| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 324247000 | Nonparallel plural magnetic sensors | 30 |
| 20080204010 | Magnetic Field Dosimeter - A portable device is used to measure exposure to magnetic fields and/or exposure to changes of magnetic field. The device ( | 08-28-2008 |
| 20080278158 | Sensor for Sensing a Magnetic Field Direction, Magnetic Field Direction Sensing, Method for Producing Magnetic Field Sensors, and Write-In Apparatus for Producing Magnetic Field Sensors - A sensor for sensing a magnetic field direction has a plurality of magnetoresistive sensor elements, each of which having a main sensitivity direction with respect to a present magnetic field. Lines associated with the main sensitivity directions of the magnetoresistive sensor elements and passing through the magnetoresistive sensor elements intersect in an area outside the magnetoresistive sensor elements themselves. | 11-13-2008 |
| 20090015251 | MAGNETIC SENSOR AND PRODUCTION METHOD THEREOF - A magnetic sensor is disclosed that has plural axes at the same time, able to be fabricated in a small number of steps. The magnetic sensor includes a substrate; and plural sensor bridge circuits each including a pair of magnetic field detectors and a pair of fixed resistors on the substrate, the pair of the magnetic field detectors and the pair of the fixed resistors being connected to form a bridge circuit, each of the magnetic field detectors being formed of a magneto-resistance effect element, and magnetization directions of the magnetic field detectors intersect with each other in a three-dimensional manner. The substrate has plural inclined surfaces, normal directions of the inclined surfaces intersect with each other in a three-dimensional manner, and the pair of the magnetic field detectors in each of the sensor bridge circuits is arranged on the same inclined surface. | 01-15-2009 |
| 20090027048 | Three-Axis Magnetic Sensor and Method for Manufacturing the Same - In the three-axis magnetic sensor of the present invention, a plurality of magnetoresistive effect element bars are connected in series by means of bias magnets to constitute magnetoresistive effect elements, and magnetoresistive effect elements of the X-axis sensor and those of the Y-axis sensor are formed on a flat surface parallel to the flat surface of the substrate. The sensitivity direction of magnetization is a direction vertical to the longitudinal direction of each of the magnetoresistive effect element bars, and magnetoresistive effect elements of the X-axis sensor and those of the Y-axis sensor are formed in such a way that the magnetization directions are orthogonal to each other. Further, magnetoresistive effect elements of the Z-axis sensor are formed on a tilted surface of the projection projected from the flat surface of the substrate in such a way that the magnetization direction is inside the tilted surface. The Z-axis sensor is provided in such a way that the sensitivity direction is vertical to the longitudinal direction of the magnetoresistive effect element bar. | 01-29-2009 |
| 20090072823 | 3D INTEGRATED COMPASS PACKAGE - A 3-axis sensor package with on-board sensor support chip on a single chip. In one aspect of the invention, a sensor package includes an X-axis sensor circuit component, a Y-axis sensor circuit component, or alternatively a combined X/Y-axis sensor circuit component, and a Z-axis sensor circuit component, each mounted to a top surface of a rigid substrate, or alternatively to a printed circuit board (PCB). The pads may be arranged in variety of designs, including a leadless chip carrier (LCC) design and a ball grid array (BGA) design. An application-specific integrated circuit (ASIC), or sensor support chip, is additionally mounted to the top surface of the rigid substrate. The sensor components and ASIC may be ball bonded or wire bonded to the substrate. | 03-19-2009 |
| 20090102475 | INTEGRATED 3-AXIS FIELD SENSOR AND FABRICATION METHODS - A multi-axis magnetic or other field sensing device and method of fabricating a multi-axis magnetic or other field sensing device. An example sensing device is a 3-axis sensor package on a substrate with sensors on opposing sides of the substrate. One side of the substrate includes an X-axis sensor and a Y-axis sensor (or alternatively an integrated X-Y-axis sensor) and the opposite side of the substrate includes a Z-axis sensor on at least one sloped surface, the surface sloped with respect to both the first and second surface areas. One surface is mechanically and electrically bonded to a circuit board via conductive bumps. The other surface electrically connects to the circuit board through bonded wires and/or vias formed through the substrate. | 04-23-2009 |
