Magnetoresistive gear tooth sensor

The invention claimed is: 1. A magnetoresistive gear tooth sensor, comprising: a first permanent magnet and a sensor chip that includes at least one sensor bridge, wherein each arm of the sensor bridge is comprised of at least one magnetic tunnel junction (MTJ) element group, wherein each MTJ element group is comprised of at least one magnetoresistive MTJ element having a sensitive direction; and a soft ferromagnetic flux concentrator with a U-shaped slot placed between the first permanent magnet and the sensor chip such that the slot is located on the side of the soft ferromagnetic flux concentrator facing the sensor chip, wherein the soft ferromagnetic flux concentrator is configured to reduce a magnetic field parallel to the sensitive direction to ensure the MTJ element operates in a linear region, wherein the magnetoresistive gear tooth sensor is configured to generate a bias magnetic field (H mag ) across each MTJ element group in an oblique direction with respect to the sensitive direction such that, for each MTJ element group, the oblique direction of H mag provides a first component perpendicular to the sensitive direction of the MTJ element group to set a sensitivity of the MTJ element group, and provides a second component parallel to the sensitive direction to cancel a Neel coupling field H 0 of the MTJ element group to also ensure the MTJ element operates in a linear region. 2. The magnetoresistive gear tooth sensor of claim 1 , wherein each arm of the sensor bridge comprises a multiplicity of MTJ element groups interconnected in series, parallel, or a combination of series and parallel. 3. The magnetoresistive gear tooth sensor of claim 2 , wherein the multiplicity of interconnected MTJ element groups has the same sensing direction. 4. The magnetoresistive gear tooth sensor of claim 1 , wherein the MTJ element groups within each arm of the sensor bridge have the same sensing direction. 5. The magnetoresistive gear tooth sensor of claim 1 , wherein the sensor chip comprises a full bridge, a half bridge, or two full bridges wired as a gradiometer. 6. The magnetoresistive gear tooth sensor of claim 1 , wherein more than one magnetoresistive MTJ elements is interconnected in series, parallel, or a combination of series and parallel. 7. The magnetoresistive gear tooth sensor of claim 1 , wherein a plurality of magnetoresistive MTJ elements with the same sensing direction connected in series, parallel or a combination of series and parallel. 8. The magnetoresistive gear tooth sensor of claim 1 , wherein the magnetoresistive MTJ element is comprised of a multilayered structure with the following sequence: a pinning layer, a ferromagnetic pinned layer, a tunnel barrier, and a ferromagnetic free layer. 9. The magnetoresistive gear tooth sensor of claim 1 , wherein the magnetoresistive gear tooth sensor includes a pair of second permanent magnets positioned around each MTJ element group to provide the bias magnetic field for each MTJ element group. 10. The magnetoresistive gear tooth sensor of claim 9 , wherein the pair of second permanent magnets is positioned on both sides of each MTJ element group obliquely with respect to the sensing direction of the corresponding MTJ element group. 11. The magnetoresistive gear tooth sensor of claim 9 , wherein the pair of the second permanent magnets have a magnetization set at an angle to provide the first and second components. 12. The magnetoresistive gear tooth sensor of claim 1 , wherein the magnetoresistive MTJ element is comprised of a multilayered structure with the following sequence: a pinning layer, a ferromagnetic pinned layer, a tunnel barrier, a ferromagnetic free layer, and a magnetic bias layer. 13. The magnetoresistive gear tooth sensor of claim 12 , wherein the magnetoresistive MTJ elements further include an isolation layer deposited between the magnetic free layer and the magnetic bias layer. 14. The magnetoresistive gear tooth sensor of claim 1 , further comprising a microcontroller electrically interconnected with the sensor bridge. 15. The magnetoresistive gear tooth sensor of claim 14 , wherein the microcontroller is used to determine the position of a gear tooth according to a relationship between the position of the gear tooth and the voltage signals of the magnetoresistive gear tooth sensor. 16. The magnetoresistive gear tooth sensor of claim 14 , comprising two full sensor bridges, wherein each arm of the two full sensor bridges includes a MTJ element group, and the microcontroller is used to determine the movement direction of a gear using the voltage output of the magnetoresistive gear tooth sensor. 17. The magnetoresistive gear tooth sensor of claim 1 , further comprising an outer casing. 18. A magnetoresistive gear tooth sensor, comprising: a first permanent magnet and a sensor chip that includes at least one sensor bridge, wherein each arm of the sensor bridge is comprised of at least one magnetic tunnel junction (MTJ) element group, wherein each MTJ element group is comprised of at least one magnetoresistive MTJ element having a sensitive direction; a soft ferromagnetic flux concentrator with a U-shaped slot placed between the first permanent magnet and the sensor chip such that the slot is located on the side of the soft ferromagnetic flux concentrator facing the sensor chip, wherein the soft ferromagnetic flux concentrator is configured to reduce a magnetic field parallel to the sensitive direction to ensure the MTJ element operates in a linear region; and a pair of second permanent magnets positioned around each MTJ element group in order to provide a bias magnetic field for each MTJ element group, wherein the pair of the second permanent magnets have a magnetization set at an oblique angle with respect to the sensitive direction to provide a parallel bias field component that is parallel to the sensitive direction to cancel Neel coupling generated by the corresponding MTJ element group to also provide a perpendicular bias field component that is perpendicular to the sensitive direction to ensure the MTJ element operates in a linear region. 19. The magnetoresistive gear tooth sensor of claim 18 , further comprising a microcontroller electrically interconnected with the at least one sensor bridge, wherein the microcontroller is used to determine the position of a gear tooth according to a relationship between the position of the gear tooth and the voltage signals of the magnetoresistive gear tooth sensor. 20. The magnetoresistive gear tooth sensor of claim 18 , wherein the at least one sensor bridge comprises two full sensor bridges, the sensor further comprising further comprising a microcontroller, wherein each arm of the two full sensor bridges includes a MTJ element group, and the microcontroller is used to determine the movement direction of a gear using the voltage output of the magnetoresistive gear tooth sensor.