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36 results on '"Petrič, Tadej"'

6. Leveraging Environmental Contact and Sensor Feedback for Precision in Robotic Manipulation.

Author

Šifrer, Jan and Petrič, Tadej

Abstract

This paper investigates methods that leverage physical contact between a robot's structure and its environment to enhance task performance, with a primary emphasis on improving precision. Two main approaches are examined: solving the inverse kinematics problem and employing quadratic programming, which offers computational efficiency by utilizing forward kinematics. Additionally, geometrical methods are explored to simplify robot assembly and reduce the complexity of control calculations. These approaches are implemented on a physical robotic platform and evaluated in real-time applications to assess their effectiveness. Through experimental evaluation, this study aims to understand how environmental contact can be utilized to enhance performance across various conditions, offering valuable insights for practical applications in robotics. [ABSTRACT FROM AUTHOR]

Published
2024
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7. End-effector Cartesian stiffness shaping - sequential least squares programming approach

Author

Knežević Nikola, Lukić Branko, Jovanović Kosta, Žlajpah Leon, and Petrič Tadej

Subjects
cartesian stiffness control, robot redundancy, physical human-robot interaction, sequential last squares programming., Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Control of robot end-effector (EE) Cartesian stiffness matrix (or the whole mechanical impedance) is still a challenging open issue in physical humanrobot interaction (pHRI). This paper presents an optimization approach for shaping the robot EE Cartesian stiffness. This research targets collaborative robots with intrinsic compliance - serial elastic actuators (SEAs). Although robots with SEAs have constant joint stiffness, task redundancy (null-space) for a specific task could be used for robot reconfiguration and shaping the stiffness matrix while still keeping the EE position unchanged. The method proposed in this paper to investigate null-space reconfiguration's influence on Cartesian robot stiffness is based on the Sequential Least Squares Programming (SLSQP) algorithm, which presents an expansion of the quadratic programming algorithm for nonlinear functions with constraints. The method is tested in simulations for 4 DOF planar robot. Results are presented for control of the EE Cartesian stiffness initially along one axis, and then control of stiffness along both planar axis - shaping the main diagonal of the EE stiffness matrix.

Published
2021
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15. Stable Heteroclinic Channel Networks for Physical Human–Humanoid Robot Collaboration.

Author

Brecelj, Tilen and Petrič, Tadej

Subjects
*HUMANOID robots, *HUMAN-robot interaction, *ROBOTS, *ROBOT motion, *ROBOT control systems, *INDUSTRIAL robots
Abstract

Human–robot collaboration is one of the most challenging fields in robotics, as robots must understand human intentions and suitably cooperate with them in the given circumstances. But although this is one of the most investigated research areas in robotics, it is still in its infancy. In this paper, human–robot collaboration is addressed by applying a phase state system, guided by stable heteroclinic channel networks, to a humanoid robot. The base mathematical model is first defined and illustrated on a simple three-state system. Further on, an eight-state system is applied to a humanoid robot to guide it and make it perform different movements according to the forces exerted on its grippers. The movements presented in this paper are squatting, standing up, and walking forwards and backward, while the motion velocity depends on the magnitude of the applied forces. The method presented in this paper proves to be a suitable way of controlling robots by means of physical human-robot interaction. As the phase state system and the robot movements can both be further extended to make the robot execute many other tasks, the proposed method seems to provide a promising way for further investigation and realization of physical human–robot interaction. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Potential Field Control of a Redundant Nonholonomic Mobile Manipulator with Corridor-Constrained Base Motion.

