会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 2. 发明申请
    • MAGNETIC SENSOR AND METHOD OF PRODUCING THE SAME
    • 磁传感器及其制造方法
    • US20070182407A1
    • 2007-08-09
    • US11682841
    • 2007-03-06
    • Hideki SatoToshiyuki OohashiYukio WakuiSusumu YoshidaKokichi Aiso
    • Hideki SatoToshiyuki OohashiYukio WakuiSusumu YoshidaKokichi Aiso
    • G01R15/18G01R33/02
    • B82Y25/00B82Y40/00G01R33/09G01R33/093H01F41/302Y10T29/49002Y10T29/49037Y10T428/32
    • On a single chip are formed a plurality of magnetoresistance effect elements provided with pinned layers having fixed magnetization axes in the directions that cross each other. On a substrate 10 are formed magnetic layers that will become two magnetic tunnel effect elements 11, 21 as magnetoresistance effect elements. Magnetic-field-applying magnetic layers made of NiCo are formed to sandwich the magnetic layers in plan view. A magnetic field is applied to the magnetic-field-applying magnetic layers. The magnetic field is removed after the magnetic-field-applying magnetic layers are magnetized in the direction shown by arrow A. As a result of this, by the residual magnetization of the magnetic-field-applying magnetic layers, magnetic fields in the directions shown by arrows B are applied to the magnetic layers that will become magnetic tunnel effect elements 11, 21, whereby the magnetization of the pinned layers of the magnetic layers that will become magnetic tunnel effect elements 11, 21 is pinned in the directions shown by arrows B.
    • 在单个芯片上形成有多个磁阻效应元件,该元件具有在彼此交叉的方向上具有固定的磁化轴的固定层。 在基板10上形成作为磁阻效应元件的两个磁隧道效应元件11,21的磁性层。 形成由NiCo制成的磁场施加磁性层,以在平面图中夹着磁性层。 对磁场施加磁性层施加磁场。 在磁场施加磁性层沿着箭头A所示的方向被磁化之后,去除磁场。结果,通过磁场施加磁性层的剩余磁化,所示方向上的磁场 通过箭头B施加到将成为磁隧道效应元件11,21的磁性层,由此将成为磁隧道效应元件11,21的磁性层的被钉扎层的磁化被固定在箭头B所示的方向 。
    • 4. 发明申请
    • Sensor, and method for measuring physical quantity by use of the sensor
    • 传感器和使用传感器测量物理量的方法
    • US20060066303A1
    • 2006-03-30
    • US11236680
    • 2005-09-28
    • Toshiyuki OohashiTamito Suzuki
    • Toshiyuki OohashiTamito Suzuki
    • G01R33/02
    • G01R33/0283
    • A sensor includes a first X-axis GMR element to a fourth X-axis GMR element fixed on a substrate, and a movable coil movably supported on the substrate. When electric current flows through the movable coil, a magnetic field is generated around the movable coil. The generated magnetic field is applied to the first to fourth X-axis GMR elements. The movable coil moves in accordance with acceleration generated in the sensor. The movement of the movable coil causes variation in the magnetic field applied to the first to fourth X-axis GMR element. While no electric current flows to the movable coil, the sensor measures an external magnetic field on the basis of resistances of the first to fourth X-axis GMR elements. While constant electric current flows through the movable coil, the sensor measures acceleration or the like on the basis of resistances of the first to fourth X-axis GMR elements.
