A MEMS self-aligned high-and-low comb tooth and manufacturing method thereof, the comb tooth having a lifting structure, the lifting structure generating a displacement in the vertical direction to drive the movement of a movable comb tooth or a fixed comb tooth attached thereto. The manufacturing method thereof adopts a silicon wafer, the lifting structure and the comb tooth are sequentially formed on a mechanical structure layer, the fixed comb tooth and the movable comb tooth are formed with the same etching process, and the stress in the lifting structure displaces the fixed comb tooth and the movable comb tooth in the vertical direction, thus forming the self-aligned high-and-low comb tooth.

A MEMS loudspeaker for generating sound waves in the audible wavelength spectrum includes a carrier substrate with a substrate cavity with two substrate openings formed on two opposite sides of the carrier substrate, and a diaphragm anchored in the substrate. An actuator structure is arranged in the region of one of the two substrate openings and configured to vibrate the diaphragm to generate sound waves. An intermediate cavity is formed in a space between the diaphragm and the actuator structure. A coupling element is disposed in the intermediate cavity and connects the actuator structure to the diaphragm and can vibrate with respect to the carrier substrate.

A microphone includes: a substrate configured to have a through hole formed at a central portion thereof; a vibration membrane disposed to cover the through hole on the substrate to include a slit pattern in which slit patterns are arranged in a plurality of lines along a circular edge thereof; a fixed membrane separately mounted at an upper portion of the vibration membrane with an air layer therebetween to have a plurality of air inlets that extend therebetween in a direction of the air layer; and a support layer configured to support the fixed membrane separately mounted on the vibration membrane.

A MEMS sound transducer for generating and/or detecting sound waves in the audible wavelength spectrum includes a membrane carrier, a membrane that is connected in its edge area to the membrane carrier, and may vibrate along a z-axis with respect to the membrane carrier, and a stopper mechanism, which limits the vibrations of the membrane in at least one direction. The stopper mechanism includes at least one reinforcing element, which is arranged on one side of the membrane, and an end stop opposite to the reinforcing element. In a neutral position of the membrane, the end stop is spaced at a distance from the membrane and against which the reinforcing element abuts at a maximum deflection. A sound transducer arrangement includes such a MEMS sound transducer.

A MEMS microphone includes a substrate (100), a supporting part (200), an upper polar plate (300) and a lower polar plate (400). The substrate (100) is provided with an opening (120) penetrating the middle thereof; the lower polar plate (400) straddles the opening (120); the supporting part (200) is fixed on the lower polar plate (400); the upper polar plate (300) is affixed to the supporting part (200); an accommodating cavity (500) is formed among the supporting part (200), the upper polar plate (300) and the lower polar plate (400); a recess (600) opposite to the accommodating cavity (500) is arranged in an intermediate region of at least one of the upper polar plate (300) and the lower polar plate (400), and insulation is achieved between the upper polar plate (300) and a lower polar plate (400).

An ultrasonic transducer element includes a substrate, a lower electrode on a first surface of the substrate, a first insulating film on the lower electrode, a first cavity layer on the first insulating film, a second insulating film on the first cavity layer, an upper electrode on the second insulating film that overlaps the first cavity layer, a third insulating film on the upper electrode, a second cavity layer on the third insulating film, a fourth insulating film on the second cavity layer, a fixing portion formed by the second to fourth insulating films, a movable portion in a membrane insides the second cavity layer, a first connection portion and a second connection portion that are stacked with a gap and the connection portions are configured by the second to fourth insulating films connecting the movable portion and the fixing portion.

The invention relates to a MEMS loudspeaker (1) for generating sound waves in the audible wavelength spectrum, with a carrier substrate (2) that features a substrate cavity (6) with two substrate openings (7, 8), which are formed on two opposite sides of the carrier substrate (2), an actuator structure (3), in particular a piezoelectric actuator structure, which is arranged in the area of one of the two substrate openings (7, 8) and is connected to the carrier substrate (2) in its edge area, and a membrane (4) anchored in its edge area, which, by means of the actuator structure (3), can be set into vibration for generating sound waves. In accordance with the invention, in a cross-sectional view of the MEMS loudspeaker (1), the membrane (4) is spaced at a distance from the actuator structure (3), such that an intermediate cavity (13) is formed between these two. Furthermore, the MEMS loudspeaker (1) features a coupling element (13) arranged in the intermediate cavity (13), which connects the actuator structure (3) to the membrane (4) and may vibrate with this with respect to the carrier substrate (2).

A MEMS sensor, in particular a microphone, of a piezoelectric type, formed in a membrane of semiconductor material accommodating a compliant portion, which extends from a first surface to a second surface of the membrane. The compliant portion has a Young's modulus lower than the rest of the membrane. A sensitive region having piezoelectric material extends on the first surface, over the compliant portion and is fixed at its ends to the membrane on opposite sides of the compliant portion. A third area of the membrane, arranged between the compliant portion and the second surface, forms a hinge element.

In some examples, a method of fabricating a transducer includes disposing a plurality of anchors on a substrate and disposing a sealing material and a device layer over the anchors and the substrate to form a cavity, the sealing material sealing the cavity. The method may further include forming, in the device layer, a plate and at least one spring member. The at least one spring member may be supported by at least one anchor of the plurality of anchors, and the at least one spring member may support the plate to allow relative movement between the plate and the substrate.

Microelectromechanical systems (MEMS) devices are described that include a proof mass movably connected to a substrate by accordion springs disposed on opposite sides of the proof mass, with a coupler coupling two of the accordion springs together. The coupler is a bar in some implementations, and may be rigid. The coupler therefore restricts the motion of the accordion springs relative to each other. In this manner, the motion of the proof mass may be restricted to preferred types and frequencies.