Luka Peternel scite author profile

In this paper we propose an exoskeleton control method for adaptive learning of assistive joint torque profiles in periodic tasks. We use human muscle activity as feedback to adapt the assistive joint torque behaviour in a way that the muscle activity is minimised. The user can then relax while the exoskeleton takes over the task execution. If the task is altered and the existing assistive behaviour becomes inadequate, the exoskeleton gradually adapts to the new task execution so that the increased muscle activity caused by the new desired task can be reduced. The advantage of the proposed method is that it does not require biomechanical or dynamical models. Our proposed learning system uses Dynamical Movement Primitives (DMPs) as a trajectory generator and parameters of DMPs are modulated using Locally Weighted Regression. Then, the learning system is combined with adaptive oscillators that determine the phase and frequency of motion according to measured Electromyography (EMG) signals. We tested the method with real robot experiments where subjects wearing an elbow exoskeleton had to move an object of an unknown mass according to a predefined reference motion. We further evaluated the proposed approach on a whole-arm exoskeleton to show that it is able to adaptively derive assistive torques even for multiple-joint motion.

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Robotic assembly solution by human-in-the-loop teaching method based on real-time stiffness modulation

Peternel

Petrič

Babič

2017

Auton Robot

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Teaching robots to cooperate with humans in dynamic manipulation tasks based on multi-modal human-in-the-loop approach

et al. 2013

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Due to copyright restrictions, the access to the full text of this article is only available via subscription.We propose an approach to efﬁciently teach robots how to perform dynamic anipulation tasks in cooperation with a human partner. The approach utilises human sensorimotor learning ability where the human tutor controls the robot through a multi-modal interface to make it perform the desired task. During the tutoring, the robot simultaneously learns the action policy of the tutor and through time gains full autonomy. We demonstrate our approach by an experiment where we taught a robot how to perform a wood sawing task with a human partner using a two-person crosscut saw. The challenge of this experiment is that it requires precise coordination of the robot’s motion and complianceaccording to the partner’s actions. To transfer the sawing skill from the tutor to the robot we used Locally Weighted Regression for trajectory generalisation, and adaptive oscillators for adaptation of the robot to the partner’s motion.Slovenian Research Agency ; Slovenian Ministry of Higher Education, Science and Technology

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A selective muscle fatigue management approach to ergonomic human-robot co-manipulation

Peternel

Fang

Tsagarakis

et al. 2019

Robotics and Computer-Integrated Manufacturing

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Towards ergonomic control of human-robot co-manipulation and handover

Peternel

Kim

Babič

et al. 2017

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In this paper, we propose a novel method for the control of human-robot co-manipulation that takes into account the ergonomic requirements for the human co-worker. The robot uses a whole-body model of the human to optimise for the position of the co-manipulation task in the workspace. In this configuration, the overloading joint torques, i.e. the effects of an external load in human body joints, are minimised. In addition, the optimisation process includes several constraints, such as human arm manipulability properties, to ensure that the human has a good manipulation capacity in the given configuration. The main advantage of this approach is that the robot can potentially help to reduce the work-related strain and increase the productivity of the human co-worker. We validated the proposed method with experiments in two co-manipulation tasks: human using a device to polish an object that is delivered by the robot and a human-robot object handover.

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A Human–Robot Co-Manipulation Approach Based on Human Sensorimotor Information

Peternel

Tsagarakis

Ajoudani

2017

IEEE Trans. Neural Syst. Rehabil. Eng.

106

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This paper aims to improve the interaction and coordination between the human and the robot in cooperative execution of complex, powerful, and dynamic tasks. We propose a novel approach that integrates online information about the human motor function and manipulability properties into the hybrid controller of the assistive robot. Through this human-in-the-loop framework, the robot can adapt to the human motor behavior and provide the appropriate assistive response in different phases of the cooperative task. We experimentally evaluate the proposed approach in two human-robot co-manipulation tasks that require specific complementary behavior from the two agents. Results suggest that the proposed technique, which relies on a minimum degree of task-level pre-programming, can achieve an enhanced physical human-robot interaction performance and deliver appropriate level of assistance to the human operator.

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Luka Peternel

Anticipatory Robot Assistance for the Prevention of Human Static Joint Overloading in Human–Robot Collaboration

Robot adaptation to human physical fatigue in human–robot co-manipulation

Adaptive Control of Exoskeleton Robots for Periodic Assistive Behaviours Based on EMG Feedback Minimisation

Robotic assembly solution by human-in-the-loop teaching method based on real-time stiffness modulation

Teaching robots to cooperate with humans in dynamic manipulation tasks based on multi-modal human-in-the-loop approach

A selective muscle fatigue management approach to ergonomic human-robot co-manipulation

Towards ergonomic control of human-robot co-manipulation and handover

A Human–Robot Co-Manipulation Approach Based on Human Sensorimotor Information

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