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An Orbit Control System for UWE-4 Using the High Fidelity Simulation Tool OrekitAzari, Pouyan January 2017 (has links)
Cubesats are picosatellites that have a mass of less than 1.3kg and have a shape of acube. As a result of their low cost of development and launch, cubesats are gainingpopularity in industry and academia. These satellites are also a cost-efective way forspace technology demonstrations. University of Würzburg has a longstanding cubesatprogram started with the launch of UWE-1 in 2005. This was followed by UWE-2 andUWE-3. Several technologies were tested and validated using the UWE platform. Thelast mission UWE-3 has successfully tested an attitude control system.In the next mission, UWE-4 will demonstrate an orbit control system. Being a picosatellite as small as this one (10 x 10 x 10cm 3 and 1kg) brings new challenges intodi↵erent aspects of satellite design, development, control and operation. The orbit con-trol of such a satellite is one of the problems that should be tackled. Being such a smallsatellite means having less propellant mass and much smaller thrusters than conventionalsatellites. These should be addressed in the orbit control. UWE-4 will take advantage of four NanoFEEP thrusters, on one side. Because of theiraccuracy and functionality, these thrusters can be used to implement a continuous thrustsystem. They are also a good choice because of their low energy usage. This work startswith the preparation that was needed to implement a control system. Then explains thestate of the art for continuous thrust control systems. Implements two di↵erent methods,based on perfect control and discusses the outcome. It discuses the limiting factors, likefuel mass, available electrical energy and their e↵ect on the controller performance andconcludes with recommendation for the future researches. / UWE-4
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Attitude and Orbit Control of Small Satellites for Autonomous Terrestrial Target TrackingIbrahim, Najmus 28 November 2013 (has links)
Terrestrial target tracking using low Earth orbit satellites provides essential daily services and vital scientific data. In this thesis, the Attitude and Orbit Control System of such a terrestrial tracking satellite, Nanosatellite for Earth Monitoring and Observation Aerosol Monitor, is presented in detail. The satellite is a new generation Earth observation mission with the objective of detecting global atmospheric aerosol content through sub-degree pointing. The design is presented from initial hardware selection and budget development to operation definition and mission operation. The efficacy of performing precise autonomous Earth-pointing on a small satellite platform is validated through high fidelity simulations involving satellite and environmental dynamics, test-characterized hardware models and flight software-in-the-loop. The results provide practical target tracking methodologies which in the past have been publicly inaccessible to the author's best knowledge and which can be now be applied to a broad range of precise Earth-pointing satellites.
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Attitude and Orbit Control of Small Satellites for Autonomous Terrestrial Target TrackingIbrahim, Najmus 28 November 2013 (has links)
Terrestrial target tracking using low Earth orbit satellites provides essential daily services and vital scientific data. In this thesis, the Attitude and Orbit Control System of such a terrestrial tracking satellite, Nanosatellite for Earth Monitoring and Observation Aerosol Monitor, is presented in detail. The satellite is a new generation Earth observation mission with the objective of detecting global atmospheric aerosol content through sub-degree pointing. The design is presented from initial hardware selection and budget development to operation definition and mission operation. The efficacy of performing precise autonomous Earth-pointing on a small satellite platform is validated through high fidelity simulations involving satellite and environmental dynamics, test-characterized hardware models and flight software-in-the-loop. The results provide practical target tracking methodologies which in the past have been publicly inaccessible to the author's best knowledge and which can be now be applied to a broad range of precise Earth-pointing satellites.
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Thermal Models for a 3 cm Miniature Xenon Ion ThrusterYounger, Coleman Thomas 01 December 2010 (has links) (PDF)
In order to support UCLA’s development of the 3 cm Miniature Xenon Ion (MiXI) thruster, Cal Poly has a 3 cm thruster under development. This version, called MiXI Cal Poly Version 1 (MiXI-CPv1), is complete and has been utilized in vacuum chamber thermal validation testing. Testing on this version was used to check the validity of heat transfer simulations modeled in SolidWorks. Investigations of the 3 cm ion thruster configuration were intended to discover the driving factors affecting the thermal behavior of the discharge chamber and surrounding design space.
