Magnetic field sensor calibratable during measurement operation and method for calibrating a magnetic field sensor during measurement operation

US 9,024,622 B2
Filed: 06/27/2007
Issued: 05/05/2015
Est. Priority Date: 08/09/2006
Status: Active Grant

First Claim

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1. A magnetic field sensor calibratable during measurement operation for detecting first, second, and third spatial components B_zB_yand B_xof a magnetic field at a reference point, wherein the magnetic field comprises at least one of measurement field components and calibration field components, wherein the measurement field components comprise first, second, and third measurement field components B_Mz, B_Myand B_Mx, and wherein the calibration field components comprise first, second, and third calibration field components B_Kz, B_Kyand B_Kx, comprising:

a first sensor element arrangement for detecting the first magnetic field component B_zcomprising at least one of a first measurement field component B_Mzand a first calibration field component B_Kz, with respect to a first spatial axis z at the reference point;

a second sensor element arrangement for detecting the second magnetic field component B_ycomprising at least one of a second measurement field component B_Myand a second calibration field component B_Ky, with respect to a second spatial axis y at the reference point;

a third sensor element arrangement for detecting the third magnetic field component B_xcomprising at least one of a third measurement field component B_Mxand a third calibration field component B_Kx, with respect to a third spatial axis x at the reference point; and

an excitation line arranged such with respect to the first, second, and third sensor element arrangements that when impressing a predetermined current into the excitation line, a first predetermined calibration field component B_Kzwith respect to the first spatial axis x in the first sensor element arrangement is generated, a second predetermined calibration field component B_Kywith respect to the second spatial axis y in the second sensor element arrangement is generated, and a third predetermined calibration field component B_Kxwith respect to the third spatial axis x in the third sensor element arrangement is generated, wherein the three spatial axes z, y, and x run along linearly independent position vectors.

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Abstract

A magnetic field sensor for detecting first, second, and third spatial components of a magnetic field at a reference point includes a first sensor element arrangement for detecting the first magnetic field component having a first measurement field component and a first calibration field component with respect to a first spatial axis at a reference point, a second sensor element arrangement for detecting the second magnetic field component having a second measurement field component and a second calibration field component with respect to a second spatial axis y at the reference point and a third sensor element arrangement for detecting the third magnetic field component having a third measurement field component and a third calibration field component with respect to a third spatial axis x at the reference point. An excitation line is arranged such with respect to the three sensor element arrangements that when impressing a predetermined current into the excitation line respective predetermined calibration field components with respect to the spatial axes in the sensor element arrangements are generated.

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19 Claims

1. A magnetic field sensor calibratable during measurement operation for detecting first, second, and third spatial components B_zB_yand B_xof a magnetic field at a reference point, wherein the magnetic field comprises at least one of measurement field components and calibration field components, wherein the measurement field components comprise first, second, and third measurement field components B_Mz, B_Myand B_Mx, and wherein the calibration field components comprise first, second, and third calibration field components B_Kz, B_Kyand B_Kx, comprising:
- a first sensor element arrangement for detecting the first magnetic field component B_zcomprising at least one of a first measurement field component B_Mzand a first calibration field component B_Kz, with respect to a first spatial axis z at the reference point;
  
  a second sensor element arrangement for detecting the second magnetic field component B_ycomprising at least one of a second measurement field component B_Myand a second calibration field component B_Ky, with respect to a second spatial axis y at the reference point;
  
  a third sensor element arrangement for detecting the third magnetic field component B_xcomprising at least one of a third measurement field component B_Mxand a third calibration field component B_Kx, with respect to a third spatial axis x at the reference point; and
  
