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Erschienen in:
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2016 | OriginalPaper | Buchkapitel

Is Active Impedance the Key to a Breakthrough for Legged Robots?

verfasst von : Claudio Semini, Victor Barasuol, Thiago Boaventura, Marco Frigerio, Jonas Buchli

Erschienen in: Robotics Research

Verlag: Springer International Publishing

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Abstract

This work addresses the question whether active impedance control is key to a breakthrough for legged robots. In this paper, we will talk about controlling the mechanical impedance of joints and legs with a focus on stiffness and damping control. In contrast to passive elements like springs, active impedance is achieved by torque-controlled joints allowing real-time adjustment of stiffness and damping. We argue that legged robots require a high degree of versatility and flexibility to execute a wide range of assistive tasks to be truly useful to humans and thus to lead to a breakthrough. Adjustable stiffness and damping in realtime is a fundamental building block towards versatility. Experiments with our 80 kg hydraulic quadruped robot HyQ demonstrate that active impedance alone (thus no springs in the structure) can successfully emulate passively compliant elements during highly-dynamic locomotion tasks (running and hopping); and, that no springs are needed to protect the actuation system. Here we present results of a flying trot, also referred to as running trot. To the authors’ best knowledge this is the first time a flying trot was successfully implemented on a robot without passive elements such as springs. A critical discussion on the pros and cons of active impedance concludes the paper. An extended version of this paper has been published in IJRR in 2015 [43].

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Nächstes Kapitel Optimal Control of Nonlinear Systems with Temporal Logic Specifications
Fußnoten
1
Compliance is the inverse of stiffness.
 
2
Reduction gears are required to amplify the low output torque of electric motors.
 
3
Note that we recently increased the hydraulic system pressure of the HyQ robot to 20 MPa, increasing the maximum torque of the hip and knee flexion/extension joints to 181 Nm.
 
4
Note that the fact that models are required for good performance does not address the question where the model comes from. For robots it can sometimes be derived from CAD data, sometimes must be estimated/learned. For humans models are typically acquired by learning.
 
5
It is worthwhile discussing these issues in the control theoretic notions of nominal behavior and disturbance reaction.
 
