Abstract: An inertially referenced motion sensor that may be rigidly coupled to a relative motion sensor. Signals from the relative motion sensor and inertially referenced motion sensor may be combined to produce an inertially referenced relative signal.

Abstract: A swinging support device is provided which includes: a display device 120 which is opened and closed between a stowage position 121 and a view position 122; an opening and closing mechanism 110 operable to open and close the display device 120; a retaining mechanism 130 for holding the display device 120 located at the view position 122 by switching between at least two levels of retaining forces; a first acceleration sensor 160 mounted to a top inner surface portion 190 of a movable carrier in the vicinity of the display device 120; and a second acceleration sensor 170 mounted to the display device 120.

Abstract: A method and apparatus for estimating a motion parameter corresponding to a subject element employs one or more accelerometers operable to measure accelerations and a processing system operable to generate a motion parameter metric utilizing the acceleration measurements and estimate the motion parameter using the motion parameter metric.

Abstract: A semiconductor acceleration sensor includes an acceleration sensor chip that includes a weight portion, a base portion provided around the weight portion with a gap therebetween, and beam portions flexibly connecting the weight portion and the base portion; and a stopper plate that is provided above the acceleration sensor chip. The stopper plate includes: a plurality of fixing portions that are protrudingly provided at positions opposite to the base portion and are fixed to the base portion; first concave portions that are formed around the fixing portions at positions opposite to the weight portion and define the displacement of the weight portion; and a second concave portion that is formed at a position opposite to the beam portions and is deeper than the first concave portion.

Abstract: A sensor having a substrate, a cap and a seismic mass is proposed, the substrate having a main extension plane, the seismic mass being deflectable perpendicular to the main extension plane, a first stop of the cap covering a first area of the seismic mass perpendicular to the main extension plane in a first coverage region and a second stop of the cap covering a second area of the seismic mass perpendicular to the main extension plane in a second coverage region, and furthermore the first and second coverage regions parallel to the main extension plane being essentially equal in size. The distances of the coverage regions from a pivot axis of the mass designed as a rocker are equal so that the torques caused by electronic forces offset one another.

Abstract: Device and method for providing inertial indications with high accuracy using micro inertial sensors with inherent very small size and low accuracy. The device and method of the invention disclose use of the cluster of multiple micro inertial sensors to receive from the multiple sensors an equivalent single inertial indication with high accuracy based on the multiple independent indications and mathematical manipulations for averaging the plurality of single readings and for eliminating common deviations based, for example, on measurements of the deviation of the single readings.

Abstract: A method and apparatus for sensing accelerations directed along multiple directions are provided. An embodiment comprises a sensor array comprising two sensor pairs, each of which provides an output signal based on acceleration along two orthogonal directions. The sensor pairs are so that they collectively provide an output signal for each of three mutually orthogonal directions. In some embodiments, the sensor array is augmented to provide three additional signals, each of which is based on rotation about an axis aligned with one of the three orthogonal directions.

Abstract: In exemplary embodiments of this invention, an inertial measurement unit (IMU) includes a cantilevered proof mass and electrostatic drive. The electrostatic drive puts the proof mass into a controlled trajectory in which it oscillates rapidly, for example, by vibrating back and forth in a plane or traveling in a circular or elliptical orbit. The IMU detects lateral or angular acceleration of the IMU, by measuring the perturbations of the proof mass trajectory from the expected motion in a fixed, non-rotating inertial frame. In exemplary embodiments of this invention, the proof mass position and motion are measured by methods of differential potential measurement (with constant slope voltage), differential displacement current measurement, or phase-sensitive or synchronous detection of motion.

Abstract: An electronic device includes: an outline configuration including a first surface, a second surface facing opposite from the first surface, and a mounting surface coupled to the first and second surfaces; a first substrate including a first electrode; a second substrate including a second electrode; a resin disposed between the first and second substrates; and an electric element sealed with the resin and having an outline configuration of a polyhedron, the electric element being disposed such that a broadest surface of the polyhedron faces one of the first substrate and the second substrate. The first surface is one surface of the first substrate, the one surface being opposite from another surface of the first substrate on a side adjacent to the resin. The second surface is one surface of the second substrate, the one surface being opposite from another surface of the second substrate on a side adjacent to the resin.

