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A Multiaxial Bionic Ankle Based on Series Elastic Actuation With a Parallel Spring

Shun Zhao, Wei Liang, Kunyang Wang, Lei Ren, Zhihui Qian, Guangrong Chen, Xuewei Lu, Di Zhao, Xu Wang, Luquan Ren

2023IEEE Transactions on Industrial Electronics51 citationsDOIOpen Access PDF

Abstract

Traditional robotic foot and ankle have received considerable attention for adaptive locomotion on complex terrain and land buffering ability. This study aims to develop a robotic ankle based on series elastic actuator with a parallel spring (SEAPS) by mimicking the two degree-of-freedom human ankle and related muscles. A unique four-SEAPS-based spring mechanism enhances motion adaptation and landing buffer. A dynamic model based on the SEAPS drive is presented, whereas a kinematic solution is realized. The bionic ankle has a wide range of motions with 30° in both the sagittal and frontal planes, which cover most of the human ankle motions. Four experiments were conducted to thoroughly characterize the capabilities. First, the static stiffness and the 2-D/3-D trajectory tracking performance of the proposed ankle were tested. Second, the angle sensing capacity under inclined road surface and the land buffering performance from a specific height were evaluated. The results show that the maximum 3-D motion tracking error is smaller than 2.3%, and the minimum sensing error of inclined road is smaller than 0.5%. The proposed ankle can closely track the 3-D walking trajectory of natural ankle joint with relative root-mean-square error well below 1.0%. Compared with no springs, landing buffer of the ankle with SEAPS can yield remarkable reduction in both peak ground reaction force (52.2%) and joint torque (57.9%). These findings prove that the SEAPS-based bioinspired robotic ankle exhibits high land buffering performance in an unstructured environment, and also well reproduces the human-like movement in terms of complex 3-D ankle motions.

Topics & Concepts

AnkleKinematicsSpring (device)Computer scienceTrajectoryStiffnessSagittal planeSimulationControl theory (sociology)TerrainJoint stiffnessTorqueTracking errorGround reaction forceStructural engineeringEngineeringArtificial intelligencePhysicsBiologyRadiologyThermodynamicsClassical mechanicsPathologyControl (management)MedicineAstronomyEcologyProsthetics and Rehabilitation RoboticsRobotic Locomotion and ControlMuscle activation and electromyography studies
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