A multi-level control architecture for the bionic handling assistant

Reimann, Matthias; Neumann, Klaus; Queißer, Jeffrey; Reinhart, René Felix; Nordmann, Arne; Steil, Jochen J.

doi:10.1080/01691864.2015.1037793

Cited by 20 publications

(10 citation statements)

References 28 publications

(38 reference statements)

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“…In addition to neural networks, the most basic form of ML algorithm, the global Jacobian can also be obtained using advanced forms of ML algorithms such as linear function approximators, [ 272 ] constrained extreme learning machines, [ 273 ] and ensembles of neural networks. [ 274 ] The mapping of the virtual global Jacobian can be obtained by performing gradient descent over the actuator configuration with the desired position as the target without deducting any models in robotics.…”

Section: Control Implementationmentioning

confidence: 99%

Control Strategies for Soft Robot Systems

Wang

Chortos

2022

Advanced Intelligent Systems

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Soft robots have recently attracted increased attention because their characteristics of low‐cost fabrication, durability, and deformability make them uniquely suited for applications in bio‐integrated systems. Being fundamentally different from traditional rigid robots, soft robots exhibit properties of infinite degrees of freedom (DOF) and nonlinear materials properties that require innovations in control systems. With the rapid development of materials science, robotics, and artificial intelligence, the diversification of actuator mechanisms and algorithms has enabled a wide range of unique control strategies. This review summarizes the basics of actuator mechanisms and control strategies, including open‐loop control, closed‐loop control, and autonomous control, and discusses their implementation from diversified perspectives. Control strategies are evaluated based on their compatibility with materials sets, application goals, and implementation route. The emerging directions are forecasted from the perspectives of interfacing between controller and actuator, underactuated control strategies, and implementation of artificial intelligence (AI).

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Section: Control Implementationmentioning

confidence: 99%

Control Strategies for Soft Robot Systems

Wang

Chortos

2022

Advanced Intelligent Systems

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“…While the challenge of controlling the segments lengths by supplying the air chambers with appropriate pressures has been addressed in previous work [ 23 , 26 ], this paper focuses on the kinematic control of the end effector. The autonomous exploration of a direct inverse model for controlling the end effector has been accomplished in [ 7 ] where the main emphasis was to start model learning from very limited prior knowledge about the plant.…”

Section: Hybrid Forward Kinematics For a Soft Robotmentioning

confidence: 99%

Hybrid Analytical and Data-Driven Modeling for Feed-Forward Robot Control †

Reinhart

Shareef

Steil

2017

Sensors

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Feed-forward model-based control relies on models of the controlled plant, e.g., in robotics on accurate knowledge of manipulator kinematics or dynamics. However, mechanical and analytical models do not capture all aspects of a plant's intrinsic properties and there remain unmodeled dynamics due to varying parameters, unmodeled friction or soft materials. In this context, machine learning is an alternative suitable technique to extract non-linear plant models from data. However, fully data-based models suffer from inaccuracies as well and are inefficient if they include learning of well known analytical models. This paper thus argues that feed-forward control based on hybrid models comprising an analytical model and a learned error model can significantly improve modeling accuracy. Hybrid modeling here serves the purpose to combine the best of the two modeling worlds. The hybrid modeling methodology is described and the approach is demonstrated for two typical problems in robotics, i.e., inverse kinematics control and computed torque control. The former is performed for a redundant soft robot and the latter for a rigid industrial robot with redundant degrees of freedom, where a complete analytical model is not available for any of the platforms.

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“…The trout fin was used as the gripper in the front end. Its structure was simple, reliable and easy to use (Rolf and Steil 2013;Rolf et al 2015;Mahl et al 2014). Inspired by the tentacles of octopus, Pi et al reported a flexible three-finger gripper for grasping apples (Pi et al 2021).…”

Section: Introductionmentioning

confidence: 99%

A novel bionic gripper based on the front tarsi of scutigers

Cong

Shi

Xiong

et al. 2022

Trans. Can. Soc. Mech. Eng.

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A novel bionic gripper with bristles is designed based on the biological structure of the front tarsi of scutigers, and its simulation model is established. It was verified that the proposed bionic gripper not only achieved the expected gripping action but also completed the pinching motion with better grasping performance. Related parameters, such as displacement, velocity, acceleration, force, and torque, were also analyzed. Friction contact finite element analysis of the bionic gripper with bristle structure was performed using ABAQUS and compared with the control group. The finite element analysis results showed that the bristles could effectively improve the capture efficiency of the bionic gripper. The diameter and density of the bristles in the bionic gripper were optimized, and their influence on the gripping efficiency was analyzed. This study provides a reference for the structural design of bionic grippers and the practical application of bionic non-smooth surfaces.

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A multi-level control architecture for the bionic handling assistant

Cited by 20 publications

References 28 publications

Control Strategies for Soft Robot Systems

Control Strategies for Soft Robot Systems

Hybrid Analytical and Data-Driven Modeling for Feed-Forward Robot Control †

A novel bionic gripper based on the front tarsi of scutigers

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