Multimodal vibration control with piezoelectric patches connected to self-tuning RLC shunts

This paper presents experimental results on the control of stochastic flexural vibrations in a plate equipped with five piezoelectric patches connected to self-tuning multi-resonant shunts composed by N-parallel resistive-inductive-capacitive (RLC) branches. The study contrasts the tuning of the branches based on the minimization of the time-averaged total flexural kinetic energy and the maximization of the time-averaged electric power absorbed by each RLC branch relative to the resonant responses of the target modes. Next, it investigates the online tuning of the branches RL components with an extremum seeking algorithm set to maximize the time-averaged electric power absorbed by each RLC branch.

Automated summary

This paper presents experimental results on controlling stochastic flexural vibrations in a plate using five piezoelectric patches and a multi-resonant shunt. The study compares tuning methods based on minimizing flexural kinetic energy and maximizing electric power absorption, and investigates online tuning with an extremum seeking algorithm.