Numerical simulations indicate that the heating of the samarium cobalt permanent magnets can be mitigated through the implementation of two proposed modifications. The first modification is to implement a 2% thoriated tungsten filament cathode. This design exhibited maximum permanent magnet temperatures of 325°C, twenty-five degrees below the maximum upper temperature of 350°C. Since some magnetic degaussing effects have been observed at temperatures above 300°C, the aforementioned solution can be combined with a thruster design modification to achieve a reduced permanent magnet temperature of 298°C. This modification would involve increase the anode wall thickness from approximately 0.7 mm to 2 mm below the permanent magnet ring, creating a stepped anode design. Additionally, less effective solutions were proposed and modeled and are presented for completeness.
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An attitude and orbit determination and control system for a small geostationary satelliteThopil, G. A. 12 1900 (has links)
Thesis (MScEng (Electrical and Electronic Engineering))--University of Stellenbosch, 2006. / An analysis of the attitude determination and control system required for a
small geostationary satellite is performed in this thesis. A three axis quaternion
feedback reaction wheel control system is the primary control system used to meet the
stringent accuracy requirements. A momentum bias controller is also evaluated to
provide redundancy and to extend actuator life.
Momentum dumping is preformed by magnetic torque rods using a crossproduct
controller. Performance of three axis thruster control is also evaluated. A full
state Extended Kalman filter is used to determine attitude and body angular rates
during normal operation whereas a Multiplicative Extended Kalman Filter is used
during attitude manoeuvres.
An analytical orbit control study is also performed to calculate the propellant
required to perform station-keeping, for a specific sub-satellite location over a ten
year period. Finally an investigation on the effects caused by thruster misalignment,
on satellite attitude is also performed.
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Autonomous Orbit Control with on-board collision risk management / Autonom banreglering med inbyggd kollisionsriskhanteringLabbe, Clément January 2021 (has links)
Many satellites have an orbit of reference defined according to their mission. The satellites need therefore to navigate as close as possible to their reference orbit. However, due to external forces, the trajectory of a satellite is disturbed and actions need to be taken. For now, the trajectories of the satellites are monitored by the operations of satellites department which gives appropriate instructions of navigation to the satellites. These steps require a certain amount of time and involvement which could be used for other purposes. A solution could be to make the satellites autonomous. The satellites would take their own decisions depending on their trajectory. The navigation control would be therefore much more efficient, precise and quicker. Besides, the autonomous orbit control could be coupled with an avoidance collision risk management. The satellites would decide themselves if an avoidance maneuver needs to be considered. The alerts of collisions would be given by the ground segment. In order to advance in this progress, this internship enables to analyse the feasibility of the implementation of the two concepts by testing them on an experiments satellite. To do so, tests plans were defined, tests procedures were executed and post-treatment tools were developed for analysing the results of the tests. Critical computational cases were considered as well. The tests were executed in real operations conditions. / Många satelliter har en referensbana definierad enligt deras uppdrag. Satelliterna behöver därför navigera så nära deras referensbana som möjligt. På grund av externa krafter störs dock satellitbanan och åtgärder måste vidtas. För närvarande övervakas satellitbanorna av satellitavdelningar på marken vilka ger lämpliga instruktioner för navigering till satelliterna. Dessa steg kräver en tid och engagemang som skulle kunna användas för andra ändamål. En lösning är att göra satelliterna autonoma. Satelliterna skulle då kunna ta sina egna beslut beroende på deras bana. Navigeringskontrollen skulle därför vara mycket mer effektiv, exakt och snabbare. Dessutom kan den autonoma banregleringen kopplas till riskhantering för undvikande av kollision med rymdskrot och andra satelliter. Satelliterna skulle själva avgöra om en undvikande manöver måste övervägas. Varningar om kollisioner skulle ges av marksegmentet. För att gå vidare i denna utveckling analyserar detta arbete genomförbarheten av implementeringen av olika koncept för undanmanövrar genom att testa dem på en experimentsatellit. För att göra detta definierades testplaner, testprocedurer utfördes och efterbehandlingsverktyg utvecklades för analys av testresultaten. Kritiska beräkningsfall togs fram. Testerna utfördes under verkliga driftsförhållanden.
