Your search keyword '"Becedas, J."' showing total 88 results

1. Design of an Intake and a Thruster for an Atmosphere-Breathing Electric Propulsion System

Author

Romano, F., Herdrich, G., Chan, Y. -A., Crisp, N. H., Roberts, P. C. E., Holmes, B. E. A., Edmondson, S., Haigh, S., Macario-Rojas, A., Oiko, V. T. A., Smith, L. A. Sinpetru K., Becedas, J., Sulliotti-Linner, V., Bisgaard, M., Christensen, S., Hanessian, V., Jensen, T. Kauffman, Nielsen, J., Fasoulas, S., Traub, C., García-Almiñana, D., Rodríguez-Donaire, S., Sureda, M., Kataria, D., Belkouchi, B., Conte, A., Seminari, S., and Villain, R.

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Challenging space missions include those at very low altitudes, where the atmosphere is source of aerodynamic drag on the spacecraft that finally defines the missions lifetime unless way to compensate for it is provided. This environment is named Very Low Earth Orbit (VLEO) and is defined for $h<450~km$. In addition to the satellite's aerodynamic design, to extend the lifetime of such missions an efficient propulsion system is required. One solution is Atmosphere-Breathing Electric Propulsion (ABEP) that collects atmospheric particles to be used as propellant for an electric thruster. The system would minimize the requirement of limited propellant availability and can also be applied to any planetary body with atmosphere, enabling new missions at low altitude ranges for longer times. One of the objectives of the H2020 DISCOVERER project, is the development of an intake and an electrode-less plasma thruster for an ABEP system. The article describes the characteristics of intake design and the respective final deigns providing collection efficiencies up to $94\%$. On the other side, the radio frequency (RF) Helicon-based plasma thruster (IPT) developed at IRS, is hereby presented as well, while its performances are being evaluated, the thruster has been operated with single atmospheric species as propellant, and has highlighted very low input power requirement for operation at comparable mass flow rates $P\sim 60~W$., Comment: arXiv admin note: substantial text overlap with arXiv:2106.15912

Published

2022

2. Development and analysis of novel mission scenarios based on Atmosphere-Breathing Electric Propulsion (ABEP)

Author

Vaidya, S., Traub, C., Romano, F., Herdrich, G., Chan, Y. -A., Fasoulas, S., Roberts, P. C. E., Crisp, N., Edmondson, S., Haigh, S., Holmes, B. A., Macario-Rojas, A., Oiko, V. T. Abrao, Smith, K., Sinpetru, L., Becedas, J., Sulliotti-Linner, V., Christensen, S., Hanessian, V., Jensen, T. K., Nielsen, J., Bisgaard, M., Garcia-Alminana, D., Rodriguez-Donaire, S., Suerda, M., Garcia-Berenguer, M., Kataria, D., Villain, R., Seminari, S., Conte, A., and Belkouchi, B.

Subjects

Physics - Space Physics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Operating satellites in Very Low Earth Orbit (VLEO) benefits the already expanding New Space industry in applications including Earth Observation and beyond. However, long-term operations at such low altitudes require propulsion systems to compensate for the large aerodynamic drag forces. When using conventional propulsion systems, the amount of storable propellant limits the maximum mission lifetime. The latter can be avoided by employing Atmosphere-Breathing Electric Propulsion (ABEP) system, which collects the residual atmospheric particles and uses them as propellant for an electric thruster. Thus, the requirement of on-board propellant storage can ideally be nullified. At the Institute of Space Systems (IRS) of the University of Stuttgart, an intake, and a RF Helicon-based Plasma Thruster (IPT) for ABEP system are developed within the Horizons 2020 funded DISCOVERER project. In order to assess possible future use cases, this paper proposes and analyzes several novel ABEP based mission scenarios. Beginning with technology demonstration mission in VLEO, more complex mission scenarios are derived and discussed in detail. These include, amongst others, orbit maintenance around Mars as well as refuelling and space tug missions. The results show that the ABEP system is not only able to compensate drag for orbit maintenance but also capable of performing orbital maneuvers and collect propellant for applications such as Space Tug and Refuelling. Thus, showing a multitude of different future mission applications.

Published

2022

3. Intake Design for an Atmosphere-Breathing Electric Propulsion System (ABEP)

Author

Romano, F., Espinosa-Orozco, J., Pfeiffer, M., Herdrich, G., Crisp, N. H., Roberts, P. C. E., Holmes, B. E. A., Edmondson, S., Haigh, S., Livadiotti, S., Macario-Rojas, A., Oiko, V. T. A., Sinpetru, L. A., Smith, K., Becedas, J., Sulliotti-Linner, V., Bisgaard, M., Christensen, S., Hanessian, V., Jensen, T. Kauffman, Nielsen, J., Chan, Y. -A., Fasoulas, S., Traub, C., García-Almiñana, D., Rodríguez-Donaire, S., Sureda, M., Kataria, D., Belkouchi, B., Conte, A., Seminari, S., and Villain, R.

Subjects

Physics - Space Physics

Abstract

Challenging space missions include those at very low altitudes, where the atmosphere is source of aerodynamic drag on the spacecraft. To extend the lifetime of such missions, an efficient propulsion system is required. One solution is Atmosphere-Breathing Electric Propulsion (ABEP) that collects atmospheric particles to be used as propellant for an electric thruster. The system would minimize the requirement of limited propellant availability and can also be applied to any planetary body with atmosphere, enabling new missions at low altitude ranges for longer times. IRS is developing, within the H2020 DISCOVERER project, an intake and a thruster for an ABEP system. The article describes the design and simulation of the intake, optimized to feed the radio frequency (RF) Helicon-based plasma thruster developed at IRS. The article deals in particular with the design of intakes based on diffuse and specular reflecting materials, which are analysed by the PICLas DSMC-PIC tool. Orbital altitudes $h=150-250$ km and the respective species based on the NRLMSISE-00 model (O, $N_2$, $O_2$, He, Ar, H, N) are investigated for several concepts based on fully diffuse and specular scattering, including hybrid designs. The major focus has been on the intake efficiency defined as $\eta_c=\dot{N}_{out}/\dot{N}_{in}$, with $\dot{N}_{in}$ the incoming particle flux, and $\dot{N}_{out}$ the one collected by the intake. Finally, two concepts are selected and presented providing the best expected performance for the operation with the selected thruster. The first one is based on fully diffuse accommodation yielding to $\eta_c<0.46$ and the second one based un fully specular accommodation yielding to $\eta_c<0.94$. Finally, also the influence of misalignment with the flow is analysed, highlighting a strong dependence of $\eta_c$ in the diffuse-based intake while, ..., Comment: Accepted Version