Author

Baumgartner, Jakob, Petrič, Tadej, and Klančar, Gregor

Subjects
ROBOT kinematics, MOBILE operating systems, CONTINUOUS functions, NONHOLONOMIC dynamical systems, MOBILE hospitals
Abstract

This work proposes a solution for redundant nonholonomic mobile manipulator control with corridor constraints on base motion. The proposed control strategy applies an artificial potential field for base navigation to achieve joint control with desired trajectory tracking of the end effector. The overall kinematic model is created by describing the nonholonomic mobile platform and the kinematics of the manipulator. The objective function used consists of a primary control task that optimizes the joint variables to achieve the desired pose or trajectory of the end effector and a secondary control task that optimizes the joint variables for the base to support the arm and stay within the corridor. As a last priority, an additional optimization is introduced to optimize the maneuverability index. The proposed baseline navigation has global convergence without local minima and is computationally efficient. This is achieved by an optimal grid-based search on a coarse discrete grid and a bilinear interpolation to obtain a continuous potential function and its gradient. The performance of the proposed control algorithm is illustrated by several simulations of a mobile manipulator model derived for a Pal Tiago mobile base and an Emiko Franka Panda robotic manipulator. [ABSTRACT FROM AUTHOR]

Published
2023
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17. Online Cartesian Compliance Shaping of Redundant Robots in Assembly Tasks.

Author

Lukić, Branko, Jovanović, Kosta, Žlajpah, Leon, and Petrič, Tadej

Subjects
INDUSTRIAL robots, MATHEMATICAL optimization, ROBOTS
Abstract

This paper presents a universal approach to shaping the mechanical properties of the interaction between a collaborative robot and its environment through an end-effector Cartesian compliance shaping. More specifically, the focus is on the class of kinematically redundant robots, for which a novel redundancy reconfiguration scheme for online optimization of the Cartesian compliance of the end-effector is presented. The null-space reconfiguration aims to enable the more efficient and versatile use of collaborative robots, including robots with passive compliant joints. The proposed approach is model-based and gradient-based to enable real-time computation and reconfiguration of the robot for Cartesian compliance while ensuring accurate position tracking. The optimization algorithm combines two coordinate frames: the global (world) coordinate frame commonly used for end-effector trajectory tracking; and the coordinate frame fixed to the end-effector in which optimization is computed. Another attractive feature of the approach is the bound on the magnitude of the interaction force in contact tasks. The results are validated on a torque-controlled 7-DOF KUKA LWR robot emulating joint compliance in a quasi-static experiment (the robot exerts a force on an external object) and a peg-in-hole experiment emulating an assembly task. [ABSTRACT FROM AUTHOR]

Published
2023
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19. Zero Moment Line—Universal Stability Parameter for Multi-Contact Systems in Three Dimensions.

Author

Brecelj, Tilen and Petrič, Tadej

Subjects
*CENTER of mass, *POLYGONS
Abstract

The widely used stability parameter, the zero moment point (ZMP), which is usually defined on the ground, is redefined, in this paper, in two different ways to acquire a more general form that allows its application to systems that are not supported only on the ground, and therefore, their support polygon does not extend only on the floor. This way it allows to determine the stability of humanoid and other floating-based robots that are interacting with the environment at arbitrary heights. In the first redefinition, the ZMP is represented as a line containing all possible ZMPs, called the zero moment line (ZML), while in the second redefinition, the ZMP is represented as the ZMP angle, i.e., the angle between the ZML and the vertical line, passing through the center of mass (COM) of the investigated system. The first redefinition is useful in situations when the external forces and their acting locations are known, while the second redefinition can be applied in situations when the COM of the system under study is known and can be tracked. The first redefinition of the ZMP is also applied to two different measurements performed with two force plates, two force sensors, and the Optitrack system. In the first measurement, a subject stands up from a bench and sits down while being pulled by its hands, while in the second measurement, two subjects stand still, hold on to two double handles, and lean backward. In both cases, the stability of the subjects involved in the measurements is investigated and discussed. [ABSTRACT FROM AUTHOR]

Published
2022
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20. Leader–Follower Role Allocation for Physical Collaboration in Human Dyads.

