Linear accelerometer comprising a fixed part, a rotationally moving part in the plane of the accelerometer around an axis of rotation orthogonal to the plane of the accelerometer, the moving part comprising a centre of gravity distinct from the point of intersection of the axis of rotation and the plane of the accelerometer, means forming pivot link between the moving part and the fixed part, means for detecting the displacement of the moving part with respect to the fixed part, means for viscous damping the displacement of the moving part in said plane, said viscous damping means comprising interdigitated combs, at least one first comb on the moving part and at least one second comb on the fixed part (2), the first comb and the second comb being interdigitated.

An inertial sensor includes a substrate, a first supporting beam being a first rotation axis extending along a first direction, a first movable member swingable around the first rotation axis, a second supporting beam being a second rotation axis extending along a second direction crossing the first direction, a second movable member swingable around the second rotation axis, a third rotation axis extending along a second direction, a third movable member swingable around the third rotation axis, and a projection, wherein the second and third movable members are line-symmetrically placed with a center line of the first movable member along the second direction as an axis of symmetry, a center of gravity of the second movable member is closer to the center line than the second supporting beam, and a center of gravity of the third movable member is closer to the center line than the third supporting beam.

A physical quantity sensor includes a substrate, a support portion fixed to the substrate, a movable body which is displaceable in a first direction with respect to the support portion and has a movable electrode provided therein, and a fixed electrode fixed to the substrate. The fixed electrode includes first and second fixed electrode fingers positioned on one side of the support portion, third and fourth fixed electrode fingers positioned on the other side thereof. The movable electrode includes first to fourth movable electrode fingers which face the first to fourth fixed electrode fingers in the first direction, respectively.

A physical quantity sensor includes a substrate, and a moving member facing the substrate in a third direction via a gap and becoming displaced in the third direction in relation to the substrate. The moving member has a first part and a second part, and a plurality of penetration holes arranged at the first part and the second part and penetrating the moving member in the third direction. In at least one of a first area overlapping the first part and a second area overlapping the second part, as viewed in a plan view from the third direction, C≤1.5×Cmin is satisfied, where C is a damping and Cmin is a minimum value of the damping.

There is provided a resonant sensor comprising: a substrate; a proof mass suspended from the substrate to allow for relative movement between the proof mass and the substrate along at least one sensitive axis; at least one resonant element coupled to the proof mass; an electrode assembly adjacent to the at least one resonant element; drive and sense circuitry connected to the electrode assembly configured to drive the electrode assembly to cause the at least one resonant element to resonate, wherein a measure of acceleration of the proof mass can be determined from changes in the resonant behavior of the at least one resonant element; at least one substrate electrode on the substrate, adjacent to the proof mass; and electric circuitry connected to the substrate electrode configured to apply a voltage to the substrate electrode providing an electrostatic force on the proof mass. The substrate electrode may be used to provide a number of different functions.

A physical quantity sensor includes a substrate and a movable body. A first region to an n-th region in which a step is provided between adjacent regions are provided on a first surface of a first mass portion of the movable body. Ends of the first region to the n-th region on a side far from the rotation axis are referred to as a first end to an n-th end. In a state in which the movable body is maximally displaced around the rotation axis AY, when a virtual straight line passing through two ends of the first end to the n-th end and having a smallest angle with respect to the X axis is set as a first virtual straight line, and a straight line along a main surface of a first fixed electrode is set as a second virtual straight line, the first virtual straight line and the second virtual straight line do not intersect with each other in a region between a first normal line intersecting with an end of the first fixed electrode of the substrate closest to the rotation axis AY and a second normal line intersecting with an end of the first fixed electrode farthest from the rotation axis.

A physical quantity sensor includes an anchor fixed to a substrate, a support beam, a fixed electrode unit, a movable body, and a damper unit. The fixed electrode unit is provided at the substrate. One end of the support beam is coupled to the anchor. The movable body includes a movable electrode unit and a frame unit. The movable electrode unit includes a movable electrode facing a fixed electrode of the fixed electrode unit. The frame unit couples the movable electrode unit and the other end of the support beam. The damper unit is coupled to the frame unit, is provided in a region surrounded by the support beam and the frame unit, and damps vibration of the frame unit in a first direction.

A physical quantity sensor includes a substrate that has a first fixed electrode and a movable body that has a first mass portion facing the first fixed electrode. The first mass portion includes a first region, and a second region farther from the rotation axis than the first region, a first through-hole group is provided in the first region, and a second through-hole group is provided in the second region, and the movable body has a first surface on a substrate side, and a second surface. The first surface of the first mass portion is provided with a step or a slope such that a first gap distance of a first gap between the first mass portion and the first fixed electrode in the first region is smaller than a second gap distance of a second gap between the first mass portion and the first fixed electrode in the second region. A depth of through-holes of the first through-hole group and the second through-hole group is smaller than a maximum thickness of the movable body.

A pair of vector sensors are provided and mounted orthogonally to each other. Each vector sensor includes a central structural member having a first end and a second end. The central structural member has four symmetric arms oriented at 90° to each other. A crystalline plate is attached perpendicular to a distal end of each arm of the central structural member. The first end of each vector sensor is embedded in a socket of a proof mass. The second end of each vector sensor is embedded in an aperture of a cubic base.

Accelerometer including a decoupling structure for fixing the accelerometer on a package and a MEMS sensor chip for measuring an acceleration. The chip is supported by the decoupling structure and includes a sensor wafer layer of a semiconductor material. The decoupling structure forms a bottom portion for fixing the decoupling structure on the package and a top portion fixed to the sensor wafer layer so that the chip is arranged above the decoupling structure. A width of the top portion in a planar direction is smaller than a width of the bottom portion and/or the sensor wafer layer in the planar direction. The decoupling structure is made of the same semiconductor material as the sensor wafer layer. The centre point of the top portion is arranged in a central region of the bottom portion. The chip includes a hermetically closed cavity which includes a seismic mass of the chip.