz, Koller, Markus T., Gaisser, Steffen, and Klinkner, Sabine

Subjects
Sun Sensors, CubeSat, Missions, EIVE, SOURCE
Abstract

Sun sensors are commonly used attitude determination equipment which measure a spacecraft’s attitude relative to the sun. Multiple types of low-cost sun sensors were developed for the SOURCE and EIVE CubeSats. The SOURCE sun sensors consist of single photodiodes which are placed in a one-sensor-per-face as well as a pyramid arrangement. EIVE employs digital vector sun sensors based on quad-pin photodiodes. The SOURCE sun sensors in the one-sensor-per-face arrangement archive an accuracy of

Published
2022

24. Status, flight preparation, and future instrument opportunities of the STUDIO balloon-borne telescope platform

Author

Bougueroua, Sarah, primary, Ångerman, Maria, additional, Barnstedt, Jürgen, additional, Colin, Angel, additional, Conti, Lauro, additional, Diebold, Sebastian, additional, Duffard, Rene, additional, Janson, Olle, additional, Kalkuhl, Christoph, additional, Kappelmann, Norbert, additional, Keilig, Thomas, additional, Klinkner, Sabine, additional, Krabbe, Alfred, additional, Lengowski, Michael, additional, Lockowandt, Christian, additional, Maier, Philipp, additional, Müller, Thomas, additional, Pahler, Andreas, additional, Rauch, Thomas, additional, Schanz, Thomas, additional, Stelzer, Beate, additional, Taheran, Mahsa, additional, Vaerneus, Alf, additional, Werner, Klaus, additional, and Wolf, Jürgen, additional

Published
2022
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25. Meteor observation with the SOURCE CubeSat – Developing a simulation to test on-board meteor detection algorithms

Author

Liegibel, Marcel, Petri, Jona, Hoffmann, Philipp, Geier, Niklas, and Klinkner, Sabine

Subjects
Meteor simulation, Earth observation, Terra (Planeta), On-board processing, Satèl·lits artificials en teledetecció, Enginyeria de la telecomunicació::Radiocomunicació i exploració electromagnètica::Satèl·lits i ràdioenllaços [Àrees temàtiques de la UPC], Detection algorithm, Earth (Planet), Meteorits, Meteorites, Artificial satellites in remote sensing
Abstract

The scientific mission objectives of the Stuttgart Operated University Research CubeSat for Evaluation and Education are meteor observation, measurement of the lower Earth's atmosphere during re-entry as well as technology demonstrations. The meteor observation is done by pointing a camera towards Earth and continuously taking images during Eclipse. Since it is not possible to downlink all images, an on-board detection algorithm is necessary and mission critical. Therefore, this algorithm needs to be tested thoroughly. Realistic test data showing meteors from orbit is needed to properly develop and test the algorithm. Existing videos, provided by the Planetary Exploration Research Center, captured from the ISS are used as a baseline but are not sufficient to test the algorithm. The videos do not have the diversity of meteors needed and the meteor properties are not settable which makes it difficult to test the detection algorithm in as many scenarios as possible. Therefore, an artificial meteor program was developed to simulate meteors with given properties as perceived from a meteor observation system in a low Earth orbit. Here, we present the details of the artificial meteor program, its working principle and how we tested an algorithm for meteor detection. The user can choose between different background videos, the existing ISS videos from PERC or the self-generated videos. Each different background is used to test a different aspect of the meteor detection algorithm. The ISS videos from PERC provide more diverse backgrounds than the self-generated videos with e.g., clouds and lightning. For these self-generated videos, a program is developed to take image sections of NASA’s Black Marble and putting them frame by frame together into a video. These videos are more suitable for simulating satellite rotation and camera properties. Independent of the background video, settable meteor properties contain important characteristics of a meteor like the light curve, brightness, speed, direction and shape. Additionally, the user can choose the meteor position in the video frame, in which frame it appears and which distance it covers. Furthermore, distortion settings can be applied which contain airplanes with adjustable parameters and scalable noise. Only a properly working meteor detection algorithm leads to a success of a mission critical part of the SOURCE CubeSat. Therefore, the development of this artificial meteor generation program is crucial. Furthermore, this technology demonstration of developing and especially testing a meteor detection algorithm will enable future space-based missions for meteor observations

