Application of Adaptive Kalman Filter Algorithm in High Accuracy Star Spot Location

Liu Nannan; Xu Shuyan; Cao Xiaotao; Wang Dong

doi:10.3788/aos201333.1115001

[1] L G Taff. Scientific results from the Hubble Space Telescope fine-guidance sensors [C]. SPIE, 1991, 1494: 66-77.

[2] N Rowlands, D Aldridge, R Allen, et al.. The JWST fine guidance sensor [C]. SPIE, 2004, 5487: 664-675.

[3] Wei Xinguo, Zhang Guangjun, Jiang Jie. Subdivided locating method of star image for star sensor [J]. J Beijing University of Aeronautics and Astronautics, 2003, 29(9): 812-815.

[4] C C Liebe. Accuracy performance of star trackers: a tutorial [J]. IEEE Trans Aero Electron Syst, 2002, 38(2): 587-599.

[5] S Lee. Pointing accuracy improvement using model-based noise reduction method [C]. SPIE, 2002, 4635: 65-71.

[6] Giancarlo Rufino, Domenico Accardo. Enhancement of the centroiding algorithm for star tracker measure refinement [J]. Acta Astronautica, 2003, 53(2): 135-147.

[7] B M Quine, V Tarasyuk, H Mebrahtu, et al.. Determining star-image location: a new sub-pixel interpolation technique to process image centroids [J]. Computer Physics Communications, 2007, 177(9): 700-706.

[8] Yang Jun, Zhang Tao, Song Jingyan, et al.. High accuracy error compensation algorithm for star image sub-pixel subdivision location [J]. Optics and Precision Engineering, 2010, 18(4): 1002-1010.

[9] D Mortari, A Romoli. StarNav III: a three fields of view star tracker [C]. IEEE Aerospace Conference Proceedings, 2002. 47-57.

[10] H Y Kim. Novel Methods for Spacecraft Attitude Estimation [M]. College Station: Texas A & M University, 2002.

[11] M A Samaan, T C Pollock, J L Junkins. Predictive centroiding for star trackers with the effect of image smear [J]. J Astronautical Sciences, 2002, 50(1): 113-123.