A packaged pressure sensor, comprising: a MEMS pressure-sensor chip; and an encapsulating layer of elastomeric material, in particular PDMS, which extends over the MEMS pressure-sensor chip and forms a means for transferring a force, applied on a surface thereof, towards the MEMS pressure-sensor chip.

A vibrator includes a base, a lid, and a functional element that is stored in a cavity formed by the base and the lid, in which the lid is provided with a sealing hole that penetrates through the lid and a sealing member that air-tightly seals the sealing hole, and in which the functional element includes a diffusion object shielding portion having a region of an accommodation opening which overlaps at least part of a region of a first opening of the sealing hole on a surface of the lid on the cavity side in a plan view of the functional element and the lid.

Measures are provided for increasing the resistance to compression of a component having a micromechanical microphone pattern. In particular, the robustness of the microphone pattern to highly dynamic pressure fluctuations is to be increased, without the microphone sensitivity, i.e. the microphone performance, being impaired. The microphone pattern of such a component is implemented in a layer construction on a semiconductor substrate and includes at least one acoustically active diaphragm, which spans a sound hole on the substrate backside, and a stationary acoustically penetrable counterelement having through hole openings, which is situated above/below the diaphragm in the layer construction. At least one outflow channel is developed which makes possible a rapid pressure equalization between the two sides of the diaphragm. In addition, at least one controllable closing element is provided, with which the at least one outflow channel is optionally able to be opened or closed.

A microelectromechanical system (MEMS) device package for encapsulating a MEMS device a molded package spacer that connects to a conductive lid and to a substrate. The molded package spacer forms either side walls or a divider of the MEMS device package and is adapted to route electrical connections from the MEMS device to either the substrate or a second MEMS device package via the substrate.

A vibrational sensor comprises a microelectromechanical (MEMS) microphone having a base and a lid defining an enclosure, a MEMS acoustic pressure sensor within the enclosure, and a port defining an opening through the enclosure and material that is arranged to plug the port of the MEMS microphone. In embodiments, the MEMS microphone further includes an integrated circuit within the enclosure that is electrically connected to the MEMS acoustic pressure sensor. In some embodiments, the integrated circuit is configured to bias and buffer the MEMS acoustic pressure sensor. In these and other embodiments, the integrated circuit includes circuitry for conditioning and processing electrical signals generated by the MEMS acoustic pressure sensor. In embodiments, the material is arranged with respect to the port so as to cause the MEMS acoustical pressure sensor to sense vibrational energy rather than acoustic energy as in a conventional MEMS microphone.

A packaged pressure sensor, comprising: a MEMS pressure-sensor chip; and an encapsulating layer of elastomeric material, in particular PDMS, which extends over the MEMS pressure-sensor chip and forms a means for transferring a force, applied on a surface thereof, towards the MEMS pressure-sensor chip.

The present disclosure provides a packaging method, including: providing a first semiconductor substrate; forming a bonding region on the first semiconductor substrate, wherein the bonding region of the first semiconductor substrate includes a first bonding metal layer and a second bonding metal layer; providing a second semiconductor substrate having a bonding region, wherein the bonding region of the second semiconductor substrate includes a third bonding layer; and bonding the first semiconductor substrate to the second semiconductor substrate by bringing the bonding region of the first semiconductor substrate in contact with the bonding region of the second semiconductor substrate; wherein the first and third bonding metal layers include copper (Cu), and the second bonding metal layer includes Tin (Sn). An associated packaging structure is also disclosed.

A semiconductor device having multiple MEMS (micro-electro mechanical system) devices includes a semiconductor substrate having a first MEMS device and a second MEMS device, and an encapsulation substrate having a top portion and sidewalls forming a first cavity and a second cavity. The encapsulation substrate is bonded to the semiconductor substrate at the sidewalls to encapsulate the first MEMS device in the first cavity and to encapsulate the second MEMS device in the second cavity. The second cavity includes at least one access channel at a recessed region in a sidewall of the encapsulation substrate adjacent to an interface between the encapsulation substrate and the semiconductor substrate. The access channel is covered by a thin film. The first cavity is at a first atmospheric pressure and the second cavity is at a second atmospheric pressure. The second air pressure is different from the first air pressure.

A capped micromachined device has a movable micromachined structure in a first hermetic chamber and one or more interconnections in a second hermetic chamber that is hermetically isolated from the first hermetic chamber, and a barrier layer on its cap where the cap faces the first hermetic chamber, such that the first hermetic chamber is isolated from outgassing from the cap.

In described examples, a cavity is formed between a substrate and a cap. One or more access holes are formed through the cap for removing portions of a sacrificial layer from within the cavity. A cover is supported by the cap, where the cover is for occulting the one or more access holes along a perspective. An encapsulant seals the cavity, where the encapsulant encapsulates the cover and the one or more access holes.