Published
2022

26. Development and testing of the 3U+ CubeSat PCDU for SOURCE

Author

Waizenegger, Kevin, Papanikolaou, Athanasios, Rudolf, Moritz, Koller, Markus, and Klinkner, Sabine

Subjects
Satèl·lits artificials, Artificial satellites, CubeSat, Ensenyament i aprenentatge::Ensenyament universitari [Àrees temàtiques de la UPC], PCDU, Aeronàutica i espai [Àrees temàtiques de la UPC], EPS, SOURCE
Abstract

SOURCE (Stuttgart Operated University CubeSat for Evaluation and Education) is a 3U+ re-search CubeSat that is being developed by students at the University of Stuttgart in coopera-tion with the Institute for Space Systems and the Small Satellite Student Society KSat e.V.. The objectives include technology demonstrations, atmospheric research and the investigation of satellite demise while also serving as an educational program. SOURCE was selected by ESA's "Fly your Satellite" program and is currently in Phase D. The electrical power supply system combines commercial off-the-shelf parts with self-devel-oped units to meet the requirements of the payloads. The solar array configuration and Power Conditioning and Distribution Unit (PCDU) are self-developed, while the battery is a commer-cial product. A total of 56 solar cells provides up to 32W under ideal conditions, which can be stored in a 75Wh space-qualified lithium-ion battery. To maximise the power output of the solar cells, maximum power point tracking is performed by the PCDU. This is controlled by a radiation hardened microcontroller. The PCDU provides regulated 3.3V, 5V and unregulated battery voltage to the subsystems with 32 switchable outputs, 27 of which are latch-up current protected. The microcontroller controls these individual output channels and the switching between the various CubeSat modes as commanded by the on-board computer. Additionally, every output channel power consumption is monitored for overcurrents. The PCDU functions as a watchdog by checking the health of the on-board computer, rebooting it in case of a failure. High priority commands can be sent directly to the PCDU from the ground via the communication system, bypassing the on-board computer. These can reset either the communication subsystem, the on-board computer or the entire satellite. Four hybrid inhibits, using a combination of mechanical switches and FETs are integrated in the PCDU, replacing the usual fully mechanical design. Three are used to deactivate the satellite in the deployer configuration and the fourth is a remove-before-flight inhibit. An engineering model was manufactured during phase C and is being tested functionally, en-vironmentally and for performance. This paper presents the detailed design of the PCDU, the acquired test results and outlines issues encountered during the tests

Published
2022

27. Downlink communication experiments with OSIRISv1 laser terminal onboard Flying Laptop satellite

Author

Giggenbach, Dirk, Fuchs, Christian, Schmidt, Christopher, Rödiger, Benjamin, Gaißer, Steffen, Klinkner, Sabine, Phung, Duy-Ha, Chabé, Julien, Courde, Clément, Maurice, Nicolas, Mariey, Hervé, Samain, Etienne, and Artaud, Géraldine

Subjects
KNOCGOP, OSIRISv1, Optical Ground Stations, signal fluctuations, Electrical and Electronic Engineering, Engineering (miscellaneous), Atomic and Molecular Physics, and Optics
Abstract

Downlink measurement campaigns from the optical downlink terminal OSIRISv1 onboard the LEO satellite Flying Laptop were carried out with the French Observatoire de la Côte d’Azur and with two Optical Ground Stations of the German Aerospace Center. On/off keyed data at 39 Mb/s were modulated on the laser signal, and according telecom reception was performed by the ground stations. The pointing of the laser terminal was achieved by open-loop body pointing of the satellite orientation, with its star sensor as attitude control signal. We report here on the measurements and investigations of the downlink signal and the data transmission.

