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A Hybrid Physical and Data-drivApproach to Motion Prediction and Control in Human-Robot Collaboration

2022-06-14 Technology & Engineering
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Release : 2022-06-14
Genre : Technology & Engineering
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Book Rating : 84X/5 ( reviews)

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Book Synopsis A Hybrid Physical and Data-drivApproach to Motion Prediction and Control in Human-Robot Collaboration by : Min Wu

Download or read book A Hybrid Physical and Data-drivApproach to Motion Prediction and Control in Human-Robot Collaboration written by Min Wu . This book was released on 2022-06-14. Available in PDF, EPUB and Kindle. Book excerpt: In recent years, researchers have achieved great success in guaranteeing safety in human-robot interaction, yielding a new generation of robots that can work with humans in close proximity, known as collaborative robots (cobots). However, due to the lack of ability to understand and coordinate with their human partners, the ``co'' in most cobots still refers to ``coexistence'' rather than ``collaboration''. This thesis aims to develop an adaptive learning and control framework with a novel physical and data-driven approach towards a real collaborative robot. The first part focuses on online human motion prediction. A comprehensive study on various motion prediction techniques is presented, including their scope of application, accuracy in different time scales, and implementation complexity. Based on this study, a hybrid approach that combines physically well-understood models with data-driven learning techniques is proposed and validated through a motion data set. The second part addresses interaction control in human-robot collaboration. An adaptive impedance control scheme with human reference estimation is presented. Reinforcement learning is used to find optimal control parameters to minimize a task-orient cost function without fully knowing the system dynamic. The proposed framework is experimentally validated through two benchmark applications for human-robot collaboration: object handover and cooperative object handling. Results show that the robot can provide reliable online human motion prediction, react early to human motion variation, make proactive contributions to physical collaborations, and behave compliantly in response to human forces.

Human-in-the-Loop Robot Control and Learning

2020-01-22
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Release : 2020-01-22
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Kind : eBook
Book Rating : 128/5 ( reviews)

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Book Synopsis Human-in-the-Loop Robot Control and Learning by : Luka Peternel

Download or read book Human-in-the-Loop Robot Control and Learning written by Luka Peternel. This book was released on 2020-01-22. Available in PDF, EPUB and Kindle. Book excerpt: In the past years there has been considerable effort to move robots from industrial environments to our daily lives where they can collaborate and interact with humans to improve our life quality. One of the key challenges in this direction is to make a suitable robot control system that can adapt to humans and interactively learn from humans to facilitate the efficient and safe co-existence of the two. The applications of such robotic systems include: service robotics and physical human-robot collaboration, assistive and rehabilitation robotics, semi-autonomous cars, etc. To achieve the goal of integrating robotic systems into these applications, several important research directions must be explored. One such direction is the study of skill transfer, where a human operator’s skilled executions are used to obtain an autonomous controller. Another important direction is shared control, where a robotic controller and humans control the same body, tool, mechanism, car, etc. Shared control, in turn invokes very rich research questions such as co-adaptation between the human and the robot, where the two agents can benefit from each other’s skills or must adapt to each other’s behavior to achieve effective cooperative task executions. The aim of this Research Topic is to help bridge the gap between the state-of-the-art and above-mentioned goals through novel multidisciplinary approaches in human-in-the-loop robot control and learning.

Advances in Computational Intelligence Systems

2019-08-29 Technology & Engineering
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Release : 2019-08-29
Genre : Technology & Engineering
Kind : eBook
Book Rating : 333/5 ( reviews)

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Book Synopsis Advances in Computational Intelligence Systems by : Zhaojie Ju

Download or read book Advances in Computational Intelligence Systems written by Zhaojie Ju. This book was released on 2019-08-29. Available in PDF, EPUB and Kindle. Book excerpt: This book highlights the latest research in computational intelligence and its applications. It covers both conventional and trending approaches in individual chapters on Fuzzy Systems, Intelligence in Robotics, Deep Learning Approaches, Optimization and Classification, Detection, Inference and Prediction, Hybrid Methods, Emerging Intelligence, Intelligent Health Care, and Engineering Data- and Model-Driven Applications. All chapters are based on peer-reviewed contributions presented at the 19th Annual UK Workshop on Computational Intelligence, held in Portsmouth, UK, on 4–6 September 2019. The book offers a valuable reference guide for readers with expertise in computational intelligence or who are seeking a comprehensive and timely review of the latest trends in computational intelligence. Special emphasis is placed on novel methods and their use in a wide range of application areas, updating both academics and professionals on the state of the art.

