Investigators: Zheng Chen, Yang Fang, Ernest Mbemmo, Stephan Shatara, Bryan Thomas, Ki-Yong Kwon, Andrew Temme

Sponsors: National Science Foundation, MSU IRGP, and International Society for Optical Engineering (SPIE)

Collaborators: Dr. Mohsen Shahinpoor (Environmental Robots Inc.), Dr. Gursel Alici (University of Wollongong, Australia), Dr. Kwang J. Kim (University of Nevada), Dr. Yantao Shen (Michigan State University), Dr. Ning Xi (Michigan State University)

Select publications:

• Y. Fang, X. Tan, Y. Shen, N. Xi, G. Alici, "A Scalable Model for Trilayer Conjugated Polymer Actuators and Its Experimental Validation," Materials Science and Engineering C: Biomimetic and Supramolecular Systems (2008)
• Z. Chen, X. Tan, "A Control-oriented and Physics-based Model for Ionic Polymer-Metal Composite Actuators," IEEE/ASME Transactions on Mechatronics ( to appear,  2007)
• E. Mbemmo, Z. Chen, S. Shatara, X. Tan, "Modeling of Biomimetic Robotic Fish Propelled by An Ionic Polymer-Metal Composite Actuator," ICRA'08
• Z. Chen, K. Kwon, X. Tan, "Integrated IPMC/PVDF Sensory Actuator and Its Validation in Feedback Control," Sensors and Actuators A: Physical (to appear, 2007)
• Y. Fang, X. Tan, G. Alici, "Redox Level-Dependent Impedance Model for Conjugated Polymer Actuators,"  Sensors and Actuators B: Chemical (to appear, 2007)
• Z. Chen, X. Tan, A. Will, C. Ziel, "A Dynamic Model for Ionic Polymer-Metal Composite Sensors," Smart Materials and Structures (2007)
• Y. Fang, X. Tan, G. Alici, "Robust Adaptive Control of Conjugated Polymer Actuators," IEEE Transactions on Control Systems Technology (to appear, 2007)
• Z. Chen, Y. Shen, N. Xi, X. Tan, "Integrated Sensing for Ionic Polymer-Metal Composite Actuators Using PVDF Thin Films," Smart Materials and Structures (2007)
• X. Tan, D. Kim, et al, "An Autonomous Robotic Fish for Mobile Sensing," IROS'06
• Z. Chen, X. Tan, M. Shahinpoor, "Quasi-static Positioning of Ionic Polymer-Metal Composite (IPMC) Actuators," IEEE/ASME AIM'05

Introduction

Modeling of Actuation and Sensing

Micromanipulation and Biological Applications

Robotic Fish for Mobile Sensing

Introduction

Electroactive polymers (EAPs), also informally known as Artificial Muscles,  are a class of smart materials that show strong coupling between the applied electric field and their mechanical strains.  We are particularly interested in two classes of EAPs, Ionic Polymer-Metal Composites (IPMCs) and Conjugated Polymers  (in particular, Polypyrroles),  since they produce large bending motions under low actuation voltages (about 1 V), are biocompatible and resilient, with tremendous potential in biomedical devices, micromanipulation, and biomimetic robotics.  Click the following two pictures for video clips of  graceful movements of an IPMC actuator and a Polypyrrole actuator, respectively.

The goal of this project is to fully realize the potential of these emerging actuation materials by 

• building faithful, control-oriented models capturing both dynamics and major nonlinearities,
• providing compact sensing solutions for EAP actuators, 
• advancing the state of the art in control methodologies targeting complicated behaviors of these materials, and
• applying findings to micro robots, biomedical devices, and biological applications.

Modeling of Actuation and Sensing

Two real-time control stations, one based on DSpace and the other on RT Linux, are dedicated to the modeling, sensing, and control research. A laser distance sensor and a PVDF micro-force sensor are used to capture the actuation performances of EAPs. To investigate their behaviors as mechanical sensors, we have built an apparatus that can provide controllable, mechanical excitation to EAP samples. Click the two pictures below to see video clips of the apparatus at work: left - the setup working in vertical configuration; right - close-up of mechanical excitation to a cantilevered IPMC sample. 

We have recently made exciting progress in developing control-oriented yet physics-based models for ionic polymer-metal composites and conjugated polymers. The models are equivalent to the governing one-dimensional partial differential equations (with appropriate boundary conditions), and take the form of infinite-dimensional transfer functions. The latter are amenable to model reduction and thus convenient for real-time sensing and control.

SML strives to make systems smaller. Sensing is often prohibitive for microsystems and nanosystems due to their limited real estate, and thus compact, accurate sensing schemes are of interest in the development of miniaturized systems. Several approaches are being investigated in our lab to detect the displacement/force generated by an EAP actuator in a way that takes no or very little extra space. One approach we have developed is to integrate a thin PVDF (polyvinylidene fluoride)  film with an IPMC. As PVDF is an piezoelectric material, the IPMC/PVDF hybrid now functions as an actuator and sensor.

Micromanipulation and Biological Applications

One promising application area for EAPs is micromanipulation. We have built an IPMC-based micromanipulator and used it for micro-injection of fruitfly embryos.  This operation, necessary for genetic modification of Drosophila embryos, has traditionally be performed manually, which is time-consuming with low yield. With sensory feedback from the PVDF layer, we expect to automate the injection process with accurate force and position control. Shown in the pictures below:  an IPMC/PVDF equipped with a pipette (tip diameter 2 microns) ready for the injection experiment (left), and snapshots of the injection into a Drosophila embryo (right). Click the snapshots below (right) for a video (3 Mb) of the injection process. We are also investigating the use of such micromanipulators in biomechanical study of single cells. 

Robotic Fish for Mobile Sensing

The goal is to develop an autonomous swimming robot propelled by EAP actuators. Without using motors, such a robotic fish will deliver noiseless and efficient locomotion. Advanced navigational capabilities, together with communication and sensing modules, will allow the robotic fish to carry out missions of practical interest, e.g., environmental monitoring and control, and reconnaissance in hostile waters. 

One objective of this robotic fish project is to develop the critical understanding and technology for exploiting multiple functionalities of electroactive polymers (sensing, actuation, structure) in miniaturized autonomous systems, which also include micro unmanned aerial vehicles (UAVs) and on-ground robotic insects.

We have developed prototypes of robotic fish using IPMC actuators as caudal fins, which are capable of mesh networking. Equipped with microcontroller, Zigbee, GPS, and temperature sensor, the robot can serve as a mobile sensing platform. Ongoing research is focused on implementing localization module (without reliance on GPS) so that groups of such fish can be used for study of swarming behaviors. Click the two pictures below for video clips  of fish in action.

We are also improving the stability, efficiency, and maneuverability of the robotic fish by drawing inspiration from biology. In addition to optimizing the size, shape, and control of the robot, we are investigating the fabrication of novel electroactive polymers that truly mimic biological muscles found in Nature.