Learning to Ascend Stairs and Ramps: Deep Reinforcement Learning for a Physics-Based Human Musculoskeletal Model

Learning to Ascend Stairs and Ramps: Deep Reinforcement Learning for a Physics-Based Human Musculoskeletal Model

This paper proposes to use deep reinforcement learning to teach a physics-based human musculoskeletal model to ascend stairs and ramps. The deep reinforcement learning architecture employs the proximal policy optimization algorithm combined with imitation learning and is trained with experimental da...

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Veröffentlicht in:Sensors (Basel, Switzerland) Switzerland), 2022-11, Vol.22 (21), p.8479
Hauptverfasser: Adriaenssens, Aurelien J. C., Raveendranathan, Vishal, Carloni, Raffaella
Format: Artikel
Sprache:eng
Schlagworte:
computer simulation
Deep learning
deep reinforcement learning
Design
Elastic foundations
Geometry
Mathematical optimization
Muscles
Neural networks
Physics
Prostheses
Public software
Ramps
Simulation
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Zusammenfassung:This paper proposes to use deep reinforcement learning to teach a physics-based human musculoskeletal model to ascend stairs and ramps. The deep reinforcement learning architecture employs the proximal policy optimization algorithm combined with imitation learning and is trained with experimental data of a public dataset. The human model is developed in the open-source simulation software OpenSim, together with two objects (i.e., the stairs and ramp) and the elastic foundation contact dynamics. The model can learn to ascend stairs and ramps with muscle forces comparable to healthy subjects and with a forward dynamics comparable to the experimental training data, achieving an average correlation of 0.82 during stair ascent and of 0.58 during ramp ascent across both the knee and ankle joints.
ISSN:1424-8220
1424-8220
DOI:10.3390/s22218479