Robust Human Motion Prediction for Safe and Efficient Human-robot Interaction

2019
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Release : 2019
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Book Synopsis Robust Human Motion Prediction for Safe and Efficient Human-robot Interaction by : Przemyslaw Andrzej Lasota

Download or read book Robust Human Motion Prediction for Safe and Efficient Human-robot Interaction written by Przemyslaw Andrzej Lasota. This book was released on 2019. Available in PDF, EPUB and Kindle. Book excerpt: From robotic co-workers in factories to assistive robots in homes, human-robot interaction (HRI) has the potential to revolutionize a large array of domains by enabling robotic assistance where it was previously not possible. Introducing robots into human-occupied domains, however, requires strong consideration for the safety and efficiency of the interaction. One particularly effective method of supporting safe an efficient human-robot interaction is through the use of human motion prediction. By predicting where a person might reach or walk toward in the upcoming moments, a robot can adjust its motions to proactively resolve motion conflicts and avoid impeding the person's movements. Current approaches to human motion prediction, however, often lack the robustness required for real-world deployment. Many methods are designed for predicting specific types of tasks and motions, and do not necessarily generalize well to other domains. It is also possible that no single predictor is suitable for predicting motion in a given scenario, and that multiple predictors are needed. Due to these drawbacks, without expert knowledge in the field of human motion prediction, it is difficult to deploy prediction on real robotic systems. Another key limitation of current human motion prediction approaches lies in deficiencies in partial trajectory alignment. Alignment of partially executed motions to a representative trajectory for a motion is a key enabling technology for many goal-based prediction methods. Current approaches of partial trajectory alignment, however, do not provide satisfactory alignments for many real-world trajectories. Specifically, due to reliance on Euclidean distance metrics, overlapping trajectory regions and temporary stops lead to large alignment errors. In this thesis, I introduce two frameworks designed to improve the robustness of human motion prediction in order to facilitate its use for safe and efficient human-robot interaction. First, I introduce the Multiple-Predictor System (MPS), a datadriven approach that uses given task and motion data in order to synthesize a high performing predictor by automatically identifying informative prediction features and combining the strengths of complementary prediction methods. With the use of three distinct human motion datasets, I show that using the MPS leads to lower prediction error in a variety of HRI scenarios, and allows for accurate prediction for a range of time horizons. Second, in order to address the drawbacks of prior alignment techniques, I introduce the Bayesian ESTimator for Partial Trajectory Alignment (BEST-PTA). This Bayesian estimation framework uses a combination of optimization, supervised learning, and unsupervised learning components that are trained and synthesized based on a given set of example trajectories. Through an evaluation on three human motion datasets, I show that BEST-PTA reduces alignment error when compared to state-of-the-art baselines. Furthermore, I demonstrate that this improved alignment reduces human motion prediction error. Lastly, in order to assess the utility of the developed methods for improving safety and efficiency in HRI, I introduce an integrated framework combining prediction with robot planning in time. I describe an implementation and evaluation of this framework on a real physical system. Through this demonstration, I show that the developed approach leads to automatically derived adaptive robot behavior. I show that the developed framework leads to improvements in quantitative metrics of safety and efficiency with the use of a simulated evaluation.

Motion Control and Physical Human-robot Interaction of Kinematically Redundant Hybrid Parallel Robots and of a Macro-mini Robotic System

2022 Human-robot interaction
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Release : 2022
Genre : Human-robot interaction
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Book Synopsis Motion Control and Physical Human-robot Interaction of Kinematically Redundant Hybrid Parallel Robots and of a Macro-mini Robotic System by : Tan Sy Nguyen

Download or read book Motion Control and Physical Human-robot Interaction of Kinematically Redundant Hybrid Parallel Robots and of a Macro-mini Robotic System written by Tan Sy Nguyen. This book was released on 2022. Available in PDF, EPUB and Kindle. Book excerpt: This thesis investigates motion control methods and physical human robot interaction (pHRI) control strategies for two robotic systems, namely a kinematically redundant hybrid parallel robot (KRHPR) and a macro-mini system. The kinematic analysis, the dynamic modelling, as well as the control methods proposed in the thesis can be generalized for a class of robots with similar architecture. The thesis firstly introduces a novel kinematically redundant (6+3)-degree-of-freedom (DoF) spatial hybrid parallel robot with revolute actuators. The kinematic equations are developed and the singularities are examined. The translational and rotational workspace of the robot is then analysed. Also, a new mechanism is introduced to operate a gripper using the redundant DoFs. Thanks to the backdrivability of the robot, a controller - which can flexibly switch between two modes: position control and interaction control - is developed to demonstrate the potential use of this robot for physical interaction without using a force/torque sensor or joint torque sensors. Secondly, the motion control problem is investigated for a class of spatial kinematically redundant hybrid parallel robots. The kinematics are recalled and the dynamics are analysed. Based on this analysis, a proposed method referred to as hybrid control algorithm is proposed. It combines a simplified computed-torque controller, that operates in the joint space, with a Cartesian compensation, that operates in the task space of the robot. The stability of this approach is verified. Then, experiments are carried out on two example architectures. The results are examined and compared to those obtained with other methods to validate the effectiveness of the proposed approach. The motion control of a macro-mini system, which combines the hybrid parallel robot and a gantry system, is then investigated. The kinematics and the dynamics of the combined system are mainly analysed in the task space since it can be assumed that the position of the macro and the mini is stably determined by their own controllers. Motion control methods, namely mid-ranging control and Model Predictive Control, are generalized and adapted. Also, the combination of PI and the redundancy resolution is proposed. Each control method is implemented and used to perform the same trajectory. Afterwards, the control error is determined in order to compare the performance of the different methods. The physical human robot interaction is then studied for each of the robotic platforms mentioned above. On the KRHPR, a stiffness-damping control is specifically developed for pHRI applications. On the macro-mini system, the interaction method is also examined. The stability and the operational performance is analysed in detail. Experiments involving pHRI are then conducted and some demonstrations of potential applications are also presented. Finally, the conclusion summarizes the results obtained and discusses current limitations and potential future work.

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