Continuous Control of an Underground Loader Using Deep Reinforcement Learning

Continuous Control of an Underground Loader Using Deep Reinforcement Learning

The reinforcement learning control of an underground loader was investigated in a simulated environment by using a multi-agent deep neural network approach. At the start of each loading cycle, one agent selects the dig position from a depth camera image of a pile of fragmented rock. A second agent i...

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Veröffentlicht in:Machines (Basel) 2021-10, Vol.9 (10), p.216
Hauptverfasser: Backman, Sofi, Lindmark, Daniel, Bodin, Kenneth, Servin, Martin, Mörk, Joakim, Löfgren, Håkan
Format: Artikel
Sprache:eng
Schlagworte:
Adaptation
Algorithms
Artificial neural networks
Automation
autonomous excavation
bucket filling
Cameras
Changing environments
Computer Science
datalogi
Deep learning
deep reinforcement learning
Energy consumption
fysik
Hydraulics
Loaders
Machine learning
mining robotics
Multiagent systems
Neural networks
Physics
simulation
wheel loader
Wheels
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Beschreibung
Zusammenfassung:The reinforcement learning control of an underground loader was investigated in a simulated environment by using a multi-agent deep neural network approach. At the start of each loading cycle, one agent selects the dig position from a depth camera image of a pile of fragmented rock. A second agent is responsible for continuous control of the vehicle, with the goal of filling the bucket at the selected loading point while avoiding collisions, getting stuck, or losing ground traction. This relies on motion and force sensors, as well as on a camera and lidar. Using a soft actor–critic algorithm, the agents learn policies for efficient bucket filling over many subsequent loading cycles, with a clear ability to adapt to the changing environment. The best results—on average, 75% of the max capacity—were obtained when including a penalty for energy usage in the reward.
ISSN:2075-1702
2075-1702
DOI:10.3390/machines9100216