Asynchronous Control of a Prototype Inchworm Actuator: Control Design and Test Results

Shields, Joel

doi:10.3390/act8010020

Cited by 8 publications

(4 citation statements)

References 13 publications

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“…They have a wide range of applications in many aspects, such as biomedicine [5][6][7], ultra-precision machining [8,9], precision optics [10,11], micro-and nano-positioners [12,13], triboelectricity [14], and microscopes [15][16][17], etc. The current mainstream research on piezoelectric precision drives focuses on stepper-type piezoelectric actuation [18][19][20], ultrasonic-type piezoelectric actuation [21,22], and inertial impact piezoelectric actuation [23,24]. Inertial impact piezoelectric actuation has received much attention, due to the distinctive actuation method of the inertial force changing the drive force and positive pressure for fast motion, a high resolution, a large stroke, and a simple structure [25,26].…”

Section: Introductionmentioning

confidence: 99%

The Frequency-Variable Rotor-Blade-Based Two-Degree-of-Freedom Actuation Principle for Linear and Rotary Motion

Li,

Wang,

Peng

et al. 2023

Sensors

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Piezoelectric accurate actuation plays an important role in industrial applications. The intrinsic frequency of previous actuators is invariable. However, variable frequency can approach the range near the low-intrinsic-frequency and realize a high actuation capability. The frequency-variable linear and rotary motion (FVLRM) principle is proposed for rotor-blade-based two-degree-of-freedom driving. Inertial force is generated by frequency-variable piezoelectric oscillators (FVPO), the base frequency and vibration modes of which are adjustable by the changeable mass and position of the mass block. The variable-frequency principle of FVPO and the FVLRM are recognized and verified by the simulations and experiments, respectively. The experiments show that the FVLRM prototype moves the fastest when the mass block is placed at the farthest position and the prototype is at the second-order intrinsic frequencies of 42 Hz and 43 Hz, achieving a linear motion of 3.52 mm/s and a rotary motion of 286.9 mrad/s. The actuator adopts a lower operating frequency of less than 60 Hz and has the function of adjusting the natural frequency. It can achieve linear and rotational motion with a larger working stroke with 140 mm linear movement and 360° rotation.

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Section: Introductionmentioning

confidence: 99%

The Frequency-Variable Rotor-Blade-Based Two-Degree-of-Freedom Actuation Principle for Linear and Rotary Motion

Li,

Wang,

Peng

et al. 2023

Sensors

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“…The flight inchworm actuators (FIA) which is composed of PEA stacks is used to position various optical elements in highly sensitive optical instruments. 3 PEA also is used as the actuator of micro-robots 4 and cell piercing 5 in life science and technology.…”

Section: Introductionmentioning

confidence: 99%

Parameter identification of Duhem model based on antlion-fish swarm hybrid algorithm and robust backstepping sliding mode control for rate-dependent hysteresis of piezoelectric actuators

Zeyu

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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A new parameter identification method of Duhem model based on antlion-fish swarm hybrid algorithm is proposed to characterize the rate-dependent hysteresis. The unknown piecewise functions in Duhem model is identified by a hybrid algorithm. Antlion optimization (ALO) algorithm and artificial fish (AF) swarm algorithm are switched in order of execution and their iterative data are fused to form the antlion-fish swarm hybrid algorithm. The comparison experiment shows the hybrid algorithm has the advantages of fast convergence and high precision. In order to compensate the rate-dependent hysteresis of PEA, a robust backstepping sliding mode feedback controller with feedforward inverse Duhem model compensator are designed. The comparative experimental results of displacement tracking show that this method has good tracking performance. The practicability and effectiveness of the method are verified.

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“…Three main issues, however, compromise the utility of these devices. The first is that the stroke of these devices is limited to about 40 μm, which for some applications, necessitates the use of dual stage actuation [2,3] or inchworm actuators [4] which combine brake PZTs with actuation PZTs to extend the dynamic range of these devices. In addition, PZTs suffer from significant amounts of hysteresis (15 percent of full stroke) and creep which causes drift of the device over time.…”

Section: Introductionmentioning

confidence: 99%

Modeling of Piezoceramic Actuators for Control

Shields¹,

Konefat²

2021

Piezoelectric Actuators - Principles, Design, Experiments and Applications

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In this chapter a full electromechanical model of piezoceramic actuators is presented. This model allows for easy integration of the piezo stack with a structural finite element model (FEM) and includes the flow of energy into and out of the piezo element, which is governed by the transducer constant of the piezo element. Modeling of the piezo stack capacitive hysteresis is achieved using backlash basis functions. The piezo model can also be used to predict the current usage of the PZT which depends on the slew rate of the voltage applied to the PZT. Data from laboratory experiments using a load frame and free response tests is used to estimate the PZT model parameters. In addition, a simplified model of a modulated full bridge strain gauge is derived based on test data which includes the effect of intrinsic bridge imbalance. Sensors of this type are often used with feedback control to linearize the behavior of the device. Taken together, the actuator and sensor model can be used for the development of piezo actuated control algorithms.

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Asynchronous Control of a Prototype Inchworm Actuator: Control Design and Test Results

Cited by 8 publications

References 13 publications

The Frequency-Variable Rotor-Blade-Based Two-Degree-of-Freedom Actuation Principle for Linear and Rotary Motion

The Frequency-Variable Rotor-Blade-Based Two-Degree-of-Freedom Actuation Principle for Linear and Rotary Motion

Parameter identification of Duhem model based on antlion-fish swarm hybrid algorithm and robust backstepping sliding mode control for rate-dependent hysteresis of piezoelectric actuators

Modeling of Piezoceramic Actuators for Control

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