The Method of Controlling an Object Identifying Trajectory Parameters of a Rectilinearly Moving Target on the Base of the Distances to it

The article deals with the problem of object control in order to determine the parameters of the moving target trajectory. We consider the conditions under which a locality map is unknown and there are no external landmarks. There is no available target position information except for non-directional measurements of the distance between an object and a target. Such conditions can arise, for example, in the case of using Wi-Fi or radio signals, when by means of a signal strength the distance to a signal source can be determined, while the direction in which a signal source is located remains unknown. A general statement of the control problem is given. The solution of the problem in a particular case of rectilinear motion of a target and a piecewise linear motion of an object is proposed. It is proved that the estimations of the parameters of target motion can be obtained by using not less than 7 measurements of distances to a target. In addition, in the measurement process, an object twice has to change the direction of its motion at least two times. An immovable object cannot determine the trajectory of a target. The method of object control which enables to determine the parameters of a target trajectory is proposed. The conditions of control existence are obtained. It is also shown that in a special case of a parallel movement of a target and an object not less than 4 measurements are needed to determine target trajectory parameters. The problem solution time corresponding to different methods of solution is estimated. The results of research can be used in the robot control problem, particularly, in the problem of robot gathering. The presented approach gives an exact solution under condition of high accuracy of distance measuring. In practice, the accuracy of measurements is influenced by a large number of factors. Therefore, a challenging problem is to study the dependence of the target trajectory parameters problem solution on the accuracy of distance measurements.

управление, позиционирование, траектория движения, расстояние, количество измерений, параллельное движение, динамическая система, control, positioning, distance between points, trajectory, number of measurements, parallel motion, dynamic system

1. Отческий С. А., Бурдинский И. Н. Алгоритм посттриангуляционной коррекции координат автономного необитаемого подводного аппарата // Труды СПИИРАН. 2016. Вып. 2 (45). С. 190-206.

2. Akcan H., Evrendilek C. (2012) GPS-free directional localization via dual wireless radios // Computer Communications. Vol. 35. P. 1151-1163.

3. Fernandes A., Couceiro M. S., Portugal D., Machado Santos J., Rocha R. P. (2015) Ad Hoc Communication in Teams of Mobile Robots Using ZigBee Technology // Computer Applications in Engineering Education. Vol. 23, Iss. 5. P. 733-745.

4. Betke M., Gurvits L. (1997) Mobile Robot Localization Using Landmarks // IEEE Transactions on Robotics and Automation. Vol. 13, N. 2. P. 251-263.

5. Малодушев С. В., Рогов А. А. Определение локации в корпоративных Wi-Fi сетях // Вестник ЮУрГУ. Сер. Матем. моделирование и программирование. 2016. № 9. С. 92-104.

6. Кучин И. Ю., Иксанов Ш. Ш., Рождественский С. К., Коряков А. Н. Разработка системы позиционирования и контроля объектов с помощью беспроводной технологии Wi-Fi // Научный вестник Новосибирского государственного технического университета. 2015. № 3 (60). С. 130-146.

7. JaeGu Lee, Jin Kim, Seon Woo Lee and Young Woong Ko (2017) A Location Tracking System using BLE Beacon Exploiting a Double-Gaussian Filter // KSII Transactions on Internet and Information Systems. Vol. 11, N. 2. P. 1162-1179. DOI: 10.3837/ tiis.2017.02.031

8. Vincent Pierlot, Marc Van Droogenbroeck. A New Three Object Triangulation Algorithm for Mobile Robot Positioning // Robotics IEEE Transactions on Robotics. 2014. Vol. 30. P. 566-577.

9. Doiphode S., Tiwari S. L. R., Mumbai S. S. Survey of Indoor Positioning Measurements, Methods and Techniques // International Journal of Computer Applications. 2016. Vol. 140, N. 7.

10. Buniyamin N., Wan Ngah W. A. J., Sariff N., Mohamad Z. A simple local path planning algorithm for autonomous mobile robots // International journal of systems applications, engineering and development. 2011. Vol. 5. Iss. 2. P. 151-159.

11. Hager G. D. A Modular System for Robust Positioning Using Feedback from Stereo Vision // IEEE Transactions on robotics and automation. 1997. Vol. 13, N. 4. P. 582-595.

12. Spletzer J. R., Fierro R. Optimal Positioning Strategies for Shape Changes in Robot Teams // Proceedings of the 2005 IEEE International Conference on Robotics and Automation Barcelona. 2005. P. 754-759.

13. Cai F., Cui J. Moving Target Tracking Based on Kalman Algorithm //Journal of engineering science and technology review. 2014. Vol. 7, N. 1. P. 148-153.

14. Zupanec Z., Ricciato F., Sajn L. Trajectory estimation of a moving target from Ultra-wideband ranging measurements // Elektrotehnniski vestnik. Vol. 83, N. 5. P. 236-242.

15. Zhang M., Liu H. H. T. Vision-based tracking and estimation of ground moving target using unmanned aerial vehicle // Proceedings of the American control conference. Marriott Waterfront, Baltimore, MD, USA. 2010. P. 696-6973.

16. Parker L. E. Distributed algorithms for multi-robot observation of multiple moving targets - Autonomous robots. 2002. Vol. 12, N. 3. P. 1-30.

17. Chaudhary G., Sinha A. Capturing a target with range only measurement // Proceedings of the European Control Conference (ECC), Zrich, Switzerland. 2013. P. 4400-4405.

18. Щеголева Л. В., Жуков А. В. Задача позиционирования движущегося объекта по расстоянию до него // Труды Карельского научного центра РАН. 2016. № 8. С. 129-135.

19. Matveev A. S., Teimoori H., Savkin A. V. Range-only measurements based target following for wheeled mobile robots // Automatica. 2011. Vol. 47. P. 177-184.