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Autonomous Robots
Erschienen in: Autonomous Robots 4/2013

01.11.2013

Implementation and stability analysis of prioritized whole-body compliant controllers on a wheeled humanoid robot in uneven terrains

verfasst von: Luis Sentis, Josh Petersen, Roland Philippsen

Erschienen in: Autonomous Robots | Ausgabe 4/2013

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Abstract

In this work, we implement the floating base prioritized whole-body compliant control framework described in Sentis et al. (IEEE Transactions on Robotics 26(3):483–501, 2010) on a wheeled humanoid robot maneuvering in sloped terrains. We then test it for a variety of compliant whole-body behaviors including balance and kinesthetic mobility on irregular terrain, and Cartesian hand position tracking using the co-actuated (i.e. two joints are simultaneously actuated with one motor) robot’s upper body. The implementation serves as a hardware proof for a variety of whole-body control concepts that had previously been developed and tested in simulation. First, behaviors of two and three priority tasks are implemented and successfully executed on the humanoid hardware. In particular, first and second priority tasks are linearized in the task space through model feedback and then controlled through task accelerations. Postures, on the other hand, are shown to be asymptotically stable when using prioritized whole-body control structures and then successfully tested in the real hardware. To cope with irregular terrains, the base is modeled as a six degree of freedom floating system and the wheels are characterized through contact and rolling constraints. Finally, center of mass balance capabilities using whole-body compliant control and kinesthetic mobility are implemented and tested in the humanoid hardware to climb terrains with various slopes.
Vorheriger Artikel Towards a swarm of agile micro quadrotors