| 20090189603 | MAGNETIC SENSOR ARRAY - A magnetic sensor array includes a first three-dimensional magnetic sensor secured to a substrate in a central location of the substrate. A number of second three-dimensional magnetic sensors are secured to the substrate at a first distance from the first magnetic sensor. Additionally, a number of one-dimensional magnetic sensors are secured to the substrate at a second distance from the first magnetic sensor greater than the first distance. Additional magnetic sensors of any dimension may also be included. The magnetic field sensitivity of the first and second three-dimensional magnetic sensors may be less than the magnetic field sensitivity of the one-dimensional magnetic sensors. The sensing range of the first and second three-dimensional magnetic sensors may be greater than the sensing range of the one-dimensional magnetic sensors. The magnetic sensor array may also include a processing circuit coupled to the magnetic sensors. | 07-30-2009 |
| 20090237074 | MAGNETIC SENSOR AND MOBILE INFORMATION TERMINAL APPARATUS - A disclosed magnetic sensor includes a substrate having a plane surface and multiple sloping surfaces; multiple soft magnetic films each disposed on a different one of the sloping surfaces and magnetized according to strength of a magnetic field; and multiple detecting devices each disposed on the plane surface, including a free layer and a pinned layer and configured to produce a detection output according to magnetization of the free layer and the pinned layer. Each of the soft magnetic films is magnetically coupled with the free layer of a different one of the detecting devices. The pinned layers of the detecting devices have magnetization directions different from each other. | 09-24-2009 |
| 20090278533 | THIN FILM 3 AXIS FLUXGATE AND THE IMPLEMENTATION METHOD THEREOF - There is provided a thin film tri-gate fluxgate for detecting a component of a magnetic field in directions of three axes, the thin film tri-gate fluxgate comprising: two first thin film fluxgates of a bar-type disposed on a plane for detecting horizontal components of the magnetic field in direction of dual axis; and a plurality of second thin film fluxgates for detecting a vertical component of the magnetic field, wherein each of the first thin film fluxgates and the plurality of the second thin film fluxgates comprises a drive coil for applying a power, a pickup coil for detecting a voltage and, a magnetic thin film, and wherein the plurality of the second thin film fluxgates are substantially perpendicular to each of the first thin film fluxgates wherein a length of the magnetic thin film of each of the plurality of the second thin film fluxgates is shorter than that of each of the two first thin film fluxgates, and wherein two end portions of each of the plurality of the second thin film fluxgates is wider than a center portion thereof. | 11-12-2009 |
| 20100207621 | MAGNETIC SENSOR AND ELECTRONIC DEVICE INCLUDING THE SAME - A magnetic sensor according to the invention includes: a detector detecting the intensity of magnetic field; a comparison portion comparing the result of the detection with a set threshold value and outputting an output signal corresponding to the result of the comparison; and a threshold-value adjuster adjusting the threshold value. Thus, inconveniences due to a reverse magnetic field phenomenon or magnetic-field offset phenomenon can be solved as simple as possible. | 08-19-2010 |
| 20100219820 | Atomic Magnetometer Sensor Array Magnetoencephalogram Systems and Methods - Devices disclosed according to various embodiments use one or more arrays of atomic magnetometers to detect biologically derived magnetic fields. The disclosed devices and methods relate to application of utilization of a magnetic sensor with unique properties requiring changes in design, allowing new functions, and requiring alternative analysis methodologies. Various embodiments are also directed to methods for obtaining and processing biological magnetic signals. These methods may take advantage of the unique spatial arrangement of the atomic magnetometers and the capacity sensors to he used in either a scalar or a vector mode. Various embodiments have advantages over current magnetometer arrays for the purpose of detecting biological magnetic fields. Such advantages may include, for example: smaller size, lower power consumption, no necessity for cryogenic cooling, potential wafer-level fabrication, and/or the potential of better localization biological signals. In addition, various embodiments may allow increased target or subject mobility. | 09-02-2010 |
