A semiconductor sensor device includes a substrate including a first main face and a second main face opposite the first main face, a semiconductor element including a sensing region, the semiconductor element on the first main face of the substrate and being electrically coupled to the substrate, a lid on the first main face of the substrate and forming a cavity, wherein the semiconductor element is in the cavity, and a vapor deposited dielectric coating covering the semiconductor element and the first main face of the substrate, the vapor deposited dielectric coating having an opening over the sensing region, wherein the second main face of the substrate is at least partially free of the vapor deposited dielectric layer.

A sensing device includes a MEMS sensor and an adjustable amplifier. The MEMS sensor is configured to generate an input signal according to environmental changes. The adjustable amplifier has a first input terminal, a second input terminal, a third input terminal, a fourth input terminal and a first output terminal. The first input terminal is electrically connected to the MEMS sensor for receiving the input signal. The second input terminal is electrically connected to a first signal terminal for receiving a first common-mode signal. The third input terminal is electrically connected to the first output terminal. The fourth input terminal is electrically connected to a second signal terminal. An electric potential of a first output signal output by the first output terminal of the adjustable amplifier is related to electric potentials of the input signal, the first signal terminal and the second signal terminal.

A micromechanical spring structure, including a spring beam and a rigid micromechanical structure, the spring beam including a first end and an opposing second end along a main extension direction. The spring beam includes a fork having two support arms on at least one of the two ends, which is anchored to the rigid micromechanical structure, the two support arms being anchored to a surface of the rigid micromechanical structure, which extends perpendicular to the main extension direction of the spring beam.

The disclosure relates to method and apparatus for micro-contact printing of micro-electromechanical systems (MEMS) in a solvent-free environment. The disclosed embodiments enable forming a composite membrane over a parylene layer and transferring the composite structure to a receiving structure to form one or more microcavities covered by the composite membrane. The parylene film may have a thickness in the range of about 100 nm-2 microns; 100 nm-1 micron, 200-300 nm, 300-500 nm, 500 nm to 1 micron and 1-30 microns. Next, one or more secondary layers are formed over the parylene to create a composite membrane. The composite membrane may have a thickness of about 100 nm to 700 nm to several microns. The composite membrane's deflection in response to external forces can be measured to provide a contact-less detector. Conversely, the composite membrane may be actuated using an external bias to cause deflection commensurate with the applied bias. Applications of the disclosed embodiments include tunable lasers, microphones, microspeakers, remotely-activated contact-less pressure sensors and the like.

A system includes a sensor device, a circuit driving he sensor device at a drive frequency, a receiver, and a low pass filter. The sensor device is configured to change its electrical characteristics in response to external stimuli. The sensor device generates a modulated signal proportional to the external stimuli. The receiver is configured to receive the modulated signal and further configured to demodulate the modulated signal to generate a demodulated signal. The demodulation signal has a guard band. The receiver consumes power responsive to receiving the modulated signal. The low pass filter is configured to receive the demodulated signal and further configured to generate a sensor output.

A component for a sensor having a sensor element and having an output interface for the outputting of an electrical signal, which is dependent on a physical variable, from the sensor element to the output interface, includinga circuit with at least one first signal path for receiving the electrical signal from the sensor element and for conducting the electrical signal to the output interface, and a second signal path, which differs from the first signal path, for conducting the electrical signal to the output interface, wherein an activity of the first signal path or of the second signal path is dependent on a position of the component in the sensor.

A microelectromechanical device includes: a substrate; a semiconductor die, bonded to the substrate and incorporating a microstructure; an adhesive film layer between the die and the substrate; and a protective layer between the die and the adhesive film layer. The protective layer has apertures, and the adhesive film layer adheres to the die through the apertures of the protective layer.

A method for forming a filter net on an MEMS sensor and an MEMS sensor are disclosed. The method comprises the following steps: disposing a dissociable adhesive tape on a base material, and forming a filter net on an adhesive surface of the dissociable adhesive tape; transferring the filter net on a film to form a self-adhesive coiled material; and transferring and adhering the filter net on the self-adhesive coiled material to collecting a hole of the MEMS sensor. The filter net formed by the method have fine and uniform meshes, and a yield is high. In addition, the method is suitable for large-scale and industrialized production.

A semiconductor gas sensor device includes a first cavity that is enclosed by opposing first and second semiconductor substrate slices. At least one conducting filament is provided to extend over the first cavity, and a passageway is provided to permit gas to enter the first cavity. The sensor device may further including a second cavity that is hermetically enclosed by the opposing first and second semiconductor substrate slices. At least one another conducting filament is provided to extend over the second cavity.

A fabric-based item may include fabric such as woven fabric having insulating and conductive yarns or other strands of material. The conductive yarns may form signal paths. Electrical components can be embedded within pockets in the fabric. Each electrical component may have an electrical device such as a semiconductor die that is mounted on an interposer substrate. The electrical device may be a light-emitting diode, a sensor, an actuator, or other electrical device. The electrical device may have contacts that are soldered to contacts on the interposer. The interposer may have additional contacts that are soldered to the signal paths. The fabric may have portions that form transparent windows overlapping the electrical components or that have other desired attributes.