Modelling and stabilizability of piezoelectric materials

In his research. Matthijs de Jong explored the modelling and stabilizability of piezoelectric materials, such as beams, actuators, and composites, focusing on their applications in high-precision positioning and shape control. A piezoelectric actuator consists of a piezoelectric layer between two electrodes, which responds to electric input signals by changing shape. Interconnecting a piezoelectric actuator with a purely mechanical layer results in a piezoelectric composite that can be shaped. De Jong contrasts different electromagnetic assumptions—dynamic, quasi-static, and static—and examines how each affects the stability and performance of piezoelectric composites. 

De Jong developed novel voltage-controlled and current-controlled composite models, with the current-controlled models leveraging a new "combined Lagrangian" method that integrates mechanical and electromagnetic dynamics through so-called traditors, which couple force and flow balance equations in a non-energetic manner. De Jong shows that voltage-controlled piezoelectric composites are stabilisable under certain system parameters, and for current-controlled piezoelectric composites, this holds only under the fully dynamic electromagnetic assumption. 

Finally, De Jong introduces a novel Passivity-Based Control (PBC) design, from which he derives two control methodologies –output shaping and input shaping- using a Krasovskii Lyapunov function as the storage function for a piezoelectric beam and applicable to a large class of (electro-)mechanical systems. These advancements provide a foundation for more efficient, stable control of piezoelectric-based systems in engineering.

Dissertation: https://hdl.handle.net/11370/c44bdc8c-2018-4006-b206-82876b727c38