A microelectromechanical device, in particular a non-volatile memory module or a relay, comprising: a mobile body including a top region and a bottom region; top electrodes facing the top region; and bottom electrodes, facing the bottom region. The mobile body is, in a resting condition, at a distance from the electrodes. The latter can be biased for generating a movement of the mobile body for causing a direct contact of the top region with the top electrodes and, in a different operating condition, a direct contact of the bottom region with the bottom electrodes. In the absence of biasing, molecular-attraction forces maintain in stable mutual contact the top region and the top electrodes or, alternatively, the bottom region and the bottom electrodes.

A temperature sensor is a temperature sensor using a MEMS resonator, and includes: a MEMS resonator; a sweeper that sweeps a frequency of an excitation signal for a vibrator of the MEMS resonator in a predetermined sweep direction, and outputs the excitation signal swept to the MEMS resonator; a discontinuity point detector that obtains a vibration state information signal, which is a characteristic quantity expressing a vibration state of the vibrator based on the excitation signal, from the MEMS resonator, and detects a detection value that is (i) a frequency of the excitation signal when the vibration state information signal obtained changes discontinuously or (ii) a time corresponding to the frequency; and a converter that determines a physical quantity acting on the MEMS resonator based on the detection value detected.

A piezoelectric sensor (e.g., for use in a piezoelectric MEMS microphone) includes a substrate and a cantilever beam attached to the substrate. The cantilever beam has a proximal portion attached to the substrate and extending to an unsupported distal end. An electrode is disposed on or in the proximal portion of the beam and has an outer boundary with a shape substantially corresponding to a contour line of a strain distribution plot for the cantilever beam resulting from a force applied to the cantilever beam.

Microelectromechanical system (MEMS) devices, methods of operating the MEMS device, and methods of manufacturing the MEMS device are disclosed. In some embodiments, the MEMS device includes a glass substrate; an electrode on the glass substrate; a hinge mechanically coupled to the electrode; a membrane mirror mechanically coupled to the hinge; a TFT on the glass substrate and electrically coupled to the electrode; and a control circuit comprising: a multiplexer configured to turn on or turn off the TFT; and a drive source configured to provide a drive signal for charging the electrode through the TFT. An amplitude of the drive signal corresponds to an amount of charge, and the amount of charge generates an electrostatic force for actuating the hinge and a portion of the membrane mirror mechanically coupled to the hinge. In some embodiments, the MEMS devices comprise a charge transfer circuit for providing the amount of charge.

A MEMS AE transducer system is provided that takes advantage of the low power consumption and lightweight characteristics of MEMS AE transducers, while also achieving higher sensing sensitivity. To address the problem of low sensitivity typically associated with MEMS AE transducers, electrical responses of multiple MEMS AE transducers operating at different frequency ranges are combined to increase the bandwidth and sensitivity of the MEMS AE transducer system. As the frequencies are constructive, the combined response on a single channel is the actual summation of two signals with an improved signal to noise ratio. Additionally, each frequency can be decomposed because they are well separated from each other due to the super narrowband response and high Quality factor of MEMS AE transducers.

A micro electro mechanical system (MEMS) device and a method for manufacturing the same are provided. The MEMS device includes a substrate, a polymer film on the substrate and having a lower surface facing toward the substrate, a cavity passing through the substrate, and coil structures on the substrate and in the polymer film. The polymer film includes a corrugation pattern on the lower surface of the polymer film. A portion of the polymer film is exposed in the cavity.

A microphone includes a microelectromechanical system (MEMS) device responsive to sound waves or vibrations having an output coupled to a first node; a programmable gain amplifier or source follower having an input coupled to a second node, and an output for generating an analog signal, wherein the MEMS device output and the programmable gain amplifier or source follower input comprise a first nonlinear equivalent capacitance having a first capacitance-to-voltage (CV) profile; and a nonlinear capacitance component coupled to the first node, the second node, and at least one reference voltage node, wherein the nonlinear capacitance component comprises a second nonlinear equivalent capacitance having a second CV profile.

A method for manufacturing a micro electro mechanical system (MEMS) device is provided. The method includes: providing a substrate; forming coil structures on the substrate; forming a dielectric layer on the substrate and the coil structures; removing a first portion of the dielectric layer to form a sacrificing corrugation pattern adjacent to the coil structures; forming a polymer film on the dielectric layer, wherein the polymer film covers the sacrificing corrugation pattern of the dielectric layer.

Disclosed is an opto-electronic module including a first substrate, a photonic integrated circuit (PIC) attached to the first substrate, a laser assembly attached to the first substrate, and a microelectromechanical systems (MEMS) micro-mirror device positioned between the laser and the waveguide. The PIC comprising a waveguide. The laser assembly is configured to generate a laser beam to optically couple to the waveguide. The laser assembly includes a thermal electric cooler (TEC) and a laser thermally coupled to the TEC. The MEMS micro-mirror device comprising an actuatable MEMS mirror and a fixed mirror.

A microelectromechanical component. The microelectromechanical component includes a substrate with a substrate surface, a mass that is movable relative to the substrate surface, and a stop spring arranged between the substrate and the movable mass, wherein the stop spring extends from a mechanical anchor in a cantilevered manner parallel to the substrate surface, and wherein the stop spring has a decreasing width along its longitudinal extension from the mechanical anchor to a free end of the stop spring. A microelectromechanical inertial sensor having such a microelectromechanical component, is also described.