Literatur
1.
Barasuol, V., De Negri, V.J., De Pieri, E.R.: WCPG: a central pattern generator for legged robots based on workspaceintentions. In: Proceedings of the ASME Dynamic System and Control Conference (DSCC), pages 111–114 (2011)
2.
Barasuol, V., Buchli, J., Semini, C., Frigerio, M., De Pieri, E.R., Caldwell, D.G.: A reactive controller framework for quadrupedal locomotion on challenging terrain. In: IEEE International Conference on Robotics and Automation (ICRA) (2013)
3.
Blickhan, R.: The spring-mass model for running and hopping. Biomechanics 22, 1217–1227 (1989)CrossRef
4.
Boaventura, T., Semini, C., Buchli, J., Frigerio, M., Focchi, M., Caldwell. D.G.: Dynamic torque control of a hydraulic quadruped robot. In: IEEE International Conference in Robotics and Automation (ICRA), pp. 1889–1894 (2012)
5.
Boaventura, T., Medrano-Cerda, G.A., Semini, C., Buchli, J., Caldwell, D.G.: Stability and performance of the compliance controller of the quadruped robot HYD. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) (2013)
6.
Bruce, P.G., Freunberger, S.A., Hardwick, L.J., Tarascon, J.-M.: Li-O2 and Li-S batteries with high energy storage. Nat. Mater. 11, 19–29 (2012)CrossRef
7.
Buchli, J., Kalakrishnan, M., Mistry, M., Pastor, P., Schaal, S.: Compliant quadruped locomotion over rough terrain. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 814–820 (2009)
8.
Buehler, M., Battaglia, R., Cocosco, R., Hawker, G., Sarkis, J., Yamazaki, K.: SCOUT: a simple quadruped that walks, climbs, and runs. Int. Conf. Robot. Autom. (ICRA) 2, 1707–1712 (1998)CrossRef
9.
Burdet, E., Osu, R., Franklin, D., Milner, T., Kawato, M.: The central nervous system stabilizes unstable dynamics by learning optimal impedance. Nature 414(6862), 446–449 (2001)CrossRef
10.
Estremera, J., Waldron, K.J.: Thrust control, stabilization and energetics of a quadruped running robot. Int. J. Robot. Res. 27, 1135–1151 (2008)CrossRef
11.
Focchi, M., Boaventura, T., Semini, C., Frigerio, M., Buchli, J., Caldwell, D.G.: Torque-control based compliant actuation of a quadruped robot. In: Proceedings of the 12th IEEE International Workshop on Advanced Motion Control (AMC) (2012)
12.
Franklin, D., Burdet, E., Osu, R., Kawato, M., Milner, T.: Functional significance of stiffness in adaptation of multijoint arm movements to stable and unstable dynamics. Exp. Brain Res. 151, 145–157 (2003)CrossRef
13.
Gehring, C., Coros, S., Hutter, M., Blösch, M., Höpflinger, M., Siegwart, R.: Control of dynamic gaits for a quadrupedal robot. In: IEEE International Conference on Robotics and Automation (ICRA) (2013)
14.
Geyer, H., Herr, H.: A muscle-reflex model that encodes principles of legged mechanics produces human walking dynamics and muscle activities. IEEE Trans. Neural Syst. Rehabil. Eng. 18(3), 263–273 (2010)CrossRef
15.
Herzog, A., Righetti, L., Grimminger, F., Pastor, P., Schaal, S.: Momentum-based balance control for torque-controlled humanoids. In: arXiv preprint arXiv:​1305.​2042 (2013)
16.
Hirzinger, G., Albu-Schäffer, A., Hahnle, M., Schaefer, I., Sporer, N.: On a new generation of torque controlled light-weight robots. In: IEEE International Conference on Robotics and Automation (ICRA), vol. 4, pp. 3356–3363 (2001)
17.
Hogan, N.: Adaptive control of mechanical impedance by coactivation of antagonist muscles. IEEE Trans. Autom. Control 29, 681–690 (1984)CrossRefMATH
18.
Hogan, N.: Impedance control: An approach to manipulation: Part I - Theory. ASME J. Dyn. Syst. Meas. Control 107, 1–7 (1985)CrossRefMATH
19.
Hogan, N.: Impedance control: An approach to manipulation: Part II - Implementation. ASME J. Dyn. Syst. Meas. Control 107, 8–16 (1985)CrossRefMATH
20.
Hutter, M., Gehring, C., Blösch, M., Höpflinger, M., Remy, C.D., Siegwart, R.: Starleth: A compliant quadrupedal robot for fast, efficient, and versatile locomotion. In: International Conference on Climbing and Walking Robots (CLAWAR) (2012)
21.
Hyon, S., Hale, J., Cheng, G.: Full-body compliant human-humanoid interaction: Balancing in the presence of unknown external forces. IEEE Trans. Robot. 23(5), 884–898 (2007)CrossRef
22.
