Inductive position sensor

What is claimed is: 1. A resonant rotor, for use in an inductive position sensor, comprising: a printed circuit board (PCB) comprising: a rotor core; a first rotor coil; and a rotor capacitor; wherein the first rotor coil includes a first twisted rotor loop; and wherein the rotor capacitor is connected in parallel with the first rotor coil on the PCB; and wherein the resonant rotor induces signals in each of two or more receive coils interconnected using one at least one of a common receive node and a three-phase circuit. 2. The resonant rotor of claim 1 , wherein the first twisted rotor loop includes a full 360-degree mechanical turn. 3. The resonant rotor of claim 1 , wherein the first rotor coil includes a second twisted rotor loop. 4. The resonant rotor of claim 3 , wherein the first twisted rotor loop is drawn symmetrically relative to the second twisted rotor loop. 5. The resonant rotor of claim 1 , comprising: a second twisted rotor loop off offset by ninety degrees relative to the first twisted rotor loop. 6. The resonant rotor of claim 3 , wherein the second twisted rotor loop is rotated, relative to the first twisted rotor loop, by half a rotational symmetry of the first twisted rotor loop. 7. The resonant rotor of claim 1 , wherein the first rotor coil has a first symmetry; wherein the inductive position sensor includes a stator; wherein an excitation coil is drawn on the stator and has a second symmetry; and wherein the first symmetry substantially corresponds to the second symmetry. 8. The resonant rotor of claim 1 , wherein the rotor core is a single layer substrate. 9. A resonant rotor comprising: a printed circuit board (PCB) comprising: a rotor core; a first rotor coil; and a rotor capacitor; wherein the first rotor coil includes a first twisted rotor loop; and wherein the rotor capacitor is connected in parallel with the first rotor coil on the PCB; wherein the resonant rotor is configured for use with an inductive position sensor; wherein the inductive position sensor comprises: an excitation element comprising: a power source; a control circuit; a first excitation coil, coupled to the power source, configured to generate a first electromagnetic field; a second excitation coil, coupled to the power source, configured to generate a second electromagnetic field; a third excitation coil, coupled to the power source, configured to generate a third electromagnetic field; wherein the control circuit controls a flow of electrical currents from the power source into and through one or more pairings of the first excitation coil, the second excitation coil and the third excitation coil; a receive element, comprising: a signal processor; a first receive coil, coupled to the signal processor, configured for at least one of the first electromagnetic field, the second electromagnetic field and the third electromagnetic field to induce a first voltage; and a second receive coil, coupled to the signal processor, configured for at least one of the first electromagnetic field, the second electromagnetic field and the third electromagnetic field to induce a second voltage; a third receive coil, coupled to the signal processor, configured for at least one of the first electromagnetic field, the second electromagnetic field and the third electromagnetic field to induce a third voltage; wherein the resonant rotor, based upon a current position of a target, is configured for coupling with each of the first electromagnetic field, the second electromagnetic field and the third electromagnetic field; and wherein the signal processor determines the current position of an object coupled to the resonant rotor based on a received voltage, wherein the received voltage is a combination of at least one of the first voltage, the second voltage and the third voltage. 10. The resonant rotor of claim 9 , wherein each of the first excitation coil, the second excitation coil and the third excitation coil and each of the first receive coil, the second receive coil and the third receive coil are looped around a stator core; and wherein each of the first excitation coil, the second excitation coil and the third excitation coil are connected in an excitation coil configuration comprising one of a common excitation node and a three-phase circuit. 11. The resonant rotor of claim 9 , wherein each of the first receive coil, the second receive coil and the third receive coil are connected in a receive coil configuration comprising one of a common receive node and a three-phase circuit. 12. The resonant rotor of claim 9 , wherein the control circuit selectively provides electrical power to each of the first excitation coil, the second excitation coil and the third excitation coil in an anti-series configuration; and wherein the control circuit selectively connects the signal processor to each of the first receive coil, the second receive coil and the third receive coil in the anti-series configuration. 13. The resonant rotor of claim 1 , wherein the inductive position sensor comprises two or more excitation coils; wherein a first set of mutual inductance arises between the two or more excitation coils and the rotor; and wherein a second set of mutual inductances arise between the two or more receive coils and the rotor; and wherein each of the first set of mutual inductances and the second set of mutual inductances are approximated by sine waveform functions of the rotor position. 14. The resonant rotor of claim 13 , wherein a third set of mutual inductances arise between the two or more excitation coils and the two or more receive coils; wherein the third set of mutual inductances generate a quadrature signal in a received voltage provided by the two or more receive coils; and wherein the first capacitor eliminates the quadrature signal. 15. The resonant rotor of claim 9 , wherein a corresponding excitation to rotor mutual inductance exists between each of the first excitation coil, the second excitation coil and the third excitation coil and the rotor; wherein a corresponding rotor to receive mutual inductance exists between each of the first receive coil, the second receive coil and the third receive coil and the rotor; wherein the position of the rotor at a given time results in a coupling of the corresponding excitation to rotor mutual inductance and the rotor to receive mutual inductance; and wherein the coupling is reflected in at least one of the first voltage, second voltage and third voltage. 16. A method for determining a position of an object using an inductive position sensor comprising: generating a first electromagnetic field using a first excitation coil; generating a second electromagnetic field using a second excitation coil; generating a third electromagnetic field using a third excitation coil; inducing a first voltage in a first receive coil; inducing a second voltage in a second receive coil; inducing a third voltage in a third receive coil; determining based on the first voltage, the second voltage and the third voltage a position of an object coupled to a resonant rotor; wherein the resonant rotor is coupled to each of the first electromagnetic field, the second electromagnetic field and the third electromagnetic field; wherein a corresponding rotor to receive coil mutual inductance arises between the resonant rotor and each of the first receive coil, the second receive coil and the third receive coil; wherein a change in the position of the object changes each of the corresponding rotor