A microelectromechanical systems (MEMS) accelerometer comprises a compliant spring structure with a first beam, a second beam, and a rigid structure. One end of the first beam and one end of the second beam are coupled to the rigid structure and a proof mass is coupled to another end of the second beam. Further, a spring anchor is coupled to another end of the first beam. In response to the proof mass moving, an extension coupled to the rigid structure moves in an opposite direction to motion of the proof mass to contact the proof mass and stop the movement of the proof mass.

A physical quantity sensor includes a substrate; a movable body that is displaceable about a support axis according to a physical quantity and includes an opening; a support that is provided on the substrate and is located in the opening, and the support includes a first fixed plate and a second fixed plate that are fixed to the substrate and provided so as to sandwich the support axis in plan view; a first beam and a second beam that each connect the first fixed plate with the second fixed plate and are spaced apart from each other; a third beam extending in a direction of the support axis and connecting the first beam with the movable body; and a fourth beam extending in a direction of the support axis and connecting the second beam with the movable body.

A physical quantity sensor includes a base, at least two arms, a movable plate, a hinge, and a physical quantity measurement element. Four quadrants of the sensor are defined by first and second orthogonal lines. The first line passes through the center of the sensor and crosses the hinge. The second line extends along the hinge. Fixed regions of the sensor are located in the first and second quadrants. No fixed regions are located in at least one of the third and fourth quadrants. The third and fourth quadrants are closer to the base than the first and second quadrants in a plan view.

In an inertial sensor, a first movable body configured to swing around a first rotation axisrotation axis along a first direction has an opening; the opening includes a second movable body configured to swing around a second rotation axisrotation axis along a second direction, a second support beam supporting the second movable body as the second rotation axisrotation axis, a third movable body configured to swing around a third rotation axisrotation axis along the second direction, and a third support beam supporting the third movable body as the third rotation axisrotation axis; and a protrusion is provided at a surface facing the second movable body and the third movable body, or at the second movable body and the third movable body, the protrusion protruding toward the second movable body and the third movable body or the surface.

A micromechanical sensor system, in particular, an acceleration sensor, including a substrate having a main extension plane, the sensor system including a first mass and a second mass. The first and second masses are each designed to be at least partially movable in a vertical direction, perpendicular to the main extension plane of the substrate. The first mass includes a stop structure, wherein the stop structure has an overlap with the second mass in the vertical direction.

An inertial sensor includes: a substrate; a movable body configured to be displaced with respect to the substrate; and an attenuator configured to attenuate a displacement of the movable body with respect to the substrate. The attenuator includes a comb-shaped first structure including a plurality of movable comb fingers whose base ends are coupled to the movable body, and a comb-shaped second structure including a plurality of fixed comb fingers whose base ends are coupled to the substrate, the plurality of fixed comb fingers intersecting with the plurality of movable comb fingers. A width of the base end of each of the movable comb fingers and the fixed comb fingers is larger than a width of a tip end thereof.

A micromechanical device includes a semiconductor body, a first mobile structure, an elastic assembly, coupled to the first mobile structure and to the semiconductor body and adapted to undergo deformation in a direction, and at least one abutment element. The elastic assembly is configured to enable an oscillation of the first mobile structure as a function of a force applied thereto. The first mobile structure, the abutment element and the elastic assembly are arranged with respect to one another in such a way that: when the force is lower than a force threshold, the elastic assembly operates with a first elastic constant; and when the force is greater than the threshold force, then the first mobile structure is in contact with the abutment element, and a deformation of the elastic assembly is generated, which operates with a second elastic constant different from the first elastic constant.

The present invention relates to MEMS (microelectromechanical systems) accelerometers, in particular to an accelerometer designed to reduce error in the accelerometer output. The MEMS accelerometer includes a proof mass, which is capable of movement along at least two perpendicular axes and at least one measurement structure. The proof mass is mechanically coupled to the measurement structure along the sense axis of the measurement structure, such that movement of the proof mass along the sense axis causes the moveable portion of the measurement structure to move, and is decoupled from the measurement structures along an axis or axes perpendicular to the sense axis of the measurement structure, such that movement of the proof mass perpendicular to the sense axis of the measurement structure does not cause the moveable portion of the measurement structure to move.

A microelectromechanical system (MEMS) device includes a substrate and a movable element at least partially suspended above the substrate and having at least one degree of freedom. The MEMS device further includes a protrusion extending from the substrate and configured to contact the movable element when the movable element moves in the at least one degree of freedom, wherein the protrusion comprises a surface having a water contact angle of higher than about 15° measured in air.

An example proof mass assembly includes a proof mass; a proof mass support; a flexure connecting the proof mass to the proof mass support, wherein the proof mass is configured to rotate relative to the proof mass support via the flexure; a first resonator connected to a first major surface of the proof mass and a first major surface of the proof mass support; and a second resonator connected to a second major surface of the proof mass and a second major surface of the proof mass support, wherein at least one of the proof mass, the proof mass support, the flexure, the first resonator, or the second resonator is formed by selective laser etching.