Method for increasing the position measurement accuracy using inductive position sensor

What is claimed is: 1. A position sensor, comprising: a transmit coil that provides a magnetic field inducing eddy currents in a metallic target, the metallic target being movable relative to the transmit coil; a first sensor formed with a first sine-shaped coil and separately a first cosine-shaped coil that detect eddy currents in the metallic target, the first sine-shaped coil and the first cosine-shaped coil of the first sensor each having a first number of periods over a range of motion of a target, the first sensor positioned within an area of the transmit coil to detect a first position of the metallic target from signals provided by each of the first sine-shaped coil and the first cosine-shaped coil; and a second sensor formed with a second sine-shaped coil and separately a second cosine-shaped coil, the second sine-shaped coil and the second cosine-shaped coil of the second sensor having a second number of periods over the range, the second sensor positioned within the transmit coil and relative to the first sensor to detect a second position of the metallic target from signals from signals provided by each of the second sine-shaped coil and the second cosine-shaped coil, wherein the first number of periods is different from the second number of periods, and wherein the first sensor and the second sensor are arranged with respect to one another such that the target engages both the first sensor and the second sensor simultaneously, and wherein the position of the metallic target is determined from the first position and the second position. 2. The position sensor of claim 1 , wherein the first number of periods is one and the second number of periods is greater than one. 3. The position sensor of claim 2 , wherein the first position determined from first sensor is a coarse position and the second position from the second sensor is a fine position location. 4. The position sensor of claim 3 , wherein the second number of periods is three. 5. The position sensor of claim 3 , wherein the second number of periods is four. 6. The position sensor of claim 3 , wherein the second number of periods is greater than four. 7. The position sensor of claim 1 , wherein the first number of periods and the second number of periods is greater than one. 8. The position sensor of claim 7 , wherein the first number of periods is greater than the second number of periods. 9. The position sensor of claim 8 , wherein the first number of periods is one more than the second number of periods. 10. A method of determining a position of a target with a position sensor, comprising providing a magnetic field with a transmit coil to induce eddy currents in the target while the target is moved relative to the position sensor; moving the target over a first sensor and a second sensor that are each positioned within an area of the transmit coil, the first sensor including a first sine-shaped coil and separately a first cosine-shaped coil that detects the eddy currents from the target, the first sine-shaped coil and the first cosine-shaped coil of the first sensor having a first number of periods over a range of motion of the target and the second sensor including a second sine-shaped coil and a second cosine-shaped coil that detects the eddy currents from the target, the second sine-shaped coil and the second cosine-shaped coil of the second sensor having a second number of periods over the range of motion of the target; determining a first position value according to signals from the first sine-shaped coil and the first cosine-shaped coil of the first sensor; determining a second position value according to signals from the second sine-shaped coil and the second cosine-shaped coil of the second sensor; and calculating a position value from the first position value and the second position value. 11. The method of claim 10 , wherein the first number of periods is one and the first sensor provides a coarse location while the second sensor provides a fine location. 12. The method of claim 10 , wherein the first number of periods and the second number of periods are both greater than one and the position value is determined by comparing the first value and the second value. 13. A position sensing system, including a first transmitter coil and a second transmit coil that provides a magnetic field to induce eddy currents in a target that moves relative to a position sensor of the position sensing system; a first sensor of the position sensor, the first sensor formed with a first sine-shaped coil and separately a first cosine-shaped coil positioned within an area of the first transmitter coil, the first sensor configured to detect the induced eddy currents in the target, the first sine coil and the first cosine coil of the first sensor having a first number of periods over a range of motion of the target; a second sensor of the position sensor, the second sensor formed with a second sine-shaped coil and separately a second cosine-shaped coil positioned within an area of the second transmitter coil, the second sensor configured to detect the induced eddy currents of the target, the second sine-shaped coil and the second cosine-shaped coil of the second sensor having a second number of periods over the range, wherein the first number of periods is different from the second number of periods, the first sensor coil and the second sensor coil are arranged with respect to one another such that the target engages both of them simultaneously; a first electronic circuit coupled to drive the first transmit coil and receive signals from each of the first sine-shaped coil and the first cosine-shaped coil of the first sensor, the first electronic circuit providing first data; a second electronic circuit coupled to drive the second transmit coil and receive signals from each of the second sine-shaped coil and the second cosine-shaped coil of the second sensor, the second electronic circuit providing second data; and a processor coupled to receive the first data and the second data and determine a location of the target based on the first data and the second data. 14. The position sensing system of claim 13 , wherein the first number of periods is one. 15. The position sensing system of claim 13 , wherein the second number of periods is one more than the first number of periods.