Abstract
In the paper the robotic systems for restorative medicine including massage are considered. The features of robot training, the features of unusual environment – patient’s soft tissues and the features of non-invasive interaction of robot with soft tissues are emphasized. Nowadays there are specialized and research robots for massage only in the world but universal robotic systems for massage are absent. So it is necessary to have the devices which can adapt the serially produced non-medical robots for performing massage. These devices have to perform the functions of mechanics, electronics, computing and to interact with biological environment – patient’s soft tissues. So they can be named bio-mechatronic modules. The following bio-mechatronic modules are considered: the handle for manual spatial continuous robot training at soft tissues deforming, active force module for compensations of displacements of a patient at his breathing, module for program training of force points and spring compensator of force overload at unexpected obstacle. These bio-mechatronic modules directly interact with soft tissue by the tool imitating masseur’s hand and they take part in the following: admittance control for the robot training by demonstration; position-force control at reproduction; bio-diagnostics and bio-technical control of patient’s state; amortization of quick approach to untrained areas and as tool carrier.
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References
Arkhipov M, Leskov A, Golovin V, Gercik Y, Kocherevskaya L (2017) Prospects of robotics development for restorative medicine. In: Rodić A, Borangiu T (eds) RAAD 2016, vol 540. AISC. Springer, Cham, pp 499–506. doi:10.1007/978-3-319-49058-8_54
Gams A, Petrič T (2017) On-line modifications of robotic trajectories: learning, coaching and force vs. position feedback. In: Rodić A, Borangiu T (eds) RAAD 2016, vol 540. AISC. Springer, Cham, pp 20–28. doi:10.1007/978-3-319-49058-8_3
Golovin V, Samorukov A (1998) Massage method and device for its implementation, No 2145833. Russian patent
Golovin V, Razumov A, Samorukov A (2004) Concept of biomechatronics in medical technique. In: Proceedings of first international workshop on restoration medicine and rehabilitation, Moscow
Golovin V, Razumov A, Poduraev Y (2005) Mechatronic approach at design of medical technique. In: Mechatronics automation control No 7, Moscow
Golovin V, Leskov A, Arkhipov M, Rachkov M, Legotin S (2015) Training of robot by demonstration of movement with considering of environment deforming. SFedU News Tech Sci 10(171):213–227 Taganrog
Golovin V, Arkhipov M, Zhuravlev V (2014) Force training for position/force control of massage robots. In: Rodić A, Pisla D, Bleuler H (eds) New trends in medical and service robots, vol 20. MMS. Springer, Cham, pp 95–107. doi:10.1007/978-3-319-05431-5_7
Golovin V, Arkhipov M, Zhuravlev V (2014) Position/force control of medical robot interacting with dynamic biological soft tissue. In: Ceccarelli M, Glazunov Victor A (eds) Advances on theory and practice of robots and manipulators, vol 22. MMS. Springer, Cham, pp 303–310. doi:10.1007/978-3-319-07058-2_34
Golovin V, Zhuravlev V, Arkhipov M (2012) Robotics in restorative medicine. LAP LAMBERT Academic Publishing, GmbH & Co., KG, Saarbrücken, p 270
Golovin V, Arkhipov M, Pavlovsky V (2015) Features of projection of robotic systems for restorative medicine. Mechatron Autom Control 16(10):664–671
Golovin V, Arkhipov M, Legotin S, Kocherevskaya L (2015) Expansion of ergonomics function in medical robotics. In: New trends in medical and service robots, Proceedings of third international workshop on medical and service robots. Springer, Heidelberg, pp 207–218
Kulakov F, Nechaev A, Chernakova C (2006) Information systems of virtual reality in mechatronics and robotics. SOLO, St. Petersburg, p 146
Leskov A, Golovin V, Arkhipov M, Kocherevskaya L (2016) Training of robot to assigned geometric and force trajectories. In: Wenger P, Chevallereau C, Pisla D, Bleuler H, Rodić A (eds) New trends in medical and service robots, vol 39. MMS. Springer, Cham, pp 75–84. doi:10.1007/978-3-319-30674-2_6
Leskov A, Yushenko A (1992) Modeling and analysis of robotic systems. In: Mechanical engineering, Moscow, p 78
Orlov I (2015) Dynamic model of the PUMA-like manipulator with a hybrid position/force control in operation with a compliant environment. In: Proceedings of the ECCOMAS thematic conference on multibody dynamics, pp 1411–1416
Sadovnichy V, Goryacheva I, et al (2009) Application of mechanics methods of contact interaction in the diagnosis of pathological states of soft biological tissues. MSU, Moscow, p 306
Vukobratovic M, Surdilovic D, Ecalo Y, Katic D (2009) Dynamics and robust control of robot — environment interaction. Monograph series in the world scientific publishing under the title «New frontiers in robotics». WSPC, p 638
Acknowledgments
The scientific work described in this paper was supported by Russian presidential grant № MК-5826.2016.8 and grant of Russian Foundation for Basic Research № 16-38-60201.
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Arkhipov, M., Orlov, I., Golovin, V., Kocherevskaya, L., Evgeny, V., Aleksander, U. (2018). Bio-Mechatronic Modules for Robotic Massage. In: Ferraresi, C., Quaglia, G. (eds) Advances in Service and Industrial Robotics. RAAD 2017. Mechanisms and Machine Science, vol 49. Springer, Cham. https://doi.org/10.1007/978-3-319-61276-8_101
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DOI: https://doi.org/10.1007/978-3-319-61276-8_101
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