Representative methods for sealing MEMS devices include depositing insulating material over a substrate, forming conductive vias in a first set of layers of the insulating material, and forming metal structures in a second set of layers of the insulating material. The first and second sets of layers are interleaved in alternation. A dummy insulating layer is provided as an upper-most layer of the first set of layers. Portions of the first and second set of layers are etched to form void regions in the insulating material. A conductive pad is formed on and in a top surface of the insulating material. The void regions are sealed with an encapsulating structure. At least a portion of the encapsulating structure is laterally adjacent the dummy insulating layer, and above a top surface of the conductive pad. An etch is performed to remove at least a portion of the dummy insulating layer.

A complementary metal oxide semiconductor (CMOS) device embedded with micro-electro-mechanical system (MEMS) components in a MEMS region is disclosed. The MEMS components, for example, are infrared (IR) thermosensors. The MEMS sensors are integrated on the CMOS device monolithically after CMOS processing. For example, the MEMS sensors are formed over a BEOL dielectric of a CMOS device. The device is encapsulated with a CMOS compatible IR transparent cap to hermetically seal the MEMS sensors in the MEMS region.

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.

This application describes methods and apparatus relating to packaging of MEMS transducers and to MEMS transducer packages. The application describes a MEMS transducer package (300) having a first integrated circuit die (200) which has an integrated MEMS transducer (202) and integrated electronic circuitry (203) for operation of the MEMS transducer. The package is arranged such that the footprint of the MEMS transducer package is substantially the same size as the footprint of the integrated circuit die. At least part of the first integrated circuit die (200) may form a sidewall of the package. The package may be formed by a first package cover (302) which overlies the MEMS transducer and a second package cover (301) on the other side of the first integrated circuit die.

Disclosed is a semiconductor device comprising a stack of patterned metal layers separated by dielectric layers, the stack comprising a first conductive support structure and a second conductive support structure and a cavity in which an inertial mass element comprising at least one metal portion is conductively coupled to the first support structure and the second support structure by respective conductive connection portions, at least one of said conductive connection portions being designed to break upon the inertial mass element being exposed to an acceleration force exceeding a threshold defined by the dimensions of the conductive connection portions. A method of manufacturing such a semiconductor device is also disclosed.

In a semiconductor pressure sensor, a fixed electrode is formed as the same layer as a diffusion layer formed to extend from a surface of a semiconductor substrate to inside of the semiconductor substrate. A void is formed by removing a sacrifice film, which is a region constituted of the same film as a floating gate electrode. A movable electrode includes an anchor portion which supports the movable electrode via the void relative to the fixed electrode and in which the sacrifice film is at least partially opened. The anchor portion has a first anchor provided to divide the movable electrode into a plurality of movable electrode units when viewed in a plan view such that one pair of adjacent movable electrode units of the plurality of movable electrode units divided share the same first anchor.

An integrated circuit includes a mechanical device for detection of spatial orientation and/or of change in orientation of the integrated circuit. The device is formed in the BEOL and includes an accommodation whose sides include metal portions formed within various metallization levels. A mobile metal component is accommodated within the accommodation. A monitor inside the accommodation defines a displacement area for the metal component and includes electrically conductive elements disposed at the periphery of the displacement area. The component is configured so as to, under the action of the gravity, come into contact with the two electrically conductive elements in response to a given spatial orientation of the integrated circuit. A detector is configured to detect an electrical link passing through the component and the electrically conductive elements.

This application describes methods and apparatus relating to packaging of MEMS transducers and to MEMS transducer packages. The application describes a MEMS transducer package (300) having a first integrated circuit die (200) which has an integrated MEMS transducer (202) and integrated electronic circuitry (203) for operation of the MEMS transducer. The package is arranged such that the footprint of the MEMS transducer package is substantially the same size as the footprint of the integrated circuit die. At least part of the first integrated circuit die (200) may form a sidewall of the package. The package may be formed by a first package cover (302) which overlies the MEMS transducer and a second package cover (301) on the other side of the first integrated circuit die.

A die is manufactured using complementary metal-oxide semiconductor (CMOS) techniques to create transistors, electrical pathways, and microelectromechanical system (MEMS) structures. The MEMS structures include springs, plates, mechanical stops, and structural supports, which can be combined to form complex MEMS structures including microphones, pressure sensors, accelerometers, resonators, gyroscopes, and the like.