Robotics: Science and Systems VI
Passive torque regulation in an underactuated flapping wing robotic insect
P. Sreetharan and R. WoodAbstract:
Recent developments in millimeter-scale fabrication
processes have led to rapid progress towards creating airborne
flapping wing robots based on Dipteran (two-winged) insects.
Previous work to regulate reaction forces and torques generated
by two flapping wings has largely focused on wing trajectory
control. An alternative approach introduces additional degrees
of freedom to the wing flapping mechanism to passively regulate
these forces and torques. The resulting âmechanically intelligentâ
devices can execute wing trajectory corrections to realize desired
body forces and torques without the intervention of an active
controller.
This paper describes an insect-scale flapping wing aeromechanical
structure consisting of a piezoelectric bimorph power
actuator, an underactuated transmission mechanism, and passively
rotating wings. The transmission is designed to passively
modulate wing stroke velocity to eliminate the net roll torque
imparted to the airframe.
The system is modeled as having four degrees of freedom
driven open-loop by a single power actuator. The theoretical
model predicts lift-generating wing trajectories as well as a
passive reduction in roll torque experienced by the airframe.
An at-scale structure constructed using Smart Composite Microstructure
(SCM) fabrication techniques provides experimental
support for the theoretical model.
Bibtex:
@INPROCEEDINGS{ Sreetharan-RSS-10, AUTHOR = {P. Sreetharan AND R. Wood}, TITLE = {Passive torque regulation in an underactuated flapping wing robotic insect}, BOOKTITLE = {Proceedings of Robotics: Science and Systems}, YEAR = {2010}, ADDRESS = {Zaragoza, Spain}, MONTH = {June}, DOI = {10.15607/RSS.2010.VI.002} }