Published
2022

28. Improved sensor fusion for flying laptop based on a multiplicative EKF

Author

Von Arnim, Maximilian, Gaisser, Steffen, Klinkner, Sabine, Von Arnim, Maximilian, Gaisser, Steffen, and Klinkner, Sabine

Abstract

Flying Laptop is a small satellite carrying an optical communications payload. It was launched in 2017. To improve the satellite’s attitude determination, which is used to point the payload, a new sensor fusion algorithm based on a low pass filter and a multiplicative extended Kalman filter (MEKF) was developed. As an operational satellite, improvements are only possible via software updates. The algorithm estimates the satellite's attitude from star tracker and fibre-optical gyroscope (FOG) measurements. It also estimates the gyroscope bias. The global attitude estimate uses a quaternion representation, while the Kalman filter uses Gibbs Parameters to calculate small attitude errors. Past Kalman filter predictions are saved for several time steps so that a delayed star tracker measurement can be used to update the prediction at the time of measurement. The estimate at the current time is then calculated by predicting the system attitude based on the updated past estimate. The prediction step relies on the low-pass-filtered gyroscope measurements corrected by the bias estimate. The new algorithm was developed as part of a master’s thesis at the University of Stuttgart, where Flying Laptop was developed and built. It was simulated in a MATLAB/Simulink environment using the European Space Agency’s GAFE framework. In addition, the new filter was applied to measurement data from the satellite. The results were used to compare the performance with the current filter implementation. The new Kalman filter can deal with delayed, missing, or irregular star tracker measurements. It features a lower computational complexity than the previous standard extended Kalman filter used on Flying Laptop. The mean error of the attitude estimate was reduced by up to 90%. The low pass filter improves the rotation rate estimate between star tracker measurements, especially for biased and noisy gyroscopes. However, this comes at the cost of potentially less accurate attitude estimates. Educ

Published
2022

29. Design and development of the re-entry sensor system for the CubeSat mission SOURCE

Author

Kuhm, Hendrik, Fischer, Hendrik, Blümler, Lars, Seeberg, Emily, Kirchner, Vincent, Galla, Daniel, Klinkner, Sabine, Kuhm, Hendrik, Fischer, Hendrik, Blümler, Lars, Seeberg, Emily, Kirchner, Vincent, Galla, Daniel, and Klinkner, Sabine

Abstract

With the number of man-made objects being launched into orbit steadily increasing, space debris is one of the big challenges for future space flight. In order to better assess the danger to humans on Earth’s surface, re-entry should be researched in more detail. SOURCE serves as a 3U+ satellite platform designed and developed by the small satellite student society (KSat e.V.) and the Institute of Space Systems (IRS) at the University of Stuttgart. It was selected by ESA in 2020 to be part of the ‘Fly your Satellite’ program, has successfully completed the CDR and is currently preparing for the MRR. SOURCE’s objectives are education, verification of several cost-saving, not yet space-proven technologies for orbital use, capturing images of meteoroids entering Earth's atmosphere and documenting its own demise during re-entry by analysing atomic oxygen, heat flux- and pressure data. In order to receive data for as long as possible during re-entry, the satellite switches from S-band to Iridium (inter-satellite link) communication at an altitude below 200 km. For the in-situ measurement during the re-entry, SOURCE is equipped with two Flux-Phi-Probe (FIPEX) sensors for the measurement of atomic oxygen and five additional sensor arrays. Each array contains one pressure sensor and two heat flux sensors, one commercial and one developed by the IRS. The arrays are placed at five positions in-line across the satellite to reduce effects of tumbling during the re-entry and to allow for the measurement of gradients. For a first estimation of the expected value ranges, simulations were performed with the software PICLas, developed by the IRS and the Institute of Aero-and Gas Dynamics (IAG) at the University of Stuttgart. In an iterative process, the collected data will be used to further improve this simulation software after the re-entry of the SOURCE satellite. The aim of this paper is to describe the design philosophy and development process of the sensor readout electronics.