Author

Kropivšek Leskovar, Rebeka, Čamernik, Jernej, and Petrič, Tadej

Subjects
DYADS, ROBOT control systems, TASK performance, MEDICAL rehabilitation, ROBOT programming, ORAL communication, HUMAN-robot interaction
Abstract

Featured Application: Findings presented in this study can be seen as beneficial in better understanding the collaborative dynamics that present themselves in human collaboration as well as in the further development of novel robot control models. Implementing the leader–follower role allocation studied in this paper into a robot control model allows the robot partner to assume both the role of a follower and that of a leader when necessary. This can be especially useful in social robotics for effective physical rehabilitation. In this regard the results could in the future be incorporated in the design of a human–robot collaborative system that is able to support the human user in more effective skill learning by adjusting its influence on the task performance. People often find themselves in situations where collaboration with others is necessary to accomplish a particular task. In such cases, a leader–follower relationship is established to coordinate a plan to achieve a common goal. This is usually accomplished through verbal communication. However, what happens when verbal communication is not possible? In this study, we observe the dynamics of a leader–follower relationship in human dyads during collaborative tasks where there is no verbal communication between partners. Using two robotic arms, we designed a collaborative experimental task in which subjects perform the task individually or coupled together through a virtual model. The results show that human partners fall into the leader–follower dynamics even when they cannot communicate verbally. We demonstrate this in two steps. First, we study how each subject in a collaboration influences task performance, and second, we evaluate whether both partners influence it equally or not using our proposed sorting method to objectively identify a leader. We also study the leader–follower dynamics by analysing the task performance of partners during their individual sessions to predict the role distribution in a dyad. Based on the results of our prediction method, we conclude that the higher-performing individual performance will assume the role of a leader in collaboration. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Phase-Synchronized Learning of Periodic Compliant Movement Primitives (P-CMPs).

Author

Petrič, Tadej

Subjects
ADAPTIVE control systems, HUMAN-robot interaction, TORQUE, PANDAS
Abstract

Autonomous trajectory and torque profile synthesis through modulation and generalization require a database of motion with accompanying dynamics, which is typically difficult and time-consuming to obtain. Inspired by adaptive control strategies, this paper presents a novel method for learning and synthesizing Periodic Compliant Movement Primitives (P-CMPs). P-CMPs combine periodic trajectories encoded as Periodic Dynamic Movement Primitives (P-DMPs) with accompanying task-specific Periodic Torque Primitives (P-TPs). The state-of-the-art approach requires to learn TPs for each variation of the task, e.g., modulation of frequency. Comparatively, in this paper, we propose a novel P-TPs framework, which is both frequency and phase-dependent. Thereby, the executed P-CMPs can be easily modulated, and consequently, the learning rate can be improved. Moreover, both the kinematic and the dynamic profiles are parameterized, thus enabling the representation of skills using corresponding parameters. The proposed framework was evaluated on two robot systems, i.e., Kuka LWR-4 and Franka Emika Panda. The evaluation of the proposed approach on a Kuka LWR-4 robot performing a swinging motion and on Franka Emika Panda performing an exercise for elbow rehabilitation shows fast P-CTPs acquisition and accurate and compliant motion in real-world scenarios. [ABSTRACT FROM AUTHOR]

Published
2020
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22. Unified Virtual Guides Framework for Path Tracking Tasks.

Author

Žlajpah, Leon and Petrič, Tadej

Subjects
*HUMAN-robot interaction, *TASKS, *ALGORITHMS, *OBJECT tracking (Computer vision), *ROBOTICS
Abstract

SUMMARY: In this paper, we propose a novel unified framework for virtual guides. The human–robot interaction is based on a virtual robot, which is controlled by the admittance control. The unified framework combines virtual guides, control of the dynamic behavior, and path tracking. Different virtual guides and active constraints can be realized by using dead-zones in the position part of the admittance controller. The proposed algorithm can act in a changing task space and allows selection of the tasks-space and redundant degrees-of-freedom during the task execution. The admittance control algorithm can be implemented either on a velocity or on acceleration level. The proposed framework has been validated by an experiment on a KUKA LWR robot performing the Buzz-Wire task. [ABSTRACT FROM AUTHOR]

Published
2020
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23. Assistive Arm-Exoskeleton Control Based on Human Muscular Manipulability.