| 20100231212 | MAGNETIC DETECTOR AND INPUT DEVICE USING THE SAME - A magnetic detector includes a detecting section having a surface facing a magnetic body which moves and emits a magnetic flux. The detecting section includes plural magnetic sensors for detecting the magnetic flux. The magnetic sensors are arranged in a matrix form having three or more rows and three or more columns arranged along the surface of the detecting section. The magnetic detector provides an input device precisely detecting a moving direction and a moving amount of the magnetic body. | 09-16-2010 |
| 20110234218 | INTEGRATED MULTI-AXIS HYBRID MAGNETIC FIELD SENSOR - A multi-axis magnetic field sensing device combines two magnetoresistive sensors to measure the two orthogonal components X, Y of a magnetic field parallel to a system's plane and a Hall sensor to measure the Z component of the magnetic field substantially perpendicular to the system's plane. The two magnetoresistive sensors may be built together in one single chip and then stacked on top of a CMOS die embedding the Hall sensor and associated electronics for the signal processing management of the three sensors and the system's interface. | 09-29-2011 |
| 20120139534 | CURRENT SENSOR ARRANGEMENT - A current sensor arrangement comprises plural sensor elements arranged around a centre point, each of the sensor elements having a plane of zero sensitivity to uniform magnetic fields. A first one ( | 06-07-2012 |
| 20120249133 | DIFFERENTIAL MAGNETIC FIELD SENSOR STRUCTURE FOR ORIENTATION INDEPENDENT MEASUREMENT - A differential magnetic field sensor that enables operation that is independent of sensor-to-target orientation is presented. The differential magnetic field sensor is provided with at least two differential channels. Each differential channel includes a pair of magnetic field sensing elements and has a respective sensing axis defined by those magnetic field sensing elements. The sensing axes are not aligned with respect to each other. One sensing axis is positioned relative to a reference axis of a target profile to define an orientation angle between the sensing axis and the reference axis. The differential magnetic field sensor includes circuitry to produce differential signals associated with the differential channels and use those differential signals to produce a single differential signal having an amplitude that is independent of the orientation angle. | 10-04-2012 |
| 20120268113 | THREE-AXIS MAGNETIC SENSOR AND METHOD FOR MANUFACTURING THE SAME - In a three-axis magnetic sensor, a plurality of magnetoresistive effect element bars are connected in series by means of bias magnets formed on a flat surface parallel to the flat surface of the substrate to constitute magnetoresistive effect elements. The sensitivity direction of magnetization is a direction perpendicular to the longitudinal direction of each of the magnetoresistive effect element bars. Magnetoresistive effect elements forming X-axis and Y-axis sensors have magnetization directions that are orthogonal to each other. Magnetoresistive effect elements of the Z-axis sensor are formed on a tilted surface substrate in such a way that the magnetization direction is inside the tilted surface. The sensitivity direction of the Z-axis sensor is perpendicular to the longitudinal direction of the magnetoresistive effect element bar. | 10-25-2012 |
| 20120299587 | THREE-AXIS MAGNETIC SENSORS - Systems and methods for three-axis magnetic sensors are provided. In one embodiment, a three-axis magnetic sensor formed on a single substrate comprises: an in-plane two-axis magnetic sensor comprising at least one of either a magnetic-resistance (MR) sensor or a magnetic-inductive (MI) sensor formed on the single substrate; and an out-of-plane magnetic sensor comprising a Hall effect sensor formed on the single substrate. The in-plane two-axis magnetic sensor measures magnetic fields in a first plane parallel to a plane of the substrate, and the out-of-plane magnetic sensor measures magnetic fields along an axis orthogonal to the first plane. | 11-29-2012 |
| 20130320969 | MAGNETIC FIELD SENSOR - A magnetic field sensor having a first magnetic sensor core for measuring a magnetic field in a first measuring direction, and a second magnetic sensor core for measuring a magnetic field in a second measuring direction, the first and second magnetic sensor cores having a shared magnetic anisotropy. | 12-05-2013 |
