Wu Pang scite author profile

This article presents the structure, design, and motion control of an inchworm inspired pneumatic soft robot, which can perform differential movement. This robot mainly consists of two columns of pneumatic multi-airbags (actuators), one sensor, one baseboard, front feet, and rear feet. According to the different inflation time of left and right actuators, the robot can perform both linear and turning movements. The actuators of this robot are composed of multiple airbags, and the design of the airbags is analyzed. To deal with the nonlinear performance of the soft robot, we use radial basis function neural networks to train the turning ability of this robot on three different surfaces and create a mathematical model among coefficient of friction, deflection angle, and inflation time. Then, we establish the closed-loop automatic control model using three-axis electronic compass sensor. Finally, the automatic control model is verified by linear and turning movement experiments. According to the experiment, the robot can finish the linear and turning movements under the closed-loop control system.

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Study on nonlinear crawling locomotion of modular differential drive soft robot

Wang

Min

Fei

et al. 2019

Nonlinear Dyn

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Analysis on nonlinear turning motion of multi-spherical soft robots

Fei

Pang

2016

Nonlinear Dyn

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Wu Pang

A Novel Fabric-Based Versatile and Stiffness-Tunable Soft Gripper Integrating Soft Pneumatic Fingers and Wrist

Design, Modeling, and Testing of a Soft Pneumatic Glove With Segmented PneuNets Bending Actuators

The Structure, Design, and Closed-Loop Motion Control of a Differential Drive Soft Robot

Study on nonlinear crawling locomotion of modular differential drive soft robot

Analysis on nonlinear turning motion of multi-spherical soft robots

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