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Literatur
Aghili, F. (2005). A unified approach for inverse and direct dynamics of constrained multibody systems based on linear projection operator: applications to control and simulation. IEEE Transactions on Robotics, 21(5), 834–849.CrossRef
Alami, R., Chatila, R., Fleury, S., Ghallab, M., & Ingrand, F. (1998). An architecture for autonomy. The International Journal of Robotics Research, 17(4), 315–337.CrossRef
Arkin, R. C., & Murphy, R. R. (1990). Autonomous navigation in a manufacturing environment. IEEE Transactions on Robotics and Automation, 6(4), 445–454.CrossRef
Asfour, T., Berns, K., & Dillmann, R. (2000). The humanoid robot armar: Design and control. The 1st IEEE-ras international conference on humanoid robots (humanoids 2000) (pp. 7–8).
Babic, J. (2009). Biarticular legged robot: Design and experiments. IEEE international conference on robotics and biomimetics. Bankok, Thailand.
Baerlocher, P. (2001). Inverse kinematics techniques for the interactive posture control of articulated figures. Ph.D. thesis, Ecole Polytechnique Federale de Lausanne, Lausanne, Switzerland.
Beetz, M., Mo, L., Senlechner, & Tenorth, M. (2010). A cognitive robot abstract machine for everyday manipulation in human environments. IEEE/rsj international conference on Intelligent robots and systems (iros) (pp. 1012–1017).
Bouyarmane, K., & Kheddar, A. (2011). Multi-contact stances planning for multiple agents. Proceedings of the IEEE international conference on robotics and automation. Shanghai.
Breazeal, C., Siegel, M., Berlin, M., Gray, J., Grupen, R., Deegan, P., Weber, J., Narendran, K., & McBean, J. (2008). Mobile, dexterous, social robots for mobile manipulation and human-robot interaction. SIGGRAPH08: ACM SIGGRAPH 2008 new tech demos.
Brock, O., Khatib, O., & Viji, S. (2002). Task-consistent obstacle avoidance and motion behavior for mobile manipulation. Proceedings of the ieee international conference on robotics and automation (pp. 388–393). Washingtion, USA.
Chang, K. S., Holmberg, R., & Khatib, O. (2000). The augmented object model: Cooperative manipulation and parallel mechanism dynamics. Proceedings of IEEE international conference on robotics and automation, 1, 470–475.
Cotton, S., Murray, A. P., & Fraisse, P. (2009). Estimation of the center of mass: From humanoid robots to human beings. IEEE/ASME Transactions on Mechatronics, 14(6), 707–712.CrossRef
DeLuca, A. (1991). Zero dynamics in robotics systems. Proceedings of the IIASA Workshop Progress in Systems and Control Theory, 9, 70–87.MathSciNet
Dietrich, A., Wimbock, T. & Albu-Schaffer, A. (2011). Dynamic whole-body mobile manipulation with a torque controlled humanoid robot via impedance control laws. IEEE/rsj international conference on Intelligent robots and systems (iros) (pp. 3199–3206).
Dubowsky, S., & Papadopoulos, E. (1993). he kinematics, dynamics, and control of free-flying and free-floating space robotic systems. IEEE Transactions on Robotics and Automation, 9(5), 531–543.CrossRef
Edsinger, A., & Kemp, C. (2008). Two arms are better than one: A behavior based control system for assistive bimanual manipulation. Recent progress in robotics: Viable robotic service to human.
Featherstone, R. (1987). Robot dynamics algorithms. Norwell, USA: Kluwer Academic Publishers.
Freitas, G., Lizarralde, F., Hsu, L., & Reis, N., Salvi dos R. (2009). Kinematic reconfigurability of mobile robots on irregular terrains. IEEE international conference on robotics and automation (ICRA) (pp. 1340–1345).
Fuchs, M., Borst, C., Giordano, P. R., Baumann, A., Kraemer, E., Langwald, J., Gruber, R., Seitz, N., Plank, G., Kunze, K., Burger, R., Schmidt, F., Wimboeck, T., & Hirzinger, G. (2009). Rollin’ justin: Design considerations and realization of a mobile platform for a humanoid upper body. IEEE international conference on robotics and automation (ICRA), (pp. 4131–4137).
Halme, A., Leppänen, I., & Salmi, S. (1999). Development of workpartner-robot-design of actuating and motion control system. 2nd international conference on climbing and walking robots, portsmouth (pp. 657–666).
Hanafusa, H., Yoshikawa, T., & Nakamura, Y. (1981). Analysis and control of articulated robot with redundancy. Proceedings of IFAC symposium on robot control. Vol. 4, (pp. 1927–1932).
Hart, S., Yamokoski, J. D., & Diftler, M. (2011). Robonaut 2: A new platform for human-centered robot learning. Robotics Science and Systems.
Hirose, S., et al. (1991). Design of practical snake vehicle: Articulated body mobile robot kr-2. The 5th international conference on advanced robotics, (pp. 833–838).
Holmberg, R., & Khatib, O. (2000). Development and control of a holonomic mobile robot for mobile manipulation tasks. The International Journal of Robotics Research, 19(11), 1066–1074.CrossRef
