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Error Correction of Infrared Earth Radiance for Autonomous Navigation

Published online by Cambridge University Press:  14 September 2016

Jianqing Li
Affiliation:
(Harbin Institute of Technology, 150001 Harbin, People's Republic of China)
Changsheng Gao*
Affiliation:
(Harbin Institute of Technology, 150001 Harbin, People's Republic of China)
Tianming Feng
Affiliation:
(Harbin Institute of Technology, 150001 Harbin, People's Republic of China)
Wuxing Jing
Affiliation:
(Harbin Institute of Technology, 150001 Harbin, People's Republic of China)
*

Abstract

A strapdown inertial navigation system and celestial navigation system integrated autonomous navigation scheme is proposed in this paper, using the navigation information obtained from Earth sensors and star sensors. To eliminate the adverse effect caused by the asymmetry of Earth infrared radiance, the relationship between Earth infrared radiance brightness and effective horizon height is found. According to the relationship as well as the measuring principle of the Earth sensor, this paper derives a function to correct the measurement of the Earth sensor. Then, the angle-distance of stars can be calculated, and using this information, we can estimate the navigation information of a ballistic missile by least square estimation. The simulation results show that the error of Earth infrared radiance has a great effect on the navigation precision, and by using the correction scheme, this adverse effect can be greatly mitigated. This correction scheme is available and effective.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2016 

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References

REFERENCES

Alex, T.K. and Shrivastava, S.K. (1989). On-board correction of systematic error of Earth sensors. IEEE Transactions on Aerospace & Electronic Systems, 25(3), 373379.CrossRefGoogle Scholar
Ali, J. and Fang, J. (2009). Realization of an autonomous integrated suite of strapdown astro-inertial navigation systems using unscented particle filtering. Computers & Mathematics with Applications, 57(2), 169183.CrossRefGoogle Scholar
Fall, R., Dipipi, M., Slivinsky, S. and Paul, C. (2008). Autonomous Ballistic Missile Inertial Guidance: A New Paradigm for the 21st Century. AIAA Guidance, Navigation and Control Conference and Exhibit.CrossRefGoogle Scholar
Gontin, R.A. and Ward, K.A. (1987). Horizon sensor accuracy improvement using Earth horizon profile phenomenology. Journal of Guidance Control & Dynamics, 10(10), 14951502.Google Scholar
Guo, C.F., Cai, H. and Hu, Z.D. (2014). Nonlinear filtering techniques for geomagnetic navigation. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 223(2), 305320.CrossRefGoogle Scholar
Hong, D., Liu, G.B., Chen, H.M. and Deng, C.L. (2010). Application of missile attitude estimation based on UKF algorithm. Systems Engineering & Electronics, 32(9), 19871990.Google Scholar
Li, J. (1999). Simple correction algorithm of scanning horizon sensor measurement for Earth oblateness. Journal of Guidance Control & Dynamics, 22(1), 187190.CrossRefGoogle Scholar
Li, Z., Wang, H.Y., Jin, Y.H., Qin, T.M., Li, J.J. and Gao, Z.Q. (2015). Strapdown inertial/geomagnetic integrated navigation method for ballistic missile. Journal of Chinese Inertial Technology, 23(5), 636641.Google Scholar
Ning, X.L. and Fang, J.C. (2009). A new autonomous celestial navigation method for the lunar rover. Robotics and Autonomous Systems, 57(1), 4854.CrossRefGoogle Scholar
Ning, X.L., Wang, L.H., Bai, X.B. and Fang, J.C. (2012). A scheme design of satellite autonomous navigation system based on stellar refraction. Journal of Astronautics, 33(11), 16011610.Google Scholar
Nordlund, P.J. and Gustafsson, F. (2009). Marginalized particle filter for accurate and reliable terrain-aided navigation. IEEE Transactions on Aerospace & Electronic Systems, 45(4), 13851399.CrossRefGoogle Scholar
Qian, H., Sun, L., Cai, J. and Peng, Y. (2013). A novel navigation method used in a ballistic missile. Measurement Science & Technology, 24(24), 13661374.CrossRefGoogle Scholar
Tekawy, J.A., Wang, P. and Gray, C.W. (1996). Scanning horizon sensor attitude correction for Earth oblateness. Journal of Guidance, Control, and Dynamics, 19(3), 706708.CrossRefGoogle Scholar
Wang, P. and Zhang, Y.C. (2008). Research on autonomous navigation algorithm based on star sensor and infrared horizon sensor. System's Engineering and Electronics, 30(8), 15141518.Google Scholar
Wang, T. and Wang, X.M. (2012). A New Modelling Method and Filter Algorithm of SINS/GPS Integrated Navigation. Journal of Projectiles, Rockets, Missiles and Guidance, 32(2), 2528.Google Scholar
Ward, K.A. (1982). Modelling of the atmosphere for analysis of horizon sensor performance. Proceedings of SPIE, 327(12), 6778.CrossRefGoogle Scholar
Wei, X.G., Li, Y.P., Li, J. and Jiang, J. (2014). Autonomous orientation for LEO spacecraft using multi-FOV star tracker. Infrared and Laser Engineering, 43(6), 18121817.Google Scholar
Zhou, J. and Qian, Y. (2003). The correction algorithms of measurement of the scanning horizon sensor based on Earth oblateness. Journal of Astronautics, 24(2), 144149.Google Scholar