A semiconductor device includes a semiconductor chip including a substrate and a MEMS element, wherein the substrate includes a surface, and wherein the MEMS element is disposed at the surface of the substrate and the MEMS element includes a sensitive area; a first electrical interconnect structure electrically connected to the surface of the substrate; a carrier electrically connected to the first electrical interconnect structure; and a first stress relieve spring entrenched in the carrier, wherein the first stress relieve spring is a single integral channel that comprises two parallel channels that join together at a periphery of the first electrical interconnect structure to form the single integral channel that wraps around a portion of the periphery of the first electrical interconnect structure, wherein the two parallel channels extend outward, in parallel, from the periphery of the first electrical interconnect structure to a first termination region of the carrier.

Electronic packages and related methods are disclosed. An example electronic package apparatus includes a substrate and an electronic component. A protective material is positioned on a first surface, a second surface and all side surfaces of the electronic component to encase the electronic component. An enclosure is coupled to the substrate to cover the protective material and the electronic component.

A micromechanical sensor is described that includes: a substrate; a first functional layer that is situated on the substrate; a second functional layer that is situated on the first functional layer and that includes movable micromechanical structures; a cavity in the substrate that is situated below the movable mechanical structures; and a vertical trench structure that surrounds the movable micromechanical structures of the second functional layer and extends into the substrate down to the cavity.

A sensor package including a fixed frame, a moveable platform, elastic restoring members and a sensor chip is provided. The moveable platform is moved with respect to the fixed frame, and used to carry the sensor chip. The elastic restoring members are connected between the fixed frame and the moveable platform, and used to restore the moved moveable platform to an original position. The sensor chip is arranged on the elastic restoring members to send detected data via the elastic restoring members.

A system includes a pressure sensor combined with a MEMS microphone. The pressure sensor and the MEMS microphone arranged side by side are formed on a same substrate.

A physical quantity sensor includes a substrate, an acceleration sensor mounted on the substrate, an integrated circuit mounted on the substrate and stacked with the acceleration sensor, and serial communication wirings provided to the substrate. In a plan view of the acceleration sensor element, a bonding wire connecting the acceleration sensor element to the integrated circuit is disposed on an opposite side to the serial communication wirings with respect to a virtual central line of the acceleration sensor element.

A semiconductor device and a method of manufacturing the same are provided. The semiconductor device includes a substrate having a first surface and a second surface arranged opposite to the first surface; a stress-sensitive sensor disposed at the first surface of the substrate, where the stress-sensitive sensor is sensitive to mechanical stress; a stress-decoupling trench that has a vertical extension that extends from the first surface into the substrate, where the stress-decoupling trench vertically extends partially into the substrate towards the second surface although not completely to the second surface; and a plurality of particle filter trenches that vertically extend from the second surface into the substrate, wherein each of the plurality of particle filter trenches have a longitudinal extension that extends orthogonal to the vertical extension of the stress-decoupling trench.

A semiconductor device includes a semiconductor chip including a substrate having a first surface and a second surface arranged opposite to the first surface; and a microelectromechanical systems (MEMS) element, including a sensitive area, disposed at the first surface of the substrate. The semiconductor device further includes at least one electrical interconnect structure electrically connected to the first surface of the substrate, and a flexible carrier electrically connected to the at least one electrical interconnect structure, where the flexible carrier wraps around the semiconductor chip and extends over the second surface of the substrate such that a folded cavity is formed around the semiconductor chip.

A micromechanical pressure sensor device and a corresponding manufacturing method. The micromechanical pressure sensor device is equipped with a sensor substrate; a diaphragm system that is anchored in the sensor substrate and that includes a first diaphragm and a second diaphragm situated spaced apart therefrom, which are circumferentially connected to one another in an edge area and enclose a reference pressure in an interior space formed in between; and a plate-shaped electrode that is suspended in the interior space and that is situated spaced apart from the first diaphragm and from the second diaphragm and forms a first capacitor with the first diaphragm and forms a second capacitor with the second diaphragm. The first diaphragm and the second diaphragm are designed in such a way that they are deformable toward one another when acted on by an external pressure.

A device includes a substrate having first and second layers and an insulator layer between the first and second layers. A microelectromechanical system (MEMS) structure is provide on a portion of the second layer. A trench is formed in the second layer and around at least a part of a periphery of the portion of the second layer. An undercut is formed in the insulator layer and adjacent to the portion of the second layer. The undercut separates the portion of the second layer from the first layer. First and second pinholes extend from a plane of the insulator layer and in the first layer. The first and second pinholes are in fluid communication with the undercut and the trench.