DESIGN AND ANALYSIS OF SELF-DRIVING ARTICULATED SOFT ACTUATOR, 473-481.

Shuqi Wang, Jizhuang Fan, Yitao Pan, and Yubin Liu

References

  1. [1] J. Pandey, N.S. Reddy, R. Ray, and S.N. Shome, Biologicalswimming mechanism analysis and design of robotic frog,Proc. 2013 IEEE International Conf. on Mechatronics andAutomation, Takamatsu, Japan, 2013, 1726–1731.
  2. [2] H. Chum, S. Felt, J. Garner, and S. Green, Biology, behavior,and environmental enrichment for the captive African clawedfrog (Xenopus spp), Applied Animal Behaviour Science, 143(2–4), 2013, 150–156.
  3. [3] W. Zhang, J.Z. Fan, Y.H.Y.L. ZhuQiu, and J. Zhao, A methodfor mechanism analysis of frog swimming based on motionobservation experiments, Advances in Mechanical Engineering,(8), 2014, 1–13.
  4. [4] J.Z. Fan, W. Zhang, B.W. Yuan, and G. Liu, Propulsiveefficiency of frog swimming with different feet and swimmingpatterns, Biology Open, 6(4), 2017, 503–510.
  5. [5] J.Z. Fan, B.W. Yuan, and Q.L. Du, Joint design and positionservo control of frog inspired robot based on pneumaticmuscle and reset spring, Proc. IEEE International Conf. onMechatronics and Automation (ICMA), Changchun, China,2018, 1914–1919.
  6. [6] J.Z. Fan, W. Zhang, P.C. Kong, H.G. Cai, and G.F. Liu,Design and dynamic model of a frog-inspired swimming robotpowered by pneumatic muscles, Chinese Journal of MechanicalEngineering, 30, 2017, 1123–1132.
  7. [7] T. Ren, Y. Zhang, and Y.J. Li, Development of an active helicaldrive self-balancing in-pipe robot based on compound planetarygearing, International Journal of Robotics and Automation,(34), 2019.
  8. [8] C. Laschi, B. Mazzolai, and M. Cianchetti, Soft robotics:Technologies and systems pushing the boundaries of robotabilities, Science Robotics, 1(1), 2016, 3690.
  9. [9] Z. Cui and H.Z. Jiang, Design and implementation of thun-niform robotic fish with variable body stiffness, InternationalJournal of Robotics and Automation, 2017.
  10. [10] C. Ma, F. Yu, and Z. Luo, Simulations and experimentalresearch on a novel soft-terrain hexapod robot, Interna-tional Journal of Robotics and Automation, 30(3), 2015,247–255.
  11. [11] Y.G. 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.
  12. [12] X. Huang, K. Kumar, M.K. Jawed, A.M. Nasab, Z. Ye, W. Shan,and C. Majidi, Highly dynamic shape memory alloy actuatorfor fast moving soft robots, Advanced Materials Technologies,4(4), 2019, 1800540.
  13. [13] Y. Tang, Q. Lei, X. Li, C.M. Chew, and J. Zhu, Afrog-inspired swimming robot based on dielectric elastomeractuators, Proc. IEEE/RSJ International Conf. on IntelligentRobots and Systems (IROS), Vancouver, BC, Canada, 2017,2403–2408.
  14. [14] Z. Yoder, N. Kellaris, C. Chase-Markopoulou, D. Ricken,S.K. Mitchell, M.B. Emmett, R.F.ff. Weir, J. Segil, and C.Keplinger, Design of a high-speed prosthetic finger driven bypeano-HASEL actuators, Frontiers in Robotics and AI, 7,2020.
  15. [15] H. Sun, N.Y. Wang, H. Jiang, and X.P. Chen, Flexiblehoneycomb pneunets robot, International Journal of Roboticsand Automation, 2016.
  16. [16] H. Zheng, M.L. Wu, and X.R. Shen, A pneumatic variable serieselastic actuator-powered transtibial prosthesis, InternationalJournal of Robotics and Automation, (6), 2020, 408–418.
  17. [17] L. Manamanchaiyaporn, T.T. Xu, X.Y. Wu, and H.H. Qian,Roles of magnetic strength in magneto-elastomer towardsswimming mechanism and performance of miniature robots,International Journal of Robotics and Automation, 2020,162–170.
