Adaptive and Energy-Efficient Optimal Control in CPGs Through Tegotae-Based Feedback

Overview

Journal Front Robot AI

Specialty Biomedical Engineering

Date 2021 Jun 14

PMID 34124172

Citations 1

Authors

Riccardo Zamboni

Dai Owaki

Mitsuhiro Hayashibe

Affiliations

Soon will be listed here.

Abstract

To obtain biologically inspired robotic control, the architecture of central pattern generators (CPGs) has been extensively adopted to generate periodic patterns for locomotor control. This is attributed to the interesting properties of nonlinear oscillators. Although sensory feedback in CPGs is not necessary for the generation of patterns, it plays a central role in guaranteeing adaptivity to environmental conditions. Nonetheless, its inclusion significantly modifies the dynamics of the CPG architecture, which often leads to bifurcations. For instance, the force feedback can be exploited to derive information regarding the state of the system. In particular, the approach can be adopted by coupling proprioceptive information with the state of the oscillation itself in the CPG model. This paper discusses this policy with respect to other types of feedback; it provides higher adaptivity and an optimal energy efficiency for reflex-like actuation. We believe this is the first attempt to analyse the optimal energy efficiency along with the adaptivity of the Tegotae approach.

Citing Articles

Editorial: Biological and Robotic Inter-Limb Coordination.

Owaki D, Manoonpong P, Ayali A Front Robot AI. 2022; 9:875493.

PMID: 35391940 PMC: 8981463. DOI: 10.3389/frobt.2022.875493.

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