Moving in an Uncertain World: Robust and Adaptive Control of Locomotion from Organisms to Machine Intelligence

Overview

Journal Integr Comp Biol

Publisher Oxford University Press

Specialty Biology

Date 2024 Aug 2

PMID 39090982

Authors

Jean-Michel Mongeau

Yu Yang

Ignacio Escalante

Noah Cowan

Kaushik Jayaram

Affiliations

Soon will be listed here.

Abstract

Whether walking, running, slithering, or flying, organisms display a remarkable ability to move through complex and uncertain environments. In particular, animals have evolved to cope with a host of uncertainties-both of internal and external origin-to maintain adequate performance in an ever-changing world. In this review, we present mathematical methods in engineering to highlight emerging principles of robust and adaptive control of organismal locomotion. Specifically, by drawing on the mathematical framework of control theory, we decompose the robust and adaptive hierarchical structure of locomotor control. We show how this decomposition along the robust-adaptive axis provides testable hypotheses to classify behavioral outcomes to perturbations. With a focus on studies in non-human animals, we contextualize recent findings along the robust-adaptive axis by emphasizing two broad classes of behaviors: (1) compensation to appendage loss and (2) image stabilization and fixation. Next, we attempt to map robust and adaptive control of locomotion across some animal groups and existing bio-inspired robots. Finally, we highlight exciting future directions and interdisciplinary collaborations that are needed to unravel principles of robust and adaptive locomotion.

Citing Articles

Lightweight Two-Layer Control Architecture for Human-Following Robot.

Acosta-Amaya G, Miranda-Montoya D, Jimenez-Builes J Sensors (Basel). 2024; 24(23).

PMID: 39686333 PMC: 11644850. DOI: 10.3390/s24237796.

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