MONITORING-BASED VISUAL SERVOING OF WHEELED MOBILE ROBOTS

Chenghao Yin, Baoquan Li, Wuxi Shi, and Ning Sun

References

1. [1] Y. Liu, R. Xiong, Y. Wang, H. Huang, X. Xie, X. Liu, and G.Zhang, Stereo visual-inertial odometry with multiple Kalmanfilters ensemble, IEEE Transactions on Industrial Electronics,63(10), 2016, 6205–6216.
2. [2] H. J. Asl, M. Yazdani, and J. Yoon, Vision-based track-ing control of quadrotor using velocity of image features,International Journal of Robotics and Automation, 31(4), 2016,301–309.
3. [3] H. Zhao, Y. Liu, X. Xie, Y. Liao, and X. Liu, Filtering basedadaptive visual odometry sensor framework robust to blurredimages, Sensors, 16(7), 2016, 1040.
4. [4] W. He and Y. Dong, Adaptive fuzzy neural network control fora constrained robot using impedance learning, IEEE Transac-tions on Neural Networks and Learning Systems, 29(4), 2018,1174–1186.
5. [5] G. Hu, W. P. Tay, and Y. Wen, Cloud robotics: Architecture,challenges and applications, IEEE Networks, 26(3), 2012,21–28.
6. [6] H. Chen, C. Wang, X. J. Li, and D. Sun, Transportation ofmultiple biological cells through saturation-controlled opticalteezers in crowded microenvironments, IEEE/ASME Transac-tions on Mechatronics, 21(2), 2016, 888–899.
7. [7] B. Li, Y. Fang, and X. Zhang, Essential-matrix-based visualservoing of mobile robots without short baseline degeneration,International Journal of Robotics and Automation, 30(4), 2015,397–406.
8. [8] G. L. Mariottini, G. Oriolo, and D. Prattichizzo, Image-based visual servoing for nonholonomic mobile robots usingepipolar geometry, IEEE Transactions on Robotics, 23(1), 2007,87–100.
9. [9] L. Wang and C. Luo, A hybrid genetic Tabu search algorithmfor mobile robot to solve AS/RS path planning, InternationalJournal of Robotics and Automation, 33(2), 2018.
10. [10] P. Salaris, A. Cristofaro, and L. Pallottino, Epsilon-optimalsynthesis for unicycle-like vehicles with limited field-of-view sensors, IEEE Transactions on Robotics, 31(6), 2015,1404–1418.
11. [11] B. P. Larouche and Z. H. Zhu, Position-based visual servoingin robotic capture of moving target enhanced by kalman filter,International Journal of Robotics and Automation, 30(3), 2015,267–277.
12. [12] Z. Zhu, W. Zou, Q. Wang, and F. Zhang, A velocity compen-sation visual servo method for oculomotor control of bioniceyes, International Journal of Robotics and Automation, 33(1),2018.
13. [13] B. Tamadazte, N. L. Piat, and E. Marchand, A direct visualservoing scheme for automatic nanopositioning, IEEE/ASMETransactions on Mechatronics, 17(4), 2012, 728–736.
14. [14] H. Wang, D. Guo, H. Xu, W. Chen, T. Liu, and K. Leang, Eye-in-hand tracking control of free-floating space manipulator,IEEE Transactions on Aerospace and Electronic Systems,53(4), 2017, 1855–1865.
15. [15] T. Meng and W. He, Iterative learning control of a robotic armexperiment platform with input constraint, IEEE Transactionson Industrial Electronics, 65(1), 2017, 664–672, 2017.
16. [16] S. Zhang, Y. Dong, Y. Ouyang, Z. Yin and K. Peng, Adaptiveneural control for robotic manipulators with output constraintsand uncertainties, IEEE Transactions on Neural Networks andLearning Systems, 29 (11), 2018, 5554–5564.
17. [17] S. Y. Chen, J. Zhang, H. Zhang, N. M. Kowk, and Y. F.Li, Intelligent lighting control for vision-based robotic manipulation, IEEE Transactions on Industrial Electronics, 59(8),2012, 3254–3263.
18. [18] H. Wang, B. Yang, Y. Liu, W. Chen, X. Liang, and R. Pfeifer,Visual servoing of soft robot manipulator in constrained envi-ronments with an adaptive controller, IEEE/ASME Transac-tions on Mechatronics, 22(1), 2017, 41–50.
19. [19] H. M. Becerra, G. Lopez-Nicolas, and C. Sagues, Asliding-mode-control law for mobile robots based on epipolar visualservoing from three views, IEEE Transactions on Robotics,27(1), 2011, 175–183.
20. [20] X. Zhang, Y. Fang, and N. Sun, Visual servoing of mobilerobots for posture stabilization: From theory to experiments,International Journal of Robust and Nonlinear Control, 25(1),2015, 1–15.
