A novel expression obtained by using artificial bee colony algorithm to calculate pull-in voltage of fixed-fixed micro-actuators

“…An SVD controller is useful for extra long stroke realization [74]. Cevher Ak et al presented an artificial bee colony algorithm for calculating the pull-in voltage of microactuators [75] A. Alneamy et al presented electrostatic MEMS actuators with contact pads and dim ples. Contact pads and dimples minimize electrostatic MEMS actuator dielectric charging prevent stiction between bottom electrodes and actuators, and eliminate multi-valuednes in actuator response [76].…”

“…An SVD controller is useful for extra long stroke realization [74]. Cevher Ak et al presented an artificial bee colony algorithm for calculating the pull-in voltage of microactuators [75].…”

Development of Electrostatic Microactuators: 5-Year Progress in Modeling, Design, and Applications

“…An SVD controller is useful for extra long stroke realization [74]. Cevher Ak et al presented an artificial bee colony algorithm for calculating the pull-in voltage of microactuators [75] A. Alneamy et al presented electrostatic MEMS actuators with contact pads and dim ples. Contact pads and dimples minimize electrostatic MEMS actuator dielectric charging prevent stiction between bottom electrodes and actuators, and eliminate multi-valuednes in actuator response [76].…”

“…An SVD controller is useful for extra long stroke realization [74]. Cevher Ak et al presented an artificial bee colony algorithm for calculating the pull-in voltage of microactuators [75].…”

Development of Electrostatic Microactuators: 5-Year Progress in Modeling, Design, and Applications

“…In practical applications, voltage control is more easily implemented than charge control. (9) Many studies have been published on voltage control approaches, such as static and dynamic output feedback, (10) nonlinear control, (11) passive control, (12) back-stepping control, (13) gain scheduling H∞ control, (14) linear parameter-varying control, (15,16) adaptive fuzzy control, (17) an artificial algorithm method, (18) and extended state observer-based control. (9,19) Among these studies, in Ref.…”

“…15 and 16. Intelligent control methods, such as adaptive fuzzy control (17) and the artificial algorithm (18) approach, were introduced for the development of control strategies for electrostatic MEM actuators. In Refs.…”

Positional Regulation of Electrostatic Micro-electromechanical Actuator via Adaptive Two-stage Sliding Mode Control

Computing the pull-in voltage of fixed–fixed micro-actuators by artificial neural network