  an excitation line arranged such with respect to the first, second, and third sensor element arrangements that when impressing a predetermined current into the excitation line, a first predetermined calibration field component B_Kzwith respect to the first spatial axis x in the first sensor element arrangement is generated, a second predetermined calibration field component B_Kywith respect to the second spatial axis y in the second sensor element arrangement is generated, and a third predetermined calibration field component B_Kxwith respect to the third spatial axis x in the third sensor element arrangement is generated, wherein the three spatial axes z, y, and x run along linearly independent position vectors.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
- - 2. The magnetic field sensor according to claim 1, wherein the first, second and third sensor element arrangements is operable in a plurality of operating phases, wherein each of the first, second, and third sensor element arrangements is implemented to provide, in every operating phase, a measurement signal attributable to the operating phase.
  - 3. The magnetic field sensor according to claim 2, wherein each of the first, second and third sensor element arrangements is implemented to provide the measurement signals attributed to the operating phases, wherein the measurement signals attributed to the operating phases are combinable to a first total measurement value by a first linear combination, such that the influence of the measurement field component in the first total measurement value is reduced, or the measurement signals attributed to the operating phases are combinable to a second total measurement value by a second linear combination, such that the influence of the calibration field component in the second total measurement value is reduced.
  - 4. The magnetic field sensor according to claim 3, wherein the measurement signals attributed to the operating phases are combinable to a first total measurement value by a first linear combination, such that the influence of the measurement field component in the first total measurement value is reduced to less than 10%, 1%, or 0.1% of the first total measurement value.
  - 5. The magnetic field sensor according to claim 3, wherein the measurement signals attributed to the operating phases are combinable to a second total measurement value by a second linear combination, such that the portion of the calibration field component in the second total measurement value is reduced to less than 10%, 1%, or 0.1% of the second total measurement value.
  - 6. The magnetic field sensor according to claim 1, wherein the first sensor element arrangement comprises a Hall sensor element horizontal with respect to a main surface of the magnetic field sensor.
  - 7. The magnetic field sensor according to claim 1, wherein the first sensor element arrangement comprises a plurality of Hall sensor elements horizontal with respect to a main surface of the magnetic field sensor, wherein the geometrical arrangement of the plurality of horizontal Hall sensor elements is symmetrical in pairs with respect to the reference point and the Hall sensor elements are coupled to each other such that the magnetic field component are detectable in an offset-compensated manner.
  - 8. The magnetic field sensor according claim 1, wherein the second sensor element arrangement comprises at least two Hall sensor elements vertical with respect to a main surface of the magnetic field sensor, wherein the geometrical arrangement of the at least two vertical Hall sensor elements is symmetrical in pairs with respect to the reference point, and that are coupled to each other such that the magnetic field component are detectable in an offset-compensated manner.
  - 9. The magnetic field sensor according to claim 1, wherein the third sensor element arrangement comprises at least two Hall sensor elements vertical with respect to a main surface of the magnetic field sensor, wherein the geometrical arrangement of the at least two vertical Hall sensor elements is symmetrical in pairs with respect to the reference point, and that are coupled to each other such that the magnetic field component are detectble in an offset-compensated manner.
  - 10. The magnetic field sensor according to claim 1, wherein the first, second and third sensor element arrangements are operable in the spinning current mode.

11. A method for calibrating a magnetic field sensor during measurement operation by detecting first, second, and third spatial components B_zB_yand B_xof a magnetic field at a reference point, wherein the magnetic field comprises at least one of measurement field components and calibration field components, wherein the measurement field components comprise first, second, and third measurement field components B_Mz, B_My, B_Mxand wherein the calibration field components comprise first, second, and third calibration field components B_Kz, B_Kyand B_Kx, comprising:
- detecting the first magnetic field component B_zcomprising at least one of a first measurement field component B_Mzand a first calibration field component B_Kzwith respect to the first spatial axis z at the reference point;
  
  detecting the second magnetic field component B_ycomprising at least one of a second measurement field component B_Myand a second calibration field component B_Kywith respect to the second spatial axis y at the reference point;
  
  detecting the third magnetic field component B_xcomprising at least one of a third measurement field component B_Myand a third calibration field component B_Kxwith respect to the third spatial axis x at the reference point; and
  