Abstract: Methods and devices for a miniature, ultra-low power impact recorder for detecting, quantifying and recording the energy of an explosive blast or ballistic projectile impact. In one embodiment, the impact recorder can included a sensor comprised of an array of electromechanical resonators that is sensitive to the vibrations produced in selected, discrete frequency ranges that approximate the spectral signature characteristics of the shockwave resulting from the ballistic impact event, even after traveling through impacted material or body tissues.

Abstract: Provided is a MEMS device which is robust to the misalignment and does not require the double-side wafer processing in the manufacture of a MEMS device such as an angular velocity sensor, an acceleration sensor, a combined sensor or a micromirror. After preparing a substrate having a space therein, holes are formed in a device layer at positions where fixed components such as a fixing portion, a terminal portion and a base that are fixed to a supporting substrate are to be formed, and the holes are filled with a fixing material so that the fixing material reaches the supporting substrate, thereby fixing the device layer around the holes to the supporting substrate.

Abstract: A fall detection apparatus that detects values ax, ay, and az in accordance with acceleration in three mutually orthogonal axes (x, y, and z). Among these detected values, the fall detection apparatus determines values dxy and dzy which are the differences between the detected value for a reference axis, e.g., the y-axis, as well as the other detected values. A falling state signal is then generated when a preliminary determination state in which the determination values are within predetermined ranges continues for a predetermined time or longer.

Abstract: The invention relates to measuring devices to be used in physical measuring, and more particularly, to a method and a device for measuring the progress of a moving person. In the solution according to the invention the quantities describing the progress of the moving person can be calculated based on vertical acceleration values of the body measured by means of an acceleration sensor, and on the measured time. The invention aims at providing a solution, better and simpler than prior solutions, for measuring the progress of a moving person, which solution is applicable for use in a multitude of measuring solutions for ways of locomotion of various types.

Abstract: In order to provide an inertial sensor such as an acceleration sensor which can be downsized and in which a high SNR can be obtained as having a plurality of measurement ranges, an inertial sensor for detecting an inertial force of acceleration based on an electrostatic capacitance change of a detecting unit includes a plurality of detecting units D1 to D4 each having a different sensitivity defined by a ratio between an applied inertial force and physical quantity generated from each of the detecting units to provide the plurality of measurement ranges. Alternatively, when the inertial sensor includes N (a natural number of 2 or larger) pieces of movable units 6a to 6c, (N+1) or more types of measurement ranges are provided.

Abstract: An apparatus is provided for monitoring projectile emission. The apparatus includes a device configured to emit a projectile. The apparatus also includes a sensor unit including an accelerometer. The accelerometer is configured to output a first signal indicative of an acceleration caused by the emission of the projectile by the device. The apparatus includes a processor unit configured to generate and output a second signal indicating whether the projectile has been emitted, based on the first signal output from the accelerometer.

Abstract: A micromechanical acceleration sensor includes at least a first seismic mass which is suspended in a deflectable manner, at least one readout device for detecting the deflection of the first seismic mass and at least one resetting device.

Abstract: An electronic device is provided that is able to detect noise to which the electronic device is exposed and an internal temperature of the device. The device contains a cooling unit to cool at least a portion of the electronic device and a subsystem coupled to the microphone and/or a thermal sensor and further coupled to the cooling unit. The cooling unit adjusts according to the detected noise and internal temperature. A method for cooling an electronic device is also provided. The method comprises monitoring the noise of the device's ambient environment, monitoring an internal temperature of the device, and actuating a user interface. The method provides for cooling the device by adjusting fan speed, clock speed, or power supply voltage applied to the device based on the noise of the ambient environment, an internal temperature of the device, and actuation of the user interface.

