Model and Design of a Power Driver for Piezoelectric Stack Actuators

A power driver has been developed to control piezoelectric stack actuators used in automotive application. A FEM model of the actuator has been implemented starting from experimental characterization of the stack and mechanical and piezoelectric parameters. Experimental results are reported to show a correct piezoelectric actuator driving method and the possibility to obtain a sensor-less positioning contro

Model and Design of a Power Driver for Piezoelectric Stack Actuators

A power driver has been developed to control piezoelectric stack actuators used in automotive application. An FEM model of the actuator has been implemented starting from experimental characterization of the stack and mechanical and piezoelectric parameters. Experimental results are reported to show a correct piezoelectric actuator driving method and the possibility to obtain a sensorless positioning control

Model and Design of a Power Driver for Piezoelectric Stack Actuators

A power driver has been developed to control piezoelectric stack actuators used in automotive application. A FEM model of the actuator has been implemented starting from experimental characterization of the stack and mechanical and piezoelectric parameters. Experimental results are reported to show a correct piezoelectric actuator driving method and the possibility to obtain a sensor-less positioning control

FPGA Operating System for Hard Real Time Applications

In mechatronics, as in many others fields, one of the main aspect is the prototyping. Since the mechatronics covers a lot of complex applications, the availability of a common digital platform to use in all of them is a valid help in the prototyping phase of the project. FPGAs are often used as software acceleration in reconfigurable computers (RC), in which the operating system is a standard off-the-shelf real time operating system such as Linux and VxWorks. The object of the first part of the work is to develop a hardware operating system for mechatronic applications, which means that the FPGA device does not host a soft core processor, able to execute one only operation at a time, but it executes many concurrent hard real time functions allowing the user to develop his own application code taking advantage of the main features of the device: concurrency, flexibility and determinism. The second part of the thesis is related to the project of an electronic module that integrates logic and power devices to drive piezoelectric stack actuators and demonstrate experimentally the results in terms of control of piezoelectric stack tip displacement on atest bench. The electronic module controls up to four piezoelectric stack actuators and guarantees that the correct tip displacement is reached starting from a desired profile. The various opening/closing phases of the actuators are tuned in terms of slew rate, timings and values to reach during all the controlled phase. The control parameters are passed to the control unit by means of a host human machine interface or by an external electronic control unit that acts as a supervisor. This part will illustrate all the passages of the design starting from the constitutive equations of the piezoelectric material up to the final architecture of the control law and implementation passing through: • creation of a FEM model of the piezoelectric stack; • construction of the modal residues model; • FEM model validation; • identification of the electrical equivalent circuit of the piezoelectric stack; • design of the power driver circuit; • design of the control loops; A complete model validation is then performed and experimental results are presente

Simple piezoelectric-actuated mirror with 180 kHz servo bandwidth

We present a high bandwidth piezoelectric-actuated mirror for length stabilization of an optical cavity. The actuator displays a transfer function with a flat amplitude response and greater than 135$^\circ$ phase margin up to 200 kHz, allowing a 180 kHz unity gain frequency to be achieved in a closed servo loop. To the best of our knowledge, this actuator has achieved the largest servo bandwidth for a piezoelectric transducer (PZT). The actuator should be very useful in a wide variety of applications requiring precision control of optical lengths, including laser frequency stabilization, optical interferometers, and optical communications

Electromechanical Simulation of Actively Controlled Rotordynamic Systems with Piezoelectric Actuators

Theories and tests for incorporating piezoelectric pushers as actuator devices for active vibration control are discussed. It started from a simple model with the assumption of ideal pusher characteristics and progressed to electromechanical models with nonideal pushers. Effects on system stability due to the nonideal characteristics of piezoelectric pushers and other elements in the control loop were investigated

Development of a micromanipulation system with force sensing

This article provides in-depth knowledge about our undergoing effort to develop an open architecture micromanipulation system with force sensing capabilities. The major requirement to perform any micromanipulation task effectively is to ensure the controlled motion of actuators within nanometer accuracy with low overshoot even under the influence of disturbances. Moreover, to achieve high dexterity in manipulation, control of the interaction forces is required. In micromanipulation, control of interaction forces necessitates force sensing in milli-Newton range with nano-Newton resolution. In this paper, we present a position controller based on a discrete time sliding mode control architecture along with a disturbance observer. Experimental verifications for this controller are demonstrated for 100, 50 and 10 nanometer step inputs applied to PZT stages. Our results indicate that position tracking accuracies up to 10 nanometers, without any overshoot and low steady state error are achievable. Furthermore, the paper includes experimental verification of force sensing within nano-Newton resolution using a piezoresistive cantilever endeffector. Experimental results are compared to the theoretical estimates of the change in attractive forces as a function of decreasing distance and of the pull off force between a silicon tip and a glass surface, respectively. Good agreement among the experimental data and the theoretical estimates has been demonstrated