  generating the first, second, and third calibration field components B_Kz, B_Kyand B_Kxwith respect to the first, second, and third spatial axes z, y and x, wherein the first, second, and third spatial axes run along a linearly independent position vector.
- View Dependent Claims (12, 13, 14, 15, 16, 17, 18)
- - 12. The method according to claim 11, wherein the steps of detecting are repeated during a plurality of operating phases, wherein measurement signals attributed to the first magnetic field component B_z, to the second magnetic field component B_y, and to the third magnetic field component B_xin the operating phases are detected.
  - 13. The method according to claim 11, further comprising first linearly combining the measurement signals of a magnetic field component attributed to the operating phases to a first total measurement value, such that the influence of the measurement field component in the first total measurement value is reduced, or second linearly combining the measurement signals of a magnetic field component attributed to the operating phases to a second total measurement value, such that the influence of the measurement field component in the second total measurement value is reduced.
  - 14. The method according to claim 13, wherein first linearly combining the measurement signals of a magnetic field component attributed to the operating phases to a first total measurement value is performed such that a portion of the measurement field component in the first total measurement value is reduced to less than 10%, 1%, or 0.1% of the first total measurement value.
  - 15. The method according to claim 13, wherein second combining the measurement signals of a magnetic field component attributed to the operating phases to a second total measurement value is performed such that the portion of the calibration field component in the second total measurement value is reduced to less than 10%, 1%, or 0.1% of the second total measurement value.
  - 16. The method according to claim 11, further comprising combining the measurement signals of a magnetic field component attributed to the operating phases, such that the magnetic field component are detectable in an offset-compensated manner.
  - 17. The method according to claim 11, wherein the operating phases are implemented according to a spinning current method.
  - 18. The method according to claim 11, further comprising:
    - storing excitation current strengths, measurement field components, or calibration field components for calibration;
      
      attributing the excitation current strength to the calibration field components or magnetic field strengths, respectively; and
      
      providing value pairs of measurement field components and magnetic field strengths.

19. A non-transitory computer readable medium product having stored thereon instructions that when read by a processor cause the processor to execute a method for calibrating a magnetic field sensor during measurement operation by detecting first, second, and third spatial components Bz, By and Bx of a magnetic field at a reference point, wherein the magnetic field comprises at least one of measurement field components and calibration field components, wherein the measurement field components comprise first, second, and third measurement field components BMz, BMy, BMx and wherein the calibration field components comprise first, second, and third calibration field components BKz, BKy and BKx, the method comprising:
- detecting the first magnetic field component Bz comprising at least one of a first measurement field component BMz and a first calibration field component BKz with respect to the first spatial axis z at the reference point;
  
  detecting the second magnetic field component By comprising at least one of a second measurement field component BMy and a second calibration field component BKy with respect to the second spatial axis y at the reference point;
  
  detecting the third magnetic field component Bx comprising at least one of a third measurement field component BMy and a third calibration field component BKx with respect to the third spatial axis x at the reference point; and
  
  generating the first, second, and third calibration field components BKz, BKy and BKx with respect to the first, second, and third spatial axes z, y and x, wherein the first, second, and third spatial axes run along a linearly independent position vector.

Specification

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Current Assignee
Fraunhofer Gesellschaft Zur Foerderung Der Angewandten Forsching E.V.
Original Assignee
Fraunhofer Gesellschaft Zur Foerderung Der Angewandten Forsching E.V.
Inventors
Hohe, Hans-Peter, Hackner, Michael, Stahl-Offergeld, Markus
Primary Examiner(s)
PATIDAR, JAY M

Application Number

US12/376,750
Publication Number

US 20120016614A1
Time in Patent Office

2,869 Days
Field of Search

324/202, 324/225
US Class Current

324/202
CPC Class Codes

G01R 15/202   using Hall-effect devices H...

G01R 33/0017   Means for compensating offs...

G01R 33/0035   Calibration of single magne...

G01R 33/0206   Three-component magnetometers

G01R 33/07   Hall effect devices

G01R 33/075   Hall devices configured for...

Magnetic field sensor calibratable during measurement operation and method for calibrating a magnetic field sensor during measurement operation

First Claim

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Abstract

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Magnetic field sensor calibratable during measurement operation and method for calibrating a magnetic field sensor during measurement operation

First Claim

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Abstract

Citations

19 Claims

Specification

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