Vision-based navigation system feature point selection method based on convex hull for non-cooperative target

Ning Mingfeng; Zhang Shijie; Wang Shiqiang

doi:10.3788/irla201948.0317004

[1] Liang Bin, Du Xiaodong, Li Cheng, et al. Advances in space robot on-orbit servicing for non-cooperative spacecraft [J]. Jiqiren (Robot), 2012, 34(2): 242-256. (in Chinese)

[2] Matthias L, Brockers R, Kuwata Y, et al. Stereo vision-based obstacle avoidance for micro air vehicles using disparity space [C]//Robotics and Automation (ICRA); 2014 IEEE International Conference on, 2014: 3242-3249.

[3] Baine N A, Rattan K S. Dilution of precision in vision Navigation systems[C]//AIAA Guidance, Navigation and Control Conference, 2012, 6: 4892.

[4] Park Y B, Jeon H C, Park C G. Analysis of geometric effects on integrated inertial/vision for lunar descent Navigation [J]. Journal of Guidance Control and Dynamics, 2016, 39(4): 937-943.

[5] Won D H, Chun S, Lee S W, et al. Geometrical distortion integrated performance index for vision-based navigation system [J]. International Journal of Control Automation and Systems, 2013, 11(6): 1196-1203.

[6] Milliken R J, Zoller C J. Principle of operation of NAVSTAR and system characteristics[J]. Navigation, 1978, 25(2): 95-106.

[7] Phatak M S. Recursive method for optimum GPS satellite selection [J]. IEEE Transactions on Aerospace and Electronic Systems, 2001, 37(2): 751-754.

[8] Hsu D Y. Relations between dilutions of precision and volume of the tetrahedron formed by four satellites[C]// Position Location and Navigation Symposium, IEEE, 1994: 669-676.

[9] Kihara M, Okada T. A satellite selection method and accuracy for the global positioning system [J]. Navigation, 1984, 31(1): 8-20.

[10] Li J, Ndili A, Ward L, et al. GPS receiver satellite/antenna selection algorithm for the Stanford gravity probe B relativity mission[C]//National Technical Meeting′ Vision 2010: Present and Future′, 1999: 541-550.

[11] Jwo D J, Lai C C. Neural network-based GPS GDOP approximation and classification [J]. GPS Solutions, 2007, 11(1): 51-60.

[12] Cryan S P, Montez M N. A survey of GPS Satellite selection algorithms for space shuttle auto landing[C]//The 5 th International Technical Meeting of the Satellite Division of the Institute of Navigation, 1992: 1165-1171.

[13] Wei M, Wang J, Li J. A new satellite selection algorithm for real-time application[C]//Systems and Informatics (ICSAI), 2012 International Conference on, IEEE, 2012: 2567-2570.

[14] Roongpibonsopit D, Karimi H A. A multi-constellations satellite selection algorithm for integrated global navigation satellite systems [J]. Journal of Intelligent Transportation Systems, 2009, 13(3): 127-141.

[15] Zhu J. Calculation of geometric dilution of precision [J]. IEEE Transactions on Aerospace and Electronic Systems, 1992, 28(3): 893-895.

[16] Jwo D J. Efficient DOP calculation for GPS with and without altimeter aiding [J]. The Journal of Navigation, 2001, 54(2): 269-279.

[17] Massatt P, Rudnick K. Geometric formulas for dilution of precision calculations [J]. Navigation, 1990, 37(4): 379-391.

[18] Xing C, Xiong Z, Zhang Y, et al. An efficient convex hull algorithm using affine transformation in planar point set [J]. Arabian Journal for Science and Engineering, 2014, 39(11): 7785-7793.

[19] Chan T M. Optimal output-sensitive convex hull algorithms in two and three dimensions [J]. Discrete & Computational Geometry, 1996, 16(4): 361-368.

[20] Graham R L. An efficient algorithm for determining the convex hull of a finite planar set [J]. Information Processing Letters, 1972, 1(4): 132-133.