<i>TMTDyn</i>: A Matlab package for modeling and control of hybrid rigid–continuum robots based on discretized lumped systems and reduced-order models

Sadati, S. M. Hadi; Naghibi, S. Elnaz; Shiva, Ali; Michael, Brendan; Renson, Ludovic; Howard, Matthew; Rucker, D. Caleb; Althoefer, Kaspar; Nanayakkara, Thrishantha; Zschaler, Steffen; Bergeles, Christos; Hauser, Helmut; Walker, Ian D.

doi:10.1177/0278364919881685

Cited by 71 publications

(108 citation statements)

References 73 publications

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“…Sadati et al introduce an open-source Matlab package for simulating continuum soft robots. The package is called TMTDyn and can be used for designing and testing control algorithms.…”

Section: Model-based Controlmentioning

confidence: 99%

Editorial: Soft Robotic Modeling and Control: Bringing Together Articulated Soft Robots and Soft-Bodied Robots

Santina

Katzschmann

Bicchi

et al. 2021

The International Journal of Robotics Research

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“…Sadati et al introduce an open-source Matlab package for simulating continuum soft robots. The package is called TMTDyn and can be used for designing and testing control algorithms.…”

Section: Model-based Controlmentioning

confidence: 99%

Editorial: Soft Robotic Modeling and Control: Bringing Together Articulated Soft Robots and Soft-Bodied Robots

Santina

Katzschmann

Bicchi

et al. 2021

The International Journal of Robotics Research

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“…Variable Curvature (VC) kinematics, based on rotation matrices and Cosserat rod theory are used to model the static mechanics of the appendage [1], [23]. The local physical curvilinear coordinates are…”

Section: A Continuum Appendage Static Modelmentioning

confidence: 99%

Stiffness Imaging With a Continuum Appendage: Real-Time Shape and Tip Force Estimation From Base Load Readings

Sadati

Shiva

Herzig

et al. 2020

IEEE Robot. Autom. Lett.

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In this paper, we propose benefiting from load readings at the base of a continuum appendage for real-time forward integration of Cosserat rod model with application in configuration and tip load estimation. The application of this method is successfully tested for stiffness imaging of a soft tissue, using a 3-DOF hydraulically actuated braided continuum appendage. Multiple probing runs with different actuation pressures are used for mapping the tissue surface shape and directional linear stiffness, as well as detecting non-homogeneous regions, e.g. a hard nodule embedded in a soft silicon tissue phantom. Readings from a 6-axis force sensor at the tip is used for comparison and verification. As a result, the tip force is estimated with 0.016-0.037 N (7-20%) mean error in the probing and 0.02-0.1 N (6-12%) in the indentation direction, 0.17 mm (14%) mean error is achieved in estimating the surface profile, and 3.4-15 [N/m] (10-16%) mean error is observed in evaluating tissue directional stiffness, depending on the appendage actuation. We observed that if the appendage bends against the slider motion (toward the probing direction), it provides better horizontal stiffness estimation and better estimation in the perpendicular direction is achieved when it bends toward the slider motion (against the probing direction). In comparison with a rigid probe, ≈ 10 times smaller stiffness and ≈ 7 times larger mean standard deviation values were observed, suggesting the importance of a probe stiffness in estimation the tissue stiffness.

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“…Digital Object Identifier 10.1109/LRA.2019.2955936 control [4], feedback dynamic control [5]. However, the research in modeling soft robots goes now much further than constant curvature approximations, with fascinating theoretical and experimental results [6]- [10]. It is worth underlying that the present letter does not aim to compete with existing models for accurately or efficiently simulate the robot -task for which these methods are well suited.…”

Section: Introductionmentioning

confidence: 99%

Control Oriented Modeling of Soft Robots: The Polynomial Curvature Case

Santina

Rus

2020

IEEE Robot. Autom. Lett.

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The complex nature of soft robot dynamics calls for the development of models specifically tailored on the control application. In this letter, we take a first step in this direction by proposing a dynamic model for slender soft robots, taking into account the fully infinite-dimensional dynamical structure of the system. We also contextually introduce a strategy to approximate this model at any level of detail through a finite dimensional system. First, we analyze the main mathematical properties of this model in the case of lightweight and non lightweight soft robots. Then, we prove that using the constant term of curvature as control output produces a minimum phase system, in this way providing the theoretical support that existing curvature control techniques lack, and at the same time opening up to the use of advanced nonlinear control techniques. Finally, we propose a new controller, i.e., the PD-poly, which exploits information on high order deformations, to achieve zero steady state regulation error in presence of gravity and generic nonconstant curvature conditions.

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TMTDyn: A Matlab package for modeling and control of hybrid rigid–continuum robots based on discretized lumped systems and reduced-order models

Cited by 71 publications

References 73 publications

Editorial: Soft Robotic Modeling and Control: Bringing Together Articulated Soft Robots and Soft-Bodied Robots

Editorial: Soft Robotic Modeling and Control: Bringing Together Articulated Soft Robots and Soft-Bodied Robots

Stiffness Imaging With a Continuum Appendage: Real-Time Shape and Tip Force Estimation From Base Load Readings

Control Oriented Modeling of Soft Robots: The Polynomial Curvature Case

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