Abstract: An optical tracking system comprises an array of point source emitters that output respective optical emissions, and a plurality of angle of arrival sensors. Each sensor comprises one or more optical elements and a focal plane array (FPA), with the optical elements arranged to resolve the optical emissions into one or more linear patterns on the FPA. A processing system in communication with the sensors establishes the orientation and position of each of the optical emitters using the linear patterns. A headgear tracking system employs point source emitters on a piece of headgear, with front and rear arrays of angle of arrival sensors located in an aircraft cockpit; a processing system in communication with the sensor arrays establishes an orientation and position for each of the optical emitters on the headgear.

Abstract: An inertial system is provided. The system includes at least one inertial sensor, a processing unit and a plurality of Kalman filters implemented in the processing unit. The Kalman filters receive information from the at least one inertial sensor, and at most one of the plurality of Kalman filters has processed zero velocity updates on the last cycle. The plurality of Kalman filters is used to optimize system response and performance during periods of intermittent motion.

Abstract: Provided are a tilted vibration sensor incorporating a plurality of electrodes and a conductive spherical body which is turned on and off by the moving displacement of the spherical body, and which may be remarkably reduced in size and may have high performance and high operating sensitivity, high durability, and high reliability; and a method of manufacturing the sensor. The case (1) of the sensor comprises a case body (5) formed of a non-conductive material having such excellent gas-barrier property and heat resistance that can stop the transmission of gases which affects on the on/off operation of the sensor due to the moving displacement of the conductive spherical body (4) and a cover body (7) sealing airtight the opening part (6) of the case body. In the method of manufacturing the vibration sensor, moisture and particulate impurities affecting the on/off operation are removed from the hollow part (2) of the case (1), and the hollow part is evacuated.

Abstract: A method is disclosed in this invention for calibrating an offset Voffset and sensitivity Vsensitivity for an accelerometer implemented in a level gauge having a known value of an offset angle ?? and a known value of a relative angle between top-and-bottom surface ?s. The method includes a step of placing the level gauge implemented with the accelerometer on a table-top surface having a tilt angle ?1 and measuring a tilt angle ?F from the level gauge and an output voltage VF from the accelerometer, then rotating the level gauge 180 degrees on the table-top surface along a perpendicular axis relative to the table top surface and measuring a tilt angle ?B from the level gauge and measuring an output voltage VB from the accelerometer.

Abstract: The present invention features a system and method for estimating body states of a vehicle. The system includes at least two sensors mounted to the vehicle. The sensors generate measured vehicle state signals corresponding to the dynamics of the vehicle. A signal adjuster transforms the measured vehicle states from a sensor coordinate system to a body coordinate system associated with the vehicle. A filter receives the transformed measured vehicle states from the signal adjuster and processes the measured signals into state estimates of the vehicle, such as, for example, the lateral velocity, yaw rate, roll angle, and roll rate of the vehicle.

Abstract: A misalignment detection sensor assembly is provided, which includes a forward-looking sensor having a sensing direction along a first axis and an inertia sensor configured to sense acceleration along a second axis, the second axis having a fixed relationship with respect to the first axis. A misalignment detection system uses the misalignment detection sensor assembly and a signal processing system to calculate a misalignment angle between the first axis and the direction of forward motion of the sensor assembly. A method of detecting angular misalignment of a forward-looking sensor assembly is also disclosed, which includes measuring acceleration along an axis having a fixed relationship with respect to the sensing axis of the forward-looking sensor assembly and comparing the acceleration measurement with a predetermined threshold.

Abstract: An acceleration sensor module is provided with sensor chips, first and second collision check sections and an OR circuit so that accelerations in different detection directions can be detected. The sensor chips of the acceleration sensor module can thus be used as a redundancy sensor in an activation device for a passenger protection system. The passenger protection system is thus prevented form being erroneously activated by only an output signal of a microcomputer, because the first switch section is controlled by both outputs of the acceleration sensor module and the microcomputer.