Published

2021

4. In-Orbit Aerodynamic Coefficient Measurements using SOAR (Satellite for Orbital Aerodynamics Research)

Author

Crisp, N. H., Roberts, P. C. E., Livadiotti, S., Rojas, A. Macario, Oiko, V. T. A., Edmondson, S., Haigh, S. J., Holmes, B. E. A., Sinpetru, L. A., Smith, K. L., Becedas, J., Dominguez, R. M., Sulliotti-Linner, V., Christensen, S., Nielsen, J., Bisgaard, M., Chan, Y-A., Fasoulas, S., Herdrich, G. H., Romano, F., Traub, C., Garcia-Alminana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Belkouchi, B., Conte, A., Seminari, S., and Villain, R.

Subjects

Physics - Space Physics

Abstract

The Satellite for Orbital Aerodynamics Research (SOAR) is a CubeSat mission, due to be launched in 2021, to investigate the interaction between different materials and the atmospheric flow regime in very low Earth orbits (VLEO). Improving knowledge of the gas-surface interactions at these altitudes and identification of novel materials that can minimise drag or improve aerodynamic control are important for the design of future spacecraft that can operate in lower altitude orbits. Such satellites may be smaller and cheaper to develop or can provide improved Earth observation data or communications link-budgets and latency. Using precise orbit and attitude determination information and the measured atmospheric flow characteristics the forces and torques experienced by the satellite in orbit can be studied and estimates of the aerodynamic coefficients calculated. This paper presents the scientific concept and design of the SOAR mission. The methodology for recovery of the aerodynamic coefficients from the measured orbit, attitude, and in-situ atmospheric data using a least-squares orbit determination and free-parameter fitting process is described and the experimental uncertainty of the resolved aerodynamic coefficients is estimated. The presented results indicate that the combination of the satellite design and experimental methodology are capable of clearly illustrating the variation of drag and lift coefficient for differing surface incidence angle. The lowest uncertainties for the drag coefficient measurement are found at approximately 300 km, whilst the measurement of lift coefficient improves for reducing orbital altitude to 200 km., Comment: 19 pages, 11 figures. Accepted for publication in Acta Astronautica (2020-12-14)

Published

2020

5. The Benefits of Very Low Earth Orbit for Earth Observation Missions

Author

Crisp, N. H., Roberts, P. C. E., Livadiotti, S., Oiko, V. T. A., Edmondson, S., Haigh, S. J., Huyton, C., Sinpetru, L., Smith, K. L., Worrall, S. D., Becedas, J., Domínguez, R. M., González, D., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Chan, Y. -A., Fasoulas, S., Herdrich, G. H., Romano, F., Traub, C., García-Almiñana, D., Rodríguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heißerer, B., and Schwalber, A.

Subjects

Physics - Space Physics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Very low Earth orbits (VLEO), typically classified as orbits below approximately 450 km in altitude, have the potential to provide significant benefits to spacecraft over those that operate in higher altitude orbits. This paper provides a comprehensive review and analysis of these benefits to spacecraft operations in VLEO, with parametric investigation of those which apply specifically to Earth observation missions. The most significant benefit for optical imaging systems is that a reduction in orbital altitude improves spatial resolution for a similar payload specification. Alternatively mass and volume savings can be made whilst maintaining a given performance. Similarly, for radar and lidar systems, the signal-to-noise ratio can be improved. Additional benefits include improved geospatial position accuracy, improvements in communications link-budgets, and greater launch vehicle insertion capability. The collision risk with orbital debris and radiation environment can be shown to be improved in lower altitude orbits, whilst compliance with IADC guidelines for spacecraft post-mission lifetime and deorbit is also assisted. Finally, VLEO offers opportunities to exploit novel atmosphere-breathing electric propulsion systems and aerodynamic attitude and orbit control methods. However, key challenges associated with our understanding of the lower thermosphere, aerodynamic drag, the requirement to provide a meaningful orbital lifetime whilst minimising spacecraft mass and complexity, and atomic oxygen erosion still require further research. Given the scope for significant commercial, societal, and environmental impact which can be realised with higher performing Earth observation platforms, renewed research efforts to address the challenges associated with VLEO operations are required., Comment: 23 pages, 19 figures. Accepted for publication in Progress in Aerospace Sciences (24-04-2020)

Published

2020

6. RF Helicon-based Inductive Plasma Thruster (IPT) Design for an Atmosphere-Breathing Electric Propulsion system (ABEP)

Author

Romano, Francesco, Chan, Yung-An, Herdrich, Georg, Roberts, Peter C. E., Fasoulas, C. Traub S., Smith, K., Edmondson, S., Haigh, S., Crisp, N. H., Oiko, V. T. A., Worrall, S. D., Livadiotti, S., Huyton, C., Sinpetru, L. A., Straker, A., Becedas, J., Domínguez, R. M., González, D., Cañas, V., Sulliotti-Linner, V., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Villain, R., Perez, J. S., Conte, A., Belkouchi, B., Schwalber, A., and Heißerer, B.

Subjects

Physics - Plasma Physics

Abstract

Challenging space missions include those at very low altitudes, where the atmosphere is source of aerodynamic drag on the spacecraft. To extend such missions lifetime, an efficient propulsion system is required. One solution is Atmosphere-Breathing Electric Propulsion (ABEP). It collects atmospheric particles to be used as propellant for an electric thruster. The system would minimize the requirement of limited propellant availability and can also be applied to any planet with atmosphere, enabling new mission at low altitude ranges for longer times. Challenging is also the presence of reactive chemical species, such as atomic oxygen in Earth orbit. Such species cause erosion of (not only) propulsion system components, i.e. acceleration grids, electrodes, and discharge channels of conventional EP systems. IRS is developing within the DISCOVERER project, an intake and a thruster for an ABEP system. The paper describes the design and implementation of the RF helicon-based inductive plasma thruster (IPT). This paper deals in particular with the design and implementation of a novel antenna called the birdcage antenna, a device well known in magnetic resonance imaging (MRI), and also lately employed for helicon-wave based plasma sources in fusion research. The IPT is based on RF electrodeless operation aided by an externally applied static magnetic field. The IPT is composed by an antenna, a discharge channel, a movable injector, and a solenoid. By changing the operational parameters along with the novel antenna design, the aim is to minimize losses in the RF circuit, and accelerate a quasi-neutral plasma plume. This is also to be aided by the formation of helicon waves within the plasma that are to improve the overall efficiency and achieve higher exhaust velocities. Finally, the designed IPT with a particular focus on the birdcage antenna design procedure is presented

