Described examples include sensor apparatus and integrated circuits having a package structure with an internal cavity and an opening that connects of the cavity with an ambient condition of an exterior of the package structure, and an electronic sensor structure mechanically supported by wires in the cavity and including a sensing surface exposed to the cavity to sense the ambient condition of an exterior of the package structure.

A MEMS device formed using the materials of the BEOL of a CMOS process where a post-processing of vHF and post backing was applied to form the MEMS device and where a total size of the MEMS device is between 50 um and 150 um. The MEMS device may be implemented as an inertial sensor among other applications.

A microelectromechanical system and a method for manufacturing a microelectromechanical system including: a substrate; a microelectromechanical device including: a diaphragm configured as a transducer to convert between electrical energy and mechanical energy and an electrode coupled to the diaphragm; a support region mechanically coupling the microelectromechanical device to the substrate, wherein the support region is confined to a first continuous region spanning an arc of less than 90 degrees around a perimeter of the diaphragm; and a second continuous region free from mechanical support of the microelectromechanical device to the substrate, the second continuous region spanning the perimeter of the diaphragm from one end of the support region to the other end of the support region; wherein the support region cantilevers the microelectromechanical device and the second continuous region mechanically decouples the microelectromechanical device from the substrate.

Stress relief structures and methods that can be applied to MEMS sensors requiring a hermetic seal and that can be simply manufactured are disclosed. The system includes a sensor having a first surface and a second surface, the second surface being disposed away from the first surface, the second surface also being disposed away from a package surface and located between the first surface and the package surface, a number of support members, each support member extending from the second surface to the package surface, the support members being disposed on and operatively connected to only a portion of the second surface. The support member are configured to reduce stress produced by package-sensor interaction.

A manufacturing method of an electronic device includes a process that forms a protective layer on at least a portion of the first base body to which a third base body is to be bonded, a process that performs first bonding of a second base body to the first base body, a process that performs a first etching of the second base body bonded by the first bonding, a process that removes the protective layer using a second etching, and a process that performs second bonding of the third base body to the first base body. In the first etching, an etching rate of the second base body is faster than those of the first base body and the protective layer, and in the second etching, an etching rate of the protective layer is faster than those of the first base body and the second base body.

A method for forming a microelectromechanical device may provide forming a first layer at least one of in or over a semiconductor carrier; forming a second layer at least one of in or over at least a central region of the first layer, such that a peripheral region of the first layer is at least partially free of the second layer; removing material under at least a central region of the second layer to release at least one of the central region of the second layer or a central region of the first layer; and/or removing material under at least the peripheral region of the first layer to such that the second layer is supported by the semiconductor carrier via the first layer.

A micro-electro-mechanical device formed in a monolithic body of semiconductor material accommodating a first buried cavity; a sensitive region above the first buried cavity; and a second buried cavity extending in the sensitive region. A decoupling trench extends from a first face of the monolithic body as far as the first buried cavity and laterally surrounds the second buried cavity. The decoupling trench separates the sensitive region from a peripheral portion of the monolithic body.

A microelectromechanical device may include: a semiconductor carrier; a microelectromechanical element disposed in a position distant to the semiconductor carrier; wherein the microelectromechanical element is configured to generate or modify an electrical signal in response to a mechanical signal and/or is configured to generate or modify a mechanical signal in response to an electrical signal; at least one contact pad, which is electrically connected to the microelectromechanical element for transferring the electrical signal between the contact pad and the microelectromechanical element; and a connection structure which extends from the semiconductor carrier to the microelectromechanical element and mechanically couples the microelectromechanical element with the semiconductor carrier.

A MEMS device, a method of making a MEMS device and a system of a MEMS device are shown. In one embodiment, a MEMS device includes a first polymer layer, a MEMS substrate disposed on the first polymer layer and a MEMS structure supported by the MEMS substrate. The MEMS device further includes a first opening disposed in the MEMS substrate and a second opening disposed in the first polymer layer.

A packaged micro-electro-mechanical system (MEMS) device (100) comprises a circuitry chip (101) attached to the pad (110) of a substrate with leads (111), and a MEMS (150) vertically attached to the chip surface by a layer (140) of low modulus silicone compound. On the chip surface, the MEMS device is surrounded by a polyimide ring (130) with a surface phobic to silicone compounds. A dome-shaped glob (160) of cured low modulus silicone material covers the MEMS and the MEMS terminal bonding wire spans (180); the glob is restricted to the chip surface area inside the polyimide ring and has a surface non-adhesive to epoxy-based molding compounds. A package (190) of polymeric molding compound encapsulates the vertical assembly of the glob embedding the MEMS, the circuitry chip, and portions of the substrate; the molding compound is non-adhering to the glob surface yet adhering to all other surfaces.