Author

Petrič, Tadej, Peternel, Luka, Morimoto, Jun, and Babič, Jan

Subjects
ROBOTIC exoskeletons, HUMAN-robot interaction
Abstract

This paper introduces a novel control framework for an arm exoskeleton that takes into account force of the human arm. In contrast to the conventional exoskeleton controllers where the assistance is provided without considering the human arm biomechanical force manipulability properties, we propose a control approach based on the arm muscular manipulability. The proposed control framework essentially reshapes the anisotropic force manipulability into the endpoint force manipulability that is invariant with respect to the direction in the entire workspace of the arm. This allows users of the exoskeleton to perform tasks effectively in the whole range of the workspace, even in areas that are normally unsuitable due to the low force manipulability of the human arm. We evaluated the proposed control framework with real robot experiments where subjects wearing an arm exoskeleton were asked to move a weight between several locations. The results show that the proposed control framework does not affect the normal movement behavior of the users while effectively reduces user effort in the area of low manipulability. Particularly, the proposed approach augments the human arm force manipulability to execute tasks equally well in the entire workspace of the arm. [ABSTRACT FROM AUTHOR]

Published
2019
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24. Robotic assembly solution by human-in-the-loop teaching method based on real-time stiffness modulation.

Author

Peternel, Luka, Petrič, Tadej, and Babič, Jan

Subjects
REMOTE control, SENSORIMOTOR integration, ROBOT control systems, HUMAN-robot interaction, MACHINE theory
Abstract

We propose a novel human-in-the-loop approach for teaching robots how to solve assembly tasks in unpredictable and unstructured environments. In the proposed method the human sensorimotor system is integrated into the robot control loop though a teleoperation setup. The approach combines a 3-DoF end-effector force feedback with an interface for modulation of the robot end-effector stiffness. When operating in unpredictable and unstructured environments, modulation of limb impedance is essential in terms of successful task execution, stability and safety. We developed a novel hand-held stiffness control interface that is controlled by the motion of the human finger. A teaching approach was then used to achieve autonomous robot operation. In the experiments, we analysed and solved two part-assembly tasks: sliding a bolt fitting inside a groove and driving a self-tapping screw into a material of unknown properties. We experimentally compared the proposed method to complementary robot learning methods and analysed the potential benefits of direct stiffness modulation in the force-feedback teleoperation. [ABSTRACT FROM AUTHOR]

Published
2018
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25. Hammering Does Not Fit Fitts' Law.

Author

Petrič, Tadej, Simpson, Cole S., Ude, Aleš, and Ijspeert, Auke J.

Subjects
HUMAN mechanics, MOVEMENT disorders, HUMAN kinematics, ROBUST control, AUTOMATIC control systems
Abstract

While movement is essential to human wellbeing, we are still unable to reproduce the deftness and robustness of human movement in automatons or completely restore function to individuals with many types of motor impairment. To better understand how the human nervous system plans and controls movements, neuromechanists employ simple tasks such as upper extremity reaches and isometric force tasks. However, these simple tasks rarely consider impacts and may not capture aspects of motor control that arise from real-world complexity. Here we compared existing models of motor control with the results of a periodic targeted impact task extended from Bernstein's seminal work: hammering a nail into wood. We recorded impact forces and kinematics from 10 subjects hammering at different frequencies and with hammers with different physical properties (mass and face area). We found few statistical differences in most measures between different types of hammer, demonstrating human robustness to minor changes in dynamics. Because human motor control is thought to obey optimality principles, we also developed a feedforward optimal simulation with a neuromechanically inspired cost function that reproduces the experimental data. However, Fitts' Law, which relates movement time to distance traveled and target size, did not match our experimental data. We therefore propose a new model in which the distance moved is a logarithmic function of the time to move that yields better results (R² 0.99 compared to R² 0.88). These results support the argument that humans control movement in an optimal way, but suggest that Fitts' Law may not generalize to periodic impact tasks. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Editorial: Human-Like Advances in Robotics: Motion, Actuation, Sensing, Cognition and Control.

