Modeling and Control of IPMC-Based Artificial Eukaryotic Flagellum Swimming Robot: Distributed Actuation

• Published in: Algorithms Vol. 15; no. 6; p. 181
• Main Authors: Traver, José Emilio, Nuevo-Gallardo, Cristina, Rodríguez, Paloma, Tejado, Inés, Vinagre, Blas M.
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.06.2022
• Subjects: Actuation; Actuators; Automation; Bioengineering; control; Control systems design; Controllers; Deflection; Dynamic models; Fluid mechanics; fractional calculus; Frequency response; Integers; ionic polymer-metal composite; Manufacturing engineering; modeling; Polymer matrix composites; Power supply; Reynolds number; Robots; Robust control; Series (mathematics); Soft robotics; Swimming; swimming robot; Wave generation; Waves
• ISSN: 1999-4893; 1999-4893
• DOI: 10.3390/a15060181

Ionic polymer-metal composites (IPMCs) are electrically driven materials that undergo bending deformations in the presence of relatively low external voltages, exhibiting a great potential as actuators in applications in soft robotics, microrobotics, and bioengineering, among others. This paper presents an artificial eukaryotic flagellum (AEF) swimming robot made up of IPMC segments for the study of planar wave generation for robot propulsion by single and distributed actuation, i.e., considering the first flagellum link as an actuator or all of them, respectively. The robot comprises three independent and electrically isolated actuators, manufactured over the same 10 mm long IPMC sheet. For control purposes, a dynamic model of the robot is firstly obtained through its frequency response, acquired by experimentally measuring the flagellum tip deflection thanks to an optical laser meter. In particular, two structures are considered for such a model, consisting of a non-integer order integrator in series with a resonant system of both non-integer and integer order. Secondly, the identified models are analyzed and it is concluded that the tip displacement of each actuator or any IPMC point is characterized by the same dynamics, which remains unchanged through the link with mere variations of the gain for low-frequency applications. Based on these results, a controller robust to gain variations is tuned to control link deflection regardless of link length and enabling the implementation of a distributed actuation with the same controller design. Finally, the deflection of each link is analyzed to determine whether an AEF swimming robot based on IPMC is capable of generating a planar wave motion by distributed actuation.