A hybrid dynamic model for bio-inspired soft robots — Application to a flapping-wing micro air vehicle

Author

Porez, Mathieu ; Boyer, Fabienne ; Belkhiri, Ayman

Author_Institution

IRCCyN, EMN - La Chantrerie, Nantes, France

fYear

2014

fDate

May 31 2014-June 7 2014

Firstpage

3556

Lastpage

3563

Abstract

The paper deals with the dynamic modeling of bio-inspired robots with soft appendages such as flying insect-like or swimming fish-like robots. In order to model such soft systems, we propose to use the Mobile Multibody System framework introduced in [1], [2], [3]. In such a framework, the robot is considered as a tree-like structure of rigid bodies where the evolution of the position of the joints is governed by stress-strain laws or control torques. Based on the Newton-Euler formulation of these systems, we propose a new algorithm able to compute at each step of a time loop both the net and passive joint accelerations along with the control torques supplied by the motors. To illustrate, based on previous work [4], the proposed algorithm is applied to the simulation of the hovering flight of a soft flapping-wing insect-like robot (see the attached video).

Keywords

Newton method; autonomous aerial vehicles; stress-strain relations; torque control; Newton-Euler formulation; bio-inspired soft robot; control torque; flapping-wing microair vehicle; hovering flight; hybrid dynamic model; mobile multibody system framework; passive joint acceleration; soft appendages; soft flapping-wing insect-like robot; stress-strain law; tree-like structure; Acceleration; Dynamics; Heuristic algorithms; Joints; Mobile communication; Robots; Vectors;

fLanguage

English

Publisher

ieee

Conference_Titel

Robotics and Automation (ICRA), 2014 IEEE International Conference on

Conference_Location

Hong Kong

Type

conf

DOI

10.1109/ICRA.2014.6907372

Filename

6907372