Abstract: A sensor for parallel measurement of pressure and acceleration of a vehicle, including a substrate, a sensor element disposed on the substrate, a material being connected with the sensor element and being exposed to the environment of the sensor, wherein the material is configured to act as a seismic mass, and an electronic circuitry connected with the sensor element and including a first filter and a second filter, wherein the first and second filters have different filter characteristics so that an output of the first filter is representative for the pressure and an output of the second is representative for the acceleration.

Abstract: A differential gas sensor includes a first sensor component to selectively detect a first gas present in the environment and to supply a first output signal, a second sensor component configured to supply a second output signal, and a circuit configured to determine a difference between the first output signal and the second output signal.

Abstract: A sensor system with a first semiconductor die part and with a second semiconductor die part is proposed, wherein the first semiconductor die part has a microelectromechanical sensor element, wherein the second semiconductor die part covers the microelectromechanical sensor element, wherein the second semiconductor die part has a via for electrically contacting the microelectromechanical sensor element, in particular directly. A method for producing a sensor system is also proposed.

Abstract: A method of producing a semiconductor component includes: providing a silicon-based substrate; depositing an oxide layer on the silicon-based substrate; depositing a polycrystalline silicon layer on the oxide layer and simultaneously a crystalline silicon layer on the silicon-based substrate; producing an electronic component based on the polycrystalline silicon layer; and mounting a glass- or silicon-based lid on the crystalline silicon layer.

Abstract: In some implementations a semiconductor die comprises a semiconductor chip. The semiconductor chip comprises a piezoresistive pressure sensor element and at least one capacitive acceleration sensor element. The piezoresistive pressure sensor element is arranged to the side of the capacitive acceleration sensor element. In some implementations, a method for producing a semiconductor die includes applying an insulation layer to the semiconductor wafer. A section of the monocrystalline cover layer may be exposed by structuring the insulation layer. A semiconductor layer having a monocrystalline section and a polycrystalline section may be generated by deposition of a semiconductor material.

Abstract: A semiconductor die is proposed, wherein the semiconductor die comprises a microelectronic section and a sensor section. The microelectronic section comprises an integrated circuit. The sensor section adjoins an edge of the semiconductor die. A sensor is also proposed, which comprises such a semiconductor die.

Abstract: A micro-electro-mechanical sensor comprises a first substrate comprising an element movable with respect to the first substrate and a second substrate comprising a first contact pad and a second contact pad. The first substrate is bonded to the second substrate such that a movement of the element changes a coupling between the first contact pad and the second contact pad.

Abstract: Techniques are discloses regarding methods of manufacturing an imager as well as an imager device.

Abstract: A semiconductor device and a method of manufacturing the same are provided. The semiconductor device includes a semiconductor chip including a substrate having a first surface and a second surface arranged opposite to the first surface; at least one stress-decoupling trench that extends from the first surface into the substrate, where the at least one stress-decoupling trench extends partially into the substrate towards the second surface although not completely to the second surface; a microelectromechanical systems (MEMS) element, including a sensitive area, disposed at the first surface of the substrate and laterally spaced from the at least one stress-decoupling trench; and a stress-decoupling material that fills the at least one stress-decoupling trench and covers the sensitive area of the MEMS element.

Abstract: Techniques are discloses regarding methods of manufacturing an imager as well as an imager device.

Abstract: A semiconductor device and a method of manufacturing the same are provided. The semiconductor device includes a semiconductor chip including a substrate having a first surface and a second surface arranged opposite to the first surface; at least one stress-decoupling trench that extends from the first surface into the substrate, where the at least one stress-decoupling trench extends partially into the substrate towards the second surface although not completely to the second surface; a microelectromechanical systems (MEMS) element, including a sensitive area, disposed at the first surface of the substrate and laterally spaced from the at least one stress-decoupling trench; and a stress-decoupling material that fills the at least one stress-decoupling trench and covers the sensitive area of the MEMS element.

Abstract: A semiconductor element includes a processed substrate arrangement including a processed semiconductor substrate and a metallization layer arrangement on a main surface of the processed semiconductor substrate. The semiconductor element further includes a passivation layer arranged at an outer border of the processed substrate arrangement.

Abstract: Embodiments related to controlling of photo-generated charge carriers are described and depicted. At least one embodiment provides a semiconductor substrate comprising a photo-conversion region to convert light into photo-generated charge carriers; a region to accumulate the photo-generated charge carriers; a control electrode structure including a plurality of control electrodes to generate a potential distribution such that the photo-generated carriers are guided towards the region to accumulate the photo-generated charge carriers based on signals applied to the control electrode structure; a non-uniform doping profile in the semiconductor substrate to generate an electric field with vertical field vector components in at least a part of the photo-conversion region.

Abstract: Techniques are discloses regarding methods of manufacturing an imager as well as an imager device.

Abstract: Various acceleration sensors are disclosed. In some cases, an inertial mass may be formed during back-end-of-line (BEOL). In other cases, a membrane may have a bent, undulated or winded shape. In yet other embodiments, an inertial mass may span two or more pressure sensing structures.

Abstract: Techniques are discloses regarding methods of manufacturing an imager as well as an imager device.

Abstract: A micro-electro-mechanical sensor comprises a first substrate comprising an element movable with respect to the first substrate and a second substrate comprising a first contact pad and a second contact pad. The first substrate is bonded to the second substrate such that a movement of the element changes a coupling between the first contact pad and the second contact pad.

Abstract: Embodiments related to a method of manufacturing of an imager and an imager device are shown and depicted.

Abstract: In accordance with an embodiment of the present invention, a semiconductor device includes a semiconductor chip having a first side and an opposite second side, and a chip contact pad disposed on the first side of the semiconductor chip. A dielectric liner is disposed over the semiconductor chip. The dielectric liner includes a plurality of openings over the chip contact pad. A interconnect contacts the semiconductor chip through the plurality of openings at the chip contact pad.

Abstract: According to various embodiments, an electrode may include at least one layer including a chemical compound including aluminum and titanium.