A New Analytical Model to Estimate the Voltage Value and Position of the Pull-In Limit of a MEMS Cantilever

In this study, we propose a new 'V'-shaped actuator with two panels and experimentally and theoretically investigate its actuation to find the most efficient structure. The V-shaped actuator operates like a seesaw. Specifically, when a high voltage input is applied between the V-shaped actuator and metal plate at the bottom substrate, another panel rises due to electrostatic attraction. Both gravity and electrostatic attraction forces are utilized for the operation of the actuator. We made a model of the actuation mechanism considering torque, gravity, and electrostatic forces. Theoretical values were compared with experimental results considering all factors of force applied to actuators. Additionally, we added torque by restoring force to compensate for the experimental conditions. The theoretical value almost coincided with the experimental value with R 2 = 0.9.

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“…In addition, we refer to a study with an analytical model of torque influenced by electrostatic force in a similar structural condition [36].…”

Section: Resultsmentioning

confidence: 99%

“…Both theoretical graphs are similar each other, however, it is slightly different with experimental data (Figure 8). This difference can be attributed to the effect of restoring force including resistance [36]. Considering this effect, we present the effect as the minus torque (τ R ) as restoring force with a coefficient, k [36].…”

Section: Resultsmentioning

confidence: 99%

A V-Shaped Actuator Utilizing Electrostatic Force

2018

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“…An applied V GS exerts a distributed force on the cantilever which, as a result, bends towards the drain. A cantilever pivot model [20] provides the amount of resultant effective F es and its acting point for a given V GS using the following formula…”

Section: Experimental Methodsmentioning

confidence: 99%

Measurement and control of stiction force in in-plane electrostatically actuated Si nanoelectromechanical cantilever relays with Pt contacts

Mamun

Smith

Horstmann

et al. 2023

J. Micromech. Microeng.

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We measure the stiction force using in-plane electrostatically actuated Si nanoelectromechanical cantilever relays with Pt contacts. The average, current-dependent values of stiction force ranging from 60 nN to 265 nN were extracted using the IDS vs VGS hysteresis curves, the cantilever displacement information from finite element method (Comsol Multiphysics)simulations, and force distribution determined using an analytical model. It is shown that stiction force is inversely and directly proportional to the contact resistance (Rc) and drain-source current (IDS), respectively. Using the dependence of stiction force on contact current, we demonstrate the tuning of voltage hysteresis for a same relay from 8V to 36V (equivalent to a stiction force of 70 nN to 260 nN respectively). We attribute the stiction force primarily to the metallic bonding force which shows a strong dependence on the contact current.

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

Yıldız

Akdağlı

et al. 2016

Microsyst Technol

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A New Analytical Model to Estimate the Voltage Value and Position of the Pull-In Limit of a MEMS Cantilever

Cited by 7 publications

References 37 publications

A V-Shaped Actuator Utilizing Electrostatic Force

A V-Shaped Actuator Utilizing Electrostatic Force

Measurement and control of stiction force in in-plane electrostatically actuated Si nanoelectromechanical cantilever relays with Pt contacts

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

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