Published

2020

7. Chapter Earth Observation Technologies: Low-End-Market Disruptive Innovation

Author

García-Almiñana, Daniel, Huyton, Claire, Ghizoni, Leonardo, Traub, C., Smith, Kate, Edmondson, Steve, Toshiyuki Abrao Oiko, Vitor, Sinpetru, Luciana, Kataria, Dhiren, Crisp, Nicholas, Chan, Y., Dominguez, R. M., Rodriguez-Donaire, Silvia, Villain, Rachel, Belkouchi, B., Becedas, J., Bay, Kristian, Morsbøl, Jonas, Romano, Francesco, Sureda, M., Sierra, Eloi, Heißerer, B., Outlaw, R., Livadiotti, Sabrina, Roberts, Peter, Perez, J. S., Schwalber, A., Fasoulas, Stefanos, Conte, Alexis, Jungnell, Victor, Herdrich, Georg, Boxberger, Adam, Haigh, Sarah J., Lyons, Rachel, Worral, Stephen D., and Gonzalez, David

Subjects

disruptive innovation, low-end market, micro- and nano-satellites, new space, Earth Observation, bic Book Industry Communication::R Earth sciences, geography, environment, planning::RB Earth sciences

Abstract

After decades of traditional space businesses, the space paradigm is changing. New approaches to more efficient missions in terms of costs, design, and manufacturing processes are fostered. For instance, placing big constellations of micro- and nano-satellites in Low Earth Orbit and Very Low Earth Orbit (LEO and VLEO) enables the space community to obtain a huge amount of data in near real-time with an unprecedented temporal resolution. Beyond technology innovations, other drivers promote innovation in the space sector like the increasing demand for Earth Observation (EO) data by the commercial sector. Perez et al. stated that the EO industry is the second market in terms of operative satellites (661 units), micro- and nano-satellites being the higher share of them (61%). Technological and market drivers encourage the emergence of new start-ups in the space environment like Skybox, OneWeb, Telesat, Planet, and OpenCosmos, among others, with novel business models that change the accessibility, affordability, ownership, and commercialization of space products and services. This chapter shows some results of the H2020 DISCOVERER (DISruptive teChnOlogies for VERy low Earth oRbit platforms) Project and focuses on understanding how micro- and nano-satellites have been disrupting the EO market in front of traditional platforms.

Published

2020

8. In-orbit aerodynamic coefficient measurements using SOAR (Satellite for Orbital Aerodynamics Research)

Author

Crisp, N.H., Roberts, P.C.E., Livadiotti, S., Macario Rojas, A., Oiko, V.T.A., Edmondson, S., Haigh, S.J., Holmes, B.E.A., Sinpetru, L.A., Smith, K.L., Becedas, J., Domínguez, R.M., Sulliotti-Linner, V., Christensen, S., Nielsen, J., Bisgaard, M., Chan, Y.-A., Fasoulas, S., Herdrich, G.H., Romano, F., Traub, C., García-Almiñana, D., Rodríguez-Donaire, S., Sureda, M., Kataria, D., Belkouchi, B., Conte, A., Seminari, S., and Villain, R.

Published

2021

9. Chapter Optimization of an Earth Observation Data Processing and Distribution System

Author

Becedas, J., González, D., and del Mar Núñez, María

Subjects

Earth Observation, distributed systems, cloud computing, ENTICE project, gs4EO, bic Book Industry Communication::R Earth sciences, geography, environment, planning::RG Geography::RGW Geographical information systems (GIS) & remote sensing

Abstract

Conventional Earth Observation Payload Data Ground Segments (PDGS) continuously receive variable requests for data processing and distribution. However, their architecture was conceived to be on the premises of satellite operators and, for instance, has intrinsic limitations to offer variable services. In the current chapter, we introduce cloud computing technology to be considered as an alternative to offer variable services. For that purpose, a cloud infrastructure based on OpenNebula and the PDGS used in the Deimos-2 mission was adapted with the objective of optimizing it using the ENTICE open source middleware. Preliminary results with a realistic satellite recording scenario are presented.

Published

2018

10. On the exploitation of differential aerodynamic lift and drag as a means to control satellite formation flight

Author

Traub, C., Romano, F., Binder, T., Boxberger, A., Herdrich, G. H., Fasoulas, S., Roberts, P. C. E., Smith, K., Edmondson, S., Haigh, S., Crisp, N. H., Oiko, V. T. A., Lyons, R., Worrall, S. D., Livadiotti, S., Becedas, J., González, G., Dominguez, R. M., González, D., Ghizoni, L., Jungnell, V., Bay, K., Morsbøl, J., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Villain, R., Perez, J. S., Conte, A., Belkouchi, B., Schwalber, A., and Heißerer, B.

Published

2020

11. Design of an intake and a thruster for an atmosphere-breathing electric propulsion system

Author

Romano, F., primary, Herdrich, G., additional, Chan, Y.-A., additional, Crisp, N. H., additional, Roberts, P. C. E., additional, Holmes, B. E. A., additional, Edmondson, S., additional, Haigh, S., additional, Macario-Rojas, A., additional, Oiko, V. T. A., additional, Sinpetru, L. A., additional, Smith, K., additional, Becedas, J., additional, Sulliotti-Linner, V., additional, Bisgaard, M., additional, Christensen, S., additional, Hanessian, V., additional, Jensen, T. Kauffman, additional, Nielsen, J., additional, Fasoulas, S., additional, Traub, C., additional, García-Almiñana, D., additional, Rodríguez-Donaire, S., additional, Sureda, M., additional, Kataria, D., additional, Belkouchi, B., additional, Conte, A., additional, Seminari, S., additional, and Villain, R., additional

Published

2022

12. Development and analysis of novel mission scenarios based on Atmosphere-Breathing Electric Propulsion (ABEP)

Author

Vaidya, S., primary, Traub, C., additional, Romano, F., additional, Herdrich, G. H., additional, Chan, Y.-A., additional, Fasoulas, S., additional, Roberts, P. C. E., additional, Crisp, N. H., additional, Edmondson, S., additional, Haigh, S. J., additional, Holmes, B. E. A., additional, Macario-Rojas, A., additional, Oiko, V. T. A., additional, Smith, K. L., additional, Sinpetru, L. A., additional, Becedas, J., additional, Sulliotti-Linner, V., additional, Christensen, S., additional, Hanessian, V., additional, Jensen, T. K., additional, Nielsen, J., additional, Bisgaard, M., additional, Garcia-Almiñana, D., additional, Rodriguez-Donaire, S., additional, Suerda, M., additional, Garcia-Berenguer, M., additional, Kataria, D., additional, Villain, R., additional, Seminari, S., additional, Conte, A., additional, and Belkouchi, B., additional

Published

2022

13. On Line Visual-Grasping System Based on a Gripper with Two Flexible Fingers

Author

Becedas, J., González, E., Payo, I., and Feliu, V.