Author

Jovanović, Kosta, Petrič, Tadej, Tsuji, Toshiaki, and Oddo, Calogero Maria

Subjects
ROBOTICS, ARTIFICIAL hands, COGNITION, HUMAN behavior, ARTIFICIAL muscles, ENGINEERING design, HUMAN-robot interaction
Abstract

Keywords: motor control; human-like perception and cognition; human-like sensing and actuation; musculoskeletal robots; digitalization of human However, one of the robotics markets with greatest growth expectations - home and service robotics (Litzenberger, [4]), apart for specialized devices such as cleaning robots or cooking assistants, is still struggling to find and adopt a robot which could respond to most challenges and demands in our homes. It aims at giving insights in the latest related scientific investigations and at presenting some samples of the current level of developed technologies importing those concepts in robotics with a I science for robotics and robotics for science i methodology (Yang et al., [9]). [Extracted from the article]

Published
2019
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27. Adaptive Control of Exoskeleton Robots for Periodic Assistive Behaviours Based on EMG Feedback Minimisation.

Author

Peternel, Luka, Noda, Tomoyuki, Petrič, Tadej, Ude, Aleš, Morimoto, Jun, and Babič, Jan

Subjects
ADAPTIVE control systems, ELECTROMYOGRAPHY, ROBOTIC exoskeletons, MUSCLE physiology, CLASSICAL mechanics
Abstract

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. [ABSTRACT FROM AUTHOR]

Published
2016
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28. Estimation of Alpine Skier Posture Using Machine Learning Techniques.

Author

Nemec, Bojan, Petrič, Tadej, Babič, Jan, and Supej, Matej

Subjects
*MACHINE learning, *DATA mining, *MENTAL arithmetic, *MENTAL calculators, *LEARNING ability, *SKIERS
Abstract

High precision Global Navigation Satellite System (GNSS) measurements are becoming more and more popular in alpine skiing due to the relatively undemanding setup and excellent performance. However, GNSS provides only single-point measurements that are defined with the antenna placed typically behind the skier's neck. A key issue is how to estimate other more relevant parameters of the skier's body, like the center of mass (COM) and ski trajectories. Previously, these parameters were estimated by modeling the skier's body with an inverted-pendulum model that oversimplified the skier's body. In this study, we propose two machine learning methods that overcome this shortcoming and estimate COM and skis trajectories based on a more faithful approximation of the skier's body with nine degrees-of-freedom. The first method utilizes a well-established approach of artificial neural networks, while the second method is based on a state-of-the-art statistical generalization method. Both methods were evaluated using the reference measurements obtained on a typical giant slalom course and compared with the inverted-pendulum method. Our results outperform the results of commonly used inverted-pendulum methods and demonstrate the applicability of machine learning techniques in biomechanical measurements of alpine skiing. [ABSTRACT FROM AUTHOR]

Published
2014
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29. Effects of supportive hand contact on reactive postural control during support perturbations.

Author

Babič, Jan, Petrič, Tadej, Peternel, Luka, and Šarabon, Nejc

Subjects
*HAND, *CONTACT mechanics, *POSTURE, *PERTURBATION theory, *TRANSLATIONAL motion, *FORCE & energy
Abstract

There are many everyday situations in which a supportive hand contact is required for an individual to counteract various postural perturbations. By emulating situations when balance of an individual is challenged, we examined functional role of supportive hand contact at different locations where balance of an individual was perturbed by translational perturbations of the support surface. We examined the effects of handle location, perturbation direction and perturbation intensity on the postural control and the forces generated in the handle. There were significantly larger centre-of-pressure (CoP) displacements for perturbations in posterior direction than for perturbations in anterior direction. Besides, the perturbation intensity significantly affected the peak CoP displacement in both perturbation directions. However, the position of the handle had no effects on the peak CoP displacement. On the contrary, there were significant effects of perturbation direction, perturbation intensity and handle position on the maximal force in the handle. The effect of the handle position was significant for the perturbations in posterior direction where the lowest maximal forces were recorded in the handle located at the shoulder height. They were comparable to the forces in the handle at eye height and significantly lower than the forces in the handle located either lower or further away from the shoulder. In summary, our results indicate that although the location of a supportive hand contact has no effect on the peak CoP displacement of healthy individuals, it affects the forces that an individual needs to exert on the handle in order to counteract support perturbations. [ABSTRACT FROM AUTHOR]

Published
2014
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30. NAVIGATION METHODS FOR THE SKIING ROBOT.

