Abstract: Accelerometers and associated techniques for detecting motion are described. For a resonant accelerometer, an externally-applied acceleration can cause a change in the electrical spring constant Ke of the electromechanical system. A resonant accelerometer can be driven to resonate in a bulk acoustic wave mode of vibration, which can have a high resonant frequency. Other accelerometers and associated techniques are disclosed.

Abstract: In one embodiment, an apparatus includes a resonant structure having a plate, a drive electrode and a sense electrode. The resonant structure defines an axis substantially orthogonal to a plane defined by the plate when the resonant structure is not excited. The plate is formed from a piezoelectric material. The drive electrode is configured to excite the resonant structure, and the sense electrode is configured to sense a signal in response to rotation of the resonant structure about the axis.

Abstract: A vibration sensor for a fluid environment includes a vibrissa that can be positioned in the fluid environment. The vibrissa is joined to a cantilever body having magnets positioned thereon. Cantilever body is supported by a resilient support member in an interior hollow within a housing. Support member allows movement of body in two dimensions while supporting the body in a third dimension. Magnetic sensors corresponding to the magnets on the body are positioned on the housing for detecting movement of the body caused by the vibrissa. In various embodiments, the support member can be a membrane shielding the housing interior from environmental fluid flow.

Abstract: A workpiece clamping status detection system and method for detecting a clamping state of a clamping device is provided. A clamping device having a clamping surface is configured to selectively clamp a workpiece to the clamping surface. The clamping device may be an electrostatic chuck or a mechanical clamp for selectively securing a semiconductor wafer thereto. A vibration-inducing mechanism is further provided, wherein the vibration-inducing mechanism is configured to selectively vibrate one or more of the clamping device and workpiece. A vibration-sensing mechanism is also provided, wherein the vibration-sensing mechanism is configured to detect the vibration of the one or more of the clamping device and workpiece. Detection of clamping status utilizes changes in acoustic properties, such as a shift of natural resonance frequency or acoustic impedance, to determine clamping condition of the workpiece.

Abstract: A physical-quantity sensor is configured to be used with a physical-quantity sensor element that outputs a sensor signal in response to a physical quantity. A physical-quantity detection circuit of the physical-quantity sensor includes a signal generating unit for generating a detecting signal and a multiplier that multiplies the sensor signal by the detecting signal. The signal generating unit converts a first phase of a predetermined signal having a frequency corresponding to a frequency of the sensor signal, into a second phase, and calculates an amplitude value corresponding to the second phase as to generate the detecting signal. This physical-quantity sensor improves accuracy of phase adjustment without increasing a sampling frequency.

Abstract: An integrated detection structure has a first inertial mass and a second inertial mass, each of which is elastically anchored to a substrate and has a linear movement along a first horizontal axis, a first detection movement of rotation about a first axis of rotation parallel to a second horizontal axis and a second detection movement of translation along the second horizontal axis; driving electrodes cause linear movement of the inertial masses, in opposite directions of the first horizontal axis; a pair of flexural resonator elements and a pair of torsional resonator elements are elastically coupled to the inertial masses, the torsional resonator elements having a resonant movement of rotation about a second axis of rotation and a third axis of rotation, parallel to one another and to the first axis of rotation.

Abstract: A gyro sensor includes a substrate, an oscillation member, fixed driving electrodes and a movable driving electrode that oscillate the oscillation member, fixed detection electrodes and a movable detection electrode that detect a signal that varies in accordance with oscillation by Coriolis' force of the oscillation member, a bias voltage application unit that applies a bias voltage to the oscillation member, and a storage unit, and the bias voltage application unit sets a value of the bias voltage based on information stored in the storage unit.

Abstract: A low-noise and high-sensitivity inertial sensor is provided. On the assumption that a movable portion VU1 and a movable portion VU2 are formed in the same SOI layer, the movable portion VU1 and the movable portion VU2 are mechanically connected to each other by a mechanical coupling portion MCU even while these movable portions are electrically isolated from each other. Thereby, according to a sensor element SE in the invention, it is possible to further suppress a shift between the capacitance of a MEMS capacitor 1 and the capacitance of a MEMS capacitor 2.

Abstract: A MEMS inertial sensor, may include a movable sensitive element; and second substrate and a third substrate. The movable sensitive element may be formed by using a first substrate which may be formed of a monocrystalline semiconductor material. The first substrate may include a first surface and a second surface which are opposite to each other. One or more conductive layers may be formed on the first surface of the first substrate The second substrate may be coupled to a surface of the one or more conductive layer on the first substrate. The third substrate may be coupled to the second surface of the first substrate. The third substrate and the second substrate are respectively arranged on two opposite sides of the movable sensitive element.

Abstract: According to an embodiment, a pressure sensor includes a support part, a flexible membrane part, and a magnetoresistive element. The flexible membrane part is supported by the support part, and includes a first region and a second region with rigidity lower than rigidity of the first region. The magnetoresistive element is provided on the membrane part, and includes a first magnetic layer, a second magnetic layer, and a spacer layer provided between the first magnetic layer and the second magnetic layer.

