TY - GEN
T1 - GPS/GLONASS/SINS synergistic integration into flight vehicle for optimal navigation solution
AU - Gaho, Anwar Ali
AU - Fang, Jiancheng
AU - Gul, Farid
PY - 2006
Y1 - 2006
N2 - This paper aims the importance of GPS/GLONASS/SINS integration into flight vehicle and the optimal use of twenty seven error states by using various error models such as SINS error model, sensors error model and GPS/GLONASS error model. The main riveted part of system model is the inclusion of GPS/GLONASS error model. Position and velocity errors of GPS as random clock errors are used as first order markov process noise inside the system model. This error model, describing the error states is considered as first order differential equation. In this paper a system model for GPS/GLONASS/SINS integration is designed and applied. Loosely coupled closed loop Kalman filter architecture is realized for this mission for its robustness and less sensitivity to parameter variations. North pointing navigation algorithm and its error model is developed and evaluated in this integration mode. The local frame ENU is used as the navigation frame. The integrated system uses the position and velocity as measurements. Both the integrated GPS/GLONASS/SINS and the stand alone noisy sensor SINS navigation simulations results are analyzed, and compared to reference ideal trajectory navigation parameters. The numerical computer simulation results demonstrate the optimal performance of GPS/GLONASS/SINS integration with required accuracy for the mission.
AB - This paper aims the importance of GPS/GLONASS/SINS integration into flight vehicle and the optimal use of twenty seven error states by using various error models such as SINS error model, sensors error model and GPS/GLONASS error model. The main riveted part of system model is the inclusion of GPS/GLONASS error model. Position and velocity errors of GPS as random clock errors are used as first order markov process noise inside the system model. This error model, describing the error states is considered as first order differential equation. In this paper a system model for GPS/GLONASS/SINS integration is designed and applied. Loosely coupled closed loop Kalman filter architecture is realized for this mission for its robustness and less sensitivity to parameter variations. North pointing navigation algorithm and its error model is developed and evaluated in this integration mode. The local frame ENU is used as the navigation frame. The integrated system uses the position and velocity as measurements. Both the integrated GPS/GLONASS/SINS and the stand alone noisy sensor SINS navigation simulations results are analyzed, and compared to reference ideal trajectory navigation parameters. The numerical computer simulation results demonstrate the optimal performance of GPS/GLONASS/SINS integration with required accuracy for the mission.
KW - Error models
KW - Global position system
KW - Kalman filter closed loop
KW - Markov process noise
KW - Strapdown inertial navigation systems
UR - https://www.scopus.com/pages/publications/34247261474
U2 - 10.1109/ICMA.2006.257516
DO - 10.1109/ICMA.2006.257516
M3 - 会议稿件
AN - SCOPUS:34247261474
SN - 1424404665
SN - 9781424404667
T3 - 2006 IEEE International Conference on Mechatronics and Automation, ICMA 2006
SP - 1848
EP - 1853
BT - 2006 IEEE International Conference on Mechatronics and Automation, ICMA 2006
T2 - 2006 IEEE International Conference on Mechatronics and Automation, ICMA 2006
Y2 - 25 June 2006 through 28 June 2006
ER -