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    • 2. 发明申请
    • MAGNETIC SENSOR DEVICE
    • 磁传感器装置
    • US20100176807A1
    • 2010-07-15
    • US12377219
    • 2007-08-07
    • Haris DuricJosephus Arnoldus Henricus Maria KahlmanBart Michiel De Boer
    • Haris DuricJosephus Arnoldus Henricus Maria KahlmanBart Michiel De Boer
    • G01R33/12
    • G01N33/54366G01N27/745G01N33/54326G01N33/54373G01N35/0098
    • The present invention provides a magnetic sensor device (20) comprising at least one sensor surface lying in a first plane, a first magnetic field generating means (12) for attracting magnetic or magnetizable objects (15) toward a sensor surface (13), the first magnetic field generating means (12) lying in a second plane different from and substantially parallel to the first plane, and a second magnetic field generating means (14) for magnetizing magnetic or magnetizable objects (15) which are bond to the sensor. The spacing between the first magnetic field generating means (12) and the at least one sensor element (11) is smaller than 2 μm down to optionally overlapping. The present invention furthermore provides a method for determining the presence and/or amount of magnetic or magnetizable objects (15) in a sample fluid using the magnetic sensor device (20) according to embodiments of the invention.
    • 本发明提供了一种包括位于第一平面中的至少一个传感器表面的磁传感器装置(20),用于将磁性或可磁化物体(15)吸引到传感器表面(13)的第一磁场产生装置(12) 第一磁场产生装置(12),其位于与第一平面不同并且基本上平行的第二平面中;以及第二磁场产生装置(14),用于磁化磁性或可磁化物体(15),所述第二磁场产生装置结合到传感器。 第一磁场产生装置(12)和至少一个传感器元件(11)之间的间隔小于2μm,直到可选地重叠。 本发明还提供一种用于使用根据本发明的实施例的磁传感器装置(20)来确定样品流体中的磁性或可磁化物体(15)的存在和/或量的方法。
    • 5. 发明申请
    • Means and Method for Reducing Magnetic Cross-Talk in Biosensors
    • 减少生物传感器中磁交互的手段和方法
    • US20080129286A1
    • 2008-06-05
    • US11719955
    • 2005-11-28
    • Josephus Arnoldus Henricus Maria KahlmanBart Michiel De Boer
    • Josephus Arnoldus Henricus Maria KahlmanBart Michiel De Boer
    • G01N27/72
    • G01R33/093B82Y25/00G01R33/1269
    • A magnetic sensor (MS) for sensing a magnetic stray field (SF) generated by magnetizable object (SPB) when magnetized and for generating an electrical object signal (UOB) which depends on the sensed magnetic stray field (SF), comprising a magnetic field generator (WR1, WR2) for generating a magnetic main field (H) for magnetizing the magnetizable object (SPB), and cross-talk reduction means for reducing the effect of a cross talk signal component in the electrical object signal (UOB) caused by magnetic cross-talk between the magnetic main field (H) and the magnetic stray field (SF), wherein the cross-talk reduction means is arranged for distinguishing a signal property between the cross-talk signal component and the remaining part of the electrical object signal (UOB) and for generating an electrical output signal (Uo).
    • 一种磁传感器(MS),用于感测磁化物体(SPB)产生的磁性杂散场(SF),当被磁化并产生取决于感测的磁性杂散场的电气对象信号(U OB OB)时 (SF),包括用于产生用于磁化可磁化物体(SPB)的磁性主场(H)的磁场发生器(WR 1,W 2),并且交叉 - 减小装置,用于降低由磁性主场(H)和磁性杂散场(H)和磁性杂散场(H)之间的磁场串扰引起的电气对象信号(U OB OB)中串扰信号分量的影响 SF),其中所述串扰降低装置被布置用于区分串扰信号分量与电对象信号的剩余部分(U OB OB)之间的信号特性,并用于产生电输出 信号(U o)。
    • 6. 发明申请
    • MAGNETIC SENSOR DEVICE WITH ROBUST SIGNAL PROCESSING
    • 具有鲁棒信号处理的磁传感器装置
    • US20100060275A1
    • 2010-03-11
    • US12518897
    • 2007-12-14
    • Jeroen VeenTheodorus Petrus Henricus Gerardus JansenBart Michiel De BoerJosephus Arnoldus Henricus Maria Kahlman
    • Jeroen VeenTheodorus Petrus Henricus Gerardus JansenBart Michiel De BoerJosephus Arnoldus Henricus Maria Kahlman
    • G01R33/12
    • G01R33/093B82Y25/00G01R33/1269
    • The invention relates to a magnetic sensor device (100) comprising a magnetic field generator (1) driven with an excitation current of a first frequency (f1) and a magnetic sensor element (e.g. a GIVER sensor (2)) driven with a sensor current (I2) of a second frequency (f2) for measuring reaction fields (HB) generated by magnetized particles (3). In an associated evaluation unit (10), a reference component (uQ) of the measurement signal (uGMR) is separated that depends on the excitation current (I1) and the sensor current (I2) but not on the presence of magnetized particles (3). The reference component (uQ) may particularly be produced by a combination of the self-magnetization (H2) of the magnetic sensor element (2) and cross-talk related currents. The reference component (uQ) may be isolated based on its phase with respect to a particle-dependent component of the measurement signal (uGMR) or based on its scaling with one of the current frequencies. Monitoring of the reference component (uQ) reveals variations in operating conditions, for example in the sensor gain, that can be used to calibrate the measurement results.