Published

2011

14. Intake design for an Atmosphere-Breathing Electric Propulsion System (ABEP)

Author

Romano, F., primary, Espinosa-Orozco, J., additional, Pfeiffer, M., additional, Herdrich, G., additional, Crisp, N.H., additional, Roberts, P.C.E., additional, Holmes, B.E.A., additional, Edmondson, S., additional, Haigh, S., additional, Livadiotti, S., additional, Macario-Rojas, A., additional, Oiko, V.T.A., additional, Sinpetru, L.A., additional, Smith, K., additional, Becedas, J., additional, Sulliotti-Linner, V., additional, Bisgaard, M., additional, Christensen, S., additional, Hanessian, V., additional, Jensen, T. Kauffman, additional, Nielsen, J., additional, Chan, Y.-A., additional, Fasoulas, S., additional, Traub, C., additional, García-Almiñana, D., additional, Rodríguez-Donaire, S., additional, Sureda, M., additional, Kataria, D., additional, Belkouchi, B., additional, Conte, A., additional, Seminari, S., additional, and Villain, R., additional

Published

2021

15. Generalized Proportional Integral Control for a Robot with Flexible Finger Gripper

Author

Becedas, J., Payo, I., Feliu, V., and Sira-Ramírez, H.

Published

2008

16. RF Helicon-based Inductive Plasma Thruster (IPT) Design for an Atmosphere-Breathing Electric Propulsion system (ABEP)

Author

Romano, F., Chan, Y. A., Herdrich, G., Traub, C., Fasoulas, S., Roberts, P. C.E., Smith, K., Edmondson, S., Haigh, S., Crisp, N. H., Oiko, V. T.A., Worrall, S. D., Livadiotti, S., Huyton, C., Sinpetru, L. A., Straker, A., Becedas, J., Domínguez, R. M., González, D., Cañas, V., Sulliotti-Linner, V., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Villain, R., Perez, J. S., Conte, A., Belkouchi, B., Schwalber, A., Heißerer, B., Romano, F., Chan, Y. A., Herdrich, G., Traub, C., Fasoulas, S., Roberts, P. C.E., Smith, K., Edmondson, S., Haigh, S., Crisp, N. H., Oiko, V. T.A., Worrall, S. D., Livadiotti, S., Huyton, C., Sinpetru, L. A., Straker, A., Becedas, J., Domínguez, R. M., González, D., Cañas, V., Sulliotti-Linner, V., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Villain, R., Perez, J. S., Conte, A., Belkouchi, B., Schwalber, A., and Heißerer, B.

Abstract

Challenging space missions include those at very low altitudes, where the atmosphere is source of aerodynamic drag on the spacecraft. To extend such missions lifetime, an efficient propulsion system is required. One solution is Atmosphere-Breathing Electric Propulsion (ABEP). It collects atmospheric particles to be used as propellant for an electric thruster. The system would minimize the requirement of limited propellant availability and can also be applied to any planet with atmosphere, enabling new mission at low altitude ranges for longer times. Challenging is also the presence of reactive chemical species, such as atomic oxygen in Earth orbit. Such species cause erosion of (not only) propulsion system components, i.e. acceleration grids, electrodes, and discharge channels of conventional EP systems. IRS is developing within the DISCOVERER project, an intake and a thruster for an ABEP system. The paper describes the design and implementation of the RF helicon-based inductive plasma thruster (IPT). This paper deals in particular with the design and implementation of a novel antenna called the birdcage antenna, a device well known in magnetic resonance imaging (MRI), and also lately employed for helicon-wave based plasma sources in fusion research. This is aided by the numerical tool XFdtd®. The IPT is based on RF electrodeless operation aided by an externally applied static magnetic field. The IPT is composed by an antenna, a discharge channel, a movable injector, and a solenoid. By changing the operational parameters along with the novel antenna design, the aim is to minimize losses in the RF circuit, and accelerate a quasi-neutral plasma plume. This is also to be aided by the formation of helicon waves within the plasma that are to improve the overall efficiency and achieve higher exhaust velocities. Finally, the designed IPT with a particular focus on the birdcage antenna design procedure is presented.

Published

2020

17. RF Helicon-based Inductive Plasma Thruster (IPT) Design for an Atmosphere-Breathing Electric Propulsion system (ABEP)

Author

Romano, F., primary, Chan, Y.-A., additional, Herdrich, G., additional, Traub, C., additional, Fasoulas, S., additional, Roberts, P.C.E., additional, Smith, K., additional, Edmondson, S., additional, Haigh, S., additional, Crisp, N.H., additional, Oiko, V.T.A., additional, Worrall, S.D., additional, Livadiotti, S., additional, Huyton, C., additional, Sinpetru, L.A., additional, Straker, A., additional, Becedas, J., additional, Domínguez, R.M., additional, González, D., additional, Cañas, V., additional, Sulliotti-Linner, V., additional, Hanessian, V., additional, Mølgaard, A., additional, Nielsen, J., additional, Bisgaard, M., additional, Garcia-Almiñana, D., additional, Rodriguez-Donaire, S., additional, Sureda, M., additional, Kataria, D., additional, Outlaw, R., additional, Villain, R., additional, Perez, J.S., additional, Conte, A., additional, Belkouchi, B., additional, Schwalber, A., additional, and Heißerer, B., additional