Hyon, S.-H., Hale, J., & Cheng, G. (2007). Full-body compliant human-humanoid interaction: Balancing in the presence of unknown external forces. IEEE Transactions on Robotics, 23(5), 884–898.CrossRef
Iwata, H., & Sugano, S. (2009). Design of human symbiotic robot twendy-one. IEEE international conference on robotics and automation (ICRA) (pp. 580–586).
Jenkins, O. C., & Mataric, M. J. (2004). Performance-derived behavior vocabularies: Data-driven acqusition of skills from motion. International Journal of Humanoid Robotics, 1(2), 237–288.CrossRef
Katz, D., Horrell, E., Yang, Y., Burns, B., Buckley, T., Grishkan, A., Zhylkovskyy, V., Brock, O., & Learned-Miller, E. (2006). The umass mobile manipulator uman: An experimental platform for autonomous mobile manipulation. Workshop on manipulation in human environments at robotics: Science and systems.
Khatib, O. (1987). A unified approach for motion and force control of robot manipulators: The operational space formulation. International Journal of Robotics Research, 3(1), 43–53.
Khatib, O., Sentis, L., Park, J. H., & Warren, J. (2004). Whole body dynamic behavior and control of human-like robots. International Journal of Humanoid Robotics, 1(1), 29–43.CrossRef
Kim, K.-G., Lee, J.-Y., Choi, D., Park, J.-M. & You, B.-J. (2010). Autonomous task execution of a humanoid robot using a cognitive model. IEEE international conference on robotics and biomimetics (ROBIO), (pp. 405–410).
Kimura, N., et al. (1991). Locomotion mechanism and its control architecture for disaster preventing robot. Proceedings of international symposium on advanced robot technology, (pp. 375–380).
King, C.-H., Chen, T. L., Jain, A., & Kemp, C. C. (2010). Towards an assistive robot that autonomously performs bed baths for patient hygiene. IEEE/rsj international conference on intelligent robots and systems (IROS), (pp. 319–324).
Lengagne, S., Vaillant, J., Yoshida, E., & Kheddar, A. (2013). Generation of whole-body optimal dynamic multi-contact motions. The International Journal of Robotics Research.
Matsumoto, O., Kajita, S., Tani, K., & Oooto, M. (1995). A four-wheeled robot to pass over steps by changing running control modes. IEEE international conference on robotics and automation. Vol. 2, (pp. 1700–1706).
Meeussen, W., Wise, M., Glaser, S., Chitta, S., McGann, C., Mihelich, P., Marder-Eppstein, E., Muja, M., Eruhimov, V., Foote, T., Hsu, J., Rusu, R.B., Marthi, B., Bradski, G., Konolige, K., Gerkey, B., & Berger, E. (2010). Autonomous door opening and plugging in with a personal robot. IEEE international conference on robotics and automation (ICRA), (pp. 729–736).
Mistry, M., Buchli, J., & Schaal, S. (2010). Inverse dynamics control of floating base systems using orthogonal decomposition. Proceedings of the IEEE international conference on robotics and automation, (pp. 3406–3412).
Mistry, M., and Righetti, L. (2011). Operational space control of constrained and underactuated systems. Robotics: Science and systems VII.
Nagasaka, K., Kawanami, Y. Shimizu, S., Kito, T., Tsuboi, T., Miyamoto, A., Fukushima, T., & Shimomura, H. (2010). Whole-body cooperative force control for a two-armed and two-wheeled mobile robot using generalized inverse dynamics and idealized joint units. IEEE international conference on robotics and automation (ICRA), (pp. 3377–3383).
Nakamura, Y., Hanafusa, H., & Yoshikawa, T. (1987). Task-priority based control of robot manipulators. International Journal of Robotics Research, 6(2), 3–15.CrossRef
Nakanishi, J., Mistry, M., & Schaal, S., (2007). Inverse dynamics control with floating base and constraints. IEEE international conference on robotics and automation, pp. 1942–1947.
Nakano, E., & Nagasaka, S. (1993). Leg-wheel robot: A futuristic mobile platform for forestry industry. Proceedings of IEEE/Tsukuba international workshop on advanced robotics, (pp. 109–112).
Oh, S., Kimura, Y., & Hori, Y. (2010). Force control based on biarticular muscle system and its application to novel robot arm driven by planetary gear system. IEEE/rsj international conference on intelligent robots and systems, Taipei.
Ohmichi, T., et al. (1985). Development of the multi-function robot for the containment vessel of the nuclear plant. Proceedings of international conference on advanced robotics, (pp. 371–378).
Oriolo, G., (1994). Stabilization of self-motions in redundant robots. Proceedings IEEE international conference on robotics and automation, (pp. 704–709).
Pastor, P., Hoffmann, H., Asfour, T. & Schaal, S. (2009). Learning and generalization of motor skills by learning from demonstration. IEEE international conference on robotics and automation (ICRA), (pp. 763–768).
Philippsen, R., Sentis, L., & Khatib, O. (2011). An open source extensible software package to create whole-body compliant skills in personal mobile manipulators. IEEE/rsj international conference on intelligent robots and systems (IROS), (pp. 1036–1041).
