Guodong Zhai, Cong Ren, and Lili Meng


  1. [1] H. Zhuohuan and L. Min, Research on moving target tracking technology of mobile robot, Computer Products and Circulation, 3, 2018, 87 (in Chinese).
  2. [2] K.C. Chicon, H.J. Lee, and M.C. Lee, Fuzzy posture control for biped walking robot based on force sensor for ZMP, SICE-ICASE International Joint Conference, Busan, South Korea, 2006, 1185–1189.
  3. [3] J. Zhou, Backstepping adaptive fuzzy control for uncertain robot manipulators, International Journal of Robotics and Automation (IJRA), 33, 2018.
  4. [4] K. Suwanratchatamanee, M. Matsumoto, and S. Hashimoto, Balance control of humanoid robot in object lifting task with tactile sensing system, International Conference on Human System Interactions (HSI), 58(8), 2011, 431–436.
  5. [5] N. Buniyamin, Mobile robot obstacle avoidance in various type of static environments using fuzzy logic approach, International Conference on Electrical, Electronics and System Engineering, Kuala Lumpur, Malaysia, 2015.
  6. [6] X. Liang, H. Wang, Y. Liu, W. Chen, and G. Hu, Adaptive task-space cooperative tracking control of networked robotics manipulators without task-space velocity measurements, Transaction on Cybernetics, 46(10), 2016, 2386–2398.
  7. [7] O. Linda and M. Manic, Self-organizing fuzzy haptic teleoperation of mobile robot using sparse sonar data, Transactions on Industrial Electronics, 58(8), 2011, 3187–3195.
  8. [8] K. Suganyadevi and N. Malmurugan, An efficient and robust foreground object detection in compressed video sequences (NY, USA: Pergamon Press, 2014).
  9. [9] P. Mukilan and A. Wahi, An efficient human object detection and tracking with the aid of morphological operation and optimization algorithm, International Journal of Innovative Computing Information & Control, 11(4), 2015, 1139–1153.
  10. [10] H. Mei, Y. Li, and W. Li, A mobile robot with the ability of climbing and striding across obstacles, Machine Tools and Hydraulics, 41(22), 2013, 14–16.
  11. [11] C. Wang, H. Ma, and W. Shang, Study on the performance of vertical obstacle-crossing of coal mine exploration robot, Coal Mine Machinery, 35(06), 2014, 61–64 (in Chinese).
  12. [12] X. Du and Z. Wang, Analysis of obstacle-crossing ability and Simulation of obstacle-surmounting process of crawler-type coal mine rescue robot, Journal of Henan University of Technology (Natural Science Edition), 35(5), 2016, 677–684 (in Chinese).
  13. [13] L. Fei, F. Lou, and Y. Wei, Structure design and analysis on the performance of obstacle surmounting for a new type small unmanned ground vehicle, Modern Manufacturing Engineering, 2015, 48–52 (in Chinese).
  14. [14] R. Ramkumar, C. Karthikeyan, and A.K. Dash, A new workspace analysis method for 6-DOF 3-RRRS parallel robot, International Journal of Robotics and Automation (IJRA), 34, 2019.
  15. [15] X. Li, F. Liu, J. Liu, and S. Liang, Obstacle avoidance for mobile robot based on improved dynamic window approach, Turkish Journal of Electrical Engineering & Computer Sciences, 25, 2017, 666–676.
  16. [16] Y. Turygin, P. Boˇzek, Y. Nikitin, E. Sosnovich, and A. Abramov, Enhancing the reliability of mobile robots control process via reverse validation, International Journal of Advanced Robotic Systems, 2016, 1–8.
  17. [17] L. Hua and Y. Bo. Research on the obstacle surmounting performance of the self-adaptive pipe robot, Machinery & Electronics, 35(8), 2017, 72–76 (in Chinese).
  18. [18] E.C. Abad, J.M. Alonso, M.J.G. Garc´ıa, and J.C. Garc´ıaPrada, Methodology for the navigation optimization of a terrain-adaptive unmanned ground vehicle, International Journal of Advanced Robotic Systems, 2018, 1–11.
  19. [19] W. Liu, C. Wang, and H. Liu, Design and analysis on obstacle-crossing of a rescue robot, Heavy Machinery, 6, 2016, 8–12 (in Chinese).
  20. [20] A. Kilin, P. Bozek, Y. Karavaev, A. Klekovkin, and V. Shestakov, Experimental investigations of a highly maneuverable mobile omni-wheel robot, International Journal of Advanced Robotic Systems, 2017, 1–9.
  21. [21] C.J. Kim and D.K. Chwa, Obstacle avoidance method for wheeled mobile robots using interval type-2 fuzzy neural network, IEEE Transactions on Fuzzy Systems, 23(3), 2015, 677–687.
  22. [22] H. Hu, J. Cheng, and Z. Niu, Obstacles crossing analysis of mine detection robot based on RPY, Coal Mine Machinery, 34(11), 2013, 109–111.
  23. [23] Y. Cai, X. Wang, S. Wang, J. Ma, Z. Kou, and X. Du, Innovative design of obstacle-crossing robot structure based on TRIZ theory, Chemical Engineering and Equipment, 03, 2014, 23–25.
  24. [24] Z. Deng, H. Gao, M. Hu, and S. Wang, Design of planetary obstacle-crossing wheeled lunar rover, Journal of Harbin University of Technology, 02, 2003, 203–206, 209–213.
  25. [25] Q. Quan, and S. Ma, Development of a modular crawler for tracked robots, Advanced Robotics, 25, 2011, 13–14, 1839–1849.
  26. [26] B. Zi, J. Lin, and S. Qian, Localization, obstacle avoidance planning and control of a cooperative cable parallel robot for multiple mobile cranes, Robotics and Computer-Integrated Manufacturing, 34, 2015, 105–123.
  27. [27] Y. Cao, J. Gu, Y. Zang, et al., Path planning-oriented obstacle avoiding workspace modelling for robot manipulator, International Journal of Robotics and Automation (IJRA), 34, 2019.
  28. [28] L. Yue, J. Zhu, K. Wu, and L. Wu, Dynamic simulation of triangular gear train mobile mechanism based on ADAMS, Machine Tool and Hydraulic, 43(05), 2015, 127–129.

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