Abstract: A resonant sensor includes a mover that is movable in a first direction, a supporter that extends in a second direction perpendicular to the first direction, the supporter being connected to the mover and a fixer, the supporter supporting the mover which is movable in the first direction, and a resonator that is vibratable, at least a part of the resonator being embedded in the supporter.

Abstract: A physical quantity sensor element of the invention is formed into a plane-shape along an XY plane, and is provided with two driving portions which vibrate in a Z-axis direction, two detecting portions, four beam portions which connect one driving portion and one detecting portion, four beam portions which connect the other detecting portion and the other driving portion, and a coupling portion of which one end is connected to a portion in one of the driving portion and the other end is connected to a portion in the other diving portion in which the each of the deriving portions includes a beam portion which is connected to the end portion of the coupling portion and is deformable so as to reduce a change of a posture of each of the driving portions with respect to an XY plane.

Abstract: A physical quantity sensor element is formed into a plane-shape which extends along an XY plane, and is provided with a driving portion which vibrates in a Z-axis direction, a detecting portion which vibrates in an X-axis direction due to Coriolis effect acting on the driving portion, a beam portion which connects the driving portion and the detecting portion, a fixing portion, and a beam portion which connects the detecting portion and the fixing portion, in which a spring constant of the beam portion in the Z-axis direction is smaller than a spring constant of the beam portion in the Z-axis direction, and a spring constant of the beam portion in the Z-axis direction is greater than a spring constant of the beam portion in the X-axis direction.

Abstract: A physical quantity sensor element is provided with a detecting portion, a driving portion, a beam portion which connects a detecting portion and the driving portion to each other, and in which the beam portion includes a branched portion. The beam portion includes two mass portion side beam portions which extend from two position of the driving portion, which are different from each other, and two supporting portion side beam portions which extend from two positions of the detecting portion, which are different from each other, and in which both end portions on the detecting portion side of two mass portion side beam portions are connected to each other, and both end portions on the driving portion side of two supporting portion side beam portions are connected to each other.

Abstract: A physical quantity sensor includes a vibration element that performs drive vibration, an acceleration detection chip that detects an acceleration, a semiconductor element which is electrically connected to at least one of the vibration element and the acceleration detection chip, and a package that has a storage space for storing the vibration element, the acceleration detection chip and the semiconductor element. The semiconductor element is fixed to the package, the acceleration detection chip is fixed to the package with the semiconductor element interposed therebetween, and at least a portion of the acceleration detection chip overlaps the vibration element when the package is seen in a plan view.

Abstract: A micromechanical device includes four open drive frames and four detection masses for double differentially detecting angular velocity about a single axis aligned with the plane of the micromechanical device. A coupling frame system couples the four open drive frames into a synchronized anti-phase driving motion. In each four pairs of adjacent open drive frames, two adjacent open drive frames move in phases opposite to each other. Axes of linear driving motion of each of the drive frames are aligned. Anti-phase synchronized driving motion of the open drive frames is relayed through a spring arrangement to an anti-phase synchronized driving motion of the four detection masses. An inner coupling lever system couples the four detection masses into a synchronized anti-phase detection motion. In each four pairs of adjacent detection masses, phases of two adjacent detection masses are opposite. Axes of linear detection motion of the detection masses are aligned.

Abstract: The accelerometers disclosed herein provide excellent sensitivity, long-term stability, and low SWaP-C through a combination of photonic integrated circuit technology with standard micro-electromechanical systems (MEMS) technology. Examples of these accelerometers use optical transduction to improve the scale factor of traditional MEMS resonant accelerometers by accurately measuring the resonant frequencies of very small (e.g., about 1 ?m) tethers attached to a large (e.g., about 1 mm) proof mass. Some examples use ring resonators to measure the tether frequencies and some other examples use linear resonators to measure the tether frequencies. Potential commercial applications span a wide range from seismic measurement systems to automotive stability controls to inertial guidance to any other application where chip-scale accelerometers are currently deployed.

Abstract: A rotation rate sensor includes a substrate having a main extension plane and a Coriolis element, in which the rotation rate sensor is configured so that the Coriolis element is excitable with the aid of an excitation arrangement to carry out an excitation oscillation along a first direction and in parallel to the main extension plane, the rotation rate sensor including a compensation element for exerting a compensation force, the compensation force having a non-linear dependence on the excitation oscillation.

Abstract: A vibration angular velocity sensor includes a substrate and a vibrator. The vibrator includes support members, linear drive beams, and a plurality of weight portions connected by the drive beams. The vibrator vibrates the plurality of weight portions by bending of the drive beams. The vibrator is fixed to the substrate through the support members at fixed points of the drive beam. A spring property of the support members is smaller than a spring property of the drive beams.

Abstract: A method and device detect the imbalance of a vehicle wheel. The method includes measuring a rotation speed of the wheel while the vehicle is moving, and calculating a filtered value by applying at least one step of band-pass filtering to the measured rotation speed value of the wheel. A position of a pass-band of the band-pass filtering step is offset while moving as a function of the rotation speed of the wheel.