Near-hover dynamics and attitude stabilization of an insect model

Author

Cheng, B. ; Deng, Xinhuan

fYear

2010

fDate

June 30 2010-July 2 2010

Firstpage

39

Lastpage

44

Abstract

In this paper, we present a mathematical model of near-hover attitude dynamics and control in flapping flight. Then we apply this model to fruit fly (Drosophila) as an example. The attitude dynamics are derived from the complete 6-DOF equations of motion. Stability derivatives are estimated based on quasi-steady aerodynamic models of Flapping counter-torques (FCTs). Control derivatives are derived in a similar manner. Results show that stable angular motions can be achieved using a simple proportional feedback control. A coupled yaw and roll rotation (similar to a banked turn) is indentified as the most stable mode of angular motion. Additionally, free response results suggest that the fruit fly is able to damp out an initial disturbance of angular velocity.

Keywords

attitude control; feedback; motion control; position control; proportional control; stability; Drosophila; angular motion; attitude control; attitude stabilization; banked turn; coupled yaw-and-roll rotation; flapping counter-torque; flapping flight; fruit fly; insect model; mathematical model; near-hover dynamics; proportional feedback control; quasi-steady aerodynamic model; stability derivative estimation; Aerodynamics; Angular velocity; Attitude control; Damping; Differential equations; Gravity; Insects; Kinematics; Open loop systems; Stability;

fLanguage

English

Publisher

ieee

Conference_Titel

American Control Conference (ACC), 2010

Conference_Location

Baltimore, MD

ISSN

0743-1619

Print_ISBN

978-1-4244-7426-4

Type

conf

DOI

10.1109/ACC.2010.5530672

Filename

5530672