Your search keyword '"M Järve"' showing total 2 results

1. ESTCube-1 nanosatellite for electric solar wind sail in-orbit technology demonstration

Author

M Noorma, A Reinart, V Allik, A Obraztsov, S Kiprich, H Koivisto, A Nuottajärvi, J Kauppinen, O Tarvainen, T Kalvas, R Kurppa, E Haeggström, J Ukkonen, H Seppänen, T Rauhala, P Toivanen, J Envall, P Janhunen, R Rosta, O Krömer, L Kimmel, A Sisask, V Evard, T Uiboupin, T Vahter, T Scheffler, T C Tamm, T Tilk, T Ani, T Peet, T Ilves, S-E Mändmaa, S Kurvits, R Valner, R Reinumägi, R Soosaar, R Rantsus, P Laes, P Liias, O Scheler, M Veske, M Mikkor, M Averin, M Pelakauskas, M Valgur, M Neerot, M Vellak, M Järve, M Lõoke, L Joost, K Kalniņa, K Tuude, K Tarbe, K-G Kruus, K-L Kusmin, K Kivistik, J Laks, J Poļevskis, J Kütt, J Šate, J Mucenieks, J Šubitidze, J Kalde, J Viru, J Mõttus, I Mahhonin, H Lillmaa, H Ehrpais, E Soolo, E Eilonen, A Agu, A Vahter, A Leitu, I Ansko, J Piepenbrock, R Vendt, K Zalite, K Laizans, T Eenmäe, I Sünter, H Kuuste, M Pajusalu, E Kulu, K Voormansik, U Kvell, E Ilbis, A Slavinskis, and S Lätt

Subjects

Engineering, Spacecraft propulsion, ta114, business.industry, nanosatellite, CubeSat, General Engineering, E-sail, Propulsion, satellite design, electric solar wind sail, plasma brake, Solar wind, ESTCube-1, Drag, Orbital motion, Systems design, Voltage source, Aerospace engineering, business

Abstract

This paper presents the mission analysis, requirements, system design, system level test results, as well as mass andpower budgets of a 1-unit CubeSat ESTCube-1 built to perform the first in-orbit demonstration of electric solar wind sail (E-sail)technology. The E-sail is a propellantless propulsion system concept that uses thin charged electrostatic tethers for turning themomentum flux of a natural plasma stream, such as the solar wind, into spacecraft propulsion. ESTCube-1 will deploy and chargea 10 m long tether and measure changes in the satellite spin rate. These changes result from the Coulomb drag interaction with theionospheric plasma that is moving with respect to the satellite due to the orbital motion of the satellite. The following subsystemshavebeendevelopedtoperformandtosupporttheE-sailexperiment: atetherdeploymentsubsystembasedonapiezoelectricmotor;an attitude determination and control subsystem to provide the centrifugal force for tether deployment, which uses electromagneticcoils to spin up the satellite to one revolution per second with controlled spin axis alignment; an imaging subsystem to verify tetherdeployment, which is based on a 640 × 480 pixel resolution digital image sensor; an electron gun to keep the tether at a highpositive potential; a high voltage source to charge the tether; a command and data handling subsystem; and an electrical powersubsystem with high levels of redundancy and fault tolerance to mitigate the risk of mission failure.

Published

2014

2. Attitude determination and control for centrifugal tether deployment on the ESTCube-1 nanosatellite

Author

Erik Kulu, Kaspars Laizans, Jouni Envall, R. Valner, Viljo Allik, Kaupo Voormansik, E. Soolo, Ilmar Ansko, M. Järve, T. Uiboupin, Urmas Kvell, Jaan Viru, Henri Kuuste, Indrek Sünter, T. Scheffler, Erik Ilbis, Mart Noorma, Tõnis Eenmäe, S. Lätt, Riho Vendt, Andris Slavinskis, Jaanus Kalde, and Hendrik Ehrpais

Subjects

Engineering, business.product_category, business.industry, General Engineering, Attitude and heading reference system, Gyroscope, Kalman filter, law.invention, Attitude control, Sun sensor, Rocket, law, Control system, CubeSat, Aerospace engineering, business, Simulation

Abstract

This paper presents the design, development, and pre-launch characterization of the ESTCube-1 Attitude Determination and Control System (ADCS). The design driver for the ADCS has been the mission requirement to spin up the satellite to 360 deg¢s i1 with controlled orientation of the spin axis and to acquire the angular velocity and the attitude during the scientific experiment. ESTCube-1 is a one-unit CubeSat launched on 7 May 2013, 2:06 UTC on board the Vega VV02 rocket. Its primary mission is to measure the Coulomb drag force exerted by a natural plasma stream on a charged tether and, therefore, to perform the basic proof of concept measurement and technology demonstration of electric solar wind sail technology. The attitude determination system uses three-axis magnetometers, three-axis gyroscopic sensors, and two-axis Sun sensors, a Sun sensor on each side of the satellite. While commercial off-the-shelf components are used for magnetometers and gyroscopic sensors, Sun sensors are custom- built based on analogue one-dimensional position sensitive detectors. The attitude of the satellite is estimated on board using an Unscented Kalman Filter. An ARM 32-bit processor is used for ADCS calculations. Three electromagnetic coils are used for attitude control. The system is characterized through tests and simulations. Results include mass and power budgets, estimated uncertainties as well as attitude determination and control performance. The system fulfils all mission requirements.

Published

2014