The Effects of Adaptive Control on Learning Directed Locomotion

Conference paper (2020)

Authors

Fuda Van Diggelen Student

R. Babuska Learning & Autonomous Control - Mechanical, Maritime and Materials Engineering

A.E. Eiben Vrije Universiteit Amsterdam

Research Group

Learning & Autonomous Control (Mechanical, Maritime and Materials Engineering) (TU Delft)

Adaptive Control Evolutionary Robotics Reality Gap Directed Locomotion

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http://resolver.tudelft.nl/uuid:3d5faad6-507f-4643-9d20-22763647b191

Published Date

2020

Language

English

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Faculty

Mechanical, Maritime and Materials Engineering

Department

Cognitive Robotics

Research Group

Learning & Autonomous Control

Abstract

This study is motivated by evolutionary robot systems where robot bodies and brains evolve simultaneously. In such systems robot 'birth' must be followed by 'infant learning' by a learning method that works for various morphologies evolution may produce. Here we address the task of directed locomotion in modular robots with controllers based on Central Pattern Generators. We present a bio-inspired adaptive feedback mechanism that uses a forward model and an inverse model that can be learned on-the-fly. We compare two versions (a simple and a sophisticated one) of this concept to a traditional (open-loop) controller using Bayesian optimization as a learning algorithm. The experimental results show that the sophisticated version outperforms the simple one and the traditional controller. It leads to a better performance and more robust controllers that better cope with noise.

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