Minimizing torque requirements in robotic manipulation through elastic elements optimization in a physics engine

The increasing number of robots and the rising cost of electricity have spurred research into energy-reducing concepts in robotics. One such concept, elastic actuation, introduces compliant elements such as springs into the robot structure. This article presents a comparative analysis between two ty...

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Vydané v:International journal of advanced robotic systems Ročník 21; číslo 1
Hlavní autori: Marchal, Maxime, Marzougui, Dries, Furnémont, Raphaël, Verstraten, Tom, wyffels, Francis
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: London, England SAGE Publications 01.01.2024
Sage Publications Ltd
SAGE Publishing
Predmet:
Actuation
Actuators
Configurations
Modulus of elasticity
Optimization
Pick and place tasks
Robot arms
Robotics
Springs (elastic)
System identification
Torque
Trajectories
methods and tools for robot system design
evolutionary robotics
Actuation and joint mechanisms
compliant joints and mechanisms
optimization and optimal control
ISSN:1729-8806, 1729-8814
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Shrnutí:The increasing number of robots and the rising cost of electricity have spurred research into energy-reducing concepts in robotics. One such concept, elastic actuation, introduces compliant elements such as springs into the robot structure. This article presents a comparative analysis between two types of elastic actuation, namely, monoarticular parallel elastic actuation and biarticular parallel elastic actuation, and demonstrates an end-to-end pipeline for their optimization. Starting from the real-world system identification of an RRR robotic arm, we calibrate a simulation model in a general-purpose physics engine and employ in silico evolutionary optimization to co-optimize spring configurations and trajectories for a pick-and-place task. Finally, we successfully transfer the in silico optimized elastic elements and trajectory to the real-world prototype. Our results substantiate the ability of elastic actuation to reduce the actuators’ torque requirements heavily. In contrast to previous work, we highlight the superior performance of the biarticular variant over the monoarticular configuration. Furthermore, we show that a combination of both proves most effective. This work provides valuable insights into the torque-reducing use of elastic actuation and demonstrates an actuator-invariant in silico optimization methodology capable of bridging the sim2real gap.
Bibliografia:ObjectType-Article-1
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ISSN:1729-8806
1729-8814
DOI:10.1177/17298806241228371