Published
2022

32. Downlink communication experiments with OSIRISv1 laser terminal onboard Flying Laptop satellite

Author

Giggenbach, Dirk, primary, Fuchs, Christian, additional, Schmidt, Christopher, additional, Rödiger, Benjamin, additional, Gaißer, Steffen, additional, Klinkner, Sabine, additional, Phung, Duy-Ha, additional, Chabé, Julien, additional, Courde, Clément, additional, Maurice, Nicolas, additional, Mariey, Hervé, additional, Samain, Etienne, additional, and Artaud, Géraldine, additional

Published
2022
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33. Transmitter Beam Bias Verification for Optical Satellite Data Downlinks with Open-Loop Pointing – the 3-OGS-Experiment

Author

Giggenbach, Dirk, Karafillis, Petro, Rittershofer, Jonas, Immerz, Andreas, Spörl, Andreas, Gaisser, Steffen, Klinkner, Sabine, and Knopp, Marcus Thomas

Subjects
KNOCGOP, optical ground station, optical LEO satellite data downlinks, star camera, satellite flash finder, open loop pointing, dynamic pointing error, CPAless, beam center-of-gravity triangulation
Published
2022

34. The EIVE CubeSat - Developing a Satellite Bus for a 71-76 GHz E-Band Transmitter Payload

Author

Koller, Markus T., Loidold, Lukas-Maximilian, Löffler, Thorben, Meier, Jakob, Klinkner, Sabine, Manoliu, Laura, Schoch, Benjamin, and Kallfass, Ingmar

Abstract

A high-speed data downlink system provides many challenges for a CubeSat design. Two major aspect are an adequate power management as well as the thermal implications of the dissipated power. The goal of the 6U CubeSat EIVE is to prove the feasibility of an E-band link at 71-76 GHz and explore the influence of different atmospheric conditions on the link quality. The requirements of the E-band transmitter in terms of mass, volume, power and pointing accuracy outline the specific constraints imposed on the design of the satellite bus. The major design drivers of the system are the peak power demand of 60 W for the payload itself and the required pointing accuracy of less than 1◦. To cope with these demands, general design considerations, the choice of the orbit and the operation of the satellite are discussed. A special focus is the power generation and consumptions by means of a dynamic attitude and power simulation. The thermal simulation is verified by building a detailed structural and thermal replica of the satellite to investigate the heat dissipation. An overview of the current EIVE CubeSat platform design concludes this paper.

Published
2021

35. Operations System vs. Operating System: Towards a Ground System Supporting Satellite Application Programming

Author

Leidig, Kai, Gaißer, Steffen, Pätschke, Susann, Schweigert, Robin, Wenzel, Sebastian, and Klinkner, Sabine

Subjects
operations system, ground system, operating system, satellite, programming
Abstract

The term operating system refers to a software component, which traditionally controls the resources and the processes of a computer, and by providing the appropriate interfaces allows for the implementation of custom user applications. This is a common definition, working very well for ordinary computer systems. Yet, what if the operating system and a corresponding application are physically separated, because the computer is within a satellite in space, while the user program is executed on ground? Then, capabilities must be created to connect both, which is of course complicated by the natural boundaries in satellite communication, for example the limited satellite contact times. Over the past decades, several systems have been developed, which are capable of managing satellite resources and the mission schedule from ground. Although this covers quite well the purpose of an operating system, other terms have evolved in this domain: operations system, ground system, mission control system, ground data handling, etc. The problem though is, those systems primarily focus on the exchange of data and satellite TM/TC, rather than the actual control process. This creates an artificial barrier between ground and space, which harms the development capabilities for ground based satellite applications. This paper introduces a novel approach for an operations system architecture, which can be considered as a ground extension of the satellite’s operating system. This approach shall not break with the existing conventions and definitions, especially in terms of operating systems, but shall introduce a new view on satellite operations. In a layered, functional software architecture, the operating system is the lowest layer between the hardware and the application. Through the definition of the appropriate interfaces in the ground system, a software architecture can be created that actively supports outsourcing parts of the satellite control process to ground. The proposed approach has great potential for various applications in satellite operations. It supports the implementation of automatic system control processes, the implementation of custom payload applications, and the integration of respective activities into the satellite schedule. As applications and operators interact with a verified schedule, and operations is thus no longer limited to low-level commanding, the approach further reduces the risk of the mission being jeopardized by human mistake.

