Showing posts with label piezoactuator. Show all posts
Showing posts with label piezoactuator. Show all posts

Saturday, 1 April 2023

Structural Parametric Model and Diagram of Electromagnetoelastic Actuator for Nanodisplacement in Chemistry and Biochemistry Research | Chapter 7 | Current Topics on Chemistry and Biochemistry Vol. 9

 Structural parametric model, fundamental diagram, origin transfer function of electromagnetoelastic actuator are obtained. Using the got solutions of the uninterrupted ordinary second-order characteristic equation for the actuator and the equating of electromagnetoelasticity, the generalized fundamental parametric model of the electromagnetoelastic actuator is constructed for nanodisplacement in allure and biochemistry research. The effects of lines and physical limits of electromagnetoelastic actuators, as well as outside load, on their dynamic traits are investigated. The fundamental diagrams and transfer functions of piezoactuators are captured for the calculation of control methods using piezoactuators. A statement structural drawing of the electromagnetoelastic actuator for nanodisplacement in chemistry and biochemistry research is built. The matrix transfer function and the fundamental diagram of the piezoactuator for the transverse, long, shift piezoelectric effects are got from structural parametric model.

Author(s) Details:

S. M. Afonin,
National Research University of Electronic Technology (MIET), Moscow, Russia.

Please see the link here: https://stm.bookpi.org/CTCB-V9/article/view/9977

Friday, 29 July 2022

Structural-Parametric Model of Electromagnetoelastic Actuator for Nanoscience and Nanotechnology | Chapter 7 | Technological Innovation in Engineering Research Vol. 6

 

The matrix equation for the electromagnetoelastic actuator and the solution to the linear ordinary differential equation are both determined in this chapter. For nanoscience and nanotechnology, the structural diagram, the matrix transfer function, and the properties of the electromagnetoelastic actuator are obtained. The electromagnetoelastic actuator's generalized structural diagram and generalized matrix transfer function are calculated from its generalized structural-parametric model. For control systems in nanoscience and nanotechnology, the piezoactuator's static and dynamic properties are established.

Author(s) Details:

S. M. Afonin,
National Research University of Electronic Technology MIET, Moscow, Russia.

Please see the link here: https://stm.bookpi.org/TIER-V6/article/view/7604