Author

PETRIČ, TADEJ, PETERNEL, LUKA, GAMS, ANDREJ, NEMEC, BOJAN, and ŽLAJPAH, LEON

Subjects
SKIING, ROBOTICS research, NAVIGATION equipment, ROBOTIC path planning, MOBILE robots
Abstract

In this paper, we propose and evaluate methods for the local navigation using only visual perception for the skiing robot. Our skiing robot, capable of skiing using the carving technique, has no direct control on the velocity of skiing as it cannot break or accelerate, therefore well known navigation methods for nonholonomic mobile robots cannot be directly applied. We consider the following methods: an intuitive method of aiming at the closest gates, a human obstacle avoidance movement model, neural networks learning from a set of human demonstrations, and a global method that uses a predefined, spline-encoded path. The navigation performance of the robot on unknown ski courses is evaluated using two criteria: successful completion of the course and the time required to complete the course. Simulation results show the applicability and drawbacks of presented methods. Finally, the method using the neural networks was applied on a real-world skiing robot and we tested navigating a slalom course on both roller blades and skies. [ABSTRACT FROM AUTHOR]

Published
2013
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31. Control approaches for robotic knee exoskeleton and their effects on human motion.

Author

Petrič, Tadej, Gams, Andrej, Debevec, Tadej, Žlajpah, Leon, and Babič, Jan

Subjects
*ROBOTICS research, *ROBOTIC exoskeletons, *HUMAN mechanics, *SYNCHRONIZATION, *NONLINEAR oscillators
Abstract

In this paper we compare three noninvasive control methods for a robotic knee exoskeleton and asses their kinematic influences on the repetitive squatting motions of able-bodied human subjects. The motion of the subjects wearing the knee exoskeleton was also compared to the motion of the subjects performing the same task without using the assistance of the knee exoskeleton. We chose the squatting motion because it approximates common movements with high metabolic cost, such as standing up from a chair and ascending or descending the stairs. Beside the two classical robotic control approaches, i.e. the position control and the gravity compensation, we propose a method that is based on a single adaptive frequency oscillator combined with an adaptive Fourier series in a feedback loop. The method can extract frequency and phase of an arbitrary periodic signal in real-time. This method is particularly appropriate for controlling novel robotic assisting devices since it does not require complex signal sensing or user calibration. The results show that the total knee torque was increased while using the exoskeleton device compared to the squatting without the assistance of the exoskeleton device. In effect, there were significant kinematic adaptations observed when the exoskleton device assisted the motion of the subjects. However, no significant kinematic differences were found between different control methods. We conclude that an assistive device can augment the abilities of the able-bodied humans in the targeted joints (i.e. the joints provided with additional mechanical power) but, on the other hand, significantly alters whole body kinematics. [ABSTRACT FROM AUTHOR]

Published
2013
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32. On-line frequency adaptation and movement imitation for rhythmic robotic tasks.

Author

Petrič, Tadej, Gams, Andrej, Ijspeert, Auke Jan, and Žlajpah, Leon

Subjects
*ROBOTICS, *SIGNAL processing, *NONLINEAR systems, *COMPUTER algorithms, *FOURIER series, *ROBOT control systems, *FEEDBACK control systems
Abstract

