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Energy-Based Control of a Thruster-Assisted Underwater Hexapod Robot on Deformable Terrains

Abstract

The thruster-assisted underwater hexapod robot can traverse structures with any dip angle, such as a drilling platform and hip hull. However, the structures are often deformable due to complex coverings, which significantly complicates the leg-terrain interaction dynamics and poses a substantial hurdle in steering the robot. Thus, we propose and experimentally implement an energy-based control method for a thruster-assisted underwater hexapod robot with C-shaped legs. The key idea is to calculate the robot's energy loss during locomotion and use thruster forces to compensate for it. First, we establish leg-terrain interaction mechanics by considering the leg's special shape and the terrain's viscoplastic characteristics. Then, we use it to calculate the robot's required energy for tracking the predesigned locomotion. Second, we introduce an energy-based control method that effectively coordinates thruster forces and torques, where the torques are designed to guide the legs in tracking the predesigned gaits, and the thruster forces are calibrated based on the remaining energy. Finally, as demonstrated in our contrastive lakebed locomotion experiment, this approach enables the robot to navigate deformable terrains smoothly.

article Article

date_range 2024

language English

link Link of the paper

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Chen Lepeng

Cui Rongxin

Yan Weisheng

Zhao Zhexuan

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Featured Keywords

Legged locomotion

Robots

Robot kinematics

Deformation

Energy loss

Force

Plastics

Deformable terrain

energy-based control

thruster-assisted underwater hexapod robot

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Numerical investigation of precast reinforced concrete beam–to–column joints by replaceable damper

Abstract

This study aimed to investigate the precast reinforced concrete beam-to-column joints behaviors through the replaceable damper under cyclic loading. The precast concrete specimens have been embedded with steel reinforcement and specially shaped connectors. After the application of the replaceable damper under cyclic loading, the energy dissipation shaped very well and increased the bearing capacity of precast specimens. The precast concrete beam–to–column joints were designed and analyzed to compare with the traditional reinforced concrete (RC) specimen. The analysis result of the loading based on the controlled displacement method showed that the precast specimen model with a damper has more hysterical behavior than the traditional RC frame. Also, the specimen (PS-1) is passed the 2.7% chord rotation, which showed higher performance, than the traditional RC specimen. The efficiency of the PS-1 specimen with a special connection has been elaborated with the finite element method (FEM) and simulated by ABAQUS software.

article Article

date_range 2022

language English

link Link of the paper

ABAQUS software F...

Monolotic model-Ampelitude (cae)