| Patent application number | Description | Published |
|---|
| 20090183570 | Micromachined cross-differential dual-axis accelerometer - Micromachined accelerometer having one or more proof masses ( | 07-23-2009 |
| 20090241634 | Micromachined accelerometer and method with continuous self-testing - Micromachined accelerometer and method in which a proof mass is suspended above a substrate for movement in response to acceleration, electrodes form capacitors which change in capacitance in response to movement of the proof mass, processing circuitry responsive to the changes in capacitance provides an output signal corresponding to movement of the proof mass, a test signal is applied to the electrodes during use of the accelerometer to produce additional movement of the proof mass and a corresponding test signal component in the output signal, and the output signal is monitored to determine whether the accelerometer is operating normally by the presence of the test signal component in the output signal. | 10-01-2009 |
| 20090272189 | Robust Six Degree-of-Freedom Micromachined Gyroscope with Anti-Phase Drive Scheme and Mehtod of Operation of the Same - A method of operating an anti-phase six degree-of-freedom tuning fork gyroscope system comprises the steps of driving a first three degree-of-freedom gyroscope subsystem, and driving a second three degree-of freedom gyroscope subsystem in an anti-phase mode with the first gyroscope subsystem at an anti-phase resonant frequency. Acceleration or an angular rate of motion is sensed by means of the first and second three degree-of-freedom gyroscope subsystems operating in a flat frequency response range where the anti-phase resonant frequency is designed. Response gain and phase are stable and environmental and fabrication perturbations are avoided by such operation. A anti-phase six degree-of-freedom tuning fork gyroscope system which operates as described is also characterized. | 11-05-2009 |
| 20090282917 | Integrated multi-axis micromachined inertial sensing unit and method of fabrication - Integrated micromachined inertial sensing unit with multi-axis angular rate and acceleration sensors and method of fabricating the same. Micromachined angular rate and acceleration sensors are integrated together with an application-specific integrated circuit (ASIC) in one compact package. The ASIC combines many separate functions required to operate multiple rate sensors and accelerometers into a single chip. The MEMS sensing elements and the ASIC are die-stacked, and electrically connected either directly using ball-grid-arrays or wirebonding. Through the use of a single package and single ASIC for multiple angular rate and acceleration sensors, significant reduction in cost is achieved. | 11-19-2009 |
| 20100095768 | Micromachined torsional gyroscope with anti-phase linear sense transduction - Micromachined gyroscope having a pair of masses disposed generally in a plane and driven for out-of-plane torsional oscillation about a pair of drive axes in the plane for sensing rotation about an input axis perpendicular to the drive axes. The masses are mounted for in-plane torsional movement about sense axes perpendicular to the drive axes and the input axis in response to Coriolis forces produced by rotation of the masses about the input axis. A link connects the two masses together for movement of equal amplitude and opposite phase both about the drive axes and about the sense axes. The masses are connected to transducers having input electrodes constrained for linear in-plane movement relative to stationary electrodes, with that torsional movement of the masses about the sense axes producing changes in capacitance between the input electrodes and the stationary electrodes. | 04-22-2010 |
| 20110030473 | MICROMACHINED INERTIAL SENSOR DEVICES - A micromachined inertial sensor with a single proof-mass for measuring 6-degree-of-motions. The single proof-mass includes a frame, an x-axis proof mass section attached to the frame by a first flexure, and a y-axis proof mass section attached to the frame by a second flexure. The single proof-mass is formed in a micromachined structural layer and is adapted to measure angular rates about three axes with a single drive motion and linear accelerations about the three axes. | 02-10-2011 |
| 20110031565 | MICROMACHINED DEVICES AND FABRICATING THE SAME - Micromachined devices and methods for making the devices. The device includes: a first wafer having at least one via; and a second wafer having a micro-electromechanical-systems (MEMS) layer. The first wafer is bonded to the second wafer. The via forms a closed loop when viewed in a direction normal to the top surface of the first wafer to thereby define an island electrically isolated. The method for fabricating the device includes: providing a first wafer having at least one via; bonding a second wafer having a substantially uniform thickness to the first wafer; and etching the bonded second wafer to form a micro-electromechanical-systems (MEMS) layer. | 02-10-2011 |
| 20110265564 | Micromachined piezoelectric x-axis gyroscope - This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for making and using gyroscopes. Such gyroscopes may include a sense frame, a proof mass disposed outside the sense frame, a pair of anchors and a plurality of drive beams. The plurality of drive beams may be disposed on opposing sides of the sense frame and between the pair of anchors. The drive beams may connect the sense frame to the proof mass. The drive beams may be configured to cause torsional oscillations of the proof mass substantially in a first plane of the drive beams. The sense frame may be substantially decoupled from the drive motions of the proof mass. Such devices may be included in a mobile device, such as a mobile display device. | 11-03-2011 |
| 20110265565 | Micromachined piezoelectric X-axis gyroscope - This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for making and using gyroscopes. Some gyroscopes include a drive frame, a central anchor and a plurality of drive beams disposed on opposing sides of the central anchor. The drive beams may connect the drive frame to the central anchor. The drive beams may include a piezoelectric layer and may be configured to cause the drive frame to oscillate torsionally in a plane of the drive beams. The gyroscope may also include a proof mass and a plurality of piezoelectric sense beams. At least some components may be formed from plated metal. The drive frame may be disposed within the proof mass. The drive beams may constrain the drive frame to rotate substantially in the plane of the drive beams. Such devices may be included in a mobile device, such as a mobile display device. | 11-03-2011 |
| 20110265566 | Micromachined piezoelectric z-axis gyroscope - This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for making and using gyroscopes. Such gyroscopes may include a central anchor, a sense frame disposed around the central anchor, a plurality of sense beams configured for connecting the sense frame to the central anchor and a drive frame disposed around and coupled to the sense frame. The gyroscope may include pairs of drive beams disposed on opposing sides of the sense frame. The gyroscope may include a drive frame suspension for substantially restricting a drive motion of the drive frame to that of a substantially linear displacement along the first axis. The sense frame may be substantially decoupled from drive motions of the drive frame. Such devices may be included in a mobile device, such as a mobile display device. | 11-03-2011 |
| 20110270569 | Micromachined piezoelectric three-axis gyroscope and stacked lateral overlap transducer (slot) based three-axis accelerometer - This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for making and using x-axis gyroscopes, y-axis gyroscopes, z-axis gyroscopes, two-axis accelerometers and three-axis accelerometers. Combining fabrication processes for such devices can enable the monolithic integration of six inertial sensing axes on a single substrate, such as a single glass substrate. Such devices may be included in a mobile device, such as a mobile display device. | 11-03-2011 |
