A three-axis accelerometer measures acceleration in three axes by a single movable mass block, so that a more compact design of the three-axis accelerometer can be achieved. In addition, a plurality of detection capacitors, which forms differential capacitor pairs, are arranged in symmetric configuration with respect to a rotation axis of the movable mass block for sensing functions. Therefore, during sensing motion of a target axis direction, the all other unwanted capacitance changes in other axis direction may be cancelled.

A MEMS device includes a first layer, a second layer connected to the first layer, a first mooring portion, a second mooring portion, and a MEMS device body. The MEMS device body is connected to the first mooring portion and the second mooring portion. The MEMS device body further includes a first cantilever attached to the first mooring portion, a second cantilever attached to the second mooring portion, and a spring. The spring is in operable communication with the first cantilever and the second cantilever.

A circuit includes: integrated circuit (IC) layers; a cavity formed in at least one of the IC layers; and a micro-acoustic resonator suspended in the cavity by an anchor. The anchor includes: a bridge portion coupled to the micro-acoustic resonator and extending over the cavity; a first acoustic reflector portion adjacent the bridge portion, extending over the cavity, and oriented differently than the bridge portion; and a second acoustic reflector portion adjacent the first acoustic reflector portion, extending over the cavity, and oriented differently than the first acoustic reflector portion.

MEMS based sensors, particularly capacitive sensors, potentially can address critical considerations for users including accuracy, repeatability, long-term stability, ease of calibration, resistance to chemical and physical contaminants, size, packaging, and cost effectiveness. Accordingly, it would be beneficial to exploit MEMS processes that allow for manufacturability and integration of resonator elements into cavities within the MEMS sensor that are at low pressure allowing high quality factor resonators and absolute pressure sensors to be implemented. Embodiments of the invention provide capacitive sensors and MEMS elements that can be implemented directly above silicon CMOS electronics.

A method for packaging a MEMS device includes the following steps. A metal cap is provided that is partially anchored to a wafer comprising the MEMS device where at least one point between the cap and the wafer is unanchored, the metal cap arranged to at least substantially extend over the MEMS device. An electrical contact pad is electrically coupled to the MEMS device. A sealing layer is provided over the metal cap and the wafer such that the sealing layer seals a gap between an unanchored portion of the metal cap and the wafer to encapsulate the MEMS device, where the electrical contact pad and the metal cap include the same composition.

A MEMS device includes a first layer and a second layer including a same material, a third layer disposed between the first layer and the second layer, a first air gap separating the first layer and the third layer, a second air gap separating the second layer and the third layer, a plurality of first pillars exposed to the first air gap and arranged in contact with the first layer and the third layer, a plurality of second pillars exposed to the second air gap and arranged in contact with the second layer and the third layer.

A MEMS microphone includes a cavity extending portion that increases the size of the cavity. The cavity extending portion can be sloped or stepped in order to create a desired profile of the extended cavity shape. Thus, the volume of the cavity may be increased in order to decrease the compliance and to increase a Signal to Noise Ratio.

A MEMS microphone includes a substrate defining a cavity, a diaphragm being spaced apart from the substrate, covering the cavity, and configured to generate a displacement of the diaphragm in response to an applied acoustic pressure, an anchor extending from an end portion of the diaphragm, and fixed to an upper surface of the substrate to support the diaphragm and a back plate disposed over the diaphragm, the back plate being spaced apart from the diaphragm such that an air gap is maintained between the back plate and the diaphragm, and defining a plurality of acoustic holes, wherein the anchor has a repetitive concave-convex shape in a direction toward a center of the diaphragm so that the anchor acts as a resistance to an acoustic wave.

A microelectromechanical systems (MEMS) package may include a wafer having a MEMS device; a metal cap partially anchored to the wafer where at least one point between the cap and the wafer is unanchored, the metal cap at least substantially extending over the MEMS device; an electrical contact pad electrically coupled to the MEMS device; and a sealing layer disposed over the metal cap and the wafer, such that the sealing layer seals a gap between an unanchored portion of the metal cap and the wafer to encapsulate the MEMS device; wherein the electrical contact pad and the metal cap include the same composition.

A MEMS device comprising: a semiconductor body defining a main cavity and forming an anchorage structure; and a first deformable structure having a first end and a second end that are opposite to one another along a first axis, the first deformable structure being fixed to the anchorage structure via the first end so as to be suspended over the main cavity. The second end is configured to oscillate, with respect to the anchorage structure, along a second axis. The first deformable structure comprises a main body having a first outer surface and a second outer surface, and a piezoelectric structure, which extends over the first outer surface. The main body comprises a bottom portion and a top portion that delimit along the second axis a first buried cavity aligned with the piezoelectric structure along the second axis, wherein a maximum thickness of the top portion of the main body along the second axis is smaller than a minimum thickness of the bottom portion of the main body along the second axis.