これは2022-04-11 02:10:09 UTCで公開された古いバージョンです。最新バージョンをお読みください。
プレプリント / バージョン1

COM Shifter and Body Rotator for Step-by-Step Teleoperation of Bipedal Robots

##article.authors##

DOI:

https://doi.org/10.51094/jxiv.45

キーワード:

Teleoperation、 Bipedal robots、 Cart-flywheel-table model

抄録

This paper presents a controller for step-by-step teleoperation of bipedal robots, in which the user commands the robot’s foot motions in a step-by-step manner through a pair of hand-held 3-degree-of-freedom haptic devices. This teleoperation scheme requires a controller that quickly responds to the user commands and maintains the balance even under erroneous user commands. The main components of the proposed controller are a COM (center of mass) shifter and a body rotator, which are built upon a cart-flywheel-table model of bipedal robots. The COM shifter is a simple feedback controller to produce a COM motion according to a reference ZMP (zero moment point). The body rotator is a complement for the COM shifter to produce an appropriate angular momentum rate to enhance the regulation of ZMP. The outputs of these components are combined by a prioritized differential inverse kinematics to generate velocity commands to the joints. The proposed controller is validated in our interactive/realtime simulation environment.

ダウンロード *前日までの集計結果を表示します

ダウンロード実績データは、公開の翌日以降に作成されます。

引用文献

Nakaoka S, Morisawa M, Kaneko K, et al. Development of an indirect-type teleoperation interface for biped humanoid robots. In: Proceedings of the 2014 IEEE/SICE International Symposium on System Integration; 2014. p. 590–596.

Cisneros R, Nakaoka S, Morisawa M, et al. Effective teleoperated manipulation for hu- manoid robots in partially unknown real environments: team AIST-NEDO’s approach for performing the plug task during the DRC finals. Advanced Robotics. 2016;30(24):1544– 1558.

Kohlbrecher S, Romay A, Stumpf A, et al. Human-robot teaming for rescue missions: Team ViGIR’s approach to the 2013 DARPA robotics challenge trials. Journal of Field Robotics. 2015;32(3):352–377.

Fallon M, Kuindersma S, Karumanchi S, et al. An architecture for online affordance-based perception and whole-body planning. Journal of Field Robotics. 2015;32(2):229–254.

Almetwally I, Mallem M. Real-time tele-operation and tele-walking of humanoid robot Nao using Kinect depth camera. In: Proceedings of International Conference on Network- ing, Sensing and Control; 2013. p. 463–466.

Penco L, Scianca N, Modugno V, et al. A multimode teleoperation framework for hu- manoid loco-manipulation: An application for the iCub robot. IEEE Robotics & Au- tomation Magazine. 2019;26(4):73–82.

Prasanga DK, Tanida K, Ohnishi K, et al. Simultaneous bipedal locomotion based on haptics for teleoperation. Advanced Robotics. 2019;33(15-16):824–839.

Ishiguro Y, Makabe T, Nagamatsu Y, et al. Bilateral humanoid teleoperation system using whole-body exoskeleton cockpit TABLIS. IEEE Robotics and Automation Letters. 2020;5(4):6419–6426.

Wang S, Ramos J. Dynamic locomotion teleoperation of a reduced model of a wheeled humanoid robot using a whole-body human-machine interface. IEEE Robotics and Au- tomation Letters. 2021;7(2):1872–1879.

Cardenas IS, Kim JH. Design of a semi-humanoid telepresence robot for plant disaster response and prevention. In: Proceedings of the 2019 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2019. p. 2748–2753.

Ando T, Watari T, Kikuuwe R. Master-slave bipedal walking and semi-automatic standing up of humanoid robots. In: Proceedings of the 2020 IEEE/SICE International Symposium on System Integration; 2020. p. 360–365.

Ando T, Watari T, Kikuuwe R. Reference ZMP generation for teleoperated bipedal robots walking on non-flat terrains. In: Proceedings of the 2021 IEEE/SICE International Sym- posium on System Integration; 2021. p. 794–780.

Herdt A, Diedam H, Wieber PB, et al. Online walking motion generation with automatic footstep placement. Advanced Robotics. 2010;24(5-6):719–737.

Sugihara T, Nakamura Y. Boundary condition relaxation method for stepwise pedipula- tion planning of biped robots. IEEE Transactions on Robotics. 2009;25(3):658–669.

Takenaka T, Matsumoto T, Yoshiike T. Real time motion generation and control for biped robot –1st report: Walking gait pattern generation–. In: Proceedings of the 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2009. p. 1084– 1091.

Harada K, Kajita S, Kaneko K, et al. An analytical method for real-time gait planning for humanoid robots. International Journal of Humanoid Robotics. 2006;3(1):1–19.

Tedrake R, Kuindersma S, Deits R, et al. A closed-form solution for real-time ZMP gait generation and feedback stabilization. In: Proceedings of IEEE-RAS International Conference on Humanoid Robots; 2015. p. 936–940.

Kajita S, Hirukawa H, Harada K, et al. Introduction to Humanoid Robotics. (Springer Tracts in Advanced Robotics; Vol. 101). Springer; 2014.

Kajita S, Kanehiro F, Kaneko K, et al. Biped walking pattern generation by using pre- view control of zero-moment point. In: Proceedings of the 2003 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2003. p. 1620–1627.