In this paper we present a novel method to obtain the basic frequency of an unknown periodic signal with an arbitrary waveform, which can work online with no additional signal processing or logical operations. The method originates from non-linear dynamical systems for frequency extraction, which are based on adaptive frequency oscillators in a feedback loop. In previous work, we had developed a method that could extract separate frequency components by using several adaptive frequency oscillators in a loop, but that method required a logical algorithm to identify the basic frequency. The novel method presented here uses a Fourier series representation in the feedback loop combined with a single oscillator. In this way it can extract the frequency and the phase of an unknown periodic signal in real time and without any additional signal processing or preprocessing. The method determines the Fourier series coefficients and can be used for dynamic Fourier series implementation. The proposed method can be used for the control of rhythmic robotic tasks, where only the extraction of the basic frequency is crucial. For demonstration several highly non-linear and dynamic periodic robotic tasks are shown, including also a task where an electromyography (EMG) signal is used in a feedback loop. [ABSTRACT FROM PUBLISHER]

Published
2011
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33. Modelling of the robotic Powerball®: a nonholonomic, underactuated and variable structure-type system.

Author

Petrič, Tadej, Curk, Boris, Cafuta, Peter, and Žlajpah, Leon

Subjects
*MATHEMATICAL models, *NONHOLONOMIC dynamical systems, *MATHEMATICAL variables, *GYROSCOPES, *DEGREES of freedom, *ROTOR dynamics, *ROBOTICS
Abstract

The Powerball® is the commercial name for a gyroscopic device that is marketed as a wrist exerciser. The device has a rotor with two underactuated degrees of freedom, which can be actuated by the appropriate motion of human or robot wrist axes. After the initial spin, applying the appropriate motion and torques to the housing leads to a spin-up of the rotor. Finding these torques intuitively is an easy task for human operators, but a complex task for a technical consideration, for example, in robotics. This article's main contribution is a novel dynamic model that considers friction effects. The presented model includes all three working principles of the device: free rotor mode and both modes of rotor rolling in the housing. The work introduces models with one and two degrees of freedom actuation, both of which are suitable for laboratory control experiments. An estimation of the friction is discussed, and both the simulation and the experimental results are presented to evaluate the models. [ABSTRACT FROM AUTHOR]

Published
2010
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34. Erratum: Jamšek et al. Gaussian Mixture Models for Control of Quasi-Passive Spinal Exoskeletons. Sensors 2020, 20 , 2705.

Author

Jamšek, Marko, Petrič, Tadej, and Babič, Jan

Subjects
*GAUSSIAN mixture models, *DETECTORS, *ROBOTIC exoskeletons
Abstract

The variable used for the superscript in the denominator of the equation, denoting the dimensionality of the model, was incorrectly written as K and thus conflicted with the variable denoting the number of Gaussian mixtures. Gaussian Mixture Models for Control of Quasi-Passive Spinal Exoskeletons. A correction has therefore been made to Section 2.3, Equation (4). [Extracted from the article]

Published
2021
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35. Gaussian Mixture Models for Control of Quasi-Passive Spinal Exoskeletons.

Author

Jamšek, Marko, Petrič, Tadej, and Babič, Jan

Subjects
*RESEARCH & development, *GAUSSIAN mixture models, *ROBOTIC exoskeletons
Abstract

Research and development of active and passive exoskeletons for preventing work related injuries has steadily increased in the last decade. Recently, new types of quasi-passive designs have been emerging. These exoskeletons use passive viscoelastic elements, such as springs and dampers, to provide support to the user, while using small actuators only to change the level of support or to disengage the passive elements. Control of such devices is still largely unexplored, especially the algorithms that predict the movement of the user, to take maximum advantage of the passive viscoelastic elements. To address this issue, we developed a new control scheme consisting of Gaussian mixture models (GMM) in combination with a state machine controller to identify and classify the movement of the user as early as possible and thus provide a timely control output for the quasi-passive spinal exoskeleton. In a leave-one-out cross-validation procedure, the overall accuracy for providing support to the user was 86. 72 ± 0. 86 % (mean ± s.d.) with a sensitivity and specificity of 97. 46 ± 2. 09 % and 83. 15 ± 0. 85 % respectively. The results of this study indicate that our approach is a promising tool for the control of quasi-passive spinal exoskeletons. [ABSTRACT FROM AUTHOR]

Published
2020
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