Paper Info
Title
Co-exploring Actuator Antagonism and Bio-inspired Control in a Printable Robot Arm.
Abstract
The human arm is capable of performing fast targeted movements with high precision, say in pointing with a mouse cursor, but is inherently 'soft' due to the muscles, tendons and other tissues of which it is composed. Robot arms are also becoming softer, to enable robustness when operating in real-world environments, and to make them safer to use around people. But softness comes at a price, typically an increase in the complexity of the control required for a given task speed/accuracy requirement. Here we explore how fast and precise joint movements can be simply and effectively performed in a soft robot arm, by taking inspiration from the human arm. First, viscoelastic actuator-tendon systems in an agonist-antagonist setup provide joints with inherent damping, and stiffness that can be varied in real-time through co-contraction. Second, a light-weight and learnable inverse model for each joint enables a fast ballistic phase that drives the arm close to a desired equilibrium point and co-contraction tuple, while the final adjustment is done by a feedback controller. The approach is embodied in the GummiArm, a robot which can almost entirely be printed on hobby-grade 3D printers. This enables rapid and iterative co- exploration of 'brain' and 'body', and provides a great platform for developing adaptive and bio-inspired behaviours.
Year
DOI
Venue
2016
10.1007/978-3-319-43488-9_22
Lecture Notes in Computer Science
Keywords
Field
DocType
Bio-inspiration,Learnable models,Agonist-antagonist joints,Variable stiffness,3D printing,Targeted movements
Robotic arm,Stiffness,Computer science,Simulation,Tuple,Equilibrium point,Robustness (computer science),3D printing,Robot,Actuator
Conference
Volume
ISSN
Citations 
9825
0302-9743
3
PageRank 
References 
Authors
0.45
10
3
Name
Order
Citations
PageRank
M. Stoelen1195.35
Fabio Bonsignorio2225.60
Angelo Cangelosi341975.30