A distributed and morphology-independent strategy for adaptive locomotion in self-reconfigurable modular robots

David Johan Christensen, Ulrik Pagh Schultz, Kasper Støy

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Abstract

In this paper, we present a distributed reinforcement learning strategy for morphology-independent life-long gait learning for modular robots. All modules run identical controllers that locally and independently optimize their action selection based on the robot’s velocity as a global, shared reward signal. We evaluate the strategy experimentally mainly on simulated, but also on physical, modular robots. We find that the strategy: (i) for six of seven configurations (3–12 modules) converge in 96% of the trials to the best known action-based gaits within 15 min, on average, (ii) can be transferred to physical robots with a comparable performance, (iii) can be applied to learn simple gait control tables for both M-TRAN and ATRON robots, (iv) enables an 8-module robot to adapt to faults and changes in its morphology, and (v) can learn gaits for up to 60 module robots but a divergence effect becomes substantial from 20–30 modules. These experiments demonstrate the advantages of a distributed learning strategy for modular robots, such as simplicity in implementation, low resource requirements, morphology independence, reconfigurability, and fault tolerance.
OriginalsprogEngelsk
TidsskriftRobotics and Autonomous Systems
Vol/bind61
Udgave nummer9
Sider (fra-til)1021-1035
Antal sider15
ISSN0921-8890
StatusUdgivet - 2013

Emneord

  • Self-reconfigurable modular robots
  • Locomotion
  • Online learning
  • Distributed control
  • Fault tolerance

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