Force Control of Series Elastic Actuator: Implications for Series Elastic Actuator Design

This paper presents a novel series-elastic actuator (SEA) design that uses a spiral torsion spring to achieve drivetrain compliance in a compact and efficient mechanism. The SEA utilizes electromechanical actuation and is designed for use in the experimental biped robot KURMET for investigating dynamic maneuvers. Similar to helical torsion springs, spiral torsion springs are particularly applicable for legged robots because they preserve the rotational motion inherent in electric motors and articulated leg joints, but with less drivetrain backlash and unwanted coil interaction under load than helical torsion springs. The general spiral torsion spring design equations are presented in a form convenient for robot design, along with a detailed discussion of the mechanism surrounding the spring. Also, the SEA mechanism has a set of unidirectional hardstops that further improves the position control by allowing series-elasticity in only one rotational direction.

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Design and analysis of ℋ∞ force control of a series elastic actuator for impedance control of an ankle rehabilitation robotic platform

2017 American Control Conference (ACC) ◽

10.23919/acc.2017.7963316 ◽

2017 ◽

Cited By ~ 7

Author(s):

Juan C. Perez-Ibarra ◽

Andres L. Jutinico Alarcon ◽

Jonathan Campo Jaimes ◽

Felix M. Escalante Ortega ◽

Marco Henrique Terra ◽

...

Keyword(s):

Force Control ◽

Impedance Control ◽

Robotic Platform ◽

Series Elastic Actuator ◽

Ankle Rehabilitation ◽

Rehabilitation Robotic ◽

Series Elastic

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Fuzzy impedance-based control with fast terminal sliding mode force control loop for a series elastic actuator system

Transactions of the Institute of Measurement and Control ◽

10.1177/01423312211043661 ◽

2021 ◽

pp. 014233122110436

Author(s):

Seyed Ali Moafi ◽

Farid Najafi

Keyword(s):

Force Control ◽

Fuzzy Logic Controller ◽

Sliding Mode ◽

Control Loop ◽

Terminal Sliding Mode ◽

Control Approach ◽

Series Elastic Actuator ◽

Control Scheme ◽

Fast Terminal Sliding Mode ◽

Series Elastic

This paper proposes a robust control scheme to accomplish the interaction control problem between a series elastic actuator (SEA) and a flexible environment. The adaptability of the controller to unknown variations and robustness of the controller during interaction of the system with environment are the main aims. The control scheme is based on a fuzzy impedance control approach and consists of an inner fast terminal sliding mode force control loop. An experimental setup is designed to prove the efficiency of the developed controller. The experimental results confirm that the proposed fuzzy logic controller guarantees the sensitivity of the controlled system to unpredictable variations. Moreover, by applying the fast terminal sliding mode algorithm for the inner force control loop, the system has faster convergence to the reference path compared with similar control methods found in the literature.

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A Series Elastic Actuator Design and Control in a Linkage Based Hand Exoskeleton

Volume 3, Rapid Fire Interactive Presentations: Advances in Control Systems; Advances in Robotics and Mechatronics; Automotive and Transportation Systems; Motion Planning and Trajectory Tracking; Soft Mechatronic Actuators and Sensors; Unmanned Ground and Aerial Vehicles ◽

10.1115/dscc2019-8996 ◽

2019 ◽

Author(s):

Raghuraj J. Chauhan ◽

Pinhas Ben-Tzvi

Keyword(s):

Series Elastic Actuator ◽

Single Finger ◽

Recent Trends ◽

Hand Exoskeleton ◽

Soft Actuators ◽

Input Motion ◽

High Level ◽

And Control ◽

Actuator Design ◽

Series Elastic

Abstract This paper presents the design of a series elastic actuator and a higher level controller for said actuator to assist the motion of a user’s hand in a linkage based hand exoskeleton. While recent trends in the development of exoskeleton gloves has been to exploit the advantages of soft actuators, their size and power requirements limit their adoption. On the other hand, a series elastic actuator can provide compliant assistance to the wearer while remaining compact and lightweight. Furthermore, the linkage based mechanism integrated with the SEA offers repeatability and accuracy to the hand exoskeleton. By measuring the user’s motion intention through compression of the elastic elements in the actuator, a virtual dynamic system can be utilized that assists the users in performing the desired motion while ensuring the motion stability of the overall system. This work describes the detailed design of the actuator followed by performance tests using a simple PD controller on the integrated robotic exoskeleton prototype. The performance of the proposed high level controller is tested using the integrated exoskeleton glove mechanism for a single finger, using two types of input motion. Preliminary results are discussed as well as plans for integrating the proposed actuator and high level controller into a complete hand exoskeleton prototype to perform intelligent grasping.

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