Published

2020

18. The benefits of very low earth orbit for earth observation missions

Author

Crisp, N.H., primary, Roberts, P.C.E., additional, Livadiotti, S., additional, Oiko, V.T.A., additional, Edmondson, S., additional, Haigh, S.J., additional, Huyton, C., additional, Sinpetru, L.A., additional, Smith, K.L., additional, Worrall, S.D., additional, Becedas, J., additional, Domínguez, R.M., additional, González, D., additional, Hanessian, V., additional, Mølgaard, A., additional, Nielsen, J., additional, Bisgaard, M., additional, Chan, Y.-A., additional, Fasoulas, S., additional, Herdrich, G.H., additional, Romano, F., additional, Traub, C., additional, García-Almiñana, D., additional, Rodríguez-Donaire, S., additional, Sureda, M., additional, Kataria, D., additional, Outlaw, R., additional, Belkouchi, B., additional, Conte, A., additional, Perez, J.S., additional, Villain, R., additional, Heißerer, B., additional, and Schwalber, A., additional

Published

2020

19. Inductive plasma thruster (IPT) for an atmosphere breathing electric propulsion system: Design and set in operation

Author

Francesco, Romano, Georg, Herdrich, Roberts, Peter C. E., Boxberger, A., Chan, Y. -A, Traub, C., Fasoulas, S., Smith, K., Edmondson, S., Haigh, S., Crisp, N., Abrao Oiko, V. T., Lyons, R., Worrall, S. D., Livadiotti, S., Huyton, C., Sinpetru, L., Outlaw, R., Becedas, J., Dominguez, R. M., González, D., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Villain, R., Santiago Perez, J., Conte, A., Belkouchi, B., Schwalber, A., Heißerer, B., mirko magarotto, and daniele pavarin

Published

2019

20. Modelling and Simulation of Very Low Earth Orbits

Author

GONZALEZ, D., CANAS, V., BECEDAS, J., DOMINGUEZ, R. M., ROBERTS, P. C. E., CRISP, N. H., OIKO, V. T. A., EDMONDSON, S., WORRALL, S. D., HAIGH, S., SMITH, K., LYONS, R. E., LIVADIOTTI, S., HUYTON, C., SINPETRU, L. A., RODRIGUEZ-DONAIRE, S., GARCIA-ALMINANA, D., NIETO, M., MUNOZ, C., SUREDA, M., KATARIA, D., HERDRICH, G. H., ROMANO, F., BINDER, T., BOXBERGER, A., FASOULAS, S., TRAUB, C., OUTLAW, R., GHIZONI, L., JUNGNELL, V., BAY, K., MORSBOL, J., VILLAIN, R., PEREZ, J. S., CONTE, A., BELKOUCHI, B., SCHWALBER, A., and HEIszERER, B.

Subjects

SIMULATION, AEROSPACE SYSTEMS, MODELLING, Astrophysics::Earth and Planetary Astrophysics, AERODYNAMICS, Physics::Atmospheric and Oceanic Physics

Abstract

Flying a satellite at very low earth orbit is a technological challenge. It presents advantages, such as increase resolution in optical payloads, reduce costs of launch and enhance the use of air breathing propulsion and specular materials. The density of the atmosphere at these altitudes is much higher, behaving as a free molecular flow. This has severe implications in the increase of drag torques and forces that has to be analyzed in depth. We analyze the effects and the perturbations to small satellites, affecting their dynamics, performance and lifetime by implementing and analyzing realistic models of the environment at VLEO.

Published

2019

21. On the exploitation of differential aerodynamic lift and drag as a means to control satellite formation flight

Author

Traub, C., primary, Romano, F., additional, Binder, T., additional, Boxberger, A., additional, Herdrich, G. H., additional, Fasoulas, S., additional, Roberts, P. C. E., additional, Smith, K., additional, Edmondson, S., additional, Haigh, S., additional, Crisp, N. H., additional, Oiko, V. T. A., additional, Lyons, R., additional, Worrall, S. D., additional, Livadiotti, S., additional, Becedas, J., additional, González, G., additional, Dominguez, R. M., additional, González, D., additional, Ghizoni, L., additional, Jungnell, V., additional, Bay, K., additional, Morsbøl, J., additional, Garcia-Almiñana, D., additional, Rodriguez-Donaire, S., additional, Sureda, M., additional, Kataria, D., additional, Outlaw, R., additional, Villain, R., additional, Perez, J. S., additional, Conte, A., additional, Belkouchi, B., additional, Schwalber, A., additional, and Heißerer, B., additional

Published

2019

22. Evaluation of Future Internet Technologies for Processing and Distribution of Satellite Imagery

Author

Becedas, J., primary, Pérez, R., additional, González, G., additional, Álvarez, J, additional, García, F., additional, Maldonado, F., additional, Sucari, A., additional, and García, J., additional

Published

2015

23. Measurement and modelling of PlanetLab network impairments for Fed4FIRE's geo-cloud experiment

Author

Gonzalez, G., primary, Perez, R., additional, Becedas, J., additional, Latorre, M. J., additional, and Pedrera, F., additional

Published

2014

24. Control of Flexible Manipulators. Theory and Practice

Author

Pereira E., Becedas J., Payo I., Ramos F., Feliu V., Pereira E., Becedas J., Payo I., Ramos F., and Feliu V.

Published

2010

25. Brain–Machine Interfaces: Basis and Advances

Author

Becedas, J., primary

Published

2012

26. Two-Flexible-Fingers Gripper Force Feedback Control System for Its Application as End Effector on a 6-DOF Manipulator

Author

Becedas, J, primary, Payo, I, additional, and Feliu, V, additional

Published

2011

27. Generalised proportional integral torque control for single-link flexible manipulators

Author

Becedas, J., primary, Payo, I., additional, and Feliu, V., additional

Published

2010

28. Algebraic parameters identification of DC motors: methodology and analysis

Author

Becedas, J., primary, Mamani, G., additional, and Feliu, V., additional

Published

2010

29. Open- and closed-loop algebraic identification method for adaptive control of DC motors

Author

Mamani, G., primary, Becedas, J., additional, Feliu-Batlle, V., additional, and Sira-Ramírez, H., additional

Published

2009

30. Adaptive Controller for Single-Link Flexible Manipulators Based on Algebraic Identification and Generalized Proportional Integral Control

Author

Becedas, J., primary, Trapero, J.R., additional, Feliu, V., additional, and Sira-Ramirez, H., additional

Published

2009

31. Open-loop algebraic identification method for a DC motor

Author

Mamani, G., primary, Becedas, J., additional, Feliu-Batlle, V., additional, and Sira-Ramirez, H., additional

Published

2007

32. Control of Flexible Manipulators affected by Non-Linear Friction Torque based on the Generalized Proportional Integral Concept

Author

Becedas, J., primary, Feliu, V., additional, and Sira-Ramirez, H., additional

Published

2007

33. Fast identification method to control a flexible manipulator with parameter uncertainties

Author

Becedas, J., primary, Trapero, J.R., additional, Sira-Ramirez, H., additional, and Feliu-Battle, V., additional

Published

2007

34. A fast on-line algebraic estimation of a single-link flexible arm applied to GPI control

Author

Becedas, J., primary, Trapero, J.R., additional, Mamani, G., additional, Sira-Ramirez, H., additional, and Feliu-Battle, V., additional

Published

2006

35. Implementation of a real time decoder for real neuroprosthetic applications.

Author

Becedas, J. and Quiroga, R.Q.