Abstract: An inertial sensor provided with a detection structure sensitive to a first, a second and a third component of acceleration along respective directions of detection, and generating respective electrical quantities as a function of said components of acceleration. The detection structure supplies at output a resultant electrical quantity obtained as combination of said electrical quantities, and correlated to the value of a resultant acceleration acting on the inertial sensor, given by a vector sum of the components of acceleration. In particular, the detection structure is of a microelectromechanical type, and comprises a mobile portion made of semiconductor material forming with a fixed portion a first, a second and a third detection capacitor, and an electrical-interconnection portion, connecting the detection capacitors in parallel; the resultant electrical quantity being the capacitance obtained from said connection in parallel.

Abstract: A vibration excitator is described, comprising: a main body (2); a stinger (3) which is adapted to move relative to the main body (2), in a particular working direction; an actuator (5) coupled to the main body (2) and the stinger (3); wherein the stinger (3) has a first end (3a) that is coupled to the main body (2), and an opposite second end (3b) that is intended for attachment to an object (V) to be examined; wherein the stinger (3) has an elastic centre point (Me); wherein the main body (2) has a centre of gravity (G); and wherein L1=L3 applies, wherein L1 is the distance between the elastic centre point (Me) and the second stinger end (3b), measured along the said working direction; and wherein L3 is the distance between the centre of gravity (G) and the second stinger end (3b), measured along the said working direction.

Abstract: A sensor device includes a time determining part that determines time point information, and adds the time point information to the output supplied from a part subjected to failure diagnosis and related to generation of a failure detection signal, and to the output related to generation of a sense signal. With this structure, the failure detection signal is correlated with the sense signal by the time point information. Alternatively, the sensor device includes an output circuit that correlates the failure detection signal with the sense signal supplied at the same time point as the failure detection signal, and outputs both signals using a time division method.

Abstract: A semiconductor sensor is disclosed that includes a semiconductor substrate, a sensing portion provided on the semiconductor substrate, and a pad in electrical communication with the sensing portion and provided on the semiconductor substrate. The semiconductor sensor also includes a bonding wire in electrical communication with the pad. Furthermore, the semiconductor sensor includes a cover member with a covering portion disposed over the semiconductor substrate for covering the sensing portion such that the covering portion is separated at a distance from the sensing portion. The cover member further includes a coupling portion provided on the semiconductor substrate at an area including the pad and for enabling electrical connection of the pad with the bonding wire therethrough.

Abstract: A sensor includes a proximity-light sensor configured to detect proximity of objects and ambient light conditions, an inertial sensor, and control circuitry coupled to the proximity-light sensor and the inertial sensor and configured to control the operation of the proximity-light sensor and the inertial sensor. The sensor further includes a substrate, wherein the proximity-light sensor, the inertial sensor, and the control circuitry are disposed on the substrate to form a single package.

Abstract: A tri-axis accelerometer includes a proof mass, at least four anchor points arranged in at least two opposite pairs, a first pair of anchor points being arranged opposite one another along a first axis, a second pair of anchor points being arranged opposite one another along a second axis, the first axis and the second axis being perpendicular to one another, and at least four spring units to connect the proof mass to the at least four anchor points, the spring units each including a pair of identical springs, each spring including a sensing unit.

Abstract: Disclosed are moveable microstructures comprising in-plane capacitive microaccelerometers, with submicro-gravity resolution (<200 ng/?Hz) and very high sensitivity (>17 pF/g). The microstructures are fabricated in thick (>100 ?m) silicon-on-insulator (SOI) substrates or silicon substrates using a two-mask fully-dry release process that provides large seismic mass (>10 milli-g), reduced capacitive gaps, and reduced in-plane stiffness. Fabricated devices may be interfaced to a high resolution switched-capacitor CMOS IC that eliminates the need for area-consuming reference capacitors. The measured sensitivity is 83 mV/mg (17 pF/g) and the output noise floor is ?91 dBm/Hz at 10 Hz (corresponding to an acceleration resolution of 170 ng/?Hz). The IC consumes 6 mW power and measures 0.65 mm2 core area.