Published
2021

37. Stereoscopic Meteor Observation: Determining Satellite Bus and Formation Parameters Requirements

Author

Petri, Jona and Klinkner, Sabine

Subjects
parameters, observation, bus, satellite, formation, determining, Astrophysics::Earth and Planetary Astrophysics, requirements, meter, Physics::History of Physics, stereoscopic
Abstract

The Institute of Space Systems (IRS) of the University of Stuttgart and the TU Berlin are planning a mission to observe meteors and dust particles using a formation of two small satellites. In this paper, we analyse the formation and satellite parameters to optimize the scientific output of the meteor observation. The stereoscopic observation of meteors allows calculating the corresponding meteor trajectory. The potential output of a meteor observation strongly depends on the configuration of the satellite formation (orbit, satellite distance) and the satellite bus parameters (knowledge of satellite position and attitude). Therefore, a simulation, based on the trajectory algorithm of the Meteor Orbit and Trajectory Determination Software (MOTS), is conducted, in order to calculate the accuracy of the meteor trajectory depending on those parameters. Furthermore, different meteor properties are taken into account to evaluate the influence on the accuracy of the calculated trajectory. According to our simulations, the satellite attitude knowledge has a huge influence on the trajectory accuracy, while the position knowledge is less relevant. Furthermore, the simulation allows calculating the ideal satellite distance with a minimal trajectory error for a specific orbit. The trajectory error is ~200 m, when typical errors on satellite position and attitude knowledge (7”) are used.

Published
2020

38. Pointing Enhancement for an Optical Laser Downlink Using Automated Image Processing

Author

Wenzel, Sebastian, Gaisser, Steffen, Kley, Christian, Reinhart, Johannes, and Klinkner, Sabine

Subjects
enchancement, optical, point, downlink, laser, automation, image processing
Abstract

The small satellite Flying Laptop, launched in July 2017, was developed and built by graduate and undergraduate students at the Institute of Space Systems of the University of Stuttgart with support by space industry and research institutions. The mission goals are technology demonstration, earth observation, and serving as an educational satellite. At a mass of 110 kg, it features three-axis stabilized attitude control and several payloads, including an AIS receiver, a multi spectral camera system, a wide angle camera, and an optical communication terminal. The pointing requirement for the optical communication is an accuracy of less than 150 arcseconds during a target overflight. To fulfill this requirement, several measures are needed. A major part of them is the characterization of the attitude control system (ACS). Since there is no optical receiver onboard, it is not possible to perform closed loop tracking of the satellite attitude. Therefore, the absolute performance and the characteristic noise levels of the attitude control system, can only be determined with other payloads. In this case the multi-spectral camera system was used, providing a ground resolution of 25 m. To use the images from the satellite to improve the ACS, three steps have to be taken. As a first action, the images have to be georeferenced to know the position of each pixel in the WGS84 coordinate system. With this information, the deviation of the image center from the desired target is measured. This second step includes the calculation of the deviation matrix. To avoid a corruption of the attitude control of the satellite, the matrix is checked for unrealistic values in a third and final step. These three actions can be repeated as needed without human interaction. By updating the ACS model onboard the satellite, the results of the image processing are used to correct the off-pointing. This deviation is time invariant and is caused by an insufficient alignment of the satellite axes and the cameras on ground. In contrast to that, characterizing noise as a time variant factor, the ACS is tested over a long period of time. This is achieved by analyzing images from one, as well as from multiple target overflights. This conquers the issue of a very low image rate while observing high frequency attitude changes. Using this mechanism, the proposed process can be used to continuously monitor the pointing quality. As a first approach the described processing is done manually by comparing the target position on Earth with the center of the taken image. The method successfully showed an improvement of the pointing in the pictures, paving the way for their automation. This paper gives an overview of the needed image processing and tools to automatically use cameras on board the satellite to validate and improve the ACS periodically. First results of the long term characteristics and pointing improvements are shown.