  18. [18] K. Liu, Y. Wu, J.Q. Xu, Y. Wang, Z. Ge, and Y. Lu,Fuzzy sliding mode control of 3-DOF shoulder joint driven bypneumatic muscle actuators, International Journal of Roboticsand Automation, 34(1), 2019, 38–45.
  19. [19] M. Li, A. Pal, A. Aghakhani, A. Pena-Francesch, and M.Sitti, Soft actuators for real-world applications, Nature ReviewsMaterials, 7, 2022, 235–249.
  20. [20] J.H. Zhang, H.X. Guo, T. Wang, and J. Hong, The designand motion analysis of a pneumatic omnidirectional soft robot,International Journal of Robotics and Automation, 32(6), 2017,569–576.
  21. [21] J.M. Ramos-Arreguin, S. Tovar-Arriaga, J.E. Vargas-Soto, andM.A. Aceves-Fernandez, FPGA embedded PD control of a1 Dof manipulator with a pneumatic actuator, InternationalJournal of Robotics and Automation, 2016.
  22. [22] A. Chen, R. Yin, L. Cao, C. Yuan, H. Ding, and W.Zhang, Soft robotics: Definition and research issues, Proc. 24thInternational Conf. on Mechatronics and Machine Vision inPractice (M2VIP), Auckland, New Zealand, 2017, 366–370.
  23. [23] J.Z. Fan, S.Q. Wang, and Q.G. Yu, Experimental study onfrog-inspired swimming robot based on articulated pneumaticsoft actuator, Journal of Bionic Engineering, 17(2), 2020,270–280.
  24. [24] Y. Yang, Y. Chen, Y. Li, M.Z. Chen, and Y. Wei, bioinspiredrobotic fingers based on pneumatic actuator and 3D printingof smart material, Soft Robotics, 4(2), 2017, 147.
  25. [25] Y. Wei, Y. Chen, T. Ren, Q. Chen, and C. Yan, A novel, variablestiffness robotic gripper based on integrated soft actuating andparticle jamming, Soft Robotics, 2016.
  26. [26] T. Kitamori, A. Wada, H. Nabae, and K. Suzumori, Untetheredthree-arm pneumatic robot using hose-free pneumatic actuator,Proc. IEEE/RSJ International Conf. on Intelligent Robots &Systems, Daejeon, Korea (South), 2016, 543–548.
  27. [27] J.Z. Fan, S.Q. Wang, Q.G. Yu, and Y. Zhu, Swimmingperformance of the frog-inspired soft robot, Soft Robotics. 7(5),2020, 615–626.
  28. [28] P. Polygerinos, W. Zheng, J. Overvelde, K.C. Galloway, R.J.Wood, K. Bertoldi, and C.J. Walsh, Modeling of soft fiber-reinforced bending actuators, IEEE Transactions on Robotics,31(3), 2015, 778–789.
  29. [29] M. Wehner, R.L. Truby, D.J. Fitzgerald, B. Mosadegh, G.M.Whitesides, J.A. Lewis, and R.J. Wood, An integrated designand fabrication strategy for entirely soft, autonomous robots,Nature, 536(7617), 2016, 451–455.
  30. [30] Y. Li, T. Ren, Y. Li, Y. Chen, and S.H. Choi, Untethered-bioinspired quadrupedal robot based on double-chamber pre-charged pneumatic soft actuators with highly flexible trunk,Soft Robotics, 8(1), 2020, 97–108.
  31. [31] Y. Chen and S. Choi, Precharged pneumatic soft actuatorsand their applications to untethered soft robots, Soft Robotics,2018, 567–575.
  32. [32] T. Ren, Y. Li, M. Xu, Y. Li, C. Xiong and Y.A. Chen, Noveltendon-driven soft actuator with self-pumping property, SoftRobotics, 7(2), 2019, 130–139.
  33. [33] A. Tony, A. Rasouli, A. Farahinia, G. Wells, H. Zhang, S.Achenbach, S.M. Yang, W. Sun, and W. Zhang, Toward a softmicrofluidic system: concept and preliminary developments,Proc. 27th International Conf. on Mechatronics and MachineVision in Practice (M2VIP), Shanghai, 2021, 755–759.

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