| 20140062469 | Electronic Devices With Magnetic Sensors - Electronic devices may be provided with magnetic sensors for detecting the Earth's magnetic field. The magnetic sensors may include thin magnetic sensors located in magnetically quiet regions of the device. The magnetic sensors may be attached to a device housing or a component such as a battery or a cover structure for a battery. The device may include unidirectional magnetic sensors aligned in three orthogonal directions or sensors with two or three magnetic sensor elements aligned in orthogonal directions. Magnetic field data from the three orthogonally aligned sensors or sensor elements may be combined to form directional compass data for the device. Each magnetic sensor may include one or more magnetic sensor elements for detecting the magnetic field and one or more shielded reference sensor elements for detecting environmental changes that can affect the magnetic sensor element. Reference sensor elements may be shared elements for multiple magnetic sensors elements. | 03-06-2014 |
| 20140103920 | MAGNETIC FIELD DETECTION DEVICE AND METHOD FOR DETECTING A MAGNETIC FIELD - A magnetic field detection device and a corresponding method for detecting a magnetic field. The magnetic field detection device includes a coil core, a receiving coil coupled to the coil core, a plurality of electrically separated field coils coupled to the coil core, an excitation unit for generating a magnetic field excitation via a particular excitation current of the plurality of field coils coupled to the coil core and an evaluation unit for evaluating a magnetic field signal received via a receiving coil coupled to the coil core. | 04-17-2014 |
| 20140159716 | PORTABLE MAGNETIC, ELECTRIC AND RADIO FREQUENCY FIELD MONITORING APPARATUS AND METHOD - The use of implanted medical devices that address a wide range of health conditions is rapidly expanding. These implanted devices include: Cochlear implants, drug dispensing pumps, cardiac pacemakers, defibrillators and other devices. Although these devices are designed to withstand interference from external radio frequency, electric and magnetic fields, interference can occur which may affect the operation of these devices and pose a health risk. An inventive personal, body-wearable electric field, radio frequency, and three-axis magnetic field monitoring device detects the ambient radio frequency, electric and magnetic fields and warns the wearer when any of these field measurements exceeds a safe level. | 06-12-2014 |
| 20140176131 | SELECTIVE SLOPE LINEAR POSITION SENSOR - A three-magnet assembly configured for use in a position sensing system is disclosed. In an example, the three-magnet assembly establishes a non-linear spatially varying magnetic field configured to be measured by a magnetic field measurement device so that resolvable measurements are spatially distributed in a non-linear fashion. The resolvable measurements are distributed to a relatively higher concentration in at least one first region along a measurement stroke and to a relatively lower concentration in at least one second region along a measurement stroke, the second region being different from the first region. In an example, the different concentrations of resolvable measurements are utilized to spatially vary the precision of a position sensor along a measurement stroke. A system and methods for correlating magnetic field measurements to expected positions are also disclosed. | 06-26-2014 |
| 20140218018 | APPARATUS AND METHOD FOR IN SITU CURRENT MEASUREMENT IN A CONDUCTOR - Improved current sensing methods and apparatus and conductor apparatus are presented for sensing current in a bus bar or other conductor using one or more circular magnetic sensors or multiple magnetic sensors disposed on a substrate in a pattern surrounding a longitudinal path within the outer periphery of the conductor to avoid or mitigate sensed magnetic field crosstalk and to facilitate use of high sensitivity magnetic sensors at locations inside the conductor periphery in which the magnetic field is relatively small. | 08-07-2014 |
| 20140232386 | CURRENT DETECTION DEVICE - A first bent portion whose extending direction changes in the order of +z, +x, +z, −x, and +z is formed in a first current path, wherein a direction in which two current paths extend in parallel as the z-direction of the x-y-z orthogonal coordinate system and a second bent portion whose extending direction changes in the order of +z, +y, +z, −y, and +z is formed in a second current path. Either one of the z-coordinate range of the middle part of the first bent portion and the z-coordinate range of the middle part of the second bent portion includes the other one and a magnetic flux density detection device that detects the x-direction magnetic flux density and the y-direction magnetic flux density is disposed within the included z-coordinate region. | 08-21-2014 |