Published
2020

39. A small satellite with a dual-frequency heterodyne spectrometer for the detection of atomic oxygen in the atmosphere of Earth

Author

Richter, Heiko, Hildebrandt, Jerome, Roth, Thomas, Lengowski, Michael, Philpot, Claudia, Braukhane, A., Delovski, Toni, Wienold, Martin, Klinkner, Sabine, and Hübers, Heinz-Wilhelm

Subjects
heterodyne, satellite, Systementwicklung und Projektbüro, THz, Terahertz- und Laserspektroskopie, Systemanalyse Raumsegment, Atomic Oxygen
Abstract

A first step towards realization, a small satellite study for OSAS (Oxygen Spectrometer for Atmospheric Science) has been performed based on Concurrent Engineering methods.

Published
2020

41. Status of the STUDIO UV balloon mission and platform

Author

Pahler, Andreas, primary, Ångermann, Maria, additional, Barnstedt, Jürgen, additional, Bougueroua, Sarah, additional, Colin, Angel, additional, Conti, Lauro, additional, Diebold, Sebastian, additional, Duffard, Rene, additional, Emberger, Moritz, additional, Hanke, Lars, additional, Kalkuhl, Christoph, additional, Kappelmann, Norbert, additional, Keilig, Thomas, additional, Klinkner, Sabine, additional, Krabbe, Alfred, additional, Janson, Olle, additional, Lengowski, Michael, additional, Lockowandt, Christian, additional, Maier, Philipp, additional, Müller, Thomas, additional, Rauch, Thomas, additional, Schanz, Thomas, additional, Stelzer, Beate, additional, Taheran, Mahsa, additional, Vaerneus, Alf, additional, Werner, Klaus, additional, and Wolf, Jürgen, additional

Published
2020
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43. Miniaturized Single-Shot Valve and its Application to the ExoMars Pasteur Payload

Author

Muller, Pierre, Henkel, Hartmut, and Klinkner, Sabine

Subjects
Space Sciences (General)
Abstract

Hermetically sealing a gas tank and opening it into tubing under telecommand control is a function required in various space instruments. There are a number of space valves that are power saving, withstand vibration, and do not contaminate the gas. But none of them combines these features with low mass and the ability to withstand temperatures of 130 C during the sterilization process mandatory for planetary missions. In this paper, a novel miniature valve is presented, which is particularly adapted to space applications. It is electrically actuated, utilizing a bimetallic snap-disc that pierces a metallic membrane by a needle pin, thereby opening the valve. The design of this single-shot valve is such that it allows it to withstand a temperature of 130 C and a pressure of 50 bars. The valve is also lightweight (6.62 g) and it requires only 9 W to operate.

Published
2010

44. Integrated Research Platform for Affordable Satellites

Author

Stäbler, Tina, Echsel, Markus, Ehresmann, Manfred, Fugmann, Martin, Galla, Daniel, Gottschalk, Nicole, Hümbert, Simon, Lengowski, Michael, Marigo, Gloria, Müller, Ilja, Sakraker, Isil, Skalden, Jonathan, Springer, Patrrick, Stindl, Torsten, Fasoulas, Stefanos, Klinkner, Sabine, and Voggenreiter, Heinz

Subjects
IRAS, CubeSats, Satellites, Additive Manufacturing, Automotive Electronics, Concurrent Engineering
Published
2019

45. Improvements in Attitude Determination and Control of the Small Satellite Flying Laptop

Author

Gaisser, Steffen, Mohr, Ulrich, Keim, Jonas, Triloff, Daniel, and Klinkner, Sabine

Subjects
Improvements in Attitude Determination, Control, Flying Laptop, Small Satellite
Abstract