    • 本发明涉及一种磁传感器装置(100),其包括用第一频率(f1)的激励电流驱动的磁场发生器(1)和由传感器电流驱动的磁传感器元件(例如GIVER传感器(2)) (I2),用于测量由磁化颗粒(3)产生的反应场(HB)的第二频率(f2)。 在相关联的评估单元(10)中,测量信号(uGMR)的参考分量(uQ)被分离,其取决于激励电流(I1)和传感器电流(I2),但不依赖于磁化颗粒(3 )。 参考分量(uQ)可以特别地通过磁传感器元件(2)的自磁化(H2)和串扰相关电流的组合来产生。 参考分量(uQ)可以基于其相对于测量信号(uGMR)的粒子相关分量的相位或者基于其与当前频率之一的比例来隔离。 参考组件(uQ)的监视显示了可用于校准测量结果的操作条件的变化,例如传感器增益。
    • 7. 发明申请
    • MAGNETIC SENSOR DEVICE WITH SUPPRESSION OF SPURIOUS SIGNAL COMPONENTS
    • 具有抑制SPUIOUS信号组件的磁传感器装置
    • US20100001722A1
    • 2010-01-07
    • US12518890
    • 2007-12-12
    • Josephus Arnoldus Henricus Maria KahlmanBart Michiel De BoerTheodorus Petrus Henricus Gerardus JansenJeroen Veen
    • Josephus Arnoldus Henricus Maria KahlmanBart Michiel De BoerTheodorus Petrus Henricus Gerardus JansenJeroen Veen
    • G01R33/02
    • G01R33/093B82Y25/00G01R33/1269
    • The invention relates to a magnetic sensor device for the determination of magnetized particles (3) which comprises a magnetic field generator (1, 1′)(e.g. a conductor wire) that is driven with an excitation current (I1) of a first frequency (f1), and a magnetic sensor element (2) (e.g. a GMR resistance), that is driven with a sensor current (I2) of a second frequency (f2) for generating measurement signals (UGMR). A preprocessed signal (uf) is then generated from the measurement signal (UGMR) that comprises a predetermined frequency (Δf), and an evaluation unit (10) separates from this preprocessed signal a spurious component that does not depend on the presence of magnetized particles (3) in the sample chamber. The spurious component (UQ) may particularly be caused by self-magnetization (H2) of the magnetic sensor element (2) in combination with parasitic (capacitive or inductive) cross-talk. Furthermore, an unknown, variable phase-shift (φSP) in the preprocessed signal (uf) may be determined by varying the ratio between the spurious component and a particle-dependent target component. This variation may for example be achieved if, in an optimization stage (OS), the excitation current (I1) is conducted through a bypass resistor (R, R′) and/or if an additional capacitor is introduced between the magnetic field generator and the magnetic sensor element. The determined phase shift can then be used to adjust the phase of a demodulation signal (udem) such that the spurious component is suppressed.
    • 本发明涉及一种用于确定磁化颗粒(3)的磁传感器装置,该磁化颗粒包括由第一频率的激励电流(I1)驱动的磁场发生器(1,1')(例如导线) f1)和由用于产生测量信号(UGMR)的第二频率(f2)的传感器电流(I2)驱动的磁传感器元件(2)(例如,GMR电阻)。 然后从包括预定频率(Deltaf)的测量信号(UGMR)生成预处理信号(uf),并且评估单元(10)从该预处理信号中分离出不依赖于磁化颗粒的存在的杂散分量 (3)。 杂散分量(UQ)可以特别地由磁传感器元件(2)与寄生(电容或电感)串扰的自磁化(H2)引起。 此外,预处理信号(uf)中的未知的可变相移(phiSP)可以通过改变杂散分量和粒子相关目标分量之间的比率来确定。 例如,如果在优化级(OS)中通过旁路电阻(R,R')传导励磁电流(I1)和/或如果在磁场发生器和 磁传感元件。 然后可以使用所确定的相移来调整解调信号(udem)的相位,使得抑制杂散分量。