| 20140247042 | TRIAXIAL MAGNETIC FIELD SENSOR - The present invention discloses a triaxial magnetoresistive sensor. It comprises a substrate integrated with a biaxial magnetic field sensor, a Z-axis sensor that has a sensing direction along Z-axis perpendicular to the two axes of the biaxial magnetic field sensor, and an ASIC. The biaxial magnetic field sensor comprises an X-axis bridge sensor and a Y-axis bridge sensor. The Z-axis sensor and the two-axis sensor are electrically interconnected with the ASIC. A single-chip implementation of the triaxial magnetic field sensor comprises a substrate, onto which a triaxial magnetic field sensor and an ASIC are stacked. The triaxial magnetic field sensor comprises an X-axis bridge sensor, a Y-axis bridge sensor, and a Z-axis bridge sensor. The above design provides a highly integrated sensor with high sensitivity, low power consumption, good linearity, wide dynamic range, excellent thermal stability, and low magnetic noise. | 09-04-2014 |
| 20150035526 | MAGNETIC SENSOR INCLUDING A LORENTZ FORCE TRANSDUCER DRIVEN AT A FREQUENCY DIFFERENT FROM THE RESONANCE FREQUENCY, AND METHOD FOR DRIVING A LORENTZ FORCE TRANSDUCER - A magnetic-field sensor, including: a die, a current generator in the die. The current generator generating a driving current. A Lorentz force transducer also in the die and being configured to obtain measurements of magnetic field based upon the Lorentz force is coupled to the current generator. The transducer having a resonance frequency. The current generator is such that the driving current has a non-zero frequency different from the resonance frequency. | 02-05-2015 |
| 20150115949 | BRIDGE CIRCUIT AND MAGNETIC SENSOR INCLUDING THE CIRCUIT - A magnetic sensor having a large magnetic-field detection angle range and a bridge circuit used in the magnetic sensor, in each of multiple MR elements in the bridge circuit, multiple strips, on the whole, along a direction substantially orthogonal to a magnetic-field detection direction are arranged in parallel at certain intervals and are sequentially connected so as to be folded back and, in each of the multiple strips, multiple strips along the magnetic-field detection direction are arranged in parallel at certain intervals and are sequentially connected so as to be folded back to form a zigzag pattern in which the multiple strips are electrically connected in series to each other. | 04-30-2015 |
| 20150301216 | METHOD FOR AUTOMATIC RECOGNITION OF A MOBILE MAGNETIC OBJECT - An automatic recognition method includes the calculation of an error representative of the difference between an estimate of the values of the magnetometer measurements when the positions, orientations and amplitudes of the magnetic moments of the P dipoles are equal to those determined, and the values of the magnetometer measurements taken. There is the selection of another system of equations linking each measurement of a triaxial magnetometer to the position, orientation and amplitude of the magnetic moment of P′ magnetic dipoles. The method includes the calculation of at least one distinctive feature of the object presented from the position, orientation, or amplitude of the magnetic moment of each dipole determined with the system of equations that minimizes the error calculated. The method includes the recognition of the magnetic object presented if the calculated distinctive features correspond to those of a known object, otherwise the lack of recognition of this object. | 10-22-2015 |
| 20150309125 | Monolithic Three-Axis Magnetometer - A three-axis magnetic field sensing device, a magnetometer, and methods of fabricating and testing are presented. The magnetometer comprises a plurality of sloped surfaces. A plurality of magnetic sensing units is disposed on the slopes. A magnetic field can be measured by the sensing units. Each of the three orthogonal-axis components of the magnetic field, a Euclidean vector, can then be solved by using a simple algorithm as an expression of the sensing unit measurement values and slope angles. Polarization, testing and characterization of the device could be done by applying a magnetic field along a common axis to all sensing units, along which each sensing unit has sensitivity. | 10-29-2015 |
| 20160011279 | MAGNETIC FIELD SENSOR DEVICE | 01-14-2016 |
