| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 073514150 | Spinning or vibrating accelerometer | 15 |
| 20090007667 | GRA MEMS ACCELEROMETER - An accelerometer that lies generally in a plane, for detecting acceleration along an input axis. There is a substrate, a generally planar Servo Member (SM) flexibly coupled to the substrate such that it is capable of oscillatory motion about a servo axis that lies in the plane, a generally planar Torque Summing Member (TSM) coplanar with and flexibly coupled to the SM such that the TSM is capable of rotary motion relative to the SM about an output axis that is in the plane and orthogonal to the servo axis, wherein the TSM is mass-imbalanced relative to the output axis, and a generally planar rotor coplanar with and flexibly coupled to the TSM such that it is capable of rotary oscillatory motion relative to the TSM about a rotor axis that is orthogonal to the plane of the members. There are drives for oscillating the rotor about the rotor axis and for oscillating the SM about the servo axis. Output sensors detect oscillation of the rotor about the rotor axis and of the SM about the servo axis. Output sensors detect rotation of the TSM about the output axis. | 01-08-2009 |
| 20090025477 | SENSOR WITH POSITION-INDEPENDENT DRIVE ELECTRODES IN MULTI-LAYER SILICON ON INSULATOR SUBSTRATE - A micoroelectromechanical system (MEMS) includes a housing defining an enclosed cavity, stator tines extending from the housing into the cavity, a MEMS device located within the cavity, the MEMS device including a proof mass and rotor tines extending from the proof mass, each rotor tine being positioned at a capacitive distance from a corresponding stator tine. The rotor tines include a first section extending a first distance from an insulating layer of the rotor tines and a second section extending a second distance from the insulating layer in an opposite direction from the first section. The stator tines include a first section extending a first distance from an insulating layer of the stator tines and a second section extending a second distance from the insulating layer in an opposite direction from the first section, the stator tine first distance being greater than the rotor tine first distance. | 01-29-2009 |
| 20090064783 | INERTIAL FORCE SENSOR - An inertial force sensor includes a detecting device which detects an inertial force, the detecting device having a first orthogonal arm and a supporting portion, the first orthogonal arm having a first arm and a second arm fixed in a substantially orthogonal direction, and the supporting portion supporting the first arm. The second arm has a folding portion. In this configuration, there is provided a small inertial force sensor which realizes detection of a plurality of different inertial forces and detection of inertial forces of a plurality of detection axes. | 03-12-2009 |
| 20090255339 | RESONANT ACCELEROMETER WITH LOW SENSITIVITY TO PACKAGE STRESS - A resonant accelerometer ( | 10-15-2009 |
| 20100043551 | Method and Apparatus for a Micromachined Multisensor - In a micromachined devices having a movable shuttle driven in oscillation, measuring the electrical charge accumulated on opposing drive capacitors to determine the displacement of the movable shuttle. Alternately, in such a micromachined device, measuring the electrical charge accumulated on a drive capacitor and comparing the measured electrical charge to a nominal electrical charge to determine the displacement of the movable shuttle. | 02-25-2010 |
| 20100269590 | SENSOR SYSTEM - A sensor system, in particular an acceleration sensor system, includes a sensor element and a cover element, at least one side of the sensor element having a covering provided by the cover element, and the cover element being at least partially designed as an infrared-protection element. | 10-28-2010 |
| 20110203372 | OUT-OF-PLANE COMB-DRIVE ACCELEROMETER - An out-of-plane comb-drive accelerometer. An example accelerometer linearizes a response. An example accelerometer includes one or more stators having a plurality of tines having a surface parallel to a surface of substrate. The tine surface is at a first distance from the surface of the substrate. A proof mass includes one or more rotors that include a plurality of rotor tines attached to an edge of the proof mass. The rotor tines are interleaved with corresponding ones of the stator tines. The rotor tines include a surface parallel to a surface of the substrate. The rotor tine surface is at a second distance from the surface of the substrate. The first distance and second distance are unequal by a threshold amount. Motion of the rotor relative to the stator in an out-of-plane direction provides a linear change in a capacitive value measured across the rotor and the stator. | 08-25-2011 |