    • 传感器包括固定在基板上的第四X轴GMR元件的第一X轴GMR元件和可移动地支撑在基板上的可动线圈。 当电流流过可动线圈时,在可动线圈周围产生磁场。 所产生的磁场被施加到第一至第四X轴GMR元件。 可动线圈根据传感器中产生的加速度移动。 可动线圈的移动引起施加到第一至第四X轴GMR元件的磁场的变化。 在没有电流流向可动线圈的情况下,传感器基于第一至第四X轴GMR元件的电阻测量外部磁场。 当恒定电流流过可动线圈时,传感器基于第一至第四X轴GMR元件的电阻来测量加速度等。
    • 5. 发明授权
    • Magnetic sensor formed of magnetoresistance effect elements
    • 磁传感器由磁阻效应元件形成
    • US07589528B2
    • 2009-09-15
    • US11682841
    • 2007-03-06
    • Hideki SatoToshiyuki OohashiYukio WakuiSusumu YoshidaKokichi Aiso
    • Hideki SatoToshiyuki OohashiYukio WakuiSusumu YoshidaKokichi Aiso
    • G01R33/02
    • B82Y25/00B82Y40/00G01R33/09G01R33/093H01F41/302Y10T29/49002Y10T29/49037Y10T428/32
    • On a single chip are formed a plurality of magnetoresistance effect elements provided with pinned layers having fixed magnetization axes in the directions that cross each other. On a substrate 10 are formed magnetic layers that will become two magnetic tunnel effect elements 11, 21 as magnetoresistance effect elements. Magnetic-field-applying magnetic layers made of NiCo are formed to sandwich the magnetic layers in plan view. A magnetic field is applied to the magnetic-field-applying magnetic layers. The magnetic field is removed after the magnetic-field-applying magnetic layers are magnetized in the direction shown by arrow A. As a result of this, by the residual magnetization of the magnetic-field-applying magnetic layers, magnetic fields in the directions shown by arrows B are applied to the magnetic layers that will become magnetic tunnel effect elements 11, 21, whereby the magnetization of the pinned layers of the magnetic layers that will become magnetic tunnel effect elements 11, 21 is pinned in the directions shown by arrows B.
    • 在单个芯片上形成有多个磁阻效应元件,该元件具有在彼此交叉的方向上具有固定的磁化轴的固定层。 在基板10上形成作为磁阻效应元件的两个磁隧道效应元件11,21的磁性层。 形成由NiCo制成的磁场施加磁性层,以在平面图中夹着磁性层。 对磁场施加磁性层施加磁场。 在磁场施加磁性层沿着箭头A所示的方向被磁化之后,去除磁场。结果,通过磁场施加磁性层的剩余磁化,所示方向上的磁场 通过箭头B施加到将成为磁隧道效应元件11,21的磁性层,由此将成为磁隧道效应元件11,21的磁性层的被钉扎层的磁化被固定在箭头B所示的方向上 。
    • 7. 发明授权
    • Magnetic sensor, production process of the magnetic sensor and magnetic array suitable for the production process
    • 磁传感器,磁传感器和磁阵列的生产过程适合生产过程
    • US06940701B2
    • 2005-09-06
    • US10874224
    • 2004-06-24
    • Toshiyuki OohashiYukio Wakui
    • Toshiyuki OohashiYukio Wakui
    • H01L43/06G01D5/14G01D5/16G01R33/09H01F10/32H01F13/00H01F17/00H01F41/30H01L43/08G11B5/127
    • G01D5/145B82Y25/00B82Y40/00G01R33/093H01F10/324H01F10/3295H01F13/00H01F17/0006H01F41/302Y10T29/49002Y10T29/49034
    • The present invention aims to provide a magnetic sensor provided with a magnetoresistive effect element capable of stably maintaining a direction of magnetization in a magnetic domain of a free layer.The magnetic sensor includes a magnetoresistive effect element provided with narrow zonal portions 11a . . . 11a including a pinned layer and a free layer. Disposed below both ends of the free layer are bias magnet films 11b . . . 11b composed of a permanent magnet that applies to the free layer a bias magnetic field in a predetermined direction and an initializing coil 31 that is disposed in the vicinity of the free layer and applies to the free layer a magnetic field having the direction same as that of the bias magnetic field by being energized under a predetermined condition. Further, magnetizing the bias magnet films and fixing the direction of magnetization of the pinned layer are performed by a magnetic field formed by a magnet array configured such that plural permanent magnets are arranged on a lattice point of a tetragonal lattice and a polarity of a magnet pole of each permanent magnet is different from a polarity of the other adjacent magnet pole spaced by the shortest route.