Wieber PB. Trajectory free linear model predictive control for stable walking in the presence of strong perturbations. In: Proceedings of IEEE-RAS International Conference on Humanoid Robots; 2006. p. 137–142.

Ding J, Zhou C, Xin S, et al. Nonlinear model predictive control for robust bipedal locomotion: exploring angular momentum and CoM height changes. Advanced Robotics. 2021;35(18):1079–1097.

Kajita S, Morisawa M, Miura K, et al. Biped walking stabilization based on linear inverted pendulum tracking. In: Proceedings of the 2010 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2010. p. 4489–4496.

Hong S, Oh Y, Kim D, et al. Real-time walking pattern generation method for humanoid robots by combining feedback and feedforward controller. IEEE Transactions on Industrial Electronics. 2014;61(1):355–364.

Lee SH, Goswami A. Reaction mass pendulum (RMP): An explicit model for centroidal angular momentum of humanoid robots. Proceedings of the 2007 IEEE International Conference on Robotics and Automation. 2007;:4667–4672.

Lee SH, Goswami A. A momentum-based balance controller for humanoid robots on non- level and non-stationary ground. Autonomous Robots. 2012;33(4):399–414.

Yamamoto K, Kamioka T, Sugihara T. Survey on model-based biped motion control for humanoid robots. Advanecd Robotics. 2020;34(21-22):1353–1369.

Sugihara T. Standing stabilizability and stepping maneuver in planar bipedalism based on the best COM-ZMP regulator. In: Proceedings of the 2009 IEEE International Conference on Robotics and Automation; 2009. p. 1966–1971.

Guan K, Yamamoto K, Nakamura Y. Virtual-mass-ellipsoid inverted pendulum model and its applications to 3D bipedal locomotion on uneven terrains. In: Proceedings of the 2019 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2019. p. 1401–1406.

Kojio Y, Ishiguro Y, Nguyen KNK, et al. Unified balance control for biped robots in- cluding modification of footsteps with angular momentum and falling detection based on capturability. In: Proceedings of the 2019 IEEE/RSJ International Conference on Intelli- gent Robots and Systems; 2019. p. 497–504.

Pratt J, Carff J, Drakunov S, et al. Capture point: A step toward humanoid push recovery. In: Proceedings of IEEE-RAS International Conference on Humanoid Robots; 2006. p. 200–207.

Nenchev DN, Iizuka R. Emergent humanoid robot motion synergies derived from the momentum equilibrium principle and the distribution of momentum. IEEE Transactions on Robotics. 2022;38(1):536–555.

Schuller R, Mesesan G, Englsberger J, et al. Online centroidal angular momentum ref- erence generation and motion optimization for humanoid push recovery. IEEE Robotics and Automation Letters. 2021;6(3):5689–5697.

Morisawa M, Kanehiro F, Kaneko K, et al. Combining suppression of the disturbance and reactive stepping for recovering balance. In: Proceedings of the 2010 IEEE/RSJ Interna- tional Conference on Intelligent Robots and Systems; 2010. p. 3150–3156.

Sugihara T. Reflexive step-out control superposed on standing stabilization of biped robots. In: Proceedings of 2012 12th IEEE-RAS International Conference on Humanoid Robots; 2012. p. 741–746.

Kajita S, Kanehiro F, Kaneko K, et al. Resolved momentum control: Humanoid mo- tion planning based on the linear and angular momentum. In: Proceedings of the 2003 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2003. p. 1644– 1650.

Nakamura Y, Hanafusa H, Yoshikawa T. Task-priority based redundancy control of robot manipulators. International Journal of Robotics Research. 1987;6(2):3–15.

Nakamura Y, Hanafusa H. Inverse kinematic solutions with singularity robustness for robot manipulator control. Transactions of ASME: Journal of Dynamic Systems, Mea- surement, and Control. 1986;108:163–171.

Chan TF, Dubey RV. A weighted least-norm solution based scheme for avoiding joint limits for redundant joint manipulators. IEEE Transactions on Robotics and Automation. 1995;11(2):286–292.

Mastalli C, Havoutis I, Focchi M, et al. Motion planning for quadrupedal locomotion: Cou- pled planning, terrain mapping, and whole-body control. IEEE Transactions on Robotics. 2020;36(6):1635–1648.

Kikuuwe R, Takesue N, Sano A, et al. Admittance and impedance representations of fric- tion based on implicit euler integration. IEEE Transactions on Robotics. 2006;22(6):1176–1188.

Kikuuwe R, Fujimoto H. Incorporating geometric algorithms in impedance-and admittance-type haptic rendering. In: Proceedings of the Second Joint EuroHaptics Con- ference and Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems; 2007. p. 249–254.

Kajita S, Morisawa M, Harada K, et al. Biped walking pattern generator allowing aux- iliary ZMP control. In: Proceedings of the 2006 IEEE/RSJ International Conference on Intelligent Robots and Systems; 2006. p. 2993–2999.

Nakaoka S. Choreonoid: Extensible virtual robot environment built on an integrated GUI framework. In: Proceedings of 2012 IEEE/SICE International Symposium on System Integration; 2012. p. 79–85.

ダウンロード

公開済


投稿日時: 2022-04-07 07:41:53 UTC

公開日時: 2022-04-11 02:10:09 UTC

バージョン

改版理由

研究分野
機械工学

ライセンス

Copyright(c)2022 Zhang, Yachen
Kikuuwe, Ryo

Creative Commons License

この作品は、Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International Licenseの下でライセンスされています。