Dynamic control of walking leg joints: A building block model perspective

Author

Zhijun Yang

Author_Institution

Jiangsu Res. Center of Inf. Security & Confidential Eng., Nanjing Normal Univ., Nanjing, China

Volume

1

fYear

2011

fDate

26-28 July 2011

Firstpage

459

Lastpage

463

Abstract

Animals like stick insects can adaptively walk on the complex terrain with different gait patterns. The change of gait patterns involves the adaptation of moving frequency and duty cycle of swing-stance period of individual legs. Inspired by the coupled Matsuoka and resonate-and-fire neuron models, we present a nonlinear oscillation model as the central pattern generator (CPG) for rhythmic gait pattern generation. This dynamic model can be used, as a building block, to actuate the motoneurons on a leg joint with adjustable driving frequencies and duty cycles by changing a few of model parameters. Three identical CPG models being used to drive three joints can make an arthropod leg of three degrees-of-freedom (DOFs). With appropriate model parameter settings, and thus suitable phase lags among joints, the leg is expected to walk on a complex terrain with adaptive steps.

Keywords

biocontrol; biomechanics; neurophysiology; zoology; animals; arthropod leg; building block model; central pattern generator; coupled Matsuoka model; dynamic control; gait patterns; motoneurons; nonlinear oscillation model; resonate-and-fire neuron model; rhythmic gait pattern generation; stick insects; swing-stance period; three degrees-of-freedom; walking leg joints; Adaptation models; Biomembranes; Generators; Joints; Legged locomotion; Neurons; Oscillators;

fLanguage

English

Publisher

ieee

Conference_Titel

Natural Computation (ICNC), 2011 Seventh International Conference on

Conference_Location

Shanghai

ISSN

2157-9555

Print_ISBN

978-1-4244-9950-2

Type

conf

DOI

10.1109/ICNC.2011.6022059

Filename

6022059