Abstract: A technique is disclosed which offers an improvement in the performance of an atom interferometric (AI) sensor, such as one that is used in an accelerometer or a gyroscope. The improvement is based on the recognition that the AI-based device, which is associated with superior low-frequency performance, can be augmented with a conventional device having a superior high-frequency performance, as well as a wider frequency response, compared with that of the AI-based device. The disclosed technique combines acceleration measurements from the AI-based device, which is characterized by transfer function G(s), with acceleration measurements from the conventional device that have been adjusted by a complementary function, 1??(s), where ?(s) is an approximation of G(s). The conventional device has a considerably wider bandwidth than that of the AI-based device, and the quasi-unity transfer function of the conventional device makes possible the 1??(s) adjustment of the measurements provided by the conventional device.

Abstract: A portable security alarm system including a movement detecting and signal transmitting member for mounting on or proximate to the object whose movement is to be detected, a signal receiving and alarm generating member for receiving a signal from the movement detecting and signal transmitting member and producing a security response, a remote control for actuating and deactuating the signal receiving and alarm generating member, an environmental monitoring member for sensing an environmental condition and providing a signal to the signal receiving and alarm generating member, a visual information gathering member for gathering visual information and providing a signal to the signal receiving and alarm generating member, an audio output member for receiving a signal from the signal receiving and alarm generating member and generating an audio output, and components for delivering a security notification to remote recipients. A security network that includes the alarm system is also disclosed.

Abstract: A communication apparatus includes a bone conduction communication apparatus with a housing having a shape which is conformable to at least a portion of at least one tooth of a user; a transceiver mounted in the housing; and a transducer disposed within or upon the housing and in vibratory communication with a surface of the at least one tooth to transmit sound through the at least one tooth. A positioning system is provided to transmit positional information to the transceiver to be delivered to the transducer; and a communication device links the transceiver with a second person. The electronic and transducer assembly may receive incoming sounds either directly or through a receiver to process and amplify the signals and transmit the processed sounds via a vibrating transducer element coupled to a tooth or other bone structure, such as the maxillary, mandibular, or palatine bone structure.

Abstract: A sensor unit has a reference base. An acceleration sensor block and angular velocity sensor support rods are arranged on the reference base, using a bottom face and one side face of the reference base as reference faces. Three acceleration sensors, which detect accelerations that act in the directions in which an X-axis, a Y-axis, and a Z-axis extend, are fitted to three faces of the acceleration sensor block, respectively. Three angular velocity sensors, which detect angular velocities about the X-axis, the Y-axis, and the Z-axis, are fitted to boards that are fitted, via rubber bushings serving as vibration-proofing rubber members, to the angular velocity sensor support rods with screws, respectively.

Abstract: The invention relates to a sensor device for monitoring accelerations to which an object is subjected. In order to detect whether a value has exceeded or is below a threshold for the acceleration to which objects have been subjected in the past, i.e. without having visual contact with the sensor, the inventive sensor device includes an acceleration sensor, which is permanently linked to the object to be monitored, so that a relative movement between the acceleration sensor and the object is prevented, and an RFID transceiver for non-contact coupling of electrical energy into the acceleration sensor and for sending out radio signals as a function of the physical state of the acceleration sensor.

Abstract: An apparatus comprises a main body member; and a transducer in communication with the main body member, the transducer adapted to receive an acceleration force imparted to the main body member. A method for assessing acceleration forces imparted to an apparatus comprises a main body member and transducer in communication with the main body member, the transducer adapted to receive the external acceleration force imparted to the main body member, wherein the transducer converts the acceleration forces to electrical signals and the acceleration forces are accessed.

Abstract: A projector apparatus has a projection device for projecting an image onto a projection surface; at least two displacement sensors for detecting horizontal displacements of the projector apparatus, the displacement sensors being spaced a predetermined distance from each other; a rotational angle calculator for calculating a rotational angle of the projector apparatus in a horizontal plane using the predetermined distance and the horizontal displacements, the horizontal displacements being detected by the displacement sensors; and a distortion corrector for correcting distortion of the image by using the rotational angle, the image being projected by the projection device, wherein the rotational angle is calculated by the rotational angle calculator as a horizontal corrective angle.

Abstract: In one embodiment, a method comprises sampling a sensor during rotation, determining a percentage of samples within a target range, and calculating a circumferential portion of the rotation associated with the percentage of samples. In other embodiments, additional systems and methods and disclosed.

