Integrated navigation based on pulsar and sun sensor in sun-earth Halo orbit

Cheng Wei Yang; Jian Hua Zheng; Ming Tao Li

Integrated navigation based on pulsar and sun sensor in sun-earth Halo orbit

Cheng Wei Yang, Jian Hua Zheng^*, Ming Tao Li

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

To improve the performance of autonomous navigation in the Halo orbits, an integrated navigation system based on X-ray pulsars and sun sensor was proposed. For X-ray pulsar-based navigation (XNAV), the X-ray pulse time of arrival could be measured by the X-ray detector. The sun sensor was used to obtain the line-of-sight vector towards sun. The full ephemeris dynamics model of the Halo orbit in sun-earth system was established. The nominal Halo orbit in the earth-centric inertial coordinate system was calculated using two-level differential correction method. The state of the navigation system was estimated via the federated unscented Kalman filter (UKF) based on UD factorization. Several perturbation factors were discussed in the simulation. Simulation results show that the proposed integrated navigation scheme is feasible in sun-earth Halo orbit. Compared with the XNAV navigation, the navigation accuracy is improved.

Original language	English
Pages (from-to)	612-616
Number of pages	5
Journal	Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology
Volume	33
Issue number	6
Publication status	Published - Jun 2013
Externally published	Yes

Keywords

Halo orbit
Integrated navigation
Pulsar
Sun sensor
Two-level differential correction

Cite this

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title = "Integrated navigation based on pulsar and sun sensor in sun-earth Halo orbit",

abstract = "To improve the performance of autonomous navigation in the Halo orbits, an integrated navigation system based on X-ray pulsars and sun sensor was proposed. For X-ray pulsar-based navigation (XNAV), the X-ray pulse time of arrival could be measured by the X-ray detector. The sun sensor was used to obtain the line-of-sight vector towards sun. The full ephemeris dynamics model of the Halo orbit in sun-earth system was established. The nominal Halo orbit in the earth-centric inertial coordinate system was calculated using two-level differential correction method. The state of the navigation system was estimated via the federated unscented Kalman filter (UKF) based on UD factorization. Several perturbation factors were discussed in the simulation. Simulation results show that the proposed integrated navigation scheme is feasible in sun-earth Halo orbit. Compared with the XNAV navigation, the navigation accuracy is improved.",

keywords = "Halo orbit, Integrated navigation, Pulsar, Sun sensor, Two-level differential correction",

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T1 - Integrated navigation based on pulsar and sun sensor in sun-earth Halo orbit

AU - Yang, Cheng Wei

AU - Zheng, Jian Hua

AU - Li, Ming Tao

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N2 - To improve the performance of autonomous navigation in the Halo orbits, an integrated navigation system based on X-ray pulsars and sun sensor was proposed. For X-ray pulsar-based navigation (XNAV), the X-ray pulse time of arrival could be measured by the X-ray detector. The sun sensor was used to obtain the line-of-sight vector towards sun. The full ephemeris dynamics model of the Halo orbit in sun-earth system was established. The nominal Halo orbit in the earth-centric inertial coordinate system was calculated using two-level differential correction method. The state of the navigation system was estimated via the federated unscented Kalman filter (UKF) based on UD factorization. Several perturbation factors were discussed in the simulation. Simulation results show that the proposed integrated navigation scheme is feasible in sun-earth Halo orbit. Compared with the XNAV navigation, the navigation accuracy is improved.

AB - To improve the performance of autonomous navigation in the Halo orbits, an integrated navigation system based on X-ray pulsars and sun sensor was proposed. For X-ray pulsar-based navigation (XNAV), the X-ray pulse time of arrival could be measured by the X-ray detector. The sun sensor was used to obtain the line-of-sight vector towards sun. The full ephemeris dynamics model of the Halo orbit in sun-earth system was established. The nominal Halo orbit in the earth-centric inertial coordinate system was calculated using two-level differential correction method. The state of the navigation system was estimated via the federated unscented Kalman filter (UKF) based on UD factorization. Several perturbation factors were discussed in the simulation. Simulation results show that the proposed integrated navigation scheme is feasible in sun-earth Halo orbit. Compared with the XNAV navigation, the navigation accuracy is improved.

KW - Halo orbit

KW - Integrated navigation

KW - Pulsar

KW - Sun sensor

KW - Two-level differential correction

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Integrated navigation based on pulsar and sun sensor in sun-earth Halo orbit

Abstract

Keywords

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