Last Modified

• March 19, 2019

Creator

• Springthorpe, Dwight, II
  • Affiliation: School of Medicine, UNC/NCSU Joint Department of Biomedical Engineering

Abstract

• Although the neurophysiological basis of insect flight control has been studied extensively and successfully in animals attached to rigid tethers, these conditions disrupt the natural feedback between the subject's intentions, sensory input, and motor output. Understanding how individual control algorithms are integrated at a behavioral level requires acquisition and modification of biopotentials in completely untethered, free-flying animals. Herein, I present and test a miniaturized animal-computer interface for use with freely-flying Manduca sexta hawkmoths. This device is capable of simultaneously acquiring two independent biopotential signals, applying electrical neuromuscular stimulation, and correlating collected and applied signals with behavioral data from high-speed videography. Application of this device may offer substantial insight into how insects fly and, by replicating these mechanisms, facilitate wider application of micro air vehicles through improved flight efficiency, stability, and maneuverability.

Date of publication

• May 2011

DOI

• https://doi.org/10.17615/50sc-fp65

Resource type

• Masters Thesis

Rights statement

• In Copyright

Note

• "... in partial fulfillment of the requirements for the degree of Master of Science in the Department of Biomedical Engineering."

Advisor

• Dennis, Robert G.

Language

• English

Publisher

• University of North Carolina at Chapel Hill

Place of publication

• Chapel Hill, NC

Access

• Open access

Parents:

This work has no parents.

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