4 results on '"Lee, Byoung-Sun"'
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2. Design and implementation of the flight dynamics system for COMS satellite mission operations
- Author
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Lee, Byoung-Sun, Hwang, Yoola, Kim, Hae-Yeon, and Kim, Jaehoon
- Subjects
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GEOSTATIONARY satellites , *OCEANOGRAPHY , *METEOROLOGICAL satellites , *LAUNCH vehicles (Astronautics) , *IMAGE converters , *PROGRAMMING languages , *EARTH'S orbit , *EARTH (Planet) - Abstract
Abstract: The first Korean multi-mission geostationary Earth orbit satellite, Communications, Ocean, and Meteorological Satellite (COMS) was launched by an Ariane 5 launch vehicle in June 26, 2010. The COMS satellite has three payloads including Ka-band communications, Geostationary Ocean Color Imager, and Meteorological Imager. Although the COMS spacecraft bus is based on the Astrium Eurostar 3000 series, it has only one solar array to the south panel because all of the imaging sensors are located on the north panel. In order to maintain the spacecraft attitude with 5 wheels and 7 thrusters, COMS should perform twice a day wheel off-loading thruster firing operations, which affect on the satellite orbit. COMS flight dynamics system provides the general on-station functions such as orbit determination, orbit prediction, event prediction, station-keeping maneuver planning, station-relocation maneuver planning, and fuel accounting. All orbit related functions in flight dynamics system consider the orbital perturbations due to wheel off-loading operations. There are some specific flight dynamics functions to operate the spacecraft bus such as wheel off-loading management, oscillator updating management, and on-station attitude reacquisition management. In this paper, the design and implementation of the COMS flight dynamics system is presented. An object oriented analysis and design methodology is applied to the flight dynamics system design. Programming language C# within Microsoft .NET framework is used for the implementation of COMS flight dynamics system on Windows based personal computer. [Copyright &y& Elsevier]
- Published
- 2011
- Full Text
- View/download PDF
3. Orbit determination performances using single- and double-differenced methods: SAC-C and KOMPSAT-2
- Author
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Hwang, Yoola, Lee, Byoung-Sun, Kim, Haedong, and Kim, Jaehoon
- Subjects
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ORBIT determination , *GLOBAL Positioning System , *GPS receivers , *AEROSPACE engineering , *ARTIFICIAL satellites , *DATA analysis - Abstract
Abstract: In this paper, Global Positioning System-based (GPS) Orbit Determination (OD) for the KOrea-Multi-Purpose-SATellite (KOMPSAT)-2 using single- and double-differenced methods is studied. The requirement of KOMPSAT-2 orbit accuracy is to allow 1m positioning error to generate 1-m panchromatic images. KOMPSAT-2 OD is computed using real on-board GPS data. However, the local time of the KOMPSAT-2 GPS receiver is not synchronized with the zero fractional seconds of the GPS time internally, and it continuously drifts according to the pseudorange epochs. In order to resolve this problem, an OD based on single-differenced GPS data from the KOMPSAT-2 uses the tagged time of the GPS receiver, and the accuracy of the OD result is assessed using the overlapping orbit solution between two adjacent days. The clock error of the GPS satellites in the KOMPSAT-2 single-differenced method is corrected using International GNSS Service (IGS) clock information at 5-min intervals. KOMPSAT-2 OD using both double- and single-differenced methods satisfies the requirement of 1-m accuracy in overlapping three dimensional orbit solutions. The results of the SAC-C OD compared with JPL’s POE (Precise Orbit Ephemeris) are also illustrated to demonstrate the implementation of the single- and double-differenced methods using a satellite that has independent orbit information available for validation. [Copyright &y& Elsevier]
- Published
- 2011
- Full Text
- View/download PDF
4. Onboard orbit determination using GPS observations based on the unscented Kalman filter
- Author
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Choi, Eun-Jung, Yoon, Jae-Cheol, Lee, Byoung-Sun, Park, Sang-Young, and Choi, Kyu-Hong
- Subjects
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ASTRONOMICAL observations , *KALMAN filtering , *NATURAL satellite orbits , *ORBIT determination , *SOLAR radiation , *NUMERICAL analysis , *TEMPERATURE & radiation of the Moon , *EARTH'S orbit - Abstract
Abstract: Spaceborne GPS receivers are used for real-time navigation by most low Earth orbit (LEO) satellites. In general, the position and velocity accuracy of GPS navigation solutions without a dynamic filter are 25m (1σ) and 0.5m/s (1σ), respectively. However, GPS navigation solutions, which consist of position, velocity, and GPS receiver clock bias, have many abnormal excursions from the normal error range for space operation. These excursions lessen the accuracy of attitude control and onboard time synchronization. In this research, a new onboard orbit determination algorithm designed with the unscented Kalman filter (UKF) was developed to improve the performance. Because the UKF is able to obtain the posterior mean and covariance accurately by using the second-order Taylor series expansion through the sampled sigma points that are propagated by using the true nonlinear system, its performance can be better than that of the extended Kalman filter (EKF), which uses the linearized state transition matrix to predict the covariance. The dynamic models for orbit propagation applied perturbations due to the 40×40 geo-potential, the gravity of the Sun and Moon, solar radiation pressure, and atmospheric drag. The 7(8)th-order Runge–Kutta numerical integration was applied for orbit propagation. Two types of observations, navigation solutions and C/A code pseudorange, can be used at the user’s discretion. The performances of the onboard orbit determination were verified using real GPS data of the CHAMP and KOMPSAT-2 satellites. The results of the orbit determination were compared with the precision orbit ephemeris (POE) of the CHAMP and KOMPSAT-2 satellites. The comparison of the orbit determination results using EKF and UKF shows that orbit determination using the UKF yields better results than that using the EKF. In addition, the estimation of the accuracy using the C/A code pseudorange is better than that using the navigation solutions. The absolute position and velocity accuracies of the UKF using GPS C/A code pseudorange were 12.098m and 0.0159m/s in the case of the CHAMP satellite, and 8.172m and 0.0085m/s in the case of the KOMPSAT-2 satellite. Moreover, the abnormal excursions of navigation solutions can be eliminated. These results verify that onboard orbit determination using GPS C/A code pseudorange, which is based on the UKF can provide more stable and accurate orbit information in the spaceborne GPS receiver. [Copyright &y& Elsevier]
- Published
- 2010
- Full Text
- View/download PDF
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