The present invention disclosed a CMOS sensing component, a CMOS single chip and a method of manufacturing the same. The CMOS single chip comprises a movable film, at least one support pillar, a base metal layer and a circuit integration. The movable film is disposed on a top layer of the CMOS single chip and has a plurality of through-vias. The support pillar is disposed under the movable film to provide a supporting force of the movable film. The base metal layer is formed under the support pillars and isolated from the support pillars, and faces towards the movable film to form a micro capacitor to sense one of the outside sensing signals, the area of the base metal layer larger than the area of the movable film. The circuit integration is formed under the base metal layer, or formed under the base metal layer and on the side of the movable film, and connected to the movable film and the base metal layer, to provide operation voltages to the movable film and the base metal layer, and to receive the outside sensing signal generated sensed by the movable film and the base metal layer and convert the outside sensing signal into an output signal.

The present invention disclosed a micro acoustic collector and CMOS microphone single chip. The micro acoustic collector comprising: a plurality of leaf-shaped structures annularly arranged with symmetry, each of the plurality of leaf-shaped structure having a suspended arm and a restrained arm, and the suspended arm of the plurality of leaf-shaped structures connected to a suspended fulcrum, and a plurality of through-vias formed in the suspended fulcrum and the plurality of leaf-shaped structures; a plurality of support pillars uniformly disposed under edges of the plurality of leaf-shaped structures corresponding to the restrained arms and the suspend arms; and a base metal layer formed under and insulated from the plurality of support pillars, and facing towards the inner-annular-supported acoustic collection film to form a hollow space.

Micro-electromagnetically actuated latched miniature relay switches formed from laminate layers comprising a spring and magnet, electromagnetic coils, magnetic latching material, and transmission line with contacts. Preferably the miniature relay switches transmit up to about 50 W of DC or AC line power, and carry up to about 10 A of load current, with an overall volume of less than about 100 mm.sup.3. In addition to switching large power, the device preferably requires less than 3 V to actuate, and has a latching feature that retains the switch state after actuation without the need for external applied voltage or current.

A micromirror device including a drive unit, which includes a movable drive element, which is situated in a first plane, and a guiding device, and a mirror, which is elastically coupled to the drive element and is situated in the idle position in a second plane, which is in parallel to the first plane, the guiding device being designed to guide a movement of the drive element on a straight line situated in the first plane. Furthermore, a corresponding projection device is described.

A microelectronic component arrangement includes a sensor and a carrier. The sensor has a detection surface and a region including contact elements situated at a first distance with respect to one another. The carrier includes a mounting surface, and the sensor is fixed on the carrier by the contact elements situated at a first distance with respect to one another at least regionally. The detection surface is opposite the mounting surface in a manner having a second distance with respect to the mounting surface. The contact elements are wetted by a mechanically stabilizing material, the region including the contact elements is enclosed by the mechanically stabilizing material, and the detection surface is free of the mechanically stabilizing material.

Micro-electromagnetically actuated latched miniature relay switches formed from laminate layers comprising a spring and magnet, electromagnetic coils, magnetic latching material, and transmission line with contacts. Preferably the miniature relay switches transmit up to about 50 W of DC or AC line power, and carry up to about 10 A of load current, with an overall volume of less than about 100 mm.sup.3. In addition to switching large power, the device preferably requires less than 3 V to actuate, and has a latching feature that retains the switch state after actuation without the need for external applied voltage or current.

A micro-electro-mechanical systems (MEMS) die includes a piston; an electrode facing the piston, wherein a capacitance between the piston and the electrode changes as the distance between the piston and the electrode changes; and a resilient structure (e.g., a gasket or a pleated wall) disposed between the piston and the electrode, wherein the resilient structure supports the piston and resists the movement of the piston with respect to the electrode. A back volume is bounded by the piston and the resilient structure and the resilient structure blocks air from leaving the back volume. The piston may be a rigid body made of a conductive material, such as metal or a doped semiconductor. The MEMS die may also include a second resilient structure, which provides further support to the piston and is disposed within the back volume.

The present disclosure includes structures and methods of forming structures for restricting out-of-plane travel. One example of forming such structures includes providing a first wafer 100, 220 comprising a bond layer of a particular thickness 101, 221 on a surface of a substrate material 105, 225, removing the bond layer 101, 221 in a first area 103-1, 103-2, 223 to expose the surface of the substrate material 105, 225, applying a mask to at least a portion of a remaining bond layer 109-1, 109-4, 229-1, 229-3 and a portion of the exposed surface of the substrate material in the first area 109-2, 109-3, 229-2 to form a second area exposed on the surface of the substrate material 105, 225, etching the second area to form a cavity 110, 230 in the substrate material 105, 225 and the bond layer 101, 221, and forming by the etching, in the cavity 110, 230, a structure 113-1, 113-2, 233 for restricting out-of-plane travel, where the structure 113-1, 113-2, 233 has a particular height from a bottom of the cavity 115, 235 determined by the particular thickness of the bond layer 101, 221.

A device includes a carrier having a plurality of cavities, a micro-electro-mechanical system (MEMS) substrate bonded on the carrier, wherein the MEMS substrate comprises a first side bonded on the carrier, a moving element over a bottom electrode, wherein the bottom electrode is formed of polysilicon and a second side having a plurality of bonding pads and a semiconductor substrate bonded on the MEMS substrate, wherein the semiconductor substrate comprises a top electrode and the first moving element is between the top electrode and the bottom electrode.

An electroacoustic transducer includes a diaphragm, a diaphragm support connected to a part of the diaphragm in a direction of vibration of the diaphragm, a driver connected to the diaphragm support to vibrate the diaphragm, a driver support connected to the driver opposite to the diaphragm to support a part of the driver, a base connected to the driver support and having a larger area than the diaphragm, and a frame connected to the base from a same side as the driver support and disposed within a gap between an outside of the diaphragm and an outside of the driver.