WSEAS Transactions on Systems and Control


Print ISSN: 1991-8763
E-ISSN: 2224-2856

Volume 14, 2019

Notice: As of 2014 and for the forthcoming years, the publication frequency/periodicity of WSEAS Journals is adapted to the 'continuously updated' model. What this means is that instead of being separated into issues, new papers will be added on a continuous basis, allowing a more regular flow and shorter publication times. The papers will appear in reverse order, therefore the most recent one will be on top.

Volume 14, 2019


State Filtering and Nonlinear Control of Fine Tracking System in Quantum Positioning Systems

AUTHORS: Shuang Cong, Zisheng Zou, Shiqi Duan, Ding Chen

Download as PDF

ABSTRACT: The accuracy of the fine tracking system is the premise of high-accuracy positioning in quantum positioning systems. In this paper, we propose a method combining model reference adaptive control (MRAC) strategy and adaptive strong tracking Kalman filter (ASTKF) to reduce the impacts of satellite platform jitter and environment noise. A mathematical model of the fine tracking system with disturbance and environmental noise are set up and analyzed. Aiming at colored irregular noise signal, we design an ASTKF to estimate the state of the system on-line, at the same time, the disturbance and noise changing with time are also estimated and eliminated. By combining a MRAC strategy, we enhance the robustness of the fine tracking system. Numerical experiments of tracking performances comparing different methods available in the literature are given. The numerical simulation results show that the proposed method can improve the tracking accuracy, and almost 99.7 % of the spots can be projected into the square area within 2 µrad.

KEYWORDS: quantum positioning, fine tracking control, adaptive filtering, nonlinear control

REFERENCES:

[1] Giovannetti V., Lloyd S., Maccone L.: Quantumenhanced positioning and clock synchronization, 412(6845), 417 (2001)

[2] Liao S. K., Cai W. Q., Liu W. Y.: Satelliteto-ground quantum key distribution. Nature, 549(7670), 43 (2017)

[3] Ren J. G., Xu P., Yong H. L.: Ground-tosatellite quantum teleportation. Nature, 549(7670), 70 (2017)

[4] Yin J., Cao Y., Li Y.H.: Satellite-to-ground entanglement-based quantum key distribution. Physical review letters, 119(20), 200501 (2017)

[5] Khalighi M. A., Khalighi M.: Survey on free space optical communication: A communication theory perspective. IEEE communications surveys & tutorials, 16(2), 2231-2258 (2014)

[6] Nadeem F., Kvicera V., Awan M.S.: Weather effects on hybrid FSO/RF communication link. IEEE journal on selected areas in communications, 27(9), 1687-1697 (2009)

[7] Davaslıoglu K., C¸ a ˘ gıral E., Koca M.: Free s- ˘ pace optical ultra-wideband communications over atmospheric turbulence channels. Optics express, 18(16), 16618-16627 (2010)

[8] Zhang M., Liang Y.: Compound tracking in ATP system for free space optical communication. Proceedings of Mechatronic Science, Electric Engineering and Computer (MEC),2011 International Conference, Jilin, China(2011)

[9] Fadhil H. A., Amphawan K. K., Shamsuddin H. A.: Optimization of free space optics parameters: An optimum solution for bad weather conditions. Optik-International Journal for Light and Electron Optics, 124(19), 3969-3973 (2013)

[10] Osborne R. W., Zhang X., Willett P.: Effect of sensor pixel size on tracking. Signal and Data Processing of Small Targets, 17(4), 71-6 (2013)

[11] Hassan M. F., Alrifai M. T., Soliman H. M.: Observer-based controller for constrained uncertain stochastic nonlinear discrete-time systems. International Journal of Robust and Nonlinear Control, 26(10), 2090-2115 (2016)

[12] Cui N., Liu Y., Chen X.: Active disturbance rejection controller of fine tracking system for free space optical communication. Proceedings of International Symposium on Photoelectronic Detection and Imaging 2013: Laser Communication Technologies and Systems, 89 (6), 13 (2013)

[13] Alvi B. A., Asif M., Siddiqui F. A.: Fast steering mirror control using embedded self-learning fuzzy controller for free space optical communication. Wireless personal communications, 76(3), 643-656 (2014)

[14] Munoz-Benavent P., Gracia L., Solanes J. E.: S- ˜ liding mode control for robust and smooth reference tracking in robot visual servoing. International Journal of Robust and Nonlinear Control, 28(5) 1728-1756 (2018)

[15] Zhao W., Ren X., Gao X.: Synchronization and tracking control for multi-motor driving servo systems with backlash and friction. International Journal of Robust and Nonlinear Control, 26(13), 2745- 2766 (2016)

[16] Yoon H., Bateman B. E., Agrawal B. N.: Laser beam jitter control using recursive-least-squares adaptive filters. Journal of Dynamic Systems, Measurement, and Control, 133(4), 1001 (2011)

[17] Perez-Arancibia N. O., Gibson J. S., Tsao T. C.: Observer-based intensity-feedback control for laser beam pointing and tracking. IEEE Transactions on control systems technology, 20(1), 31-47 (2012)

[18] Kadir N., Aziz A. I., Chowdhury S. J.: Performance improvement of the tracking system of a satellite laser communication. International Journal of Computer Applications, 26(6), 19-25 (2011)

[19] Chen C. Y., Yang H. M., Tong S. F.: Real-time simulation of satellite-platform vibration of space optical communication. Journal of System Simulation, 19(16), 3834-3837 (2007)

[20] Lin D., Wu Y. M., Zhu F.: Research on Precision Tracking on Fast Steering Mirror and Control Strategy. Proceedings of IOP Conference Series: Earth and Environmental Science, 114(1), 2009 (2018)

[21] Fu C., Jiang L., Ren G.: Experiment system of fast steering mirror. Opto-Electronic Engineering, 21(3), 1-8 (1994)

WSEAS Transactions on Systems and Control, ISSN / E-ISSN: 1991-8763 / 2224-2856, Volume 14, 2019, Art. #34, pp. 264-276


Copyright Β© 2019 Author(s) retain the copyright of this article. This article is published under the terms of the Creative Commons Attribution License 4.0

Bulletin Board

Currently:

The editorial board is accepting papers.


WSEAS Main Site