21. [21] X. Zhang, Y. Fang, and X. Liu, Motion-estimation-based visualservoing of nonholonomic mobile robots, IEEE Transactionson Robotics, 27(6), 2011, 1167–1175.
22. [22] N. Sun, T. Yang, Y. Fang, B. Lu, and Y. Qian, Nonlinearmotion control of underactuated three-dimensional boom cranesystems with hardware experiments, IEEE Transactions onIndustrial Informatics, 14(3), 2018, 887–897.
23. [23] J. Chen, B. Jia, and K. Zhang, Trifocal tensor-based adaptivevisual trajectory tracking control of mobile robots, IEEETransactions on Cybernetics, 47(11), 2017, 3784–3798.
24. [24] R. Brockett, The early days of geometric nonlinear control,Automatica, 50(9), 2014, 2203–2224.
25. [25] N. Sun, Y. Fang, H. Chen, Y. Fu, and B. Lu, Nonlinearstabilizing control for ship-mounted cranes with disturbancesinduced by ship roll and heave movements: Design, analysis,and experiments, IEEE Transactions on Systems, Man, andCybernetics: Systems, DOI: 10.1109/TSMC.2017.2700393.
26. [26] P. Murrieri, D. Fontanelli, and A. Bicchi, A hybrid-controlapproach to the parking problem of a wheeled vehicle usinglimited view-angle visual feedback, International Journal ofRobotics Research, 23(4–5), 2004, 437–448.
27. [27] A. D. Luca, G. Oriolo, and P. R. Giordano, Feature depthobservation for image-based visual servoing: Theory and ex-periments, International Journal of Robotics Research, 27(10),2008, 1093–1116.
28. [28] Y. Fang, X, Liu, and X. Zhang, Adaptive active visual ser-voing of nonholonomic mobile robots, IEEE Transactions onIndustrial Electronics, 59(1), 2012, 486–497.
29. [29] N. Sun, Y. Wu, Y. Fang, and H. Chen, Nonlinear antiswingcontrol for crane systems with double-pendulum swing effectsand uncertain parameters: design and experiments, IEEETransactions on Automation Science and Engineering, 15(3),2018, 1413–1422.
30. [30] A. P. Dani, N. R. Fischer, and W. E. Dixon, Single cam-era structure and motion, IEEE Transactions on AutomaticControl, 57(1), 2012, 241–246.
31. [31] D. Chwa, A. P. Dani, and W. E. Dixon, Range and motionestimation of a monocular camera using static and movingobjects, IEEE Transactions on Control Systems Technology,24(4), 2016, 1174–1183.
32. [32] W. MacKunis, N. Gans, A. Parikh, and W. E. Dixon, Unifiedtracking and regulation visual servo control for wheeled mobilerobots, Asian Journal of Control, 16(3), 2014, 669–678.
33. [33] Z. Li, C. Yang, C.-Y. Su, J. Deng, and W. Zhang, Vision-basedmodel predictive control for steering of a nonholonomic mobilerobot, IEEE Transactions on Control Systems Technology,24(2, pp. 553–564, Mar. 2016.
34. [34] X. Zhang, Y. Fang, B. Li, and J. Wang, Visual servoing of non-holonomic mobile robots with uncalibrated camera-to-robot pa-rameters, IEEE Transactions on Industrial Electronics, 64(1),2017, 390–400.
35. [35] B. Li, Y. Fang, and X. Zhang, Visual servo regulation ofwheeled mobile robots with an uncalibrated onboard cam-era, IEEE/ASME Transactions on Mechatronics, 21(5), 2016,2330–2342.
36. [36] Z. Ma and J. Su, Robust uncalibrated visual servoing controlbased on disturbance observer, ISA Transactions, 59, 2015,193–204.
37. [37] M. Liu, C. Pradalier, and R. Siegwart, Visual homing from scalewith an uncalibrated omnidirectional camera, IEEE Transac-tions on Robotics, 29(6), 2013, 1353–1365.
38. [38] J. J. Craig, Introduction to robotics: Mechanics and control,3rd ed. (Englewood Cliffs, NJ: Prentice-Hall, 2005).
39. [39] D. F. Dementhon and L. S. Davis, Model-based object posein 25 lines of code, International Journal of Computer Vision,15(1), 1995, 123–141.
40. [40] M. Aicardi, G. Casalino, A. Bicchi, and A. Balestrino, Closedloop steering of unicycle-like vehicles via Lyapunov tech-niques, IEEE Robotics & Automation Magazine, 2(1), 1995,27–35.

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• Abstract
• DOI: 10.2316/J.2019.206-0028
• From Journal (206) International Journal of Robotics and Automation - 2019

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