    • 本发明的目的在于提供一种具有能够稳定地保持自由层的磁畴中的磁化方向的磁阻效应元件的磁传感器。 磁传感器包括具有窄带状部分11a的磁阻效应元件。 。 。 包括钉扎层和自由层。 位于自由层两端下方的是偏置磁体膜11b。 。 。 11b,其由施加到自由层的预定方向上的偏置磁场的永磁体和设置在自由层附近的初始化线圈31构成,并且向自由层施加具有与 通过在预定条件下通电来施加偏置磁场的电压。 此外,磁化偏置磁体膜并固定被钉扎层的磁化方向由磁场阵列形成的磁场进行,磁体阵列构造成使得多个永久磁铁布置在四方晶格的点阵点和磁体的极性 每个永久磁铁的极点与由最短路线隔开的另一相邻磁极的极性不同。
    • 9. 发明授权
    • Magnetic sensor for pointing device
    • 定位装置磁传感器
    • US07508196B2
    • 2009-03-24
    • US11391579
    • 2006-03-28
    • Toshiyuki OohashiYukio Wakui
    • Toshiyuki OohashiYukio Wakui
    • G01B7/14G01R33/09H01L43/08G01P15/105
    • G06F3/0338
    • A magnetic sensor includes first through fourth GMR elements. The fixed layers of the first through fourth GMR elements have respective magnetization directions toward the X-axis positive, X-axis negative, Y-axis negative, and Y-axis positive directions. When a magnet is located at the initial position, the free layers of the first through fourth GMR elements have respective magnetization directions toward the Y-axis positive, Y-axis negative, X-axis negative, and X-axis positive directions. When the magnet is located at the initial position, the magnetization axis of the magnet passes through the centroid of the first through fourth GMR elements. The magnetic sensor detects, from the resistances of these GMR elements, changes in horizontal magnetic fields of the magnet which pass through the first through fourth GMR elements and which change in accordance with the moved position of the magnet, to thereby determine the position of the magnet.
    • 磁传感器包括第一至第四GMR元件。 第一至第四GMR元件的固定层具有朝向X轴正,X轴负,Y轴负和Y轴正方向的各自的磁化方向。 当磁体位于初始位置时,第一至第四GMR元件的自由层具有朝向Y轴正,Y轴负,X轴负和X轴正方向的各自的磁化方向。 当磁体位于初始位置时,磁体的磁化轴穿过第一至第四GMR元件的质心。 磁传感器从这些GMR元件的电阻检测出通过第一至第四GMR元件的磁体的水平磁场的变化,并且根据磁体的移动位置发生变化,从而确定 磁铁。
    • 10. 发明申请
    • Three-Axis Magnetic Sensor and Method for Manufacturing the Same
    • 三轴磁传感器及其制造方法
    • US20090027048A1
    • 2009-01-29
    • US11908549
    • 2006-03-17
    • Hideki SatoMasayoshi OmuraHiroshi NaitoToshiyuki OohashiYukio WakuiChihiro Osuga
    • Hideki SatoMasayoshi OmuraHiroshi NaitoToshiyuki OohashiYukio WakuiChihiro Osuga
    • G01R33/09G01R3/00
    • H01L27/22B82Y25/00G01R33/09G01R33/093Y10T29/49002Y10T29/4902
    • 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.
    • 在本发明的三轴磁传感器中,多个磁阻效应元件棒通过偏置磁铁串联连接,构成磁阻效应元件,X轴传感器和Y轴传感器的磁阻效应元件, 轴传感器形成在平行于基板的平坦表面的平坦表面上。 磁化的灵敏度方向是垂直于每个磁阻效应元件棒的纵向的方向,并且X轴传感器和Y轴传感器的磁阻效应元件以这样的方式形成,使得磁化方向 彼此正交。 此外,Z轴传感器的磁阻效应元件形成在从基板的平坦表面突出的突起的倾斜表面上,使得磁化方向在倾斜表面内。 Z轴传感器以灵敏度方向垂直于磁阻效应元件棒的纵向的方式设置。