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Integration and validation of a nanosatellite flight software (ESA OPS-SAT project) / Integration och validering av flygprogramvara för nanosatelliter inom projektet ESA OPS-SATSurivet, Anthony January 2021 (has links)
With the increasing number of satellites operating in orbit and the development of nanosatelliteconstellations, it has become more and more arduous for operators to keep track of every satellitestate, and perform corrective or avoidance manoeuvres. That is why CNES, the French space agency,is developing new algorithms, which aimed at making satellites more self-su cient. More especially,these algorithms are in charge of autonomous orbit control, collision risk calculations and satellitestatus monitoring. In this thesis, we present the architecture of these three algorithms and how theyinteract between them to deal with the autonomous control of a satellite. In addition, this paper studiestheir integration within the OPS-SAT nanosatellite, which is an in-orbit demonstrator developed bythe European Space Agency (ESA) and opened to worldwide experimenters. By analysing the dataused by the numerical propagators, the size of the input configuration files sent to the nanosatellitewas optimised. Thanks to this optimisation, the size of telecommands sent during each OPS-SATflyby above the ESOC ground station meets the requirements. Due to some issues encountered with the nanosatellite’s GPS, a solution was found to update thecurrent orbit on-board, and thus allow the proper algorithms’ operation. This thesis also introduceshow the tests were carried out in order to validate these algorithms, both on flat-sat and on the realsatellite. The results demonstrate that their integration on the OPS-SAT numerical environment issuccessful, meaning that the algorithms and their dependences are correctly packaged, sent and uploaded,and that they work as expected. Their execution time are of course longer due to the limitedcalculation capacity of the on-board computer, but are still compatible with real operations, except forthe collision risk computation, which can exceed the orbital period depending on the initial conditions.Finally, the thesis presents the process of real operations for one of the three algorithms developed byCNES, the di culties encountered and the solutions considered. / Med det ökande antalet satelliter i omloppsbana och utvecklingen av nanosatellitkonstellationer hardet blivit mer och mer krävande för operatörer att hålla reda på varje satellits tillstånd och utförakorrigerande eller undvikande manövrar. Det är därför som CNES, den franska rymdorganisationen,utvecklar nya algoritmer som syftar till att göra satelliter mer autonoma. Närmare bestämt ansvarardessa algoritmer för autonom omloppsbanereglering, kollisionsriskberäkningar och satellitstatusövervakning.I detta examensarbete presenterar vi arkitekturen för dessa tre algoritmer och hur de interagerarmellan sig för att hantera den autonoma styrningen av en satellit. Dessutom studeras deras integrationinom OPS-SAT-nanosatelliten, som är en demonstrator i omloppsbana som utvecklats av Europeiskarymdorganisationen (ESA) och öppnad för globala experiment. Genom att analysera de datasom används av de numeriska propagatorerna optimerades storleken på de ingångskonfigurationsfilersom skickades till nanosatelliten. Tack vare denna optimering uppfylls storlekskraven på telekommandonsom skickas under varje passage av OPS-SAT ovanför ESOC-markstationen. På grund av vissa problem med nanosatellitens GPS hittades en lösning för att uppdatera den aktuellaomloppsbanan ombord och därmed möjliggöra korrekt funktion av algoritmerna. Detta examensarbeteintroducerar också hur testerna genomfördes för att validera dessa algoritmer, både på en s.k. flat-satoch på den verkliga satelliten. Resultaten visar att deras integration i den numeriska miljön OPS-SATär framgångsrik, vilket innebär att algoritmerna och deras beroende är korrekt förpackade, skickade ochuppladdade och att de fungerar som förväntat. Deras exekveringstid är naturligtvis längre på grundav den inbyggda datorns begränsade beräkningskapacitet, men är fortfarande kompatibel med verkligaoperationer, förutom beräkningen av kollisionsrisk, som kan överstiga omloppsperioden beroende påde initiala förhållandena. Slutligen presenterar rapporten processen för verkliga operationer för en avde tre algoritmerna som utvecklats av CNES, svårigheterna och de lösningar som övervägs.