Precise attitude control is a key factor of many payloads with high ground resolutions, small fields of view or narrow beams such as an optical data downlink. The small satellite Flying Laptop (FLP), launched in July 2017, was developed by graduate and undergraduate students at the Institute of Space Systems of the University of Stuttgart with support by the space industry and research institutions. The satellite is three-axis stabilized with reaction wheels as main actuators. FLP is equipped with the OSIRIS optical data downlink which was built by the German Aerospace Center (DLR). As this instrument is body mounted on an optical bench, the attitude determination and control system (ACS) is required to point the whole satellite in the direction of the ground station with a high pointing accuracy of 150 arcseconds. At the time of launch the ACS did not reach this precision. This paper describes how the attitude determination and control were improved to achieve the required performance. The improvements can be divided into two parts. The first part includes the enhancement of on-board sensor processing and attitude control. In the second part, in-orbit data were utilized to increase the accuracy of parameters which are used to control the spacecraft. The first part includes the addition of a Kalman filter, an improved position propagation, and the introduction of adaptive gains to the on-board ACS. The FLP simulation test bed was used to verify the changes. The test bed was also used to find adequate initial values for the Kalman filter and to find inaccuracies in the sensor processing. In the second part, the adaptive gains and the Kalman initial values were validated in-orbit after the upload of the new sensor processing. Moreover, the on-board component orientation settings were corrected for the star trackers, the multi-spectral camera system, and the OSIRIS instrument on FLP. As a result, the satellite fulfills the pointing requirement of less than 150 arcsecond deviation from the target attitude for a sufficient period of time during a pass over the target. Successful links with the optical data downlink were demonstrated with the DLR ground station in Oberpfaffenhofen.

Published
2019

50. Towards a European Stratospheric Balloon Observatory: The ESBO design study

Author

European Commission, Maier, Philipp, Wolf, Jürgen, Keilig, Thomas, Krabbe, Alfred, Duffard, René D., Ortiz, José Luis, Klinkner, Sabine, Lengowski, Michael, Müller, Thomas, Lockowandt, Christian, Krockstedt, Christian, Kappelmann, Norbert, Stelzer, Beate, Werner, Klaus, Geier, Stephan, Kalkuhl, Christoph, Rauch, Thomas, Schanz, Thomas, Barnstedt, Jürgen, Conti, Lauro, Hanke, Lars, European Commission, Maier, Philipp, Wolf, Jürgen, Keilig, Thomas, Krabbe, Alfred, Duffard, René D., Ortiz, José Luis, Klinkner, Sabine, Lengowski, Michael, Müller, Thomas, Lockowandt, Christian, Krockstedt, Christian, Kappelmann, Norbert, Stelzer, Beate, Werner, Klaus, Geier, Stephan, Kalkuhl, Christoph, Rauch, Thomas, Schanz, Thomas, Barnstedt, Jürgen, Conti, Lauro, and Hanke, Lars

Abstract

This paper presents the concept of a community-accessible stratospheric balloon-based observatory that is currently under preparation by a consortium of European research institutes and industry. The planned European Stratospheric Balloon Observatory (ESBO) aims at complementing the current landscape of scientific ballooning activities by providing a service-centered infrastructure tailored towards broad astronomical use. In particular, the concept focuses on reusable platforms with exchangeable instruments and telescopes performing regular flights and an operations concept that provides researchers with options to test and operate own instruments, but later on also a proposal-based access to observations. It thereby aims at providing a complement to ground-, space-based, and airborne observatories in terms of access to wavelength regimes - particularly the ultraviolet (UV) and far infrared (FIR) regimes -, spatial resolution capability, and photometric stability. Within the currently ongoing ESBO Design Study (ESBO DS), financed within the European Union's Horizon 2020 Programme, a prototype platform carrying a 0.5-m telescope for UV and visible light observations is being built and concepts for larger following platforms, leading up to a next-generation FIR telescope are being studied. A flight of the UV/visible prototype platform is currently foreseen for 2021. We present the technical motivation, science case, instrumentation, and a two-stage image stabilization approach of the 0.5-m UV/visible platform. In addition, we briefly describe the novel mid-sized stabilized balloon gondola under design to carry telescopes in the 0.5 to 0.6 m range as well as the currently considered flight option for this platform. Secondly, we outline the scientific and technical motivation for a large balloon-based FIR telescope and the ESBO DS approach towards such an infrastructure. © 2018 SPIE.

Published
2018

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