Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design
This paper describes the attitude ground system (AGS) design to be used for support of the Magnetospheric MultiScale (MMS) mission. The AGS exists as one component of the mission operations control center. It has responsibility for validating the onboard attitude and accelerometer bias estimates, ca...
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2011
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| Online Access: | http://hdl.handle.net/2060/20180001145 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20180001145 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20180001145 2023-05-15T17:40:04+02:00 Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design Raymond, Juan C. Superfin, Emil Sedlak, Joseph E. Unclassified, Unlimited, Publicly available February 28, 2011 application/pdf http://hdl.handle.net/2060/20180001145 unknown Document ID: 20180001145 http://hdl.handle.net/2060/20180001145 Copyright, Public use permitted CASI Spacecraft Design Testing and Performance LEGNEW-OLDGSFC-GSFC-LN-1214 International Symposium on Space Flight Dynamics; 28 Feb. - 4 Mar. 2011; Sao Jose dos Campos; Brazil 2011 ftnasantrs 2019-07-20T23:20:02Z This paper describes the attitude ground system (AGS) design to be used for support of the Magnetospheric MultiScale (MMS) mission. The AGS exists as one component of the mission operations control center. It has responsibility for validating the onboard attitude and accelerometer bias estimates, calibrating the attitude sensors and the spacecraft inertia tensor, and generating a definitive attitude history for use by the science teams. NASA's Goddard Space Flight Center (GSFC) in Greenbelt, Maryland is responsible for developing the MMS spacecraft, for the overall management of the MMS mission, and for mission operations. MMS is scheduled for launch in 2014 for a planned two-year mission. The MMS mission consists of four identical spacecraft flying in a tetrahedral formation in an eccentric Earth orbit. The relatively tight formation, ranging from 10 to 400 km, will provide coordinated observations giving insight into small-scale magnetic field reconnection processes. By varying the size of the tetrahedron and the orbital semi-major axis and eccentricity, and making use of the changing solar phase, this geometry allows for the study of both bow shock and magnetotail plasma physics, including acceleration, reconnection, and turbulence. The mission divides into two phases for science; these phases will have orbit dimensions of l.2xl2 Earth radii in the first phase and l.2x25 Earth radii in the second in order to study the dayside magnetopause and the nightside magnetotail, respectively. The orbital periods are roughly one day and three days for the two mission phases. Each of the four MMS spacecraft will be spin stabilized at 3 revolutions per minute (rpm), with the spin axis oriented near the ecliptic north pole but tipped approximately 2.5 deg towards the Sun line. The main body of each spacecraft will be an eight-sided platform with diameter of 3.4 m and height of 1.2 m. Several booms are attached to this central core: two axial booms of 14.9 m length, two radial magnetometer booms of 5 m length, and four radial -wire booms of 60 m length. Attitude and orbit control will use a set of axial and radial thrusters. A four-head star tracker and a slit-type digital Sun sensor (DSS) provide input for attitude determination. In addition, an accelerometer will be used for closed-loop orbit maneuver control. The primary AGS product will be a daily definitive attitude history. Due to power limitations; the star tracker and accelerometer data will not be available at all times. However, tracker data from at least 10 percent of each orbit and continuous DSS data will be provided. An extended Kalman filter (EKF) will be used to estimate the three-axis attitude (i.e., spin axis orientation and spin phase) and rotation rate for all times when the tracker data is valid. For other times, the attitude is generated by assuming a constant angular momentum vector in the inertial frame. The DSS sun pulse will provide a timing signal to maintain an accurate spin phase. There will be times when the Sun is occulted and DSS data is not available. If this occurs at the start or end of a definitive attitude product, then the spin phase will be extrapolated using the mean rate determined by the EKF. Other/Unknown Material North Pole NASA Technical Reports Server (NTRS) North Pole |
| institution |
Open Polar |
| collection |
NASA Technical Reports Server (NTRS) |
| op_collection_id |
ftnasantrs |
| language |
