Title :
Controlling Levitation and Enhancing Displacement in Electrostatic Comb Drives of MEMS Actuators
Author :
Imboden, Matthias ; Morrison, Jim ; Lowell, Evan ; Han Han ; Bishop, David J.
Author_Institution :
Electr. & Comput. Eng. Dept., Boston Univ., Boston, MA, USA
Abstract :
Capacitive comb actuators are widely used as MEMS motors due to their long range of linear motion, low power consumption, and ease of fabrication. Here, we present data from a thin comb capacitive actuator where fringe fields contribute significantly to the device performance. We characterize the observed levitation effect and discuss two methods to control the out-of-plane forces: 1) by means of alternating the comb polarity; and 2) by using an additional electrode below the comb. Considering two alternative designs, it is shown how the levitation force can be mitigated. One design decreases the out-of-plane motion by a factor of two, but also reduces the lateral range. An alternative design proved successful in decreasing out-of-plane motion by 75%, while enhancing the in-plane displacement of the linear comb actuator by over 35%.
Keywords :
electrostatic actuators; MEMS actuators; MEMS motors; comb polarity; device performance; displacement enhancement; electrostatic comb drives; fringe fields; in-plane displacement; levitation control; levitation force; linear comb actuator; linear motion; out-of-plane forces; thin comb capacitive actuator; Actuators; Capacitance; Electric potential; Electrodes; Force; Levitation; Springs; Comb drive; large deflection electrostatic actuator; position control; position control.;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2014.2303898