Published

2010

36. Algebraic Observers to Estimate Unmeasured State Variables of DC Motors.

Author

Mamani, G., Becedas, J., Feliu-Batlle, V., and Sira-Ramírez, H.

Subjects

*OBSERVABILITY (Control theory), *ESTIMATION theory, *ELECTRIC motors, *DIRECT currents, *FRICTION

Abstract

In this article, an original algebraic method is used for the estimation of state variables. The estimation is used to implement a position control scheme for DC motors. In addition, the estimation of the Coulomb's friction coefficient of the servo motor model is also investigated. The approach is based on elementary algebraic manipulations which lead to specific formulaes for the unmeasured states. The state estimation algorithm is verified by simulations. [ABSTRACT FROM AUTHOR]

Published

2008

37. KeyNote: Discoverer - Making commercial satellite operations in very low earth orbit a reality

Author

Roberts, P. C. E., Crisp, N. H., Romano, F., Herdrich, G. H., Oiko, V. T. A., Edmondson, S., Haigh, S. J., Huyton, C., Livadiotti, S., Lyons, R. E., Smith, K. L., Sinpetru, L. A., Straker, A., Worral, S. D., Becedas, J., Domínguez, R. M., González, D., Cañas, V., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Boxberger, A., Chan, Y. -A, Fasoulas, S., Traub, C., Garcia-Almiñana, D., Silvia Rodriguez-Donaire, Sureda, M., Kataria, D., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heißerer, B., and Schwalber, A.

38. Attitude control for satellites flying in VLEO using aerodynamic surfaces

Author

Munoz, V. C., Gonzalez, D., Becedas, J., Dominguez, R. M., Roberts, P. C. E., Crisp, N. H., Oiko, V. T. A., Edmondson, S., Worrall, S. D., Haigh, S., Smith, K., Lyons, R. E., Livadiotti, S., Huyton, C., Sinpetru, L. A., Rodriguez-Donaire, S., Garcia-Alminana, D., Nieto, M., Munoz, C., Miquel Sureda, Kataria, D., Herdrich, G. H., Romano, F., Binder, T., Boxberger, A., Fasoulas, S., Traub, C., Outlaw, R., Hanessian, V., Morsbol, J., Villain, R., Perez, J. S., Conte, A., Belkouchi, B., Schwalber, A., and Heisserer, B.

39. SOAR - Satellite for Orbital Aerodynamics Research

Author

Nicholas Crisp, Peter Roberts, Stephen Edmondson, Sarah Haigh, Claire Huyton, Sabrina Livadiotti, Oiko, V. T. A., Katharine Smith, Stephen Worrall, Becedas, J., Gonzalez, D., Gonzalez, G., Dominguez, R., Bay, K., Ghizoni, L., Jungnell, V., Morsbøl, J., Binder, T., Boxberger, A., Fasoulas, S., Herdrich, G., Romano, F., Traub, C., Garcia-Alminana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heiberer, A., and Schwalber, A.

Subjects

National Graphene Institute, ResearchInstitutes_Networks_Beacons/national_graphene_institute, Astrophysics::Earth and Planetary Astrophysics, Physics::Atmospheric and Oceanic Physics

Abstract

SOAR (Satellite for Orbital Aerodynamics Research) is a CubeSat mission designed to investigate the interaction between different materials and the atmospheric flow regime in Very Low Earth Orbits (VLEO) and to demonstrate aerodynamic attitude and orbit control manoeuvres. Improving knowledge of the gas-surface interactions is important for the design of future satellites operating in lower altitude orbits and will enable the identification of materials which can minimise drag or improve aerodynamic control, a key aim of the Horizon 2020 DISCOVERER project. In order to achieve these objectives, SOAR features two payloads: i) a set of steerable fins which provide the ability to expose different materials or surface finishes to the oncoming flow with varying angle of incidence whilst also providing variable geometry to investigate aero stability and aerodynamic control; and ii) an Ion and Neutral Mass Spectrometer with Time-of-Flight capability which enables accurate measurement of the in-situ flow composition, density, and thermospheric wind velocity.Using precise orbit and attitude determination information and the measured atmospheric flow characteristics the dragand side-force experienced by the satellite in orbit can studied and estimates of the aerodynamic coefficients calculated.This paper first presents the scientific design and operational concept of the SOAR mission, focusing on the stability and control strategy which enables the spacecraft to maintain the flow-pointing attitude required by the payloads. The methodology for recovery of the (relative) aerodynamic coefficients from the measured orbit and in-situ atmospheric data is then presented. Finally, the uncertainty of the resolved aerodynamic coefficients is estimated statistically using simulations.

40. RF helicon-based plasma thruster (IPT): Design, set-up, and first ignition

Author

Romano, F., Chan, Y. -A, Herdrich, G., Roberts, P. C. E., Traub, C., Fasoulas, S., Crisp, N., Edmondson, S., Haigh, S., Holmes, B. A., Livadiotti, S., Alejandro Macario Rojas, Abrao Oiko, V. T., Smith, K., Sinpetru, L., Becedas, J., Dominguez, R. M., Christensen, S., Jensen, T. K., Nielsen, J., Bisgaard, M., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Garcia-Berenguer, M., Kataria, D., Villain, R., Seminari, S., Conte, A., and Belkouchi, B.

