The MEMS actuator is formed by a substrate, which surrounds a cavity; by a deformable structure suspended on the cavity; by an actuation structure formed by a first piezoelectric region of a first piezoelectric material, supported by the deformable structure and configured to cause a deformation of the deformable structure; and by a detection structure formed by a second piezoelectric region of a second piezoelectric material, supported by the deformable structure and configured to detect the deformation of the deformable structure.

The invention provides a method for preparing a MEMS conductive part and a conductive coating. A conductive unit includes a fixed member, a moving member which can reciprocate relative to the fixed member, and a plurality of groups of conductive electroplating layers which are electrically connected with the moving member and the fixed member, the moving member includes a first wall and a second wall connected with the first wall, and the fixed member includes a first wall connected with the first wall. The end components (fixed and moving components) displace relatively freely and transmit electric signals at the same time.

A chip package includes a first chip, a second chip, a first molding compound, and a first distribution line. The second chip vertically or laterally overlaps the first chip. The second chip has a conductive pad. The first molding compound covers the first and second chips, and surrounds the second chip. The first molding compound has a first through hole. The conductive pad is in the first through hole. The first distribution line is located on a surface of the first molding compound facing away from the second chip, and electrically connects the conductive pad in the first through hole.

There is provided a micro-electromechanical system (MEMS) device (102, 200, 300, 404) for cancelling noise generated by oscillation of a movable micro-electromechanical system (MEMS) element (104, 204, 304, 406). The micro-electromechanical system (MEMS) device (102, 200, 300, 404) includes the movable micro-electromechanical system (MEMS) element (104, 204, 304, 406), an actuator (106, 208, 306, 408), a controller (108, 410) and a movable noise cancelling element (110, 202, 312, 412). The controller (108, 410) provides electrical signals to drive the actuator (106, 208, 306, 408) and the movable noise cancelling element (110, 202, 312, 412) in a way to cancel the noise generated in the micro-electromechanical system (MEMS) device (102, 200, 300, 404) by oscillation of the movable MEMS element (104, 204, 304, 406). The movable noise-cancelling element (110, 202, 312, 412) produces anti-phase noise based on the electrical signals received from the controller (108, 410) to cancel noise caused by oscillation of the movable MEMS element (104, 204, 304, 406) based on the control signals received from the controller (108, 410).

Some embodiments of a device comprise an image-forming medium and one or more sensors that are attached to the image-forming medium. Also, in some embodiments, the image-forming medium is paper or a medium that has paper-like characteristics, at least some of the one or more sensors are microelectromechanical systems (MEMS), or the one or more sensors are configured to be powered by wireless power transfer. And some embodiments of the device further comprise a system-on-a-chip that is in communication with the one or more sensors, a transceiver that is in communication with the system-on-a-chip, or a radio-frequency identification (RFID) tag.

A microelectromechanical device includes a support structure, a microelectromechanical system die, incorporating a microstructure and a connection structure between the microelectromechanical system die and the support structure. The connection structure includes a spacer structure, joined to the support structure, and a film applied to one face of the spacer structure opposite to the support structure. The spacer structure laterally delimits at least in part a cavity and the film extends on the cavity, at a distance from the support structure. The microelectromechanical system die is joined to the film on the cavity.

A method of operating a MEMS device includes generating a MEMS drive signal, and generating and modifying the MEMS drive signal based upon a control signal to produce a modified drive signal. The method further includes generating the control signal by determining when a feedback signal from the MEMS device is at its peak value, comparing the peak value to a desired value when the feedback signal is as its peak, and generating the control signal depending upon whether the peak value is at least equal to a desired value. The modification of the MEMS drive signal based upon the control signal to produce the modified drive signal includes skipping generation of a next pulse of the modified drive signal when the control signal indicates the peak value is at least equal to the desired value.

The present disclosure relates to a system for detecting movement of a microelectromechanical system (MEMS) device. The system uses a drive voltage signal source for generating a low frequency drive voltage signal for driving the MEMS device. An excitation signal source may be used for generating an excitation signal which is also applied to the MEMS device. The excitation signal has a frequency which is above a physical response capability of the MEMS device, such that operation of the MEMS device is not significantly affected by the excitation signal. A sensing impedance is used to help generate a signal which is responsive to the capacitance of the MEMS device. The capacitance of the MEMS device changes in response to movement of the MEMS device. An output subsystem is provided which responds to changes sensed by the sensing impedance, and which produces an output voltage signal. A filter filters the output voltage signal to produce a filtered output voltage signal. The filtered output voltage signal is indicative of a position of the MEMS device.

The configuring of a micromirror to suppress a resonance of the micromirror. As part of the configuring process, the micromirror is subjected to multiple actuation frequencies, and the micromirror response is measured in response to at least some of these actuation frequencies. A resonant frequency of the micromirror is then determined using at least some of the measured mechanical responses. Then, depending on this determined resonant frequency of the micromirror, notch filter parameters are selected. There is more than one possibility for notch filter parameters, where the selected possibility depends on the determined resonant frequency. The notch filter is then configured with the selected notch filter parameters.

A MEMS vibration sensor includes a membrane having an inertial mass, the membrane being affixed to a holder of the MEMS vibration sensor; and a segmented backplate spaced apart from the membrane, the segmented backplate being affixed to the holder.