A Method to Identify the Nonlinear Stiffness Characteristics of an Elastic Continuum Mechanism

被引：12

作者：

Deutschmann B. ^{[1
]}

Liu T. ^{[2
]}

Dietrich A. ^{[1
]}

Ott C. ^{[1
]}

Lee D. ^{[2
]}

机构：

[1] Institute of Robo-tics and Mechatronics, German Aerospace Center, Wessling

[2] Human-Centered Assistive Robotics Group, Technical University of Munich, Munich

来源：

Deutschmann, Bastian (bastian.deutschmann@dlr.de) | 2018年 / Institute of Electrical and Electronics Engineers Inc., United States卷 / 03期

关键词：

compliant joint/mechanism; Model learning for control; soft material robotics;

D O I：

10.1109/LRA.2018.2800098

中图分类号：

学科分类号：

摘要：

The humanoid robot David is equipped with a novel robotic neck based on an elastic continuum mechanism (ECM). To realize a model-based motion control, the six dimensional stiffness characteristics needs to be known. This letter presents an approach to experimentally identify the stiffness characteristic using a robot manipulator to deflect the ECM and measure the Cartesian wrenches and Cartesian poses with external sensors. A three-step process is proposed to establish Cartesian wrench and pose pairs experimentally. The process consists of a simulation step, to select a good model, a second step that extracts effective poses from workspace which are sampled experimentally and the third step, the pose sampling procedure in which the robot drives the ECM to these effective poses. A full cubic polynomial regression model is adopted based on simulation data to fit the stiffness characteristics. To extract the poses to be sampled in the experiments, two different approaches are evaluated and compared to ensure a well-posed identification. The identification process on the hardware is performed by using Cartesian impedance and inverse kinematics control in combination to comply with the physical constraints imposed by the ECM. © 2016 IEEE.

引用

页码：1450 / 1457

页数：7

共 31 条

[1]

Reinecke J., Deutschmann B., Fehrenbach D., A structurally flexible humanoid spine based on a tendon-driven elastic continuum, Proc. IEEE IEEE Int. Conf. Robot. Autom., pp. 4714-4721, (2016)

[2]

Odhner L.U., Et al., A compliant, underactuated hand for robust manipulation, Int. J. Robot. Res., 33, 5, pp. 736-752, (2014)

[3]

Case J.C., White E.L., SunSpiral V., Kramer-Bottiglio R., Reducing actuator requirements in continuum robots through optimized cable routing, Soft Robot., 5, 1, pp. 109-118, (2018)

[4]

Deutschmann B., Dietrich A., Ott C., Position control of an underactuated continuum mechanism using a reduced nonlinear model, Proc. IEEE Int. Conf. Decis. Control., pp. 5223-5230, (2017)

[5]

Deutschmann B., Ott C., Monje C.A., Balaguer C., Robust motion control of a soft robotic system using fractional order control, Proc. Int. Conf. Robot. Alpe-Adria Danube Region, pp. 147-155, (2017)

[6]

Chalon M., Friedl W., Reinecke J., Wimboeck T., Albu-Schaeffer A., Impedance control of a non-linearly coupled tendon driven thumb, Proc. IEEE/RSJ Int. Conf. Intell. Robots Syst., pp. 4215-4221, (2011)

[7]

Caleb Rucker D., Webster R.J., Statics and dynamics of continuum robots with general tendon routing and external loading, IEEE Trans. Robot., 27, 6, pp. 1024-1030, (2011)

[8]

Renda F., Giorelli M., Calisti M., Cianchetti M., Laschi C., Dynamic model of a multibending soft robot arm driven by cables, IEEE Trans. Robot., 30, 5, pp. 1109-1122, (2014)

[9]

Allard J., Et al., Sofa-an open source framework for medical simulation, MMVR 15-Medicine Meets Virtual Reality, 125, pp. 13-18, (2007)

[10]

Duriez C., Control of elastic soft robots based on real-time finite element method, Proc. IEEE Int. Conf. Robot. Autom., pp. 3982-3987, (2013)

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