Subjects

ResearchInstitutes_Networks_Beacons/dalton_nuclear_institute, Dalton Nuclear Institute

Abstract

To extend missions lifetime at very low altitudes, an efficient propulsion system is required to compensate for aerodynamic drag. One solution is Atmosphere-Breathing Electric Propulsion (ABEP). It collects atmospheric particles to be used as propellant for an electric thruster. The system ideally nullifies the requirement of onboard propellant storage. An ABEP system can be applied to any celestial body with atmosphere (Mars, Venus, Titan, etc.), enabling new mission at low altitude ranges for longer times. Challenging is operation of the thruster on reactive chemical species, such as atomic oxygen (AO), that is highly present in low Earth orbit, as they cause erosion of (not only) propulsion system components, i.e. acceleration grids, electrodes, neutralizers, and discharge channels of conventional EP systems. For this reason, a contactless plasma thruster is developed: the RF helicon-based plasma thruster (IPT). The paper describes the thruster design, implementation, and first ignition tests. The thruster presents a novel antenna called the birdcage antenna that is implemented for decades in magnetic resonance imaging (MRI) machines. The design is supported by the simulation tool XFdtd®. The IPT is aided by an externally applied static magnetic field that provides the boundary condition for the helicon wave formation within the plasma discharge. The antenna working principle allows to minimize losses in the electric circuit and provides, together with the applied magnetic field, acceleration of a quasi-neutral plasma plume.

41. Demonstration of aerodynamic control manoeuvres in very low earth orbit using SOAR (Satellite for Orbital Aerodynamics Research)

Author

Crisp, N. H., Livadiotti, S., Roberts, P. C. E., Edmondson, S., Haigh, S. J., Huyton, C., Lyons, R. E., Oiko, V. T. A., Smith, K. L., Sinpetru, L. A., Straker, A., Worral, S. D., Becedas, J., Domínguez, R. M., González, D., Cañas, V., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Boxberger, A., Chan, Y. -A, Herdrich, G. H., Francesco Romano, Fasoulas, S., Traub, C., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heißerer, B., and Schwalber, A.

42. Discoverer - Radical redesign of earth observation satellites for sustained operation at significantly lower altitudes

Author

Roberts, P. C. E., Crisp, N. H., Edmondson, S., Haigh, S. J., Lyons, R. E., Oiko, V. T. A., Rojas, A. M., Smith, K. L., Becedas, J., González, G., Vázquez, I., Braña, Á, Antonini, K., Bay, K., Ghizoni, L., Jungnell, V., Morsbøl, J., Binder, T., Boxberger, A., Georg Herdrich, Romano, F., Fasoulas, S., Garcia-Almiñana, D., Rodriguez-Donaire, S., Kataria, D., Davidson, M., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heißerer, B., and Schwalber, A.

43. Discoverer: Developing technologies to enable commercial satellite operations in very low earth orbit

Author

Roberts, P. C. E., Crisp, N. H., Edmondson, S., Haigh, S. J., Holmes, B. E. A., Livadiotti, S., Macario-Rojas, A., Oiko, V. T. A., Smith, K. L., Sinpetru, L. A., Becedas, J., Domínguez, R. M., Sulliotti-Linner, V., Christensen, S., Jensen, T. K., Nielsen, J., Bisgaard, M., Chan, Y. -A, Herdrich, G. H., Romano, F., Fasoulas, S., Traub, C., Garcia-Almiñana, D., Garcia-Berenguer, M., Rodriguez-Donaire, S., Miquel Sureda, Kataria, D., Belkouchi, B., Conte, A., Seminari, S., Villain, R., and Schwalber, A.

Subjects

ResearchInstitutes_Networks_Beacons/dalton_nuclear_institute, Dalton Nuclear Institute

Abstract

The DISCOVERER project is developing technologies to enable commercially-viable sustained-operation of satellites in very low Earth orbits for communications and remote sensing applications. Operating closer to the surface of the Earth significantly reduces latency for communications applications and improves link budgets, whilst remote sensing also benefits from improved link budgets, the ability to have higher resolution or smaller instruments, all of which provide cost benefits. In addition, all applications benefit from increased launch mass to lower altitudes, whilst end-of-life removal is ensured due to the increased atmospheric drag. However, this drag must also be minimised and compensated for. DISCOVERER is developing several critical technologies to enable commercially viable operations in at these lower altitudes including aerodynamic materials, aerodynamic attitude and orbit control methods, atmosphere breathing electric propulsion and an in-situ environment monitoring payload. The current status of these developments are summarised, along with the plans for the coming year.

44. Ground-based experimental facility for orbital aerodynamics research: Design, construction and characterisation

Author

Oiko, V. T. A., Roberts, P. C. E., Macario-Rojas, A., Edmondson, S., Haigh, S. J., Holmes, B. E. A., Livadiotti, S., Crisp, N. H., Smith, K. L., Sinpetru, L. A., Becedas, J., Domínguez, R. M., Sulliotti-Linner, V., Christensen, S., Jensen, T. K., Nielsen, J., Bisgaard, M., Chan, Y. -A, Herdrich, G. H., Romano, F., Fasoulas, S., Traub, C., Garcia-Almiñana, D., Garcia-Berenguer, M., Rodriguez-Donaire, S., Sureda, M., Dhiren Kataria, Belkouchi, B., Conte, A., Seminari, S., and Villain, R.

Subjects

ResearchInstitutes_Networks_Beacons/dalton_nuclear_institute, Dalton Nuclear Institute

Abstract

In very low Earth orbits (VLEO), below 450 km altitude, the aerodynamic properties of satellites are primarily determined by the flow regime, free molecular flow, and the interaction of atomic oxygen with the surfaces of the spacecraft. The Rarefied Orbital Aerodynamics Research (ROAR) facility is a novel experimental facility designed to simulate these conditions in a controlled environment to characterise the aerodynamic properties of materials. It is built as part of DISCOVERER, a Horizon 2020 project developing the different technologies required to enable the sustainable operation of satellites in VLEO. Because ROAR isn’t intended to perform erosion studies, it differs quite significantly from other atomic oxygen exposure experiments and its characteristics are discussed in this work. ROAR consists of an ultrahigh vacuum system, responsible for generating the free molecular flow conditions, a source of hyperthermal oxygen atoms at orbital velocities, and mass spectrometers; the latter used to characterise the gas-surface interactions, and therefore the material’s aerodynamic performance. This paper includes a description of ROAR’s main components, together with the experimental methodology for materials testing and early results. Among the main parameters to be considered are atomic oxygen flux, beam shape and energy spread, mass resolution, and signal-tonoise ratio.

