References
- Raibert M , Blankespoor K , Nelson G , et al. The Bigdog team, Bigdog, the rough-terrain quadruped robot. In: Proceedings of the 17th world congress. Vol. 17; Seoul; 2008. p. 10822–10825.
- Semini C , Tsagarakis NG , Guglielmino E , et al . Design of HyQ -- a hydraulically and electrically actuated quadruped robot. Proc Inst Mech Eng Part I: J Syst Control Eng. 2011;225:831–849.
- Schulte HF . The characteristics of the McKibben artificial muscle. Appl External Power Prosthetics Orthotics. 1961:94–115.
- Yokota S , Komatsu T . A study on a flexible hydraulic actuator for space manipulators. Trans JSME. 1991;57-C:3222–3227.
- Zhang Z , Hou J , Ning D , et al . Modeling and experiments on the drive characteristics of high-strength water hydraulic artificial muscles. Smart Mater Struct. 2017;26:055023.
- Iwata K , Suzumori K , Wakimoto S . A method of designing and fabricating mckibben muscles driven by 7 mpa hydraulics. Int J Automat Technol. 2012;6:482–487.
- Solano B , Rotinat-Libersa C . Compact and lightweight hydraulic actuation system for high performance millimeter scale robotic applications: modeling and experiments. J Intell Mater Syst Struct. 2011;22:1479–1487.
- Tiwari R , Meller MA , Wajcs KB , et al . Hydraulic artificial muscles. J Intell Mater Syst Struct. 2012;23:301–312.
- Meller M , Chipka J , Volkov A , et al . Improving actuation efficiency through variable recruitment hydraulic mckibben muscles: modeling, orderly recruitment control, and experiments. Bioinspiration Biomimetics. 2016;11:065004.
- Morita T , Sugano S . Development and evaluation of seven-D.O.F MIA ARM. In: Proceedings. 1997 IEEE International Conference on Robotics and Automation. Vol. 1; Albuquerque; 1997. p. 462–467.
- Van Ham R , Vanderborght B , Van Damme M , et al . Maccepa, the mechanically adjustable compliance and controllable equilibrium position actuator: Design and implementation in a biped robot. Rob Autonom Syst. 2007;55:761–768.
- Kim HS , Park JJ , Song JB , et al . Design of safety mechanism for an industrial manipulator based on passive compliance. J Mech Sci Technol. 2010;24:2307–2313.
- Choi J , Hong S , Lee W , et al . A robot joint with variable stiffness using leaf springs. IEEE Trans Rob. 2011;27:229–238.
- Barrett E , Fumagalli M , Carloni R . Elastic energy storage in leaf springs for a lever-arm based variable stiffness actuator. In: 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS); Daejeon; 2016. p. 537–542.
- Wolf S , Eiberger O , Hirzinger G . The DLR FSJ: energy based design of a variable stiffness joint. In: 2011 IEEE International Conference on Robotics and Automation (ICRA); 2011. p. 5082–5089.
- Tsagarakis NG , Sardellitti I , Caldwell DG . A new variable stiffness actuator (CompAct-VSA): design and modelling. In: 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS); San Francisco; 2011. p. 378–383.
- Okada M , Nakamura Y , Ban S . Design of programmable passive compliance shoulder mechanism. In: Proceedings 2001 ICRA. IEEE International Conference on Robotics and Automation. Vol. 1; Seoul; 2001. p. 348–353.
- Choi J , Park S , Lee W , et al. Design of a robot joint with variable stiffness. In: IEEE International Conference on Robotics and Automation, 2008. ICRA 2008; Pasadena; 2008. p. 1760–1765.
- Tondu B , Lopez P . Modeling and control of McKibben artificial muscle robot actuators. IEEE Control Syst. 2000;20:15–38.
- Tondu B , Ippolito S , Guiochet J , et al . A seven-degrees-of-freedom robot-arm driven by pneumatic artificial muscles for humanoid robots. Int J Rob Res. 2005;24:257–274.
- Mori M , Suzumori K , Seita S , et al . Development of very high force hydraulic McKibben artificial muscle and its application to shape-adaptable power hand. In: 2009 IEEE International Conference on Robotics and Biomimetics (ROBIO); Guilin; 2009. p. 1457–1462.
- Mori M , Suzumori K , Takahashi M , et al . Very high force hydraulic McKibben artificial muscle with a p-Phenylene-2,6-benzobisoxazole Cord Sleeve. Adv Rob. 2012;24:233–254.
- Bridgestone Corporation . Japan patent JP2012-25970A. 2017 Feb 2.
- Bridgestone Corporation . Japan patent JP2012-20608A. 2017 Jan 26.
- Meller MA , Bryant M , Garcia E . Reconsidering the mckibben muscle: energetics, operating fluid, and bladder material. J Intell Mater Syst Struct. 2014;25:2276–2293.
- Sangian D , Naficy S , Spinks GM , et al . The effect of geometry and material properties on the performance of a small hydraulic mckibben muscle system. Sens Actuators A: Phys. 2015;234:150–157.
- Vo-Minh T , Tjahjowidodo T , Ramon H , et al . A new approach to modeling hysteresis in a pneumatic artificial muscle using the maxwell-slip model. IEEE/ASME Trans Mechatron. 2011;16:177–186.
- Zupan M , Ashby MF , Fleck NA . Actuator classification and selection -- the development of a database. Adv Eng Mater. 2002;4:933–940.
- Kuribayashi K . Criteria for the evaluation of new actuators as energy converters. Adv Rob. 1992;7:289–307.
- Semini1 C , Baker M , Laxman K , et al. A brief overview of a novel, highly-integrated hydraulic servo actuator with additive-manufactured titanium body. In: IROS 2016 Workshop: Force/Torque Controlled Actuation; Daejeon; 2016.
- Nachi-Fujikoshi Corporation ; 2014. Available from: https://www.nachi-fujikoshi.co.jp/web/pdf/9505.pdf