Abstract
The parametric block diagram of the electromagnetoelastic actuator nanodisplacement or the piezoactuator is determined in contrast the electrical equivalent circuit types Cady or Mason for the calculation of the piezoelectric transmitter and receiver, the vibration piezomotor with the mechanical parameters in form the velosity and the pressure. The method of mathematical physics is used. The parametric block diagram of electromagnetoelastic actuator is obtained with the mechanical parameters the displacement and the force. The transfer functions of the electroelastic actuator are determined. The the generalized parametric block diagram, the generalized matrix equation for the electromagnetoelastic actuator nanodisplacement are obtained. The deformations of the electroelastic actuator for the nanotechnology are described by the matrix equation. Block diagram and structural-parametric model of electromagnetoelastic actuator nanodisplacement for nanodisplacement of the communications systems are obtained, its transfer functions are bult. Effects of geometric and physical parameters of electromagnetoelastic actuators and external load on its dynamic characteristics are determined. For calculations the communications systems with the piezoactuator for nanodisplacement the parametric block diagram and the transfer functions of the piezoactuator are obtained.
Highlights
The parametric block diagram of electromagnetoelastic actuator for nanodisplacement on the piezoelectric, piezomagnetic, electrostriction, magnetostriction effects, for example, the piezoactuator is determined in contrast electrical equivalent circuit types Cady or Mason for the calculation of the piezotransmitter and piezoreceiver, the vibration piezomotor with the mechanical parameters in form the velosity and the pressure [1 – 11]
The transfer functions and the parametric block diagrams of the electromagnetoelastic actuators are obtained from the set of equations describing the corresponding structural parametric model of the actuator for the communications systems
The parametric block diagram and the matrix transfer functions of the electromagnetoelastic actuator for the nanotechnology are obtained from the structural-parametric model of the electromagnetoelastic actuator with the mechanical parameters the displacement and the force
Summary
The parametric block diagram of electromagnetoelastic actuator for nanodisplacement on the piezoelectric, piezomagnetic, electrostriction, magnetostriction effects, for example, the piezoactuator is determined in contrast electrical equivalent circuit types Cady or Mason for the calculation of the piezotransmitter and piezoreceiver, the vibration piezomotor with the mechanical parameters in form the velosity and the pressure [1 – 11]. The transfer functions and the parametric block diagrams of the electromagnetoelastic actuators are obtained from the set of equations describing the corresponding structural parametric model of the actuator for the communications systems. The method of mathematical physics is applied for the solution of the wave equation of the electromagnetoelastic actuator for the communications systems with using the Laplace transform for the construction the parametric block diagram of the electromagnetoelastic actuator. As the result of the joint solution of the wave equation of the actuator with the Laplace transform, the equation of the electromagnetoelasticity, the boundary conditions on the two loaded working surfaces of the actuator, we obtain the corresponding structural-parametric model and the parametric block diagram of the electromagnetoelastic actuator
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