45. Concepts and applications of aerodynamic attitude and orbital control for spacecraft in very low earth orbit

Author

Livadiotti, S., Crisp, N. H., Roberts, P. C. E., Edmondson, S., Haigh, S. J., Huyton, C., Lyons, R. E., Oiko, V. T. A., Smith, K. L., Sinpetru, L. A., Straker, A., Worral, S. D., Becedas, J., Domínguez, R. M., González, D., Cañas, V., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Boxberger, A., Chan, Y. -A, Herdrich, G. H., Romano, F., Fasoulas, S., Traub, C., Garcia-Almiñana, D., Silvia Rodriguez-Donaire, Sureda, M., Kataria, D., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heißerer, B., and Schwalber, A.

46. Investigation of novel drag-reducing and atomic oxygen resistant materials in very low earth orbit using SOAR (Satellite for orbital aerodynamics research)

Author

Crisp, N. H., Alejandro Macario Rojas, Roberts, P. C. E., Edmondson, S., Haigh, S. J., Holmes, B. E. A., Livadiotti, S., Oiko, V. T. A., Smith, K. L., Sinpetru, L. A., Becedas, J., Domínguez, R. M., Sulliotti-Linner, V., Christensen, S., Jensen, T. K., Nielsen, J., Bisgaard, M., Chan, Y. -A, Herdrich, G. H., Romano, F., Fasoulas, S., Traub, C., Garcia-Almiñana, D., Garcia-Berenguer, M., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Belkouchi, B., Conte, A., Seminari, S., and Villain, R.

47. Inductive plasma thruster (IPT) design for an atmosphere-breathing electric propulsion system (ABEP)

Author

Romano, F., Herdrich, G., Roberts, P. C. E., Chan, Y. -A, Traub, C., Fasoulas, S., Smith, K., Edmondson, S., Haigh, S., Nicholas Crisp, Abrao Oiko, V. T., Lyons, R., Worrall, S. D., Livadiotti, S., Huyton, C., Sinpetru, L., Outlaw, R., Becedas, J., Dominguez, R. M., González, D., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Garcia-Almiñana, D., Rodriguez-Donaire, S., Sureda, M., Kataria, D., Villain, R., Santiago Perez, J., Conte, A., Belkouchi, B., Schwalber, A., Heißerer, B., Magarotto, M., and Pavarin, D.

48. Early Results from the DISCOVERER Project

Author

Roberts, P. C. E., Crisp, N. H., Oiko, V. T. A., Edmondson, S., Romano, F., Rodriguez-Donaire, S., Garcia-Almiñana, D., Haigh, S. J., Holmes, B. E. A., Livadiotti, S., Macario-Rojas, A., Smith, K. L., Sinpetru, L. A., Becedas, J., Sulliotti-Linner, V., Christensen, S., Jensen, T. K., Nielsen, J., Bisgaard, M., Chan, Y. -A, Georg Herdrich, Fasoulas, S., Traub, C., Sureda, M., Kataria, D., Belkouchi, B., Conte, A., Seminari, S., Villain, R., and Schwalber, A.

49. ROAR -- A Ground-Based Experimental Facility for Orbital Aerodynamics Research

Author

Oiko, V. T. A., Peter Roberts, Worrall, Stephen D., Stephen Edmondson, Sarah Haigh, Nicholas Crisp, Sabrina Livadiotti, Claire Huyton, Rachel Lyons, Katharine Smith, Luciana Sinpetru, Brandon Holmes, Alastair Straker, Becedas, J., Rosa María Domínguez, David Gonzalez, Valentin Cañas, Virginia Hanessian, Anders Mølgaard, Jens Nielsen, Morten Bisgaard, Adam Boxberger, Yung-An Chan, Herdrich, Georg H., Francesco Romano, Stefanos Fasoulas, Constantin Traub, Daniel Garcia-Almiñana, Silvia Rodriguez-Donaire, Miquel Sureda, Dhiren Kataria, Ron Outlaw, Badia Belkouchi, Alexis Conte, Jose Santiago Perez, Rachel Villain, Barbara Heißerer, and Ameli Schwalber

Subjects

vacuum, Atomic oxygen, very low Earth Orbit, gas-surface interactions, free molecular flow, mass spectrometry

Abstract

DISCOVERER is a European Commission funded project aiming to revolutionise satellite applications in Very Low Earth Orbits (VLEO). The project encompasses many different aspects of the requirements for sustainable operation, including developments on geometric designs, aerodynamic attitude and orbital control, improvement of intake designs for atmosphere breathing electric propulsion, commercial viability, and development of novel materials. This paper is focused solely on the description of the experimental facility designed and constructed to perform ground testing of materials, characterising their behaviour in conditions similar to those found in VLEO. ROAR, Rarefied Orbital Aerodynamics Research facility, is an experiment designed to provide a controlled environment with free molecular flow and atomic oxygen flux comparable to the real orbital environment. ROAR is a novel experiment, with the objective of providing better and deeper understanding of the gas-surface interactions between the material and the atmosphere, rather than other atomic oxygen exposure facilities which are mainly focused on erosion studies. The system is comprised of three major parts, (i) ultrahigh vacuum setup, (ii) hyperthermal oxygen atom generator (HOAG) and (iii) ion-neutral mass spectrometers (INMS). Each individual part will be considered, their performance analysed based on experimental data acquired during the characterisation and commissioning, thus leading to a complete description of ROAR’s capabilities. Among the key parameters to be discussed are operational pressure, atomic oxygen flux, beam shape and energy spread, mass resolution, signal-to-noise ratio and experimental methodology.

50. System analysis and test-bed for an atmosphere-breathing electric propulsion system using an inductive plasma thruster

Author

Romano, F., Binder, T., Herdrich, G. H., Roberts, P. C. E., Silvia Rodriguez-Donaire, Garcia-Almiñana, D., Crisp, N. H., Edmondson, S., Haigh, S. J., Lyons, R. E., Oiko, V. T. A., Smith, K. L., Becedas, J., González, G., Vázquez, I., Braña, Á, Antonini, K., Bay, K., Ghizoni, L., Jungnell, V., Morsbøl, J., Boxberger, A., Fasoulas, S., Kataria, D., Davidson, M., Outlaw, R., Belkouchi, B., Conte, A., Perez, J. S., Villain, R., Heißerer, B., and Schwalber, A.