Reiser, U., Connette, C., Fischer, J., Kubacki, J., Bubeck, A., Weisshardt, F., Jacobs, T., Parlitz, C., Hagele, M., & Verl, A. (2009). Care-o-bot; 3: Creating a product vision for service robot applications by integrating design and technology. IEEE/rsj international conference on intelligent robots and systems (IROS), (pp.1992–1998).
Righetti, L., Buchli, J., Mistry, M., & Schaal, S. (2011). Inverse dynamics control of floating-base robots with external constraints: A unified view. IEEE international conference on robotics and automation (ICRA), (pp. 1085–1090).
Righetti, L., Buchli, J., Mistry, M., Kalakrishnan, M., & Schaal, S. (2013). Optimal distribution of contact forces with inverse dynamics control. The International Journal of Robotics Research, 32(3), 280–298.CrossRef
Saab, L., Ramos, O. E., Keith, F., Mansard, N., Soueres, P., & Fourquet, J.-Y. (2013). Dynamic whole-body motion generation under rigid contacts and other unilateral constraints.
Salini, J. (2012). Dynamic control for the task/posture coordination of humanoids: Toward synthesis of complex activities. These de doctorat. Paris, France: Universit Pierre et Marie Curie.
Salini, J., Padois, V., Ibanez, A., Bidaud, P., & Buendia, A. (2011). A goal driven perspective to generate humanoid motion synthesis. Field robotics: Proceedings of the 14th international conference on climbing and walking robots and the support technologies for mobile machines, (pp. 889–897). World Scientific.
Schaal, S., Auke, I., & Aude, B. (2003). Computational approaches to motor learning by imitation. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences, 358(1413), 537–547.CrossRef
Sentis, L. (2007). Synthesis and control of whole-body behaviors in humanoid systems. Ph.D. thesis, Stanford University, Stanford, USA.
Sentis, L., & Khatib, O. (2005). Synthesis of whole-body behaviors through hierarchical control of behavioral primitives. International Journal of Humanoid Robotics, 2(4), 505–518.CrossRef
Sentis, L., Park, J., & Khatib, O. (2010). Compliant control of multi-contact and center of mass behaviors in humanoid robots. IEEE Transactions on Robotics, 26(3), 483–501.CrossRef
Sentis, L., Petersen, J., & Philippsen, R. (2012). Experiments with balancing on irregular terrains using the dreamer mobile humanoid robot. Robotics science and systems, Sidney.
Siciliano, B., & Slotine, J., (1991). A general framework for managing multiple tasks in highly redundant robotic systems. Proceedings of the IEEE international conference on advanced robotics, (pp. 1211–1216). Pisa, Italy
Simmons, R., & Apfelbaum, D. (1998). A task description language for robot control. Proceedings IEEE/rsj international conference on Intelligent robots and systems, Vol. 3, (pp. 1931–19373).
Stilman, M., Olson, J., Gloss, W. (2010). Golem krang: Dynamically stable humanoid robot for mobile manipulation. IEEE international conference on robotics and automation (ICRA), (pp. 3304–3309).
Theobold, D., Ornstein, J., Nichol, J. G., Kullberg, S. E., et al. (2008). Mobile robot platform Google Patents. US Patent 7,348,747.
Umetami, Y., & Yoshida, K. (1989). Resolved motion rate control of space manipulators with generalized Jacobian matrix. IEEE Transactions on Robotics and Automation, 5(3), 303–314.
Vallery, H., Ekkelenkamp, R., Van Der Herman, K., & Buss, M. (2007). Passive and accurate torque control of series elastic actuators. IEEE/rsj international conference on intelligent robots and systems (IROS), (pp. 3534–3538).
Volpe, R., Nesnas, I., Estlin, T., Mutz, D., Petras, R., & Das, H. (2001). The claraty architecture for robotic autonomy. IEEE proceedings on aerospace conference, Vol. 1, (pp. 1–12111321).
Vukobratović, M., & Borovac, B. (2004). Zero-moment point thirty tive years of its life. International Journal of Humanoid Robotics, 1(1), 157–173.CrossRef
Wakita, K., Huang, J., Di, P., Sekiyama, K., & Fukuda, T. (2011). Human-walking-intention-based motion control of an omnidirectional-type cane robot. IEEE/ASME Transactions on Mechatronics, 99, 1–12.
Wilcox, B. H., Litwin, T., Biesiadecki, J., Matthews, J., Heverly, M., Morrison, J., et al. (2007). Athlete: A cargo handling and manipulation robot for the moon. Journal of Field Robotics, 24(5), 421–434.CrossRef
Ylonen, S. J., & Halme, A. J. (2002). Workpartner: centaur like service robot. IEEE/rsj international conference on intelligent robots and systems Vol. 1, (pp. 727–732).
Metadaten
Titel
Implementation and stability analysis of prioritized whole-body compliant controllers on a wheeled humanoid robot in uneven terrains
verfasst von
Luis Sentis
Josh Petersen
Roland Philippsen
Publikationsdatum
01.11.2013
Verlag
Springer US
Erschienen in
Autonomous Robots / Ausgabe 4/2013
Print ISSN: 0929-5593
Elektronische ISSN: 1573-7527
DOI
https://doi.org/10.1007/s10514-013-9358-8

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