MOTION CHARACTERISTIC EVALUATION OF AN AMPHIBIOUS SPHERICAL ROBOT

Yanlin He, Shuxiang Guo, Liwei Shi, Huiming Xing, Zhan Chen, and Shuxiang Su

References

1. [1] S. Zhang, X. Liang, L. Xu, and M. Xu. Initial development ofa novel amphibious robot with transformable fin-leg compositepropulsion mechanisms, Journal of Bionic Engineering, 10(4),2013, 434–445.
2. [2] A.S. Boxerbaum, P. Werk, R.D. Quinn, and R. Vaidyanathan,Design of an autonomous amphibious robot for surf zone operation: Part I-Mechanical design for multi-mode mobility, Proc.IEEE Conf. on Advanced Intelligent Mechatronics, Monterey,CA, 2005, 459–1464.
3. [3] Y. He, L. Shi, S. Guo, S. Pan, and Z. Wang, Preliminarymechanical analysis of an improved amphibious spherical fatherrobot, Microsystem Technologies, 22(8), 2015, 1–16.
4. [4] S. Pan, S. Guo, L. Shi, Y. He, Z. Wang, and Q. Huang,A spherical robot based on all programmable SoC and3-D printing, Proc. 2014 IEEE Conf. on Mechatronics andAutomation, Tianjin, 2014, 150–155.
5. [5] S. Guo, Y. He, L. Shi, S. Pan, et al., Modeling and experimentalevaluation of an improved amphibious robot with compactstructure, Robotics and Computer Integrated Manufacturing,51, 2018, 37–52.
6. [6] M. Li, S. Guo, H. Hirata, and H. Ishihara, Design andperformance evaluation of an amphibious spherical robot,Robotics and Autonomous Systems, 64, 2015, 21–34.
7. [7] L. Shi, S. Guo, S. Mao, C. Yue, M. Li, and K. Asaka,Development of an amphibious turtle-inspired spherical motherrobot, Journal of Bionic Engineering, 10(4), 2013, 446–455.
8. [8] S. Guo, L. Shi, S. Mao, and M. Li, Design and kinematicanalysis of an amphibious spherical robot, Proc. 2012 IEEEConf. on Mechatronics and Automation, Tianjin, Chengdu,2012, 2214–2219.
9. [9] S. Guo, J. Du, X. Ye, R. Yan, and H. Gao, The computationaldesign of a water jet propulsion spherical underwater vehicle,Proc. 2011 IEEE Conf. on Mechatronics and Automation,Tianjin, 2014; Beijing, 2011, 2375–2379.
10. [10] Z.G. Zhang, T. Masuda, H. Kimura, and K. Takase, Towardsrealization of adaptive running of a quadruped robot usingdelayed feedback control, Proc. 2013 IEEE Conf. on Roboticsand Automation, Roma, 2007, 4325–4330.
11. [11] C. Yue, S. Guo, L. Shi, and J. Du, Characteristics evaluationof the vertical motion of a spherical underwater robot, Proc.2014 IEEE Conf. on Robotics and Biomimetics, Guangzhou,2012, 759–764.
12. [12] Y. Li, S. Guo, and C. Yue, Preliminary concept and kinematicssimulation of a novel spherical underwater robot, Proc. 2014IEEE Conf. on Mechatronics and Automation, Tianjin, 2014,1907–1912.
13. [13] X. Lin and S. Guo, Development of a spherical underwater robotequipped with multiple vectored water-jet-based thrusters,Journal of Intelligent and Robotic Systems, 67(3–4), 2012,307–321.
14. [14] S. Pan, L. Shi, S. Guo, P. Guo, Y. He, and R. Xiao, A low-powerSoC-based moving target detection system for amphibiousspherical robots, Proc. 2015 IEEE Conf. on Mechatronics andAutomation, Beijing, 2015, 1116–1121.
15. [15] Y. He, S. Guo, L. Shi, S. Pan, and P. Guo, Dynamic gait analysisof a multi-functional robot with bionic springy legs, Proceedingsof 2016 IEEE International Conference on Mechatronics andAutomation, Harbin, 2016, 689–694.
16. [16] L. Bi, J. Guo, and S. Guo, Virtual prototyping technology-baseddynamics analysis for an amphibious spherical robot, Proc.2015 IEEE Conf. on Information and Automation, Lijiang,2015, 2563–2568.
17. [17] A. Delibasi, E. Zergeroglu, I.B. K¨u¸c¨ukdemiral, andG. Cansever, Adaptive self-tuning control of robot manipulators with periodic disturbance estimation, InternationalJournal of Robotics and Automation, 25(1), 2010, 48–56.
18. [18] Z. Lu, Z. Ge, and W. Ding, Co-simulating quadruped weeding robot using ADAMS and MATLAB, Mechanical Science and Technology for Aerospace Engineering, 35(3), 2016,375–380.
19. [19] J. Wang, Y. Zhao, Y. Zhu, and Z. Ma, Coordinated simulation of trot gait for quadruped robot based on ADAMS and MATLAB,Machine Tool & Hydraulics, 43(3), 2015, 57–59.
20. [20] D. Pan, F. Gao, Y. Miao, and R. Cao, Co-simulation researchof a novel exoskeleton-human robot system on humanoidgaits with fuzzy-PID/PID algorithms, Advances in EngineeringSoftware, 79, 2015, 36–46.
21. [21] Y. Zhu and B. Jin, Compliance control of a legged robotbased on improved adaptive control: Method and experiments,International Journal of Robotics and Automation, 31(5), 2016,366–373.
22. [22] S. Subramanian, T. George, and A. Thondiyath, Real-timeobstacle avoidance for an underactuated flat-fish type autonomous underwater vehicle in 3D space space[J], 2012 Conf.on Instituto Argentino de Normalizaci´on y Certific aci´on, doi.10.2316/Journal.206.2014.4.206-4054, 2012, 1–16.
23. [23] C. Yue, S. Guo, and M. Li, ANSYS FLUENT-based modelingand fluid dynamic analysis for a spherical underwater robot,301Proc. 2013 IEEE Conf. on Mechatronics and Automation,Takamatsu, 2013, 1577–1581.
24. [24] C.J. Lin, A GPU-based evolution algorithm for motion planningof a redundant robot, International Journal of Robotics andAutomation, 2(2), 2017, 00015.

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• Abstract
• DOI: 10.2316/J.2019.206-5399
• From Journal (206) International Journal of Robotics and Automation - 2019

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