A waterproofed environmental sensing device with water detection provisions includes an environmental sensor to sense one or more environmental properties. The device further includes an electronic integrated circuit implemented on a substrate and coupled to the environmental sensor via a wire bonding. An air-permeable cap structure is formed over the environmental sensor, and a protective layer is formed over the wire bonding to protect the wire bonding against damage.

A method includes: providing a first substrate on which a plurality of first semiconductor devices is formed; providing a second substrate on which a plurality of second semiconductor devices is formed; and coupling the first and second substrates by contacting respective dummy pads of the first and second substrates, wherein at least one of the dummy pads of the first and second substrates comprises plural peaks and valleys.

A microphone assembly includes an acoustic transducer having a back plate and a diaphragm, such that a surface of the back plate includes a plurality of holes. At least a portion of the plurality of holes are arranged in a non-uniform pattern. The non-uniform pattern includes holes of varying sizes spaced apart from neighboring holes by varying distances. The microphone assembly further includes an audio signal electrical circuit configured to receive an acoustic signal from the acoustic transducer.

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.

An embodiment as described herein includes a microelectromechanical system (MEMS) with a first MEMS transducer element, a second MEMS transducer element, and a semiconductor substrate. The first and second MEMS transducer elements are disposed at a top surface of the semiconductor substrate and the semiconductor substrate includes a shared cavity acoustically coupled to the first and second MEMS transducer elements.

A waterproofed environmental sensing device with water detection provisions includes an environmental sensor to sense one or more environmental properties. The device further includes an electronic integrated circuit implemented on a substrate and coupled to the environmental sensor via a wire bonding. An air-permeable cap structure is formed over the environmental sensor, and a protective layer is formed over the wire bonding to protect the wire bonding against damage.

An integrated MEMS electronic circuit that comprises a circuit wafer; a micromechanical structure being attached to a first surface of the circuit wafer and electrically coupled to an integrated circuit formed under said first surface. A capping chip having side surfaces substantially perpendicular to its main surfaces comprises a recess and is bonded to the first surface of the circuit wafer such that said micromechanical structure is enclosed in a cavity comprising the recess in the capping chip. Both the circuit wafer and the capping wafer can be further thinned while exposing at least one connection pad on the first surface of the circuit wafer that is not covered by the capping chip and that is coupled electrically to the integrated circuit.

The present disclosure relates to a packaging process to enhance performance of a wafer-level package. The disclosed package includes multiple mold compounds, a multilayer redistribution structure, and a thinned die with a device layer and die bumps underneath the device layer. The multilayer redistribution structure includes package contacts at a bottom of the multilayer redistribution structure and redistribution interconnects connecting the die bumps to the package contacts. A first mold compound resides around the thinned die to encapsulate sidewalls of the thinned die, and extends beyond a top surface of the thinned die to define an opening over the thinned die. A second mold compound resides between the multilayer redistribution structure and the first mold compound to encapsulate a bottom surface of the device layer and each die bump. A third mold compound fills the opening and is in contact with the top surface of the thinned die.

This application relates to the field of semiconductor technologies, and discloses a test structure and a manufacturing method therefor. Forms of the method may include: providing a top wafer structure, where the top wafer structure includes a top wafer and multiple first pads that are spaced from each other at a bottom of the top wafer; providing a bottom wafer structure, where the bottom wafer structure includes a bottom wafer and multiple second pads that are spaced from each other at a top of the bottom wafer, where a side surface of at least one of two adjacent second pads has an insulation layer; bonding the multiple first pads with the multiple second pads in a eutectic bonding manner, where each first pad is bonded with a second pad, to form multiple pads. This application may mitigate a problem that bonded pads are connected to each other.

A MEMS device includes a substrate, a MEMS element portion disposed on a surface of the substrate, a cap having a cavity formed to oppose the MEMS element portion, and a diffusion prevention layer formed on at least a portion of the cap, wherein at least one of the cap and the substrate includes a bonding layer disposed outside of the cavity, and wherein the cap includes a spreading prevention portion disposed between the bonding layer and the cavity and having a V-shape in cross-section.