Abstract: In order to count the number of steps without involving an increase in circuit size or in computational load, a mobile phone includes a three-axis acceleration sensor to detect accelerations in three directions of X axis, Y axis, and Z axis, which are different from each other, a gravity direction detecting portion to detect a gravity direction on the basis of the detected accelerations in the three directions, a gravity direction acceleration calculating portion to calculate an acceleration in the detected gravity direction on the basis of the detected accelerations in the three directions, and a step counting portion to count the number of steps on the basis of the calculated gravity direction acceleration.

Abstract: An accelerometer captures multiple frames of image information and uses the image information to generate acceleration data related to an object. In particular, multiple image frames are used to determine relative movement between a target and an image collection system. The relative movement between the target and the image collection system is tracked over time to generate acceleration data related to the object.

Abstract: A sensor for detecting position and/or movement in space and/or for detecting fluid-properties comprising at least one transmitter and at least one receiver which are enclosed by a fluid, characterized in that the at least one transmitter generates cyclic fluid density fluctuations and the at least one receiver detects the change in transit time and/or the phase shift and/or the frequency change and/or the amplitude change.

Abstract: An impact sensor comprises a support 26, a first inertial weight 38, and a first retainer 32 holding the weight 38 against movement relative to the support 26, the retainer 32 being movable relative to the support 26 to permit release the weight 38 for movement relative to the support 26 in the event that the support 26 is subject to an acceleration/deceleration of magnitude greater than a predetermined level.

Abstract: A MEMS device includes a substrate; a movable mass suspended in proximity to the substrate; and at least one suspension structure coupled to the movable mass for performing a mechanical spring function. The at least one suspension structure has portions that move in tandem when the MEMS device is subject to at least one stimulus in a sensing direction, and further includes at least one link between the portions that move in tandem.

Abstract: Methods of wirelessly communicating are disclosed. In one embodiment, a transmit angle along a circumference of a revolution is determined, a transmit time of the transmit angle based at least in part on a time required to complete a revolution is determined, and a signal is wirelessly transmitted at the transmit angle and the transmit time. Apparatuses and systems are also disclosed.

Abstract: A MEMS system includes an inertial sensor having sensor circuitry and management circuitry implemented with the sensor circuitry. The management circuitry includes a detection module that detects a condition of the system and a management module that coordinates the functionality of the inertial sensor and the detection module based on the detected condition.

Abstract: In an embodiment, a device is provided comprising an accelerometer and an electroactive material. A control circuit is coupled between the accelerometer and the electroactive material.

Abstract: A method for monitoring operating parameters of a rotating blade is provided. The blade includes at least one sensor thereon, the sensor operatively coupled to a data acquisition device. The method includes transferring data from the sensor to the data acquisition device, the data relating to blade acceleration measurements, transmitting a signal representative of the transferred data from the data acquisition device to a control system, and controlling blade loads using the transmitted signal.

Abstract: An acceleration sensor chip package includes an acceleration sensor chip formed of a frame portion with an opening portion, a movable structure, a detection element, and an electrode pad. The movable structure has a beam portion and a movable portion supported on the beam portion to be movable. The acceleration sensor chip package further includes a re-wiring layer with a wiring portion having one end connected to the electrode pad; an outer terminal connected to the other end of the wiring portion; a first sealing portion for sealing the electrode pad and the re-wiring layer; and a substrate for sealing the opening portion of the frame portion.

Abstract: Piezomagnetic, magneto-strictive, or electro-strictive material particles may also be distributed throughout the structural material of the structural member, which serve to amplify and otherwise enhance the signals from the piezoelectric material particles. The piezoelectric, electro-strictive, magneto-strictive, and/or piezomagnetic material particles may allow the structural member to exhibit an electrical and/or magnetic response to forces on the structural member, such as accelerations. This may allow the structural member to function as a force sensor or an accelerometer. Signals induced by such external forces or accelerations may be taken from the conductive pickups and used for various operations, for example, for arming a warhead of a missile or for triggering passenger safety features such as air bags in automobiles.