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Attitude and Orbit Control During Deorbit of Tethered Space DebrisFlodin, Linus January 2015 (has links)
Due to the unsustainable space debris environment in Low Earth Orbit, debris objects must be removed to ensure future safe satellite operations. One proposed concept for deorbiting larger space debris objects, such as decommissioned satellites or spent upper rocket stages, is to use a chaser spacecraft connected to the debris object by an elastic tether, but the required technology is immature and there is a lack of flight experience. The inoperable satellite, Envisat, has been chosen as a representative object for controlled re-entry by performing several high thrust burns. The aim of this paper is to develop a control system for the deorbit phase of such a mission. Models of the spacecraft dynamics, the tether, and sensors are developed to create a simulator. Two different tether models are considered: the massless model and the lumped mass model. A switched linear-quadratic-Gaussian (LQG) controller is designed to control the relative position of the debris object, and a switched proportional-integral-derivative (PID) controller is designed for attitude control. Feedforward compensation is used to counteract the couplings between relative position and attitude dynamics. An analysis of the system suggests that the tether should be designed in regard to the control system and it is found that the lumped mass model comes with higher cost than reward compared to the massless tether model in this case. Simulations show that the control system is able to control the system under the influence of modeling errors during a multi-burn deorbit strategy and even though more extensive models are suggested to enable assessment of the feasibility to perform this mission in reality, this study has resulted in extensive knowledge and valuable progress in the technical development. / En ökande mängd rymdskrot har lett till en ohållbar miljö i låga omloppsbanor och föremål måste nu tas bort för att säkerställa framtida satellitverksamhet. En föreslagen metod för att avlägsna större skrotföremål, såsom avvecklade satelliter och använda övre raketsteg, är att koppla en jagande rymdfarkost till föremålet med en elastisk lina. Dock är den teknik som behövs inte mogen och det finns en brist på praktisk erfarenhet. Den obrukbara satelliten Envisat har valts som representativt objekt för kontrollerat återinträde genom flera perigeumsänkande raketmanövrar. Syftet med detta arbete är att utveckla ett system för att kontrollera de två sammankopplade rymdfarkosterna under avlägsningsfasen under ett sådant uppdrag. Modeller för farkosternas dynamik, den sammankopplande linan och sensorer byggs för att utveckla en simulator. Två olika modeller för linan undersöks: den masslösa modellen och den klumpade nodmassmodellen. En omkopplande regulator designas genom minimering av kvadratiska kriterier för att kontrollera skrotföremålets relativa position till den jagande farkosten. Vidare designas en omkopplande proportionerlig-integrerande-deriverande (PID) regulator för att reglera pekningen hos den jagande farkosten. Kompensering genom framkoppling används för att motverka de korskopplingar som förekommer mellan translations- och rotationsdynamiken. En analys av systemet visar att linan bör designas med reglersystemet i åtanke och det framkommer att nackdelarna överväger fördelarna för den klumpade nodmassmodellen jämfört med den masslösa modellen. Simuleringar visar att reglersystemet klarar att kontrollera systemet under ett scenario med flera manövrar och under inverkan av modellfel. Även om mer omfattande modeller föreslås för att möjliggöra en fullständig bedömning av genomförbarheten för detta uppdrag så har denna studie resulterat i en omfattande kunskapsvinst och värdefulla framgångar i det tekniska utvecklingsarbetet.
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