| 20120017680 | PIEZOELECTRIC RESONATOR ELEMENT, PIEZOELECTRIC RESONATOR, AND ACCELERATION SENSOR - A piezoelectric resonator element includes: a resonating arm extending in a first direction and cantilever-supported; a base portion cantilever-supporting the resonating arm; and an excitation electrode allowing the resonating arm to perform flexural vibration in a second direction that is orthogonal to the first direction. In the piezoelectric resonator element, the resonating arm includes an adjusting part adjusting rigidity with respect to a bend in a third direction that is orthogonal to the first and second directions. | 01-26-2012 |
| 20120240678 | INERTIAL FORCE SENSOR - An inertial force sensor is composed of a plurality of arms and an oscillator having a base for linking the arms, in which a trimming slit is formed on a part of the arm except for a ridge portion, thus controlling damage to a tuning fork arm to be caused by the trimming. | 09-27-2012 |
| 20140102196 | ACCELERATION SENSOR AND METHOD FOR PRODUCING AN ACCELERATION SENSOR - An acceleration sensor includes a circuit board with a recess that exposes a spring structure. The spring structure is formed from a material of the circuit board exposed by the recess and includes a vibrating element that is held in a resilient manner via at least one spring element. The sensor further includes a reference element connected rigidly to the circuit board and arranged at a distance from and opposite the vibrating element, an electrical circuit arranged on the vibrating element at a distance from the reference element, and at least one detection element. The circuit is configured to evaluate a signal that is configured to be influenced by a change in distance between the reference element and the at least one detection element in order to sense an acceleration of the acceleration sensor. | 04-17-2014 |
| 20140165724 | BISTABLE FORCE AND/OR ACCELERATION SENSOR - A technique is provided for determining a force/acceleration acting on a proof mass of a bistable device. According to an aspect of the invention, the location of a boundary of one of the stable configurations of the device is monitored. The monitored location is compared to a predetermined location of the same boundary, said predetermined location corresponding to a condition in which the force/acceleration is absent, to detect a deviation of said location. The deviation is indicative of the force/acceleration and can be used to determine the force/acceleration. According to another aspect of the invention, the resonance frequency of the proof mass' oscillation in one of the stable regions is monitored, and compared to a predetermined resonance frequency the proof mass' oscillation in the same region corresponding to a condition in which the force/acceleration is absent, to determine a deviation of the resonance frequency due to the presence of force/acceleration. The deviation in the resonance frequency can be used to determine the force/acceleration. | 06-19-2014 |
| 20140290363 | PHYSICAL QUANTITY SENSOR, ELECTRONIC DEVICE, AND MOVING OBJECT - A physical quantity sensor includes: a sensor element which detects predetermined physical quantity; a driving circuit which generates a driving signal of the sensor element; and an AGC circuit which controls the driving signal at a constant level according to a reference voltage, based on an output signal of the sensor element, in which the reference voltage is variable. | 10-02-2014 |
| 20150053002 | MICROMECHANICAL SENSOR AND METHOD FOR MANUFACTURING A MICROMECHANICAL SENSOR - A micromechanical sensor is provided which includes a substrate having a main plane of extension and a rocker structure which is connected to the substrate via a torsion means. The torsion means extends primarily along a torsion axis, and the torsion axis is situated essentially in parallel to the main plane of extension of the substrate. The rocker structure is pivotable about the torsion axis from a neutral position into a deflected position, and the rocker structure has a mass distribution which is asymmetrical with respect to the torsion axis. The mass distribution is designed in such a way that a torsional motion of the rocker structure about the torsion axis is effected as a function of an inertial force which is oriented along a Z direction which is essentially perpendicular to the main plane of extension of the substrate. | 02-26-2015 |
| 20160010992 | SYSTEMS AND METHODS FOR INERTIAL REFERENCE SYSTEM ALIGNMENT | 01-14-2016 |
| 20220137085 | SENSOR AND ELECTRONIC DEVICE - According to one embodiment, a sensor includes a first detection element, and a processing part. The first detection element includes a base body, a first supporter fixed to the base body, a first movable part, first and second counter conductive parts. The first movable part is supported by the first supporter and separated from the base body. The first movable part includes a first movable base part supported by the first supporter, a second movable base part connected with the first movable base part, a first movable beam including a first beam, and a second movable beam including a second beam. The first beam includes a first end portion and a first other end portion. The second beam includes a second end portion and a second other end portion. The first counter conductive part faces the first movable beam. The second counter conductive part faces the second movable beam. | 05-05-2022 |