Ijspeert, A.J.: Central pattern generators for locomotion control in animals and robots: a review. Neural Netw. 21(4), 642–653 (2008)CrossRef
23.
Kandel, E., Schwartz, J., Jessell, T.: Principles of Neural Science, 4th edn, McGraw-Hill Medical, (2000)
24.
Khatib, O.: A unified approach for motion and force control of robot manipulators: The operational space formulation. IEEE J. Robot. Autom. 3(1), 43–53 (1987)CrossRef
25.
26.
Ott, C., Eiberger, O., Englsberger, J., Roa, M.A., Albu-Schäffer, A.: Hardware and control concept for an experimental bipedal robot with joint torque sensors. J. Robot. Soc. Jpn. 30(4), 378–382 (2012)
27.
Pratt, G., Williamson, M.: Series elastic actuators. In: IEEE International Conference on Intelligent Robots and Systems (IROS) (1995)
28.
Pratt, J., Chew, C., Torres, A., Dilworth, P., Pratt, G.: Virtual model control: An intuitive approach for bipedal locomotion. Int. J. Robot. Res 20(2), 129–143 (2001)
29.
Raibert, M.H.: Legged Robots That Balance. The MIT Press, Cambridge (1986)
30.
Raibert, M., Blankespoor, K., Nelson, G., Playter, R., the BigDog Team,: Bigdog, the rough-terrain quadruped robot. In: Proceedings of the 17th World Congress The International Federation of Automatic Control (IFAC) (2008)
31.
Selen, L., Franklin, D., Wolpert, D.: Impedance control reduces instability that arises from motor noise. J Neurosci 29(40), 12606–16 (2009)CrossRef
32.
Semini, C.: HyQ—Design and Development of a Hydraulically Actuated Quadruped Robot. Ph.D thesis, Istituto Italiano di Tecnologia (IIT) (2010)
33.
Semini, C., Tsagarakis, N.G., Guglielmino, E., Focchi, M., Cannella, F., Caldwell, D.G.: Design of HyQ—a hydraulically and electrically actuated quadruped robot. J. Syst. Control Eng. 225(6), 831–849 (2011)
34.
Seok, S., Wang, A., Otten, D., Kim, S.: Actuator design for high force proprioceptive control in fast legged locomotion. In: IEEE/RSJ Intelligent Robots and Systems (IROS), pp. 1970–1975 (2012)
35.
Seok, S., Wang, A., Chuah, M.Y.M., Otten, D., Lang, J., Kim, S.: Design principles for highly efficient quadrupeds and implementation on the mit cheetah robot. In: IEEE International Conference on Robotics and Automation (ICRA) (2013)
36.
Shadmer, R., Arbib, M.: A mathematical analysis of the force-stiffness characteristics of muscles in control of a single joint system. Biol. Cybern. 66, 463–477 (1992)CrossRefMATH
37.
Spröwitz, A., Tuleu, A., Vespignani, M., Ajallooeian, M., Badri, E., Ijspeert, A.: Towards dynamic trot gait locomotion-design, control and experiments with Cheetah-cub, a compliant quadruped robot. Int. J. Robot. Res 32(8), 933–951 (2013)
38.
Sreenath, K., Park, H.W., Grizzle, J.W.: Design and experimental implementation of a compliant hybrid zero dynamics controller with active force control for running on mabel. In: IEEE International Conference in Robotics and Automation (ICRA) (2012)
39.
Stephens, B., Atkeson, C.: Modeling and control of periodic humanoid balance using the linear biped model. In: IEEE-RAS International Conference on Humanoid Robots (Humanoids) (2010)
40.
Tee, K., Franklin, D., Kawato, M., Milner, T., Burdet, E.: Concurrent adaptation of force and impedance in the redundant muscle system. Biol. Cybern. 120(1), 31–44 (2009)MATH
41.
Tsagarakis, N., Sardellitti, I., Caldwell, D.: A new variable stiffness actuator (compact-vsa): Design and modelling. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 378–383 (2011)
42.
Vanderborght, B. et al.: Variable impedance actuators: a review. Robotics and Autonomous Systems (2013)
43.
Semini, C., Barasuol, V., Boaventura, T., Frigerio, M., Focchi, M., Caldwell, D.G., Buchli, J.: Towards versatile legged robots through active impedance control. Int. J. Robot. Res 34(7), 1003–1020 (2015)
Metadaten
Titel
Is Active Impedance the Key to a Breakthrough for Legged Robots?
verfasst von
Claudio Semini
Victor Barasuol
Thiago Boaventura
Marco Frigerio
Jonas Buchli
Copyright-Jahr
2016
Buch
Robotics Research

Print ISBN: 978-3-319-28870-3

Electronic ISBN: 978-3-319-28872-7

Copyright-Jahr: 2016

DOI
https://doi.org/10.1007/978-3-319-28872-7_1

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