A micro-electro-mechanical system (MEMS) package structure and a method for fabricating the MEMS package structure. The MEMS package structure includes a MEMS die (210,220) and a device wafer (100). The MEMS die (210,220) is arranged on a first surface (100a) of the device wafer and includes a closed micro-cavity (211,221) and a contact pad (212,222) configured to be coupled to an external electrical signal. In the device wafer (100), there are arranged a control unit and an interconnection structure (300) electrically connected to each of the contact pad (212,222) and the control unit. On a second surface (100b) of the device wafer, there is arranged a rewiring layer (400) electrically connected to the interconnection structure (300). According to the MEMS package structure fabrication method, arranging the MEMS die (210,220) and the rewiring layer (400) on opposing sides of the device wafer (100) is conducive to shrinkage of the MEMS package structure. In addition, the MEMS package structure allows the integration of a plurality of MEMS dies of the same or different structures and functions on the same device wafer.

A monolithically integrated multi-sensor (MIMS) is disclosed. A MIMs integrated circuit comprises a plurality of sensors. For example, the integrated circuit can comprise three or more sensors where each sensor measures a different parameter. The three or more sensors can share one or more layers to form each sensor structure. In one embodiment, the three or more sensors can comprise MEMs sensor structures. Examples of the sensors that can be formed on a MIMs integrated circuit are an inertial sensor, a pressure sensor, a tactile sensor, a humidity sensor, a temperature sensor, a microphone, a force sensor, a load sensor, a magnetic sensor, a flow sensor, a light sensor, an electric field sensor, an electrical impedance sensor, a galvanic skin response sensor, a chemical sensor, a gas sensor, a liquid sensor, a solids sensor, and a biological sensor.

Microelectromechanical sensor comprising a fixed part and a mobile part suspended from the fixed part such that the mobile part can move at least in an out-of-plane displacement direction, the fixed part comprising at least first electrodes extending parallel to the displacement direction of the mobile part, the mobile part comprising a seismic mass and at least second electrodes extending parallel to the out-of-plane displacement direction, the first electrodes and the second electrodes being located relative to each other so as to be interdigitated, in which the second electrodes are directly connected to the inertial mass and only part of the face of each mobile electrode is facing an electrode fixed at rest.

Integrated circuit substrates having through silicon vias (TSVs) are described. The TSVs are vias extending through the silicon substrate in which the integrated circuitry is formed. The TSVs may be formed prior to formation of the integrated circuitry on the integrated circuit substrate, allowing the use of via materials which can be fabricated at relatively small sizes. The integrated circuit substrates may be bonded with a substrate having a microelectromechanical systems (MEMS) device. In some such situations, the circuitry of the integrated circuit substrate may face away from the MEMS substrate since the TSVs may provide electrical connection from the circuitry side of the integrated circuit substrate to the MEMS device.

A MEMS device formed using the materials of the BEOL of a CMOS process where a post-processing of vHF and post backing was applied to form the MEMS device and where a total size of the MEMS device is between 50 um and 150 um. The MEMS device may be implemented as an inertial sensor among other applications.

A method for producing a micromechanical device having a damper structure. The method includes: (A) providing a micromechanical wafer having a rear side; (B) applying a liquid damper material onto the rear side; (C) pressing a matrix against the rear side in order to form at least one damper structure in the damper material; (D) curing the damper material; and (E) removing the matrix.

A sensor system includes a transducer for sensing a physical stimulus along at least two orthogonal axes and an excitation circuit. The transducer includes a movable mass configured to react to the physical stimulus and multiple differential electrode pairs of electrodes. Each of the electrode pairs is configured to detect displacement of the movable mass along one of the orthogonal axes. The excitation circuit is connectable to the electrodes in various electrode connection configurations, with different polarity schemes, that enable excitation and sampling of each of the orthogonal axes during every sensing period. For each sensing period, a composite output signal is produced that includes the combined information sensed along each of the orthogonal axes. The individual sense signals for each orthogonal axis may be extracted from the composite output signals.

A microelectromechanical and/or nanoelectromechanical device having a fixed part, at least one suspended part configured to be moveable in the plane of the device with respect to the fixed part along at least one first direction and a first suspension means for suspending the suspended part. The first suspension means includes two suspension elements each having a first end fixed directly to the suspended part and a second end connected to the fixed part, each suspension element having a half-ellipse shape in the plane and extending between the first end and the second end, and the two suspension elements being arranged with respect to each other so as to form an ellipse.

The present invention relates to an electronic system comprising an electronic system comprising an electromechanical microsystem and a hermetic box encapsulating said microsystem. The box includes a fastening plane. The electromechanical microsystem includes a sensitive part and at least two beams connecting the sensitive part to the fastening plane. The beams are thermally coupled to the sensitive part and are electrically coupled to one another. The system further includes a thermal regulator of the electromechanical microsystem including an electrical circuit including at least two ends connected to the beams, and a circuit controller able to generate an electrical current in the electrical circuit to modify the temperature of the sensitive part.

A microelectromechanical (MEMS) sensor comprises MEMS components located within a MEMS layer and located relative to one or more electrodes. A plurality of proof masses are located within the MEMS layer and are not electrically coupled to each other within the MEMS layer. Both the first proof mass and the second proof mass move relative to at least a common electrode of the one or more electrodes, such that the relative position of each of the proof masses relative to the electrode may be sensed. A sensed parameter may be determined based on the sensed relative positions.