unknown |
| topic |
Spacecraft Design Testing and Performance |
| spellingShingle |
Spacecraft Design Testing and Performance Raymond, Juan C. Superfin, Emil Sedlak, Joseph E. Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design |
| topic_facet |
Spacecraft Design Testing and Performance |
| description |
This paper describes the attitude ground system (AGS) design to be used for support of the Magnetospheric MultiScale (MMS) mission. The AGS exists as one component of the mission operations control center. It has responsibility for validating the onboard attitude and accelerometer bias estimates, calibrating the attitude sensors and the spacecraft inertia tensor, and generating a definitive attitude history for use by the science teams. NASA's Goddard Space Flight Center (GSFC) in Greenbelt, Maryland is responsible for developing the MMS spacecraft, for the overall management of the MMS mission, and for mission operations. MMS is scheduled for launch in 2014 for a planned two-year mission. The MMS mission consists of four identical spacecraft flying in a tetrahedral formation in an eccentric Earth orbit. The relatively tight formation, ranging from 10 to 400 km, will provide coordinated observations giving insight into small-scale magnetic field reconnection processes. By varying the size of the tetrahedron and the orbital semi-major axis and eccentricity, and making use of the changing solar phase, this geometry allows for the study of both bow shock and magnetotail plasma physics, including acceleration, reconnection, and turbulence. The mission divides into two phases for science; these phases will have orbit dimensions of l.2xl2 Earth radii in the first phase and l.2x25 Earth radii in the second in order to study the dayside magnetopause and the nightside magnetotail, respectively. The orbital periods are roughly one day and three days for the two mission phases. Each of the four MMS spacecraft will be spin stabilized at 3 revolutions per minute (rpm), with the spin axis oriented near the ecliptic north pole but tipped approximately 2.5 deg towards the Sun line. The main body of each spacecraft will be an eight-sided platform with diameter of 3.4 m and height of 1.2 m. Several booms are attached to this central core: two axial booms of 14.9 m length, two radial magnetometer booms of 5 m length, and four radial -wire booms of 60 m length. Attitude and orbit control will use a set of axial and radial thrusters. A four-head star tracker and a slit-type digital Sun sensor (DSS) provide input for attitude determination. In addition, an accelerometer will be used for closed-loop orbit maneuver control. The primary AGS product will be a daily definitive attitude history. Due to power limitations; the star tracker and accelerometer data will not be available at all times. However, tracker data from at least 10 percent of each orbit and continuous DSS data will be provided. An extended Kalman filter (EKF) will be used to estimate the three-axis attitude (i.e., spin axis orientation and spin phase) and rotation rate for all times when the tracker data is valid. For other times, the attitude is generated by assuming a constant angular momentum vector in the inertial frame. The DSS sun pulse will provide a timing signal to maintain an accurate spin phase. There will be times when the Sun is occulted and DSS data is not available. If this occurs at the start or end of a definitive attitude product, then the spin phase will be extrapolated using the mean rate determined by the EKF. |
| format |
Other/Unknown Material |
| author |
Raymond, Juan C. Superfin, Emil Sedlak, Joseph E. |
| author_facet |
Raymond, Juan C. Superfin, Emil Sedlak, Joseph E. |
| author_sort |
Raymond, Juan C. |
| title |
Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design |
| title_short |
Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design |
| title_full |
Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design |
| title_fullStr |
Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design |
| title_full_unstemmed |
Magnetospheric Multiscale (MMS) Mission Attitude Ground System Design |
| title_sort |
magnetospheric multiscale (mms) mission attitude ground system design |
| publishDate |
2011 |
| url |
http://hdl.handle.net/2060/20180001145 |
| op_coverage |
Unclassified, Unlimited, Publicly available |
| geographic |
North Pole |
| geographic_facet |
North Pole |
| genre |
North Pole |
| genre_facet |
North Pole |
| op_source |
CASI |
| op_relation |
Document ID: 20180001145 http://hdl.handle.net/2060/20180001145 |
| op_rights |
Copyright, Public use permitted |
| _version_ |
1766140883540901888 |