Multi-level rotational resolvers using inductive sensors

What is claimed is: 1. A rotational resolver comprising: a rotational shaft; at least one conductive eccentric coarse resolution disc fixed on the shaft; and at least one conductive fine resolution disc fixed on the shaft, the fine resolution disc defining a plurality of generally semicircular protruding edge segments; the fine resolution disc to provide a rotational resolution that is greater than the coarse resolution disc; at least one conductive coarse-disc sensing coil disposed adjacent an edge of the coarse resolution disc; and at least one conductive fine-disc sensing coil disposed adjacent the edge of the fine resolution disc. 2. The rotational resolver of claim 1 , wherein the coils are oriented for axial sensing of the respective disc. 3. The rotational resolver of claim 1 , wherein rotation of the shaft and thereby the discs causes the distance between each coarse-disc sensing coil and the coarse resolution disc to cycle between a maximum distance and a minimum distance each rotation cycle, corresponding to one sensing cycle per rotation cycle. 4. The rotational resolver of claim 3 , wherein rotation of the shaft and thereby the discs causes the distance between each fine-disc sensing coil and the fine resolution disc to cycle between a maximum, a minimum and back to the maximum during the passage of each edge segment, corresponding to a number of sensing cycles per rotation cycle equal to the number of edge segments. 5. The rotational resolver of claim 1 wherein the at least one coarse-disc sensing coil comprises at least one pair of coarse-disc sensing coils comprising an in-phase coarse-disc sensing coil and a quadrature coarse-disc sensing coil, and the at least one fine-disc sensing coil comprises at least one pair of fine-disc sensing coils comprising an in-phase fine-disc sensing coil and a quadrature fine-disc sensing coil. 6. The rotational resolver of claim 1 , wherein the at least one conductive fine resolution disc comprises a pair of conductive fine resolution discs, with a first of the fine resolution discs disposed in-phase and a second of the fine resolution discs disposed in quadrature with respect to the first fine resolution disc. 7. The rotational resolver of claim 6 , wherein rotation of the shaft, and thereby the discs, causes the distance between each fine-disc sensing coil and the fine resolution disc to cycle between a maximum, a minimum and back to the maximum during the passage of each edge segment, and the one or more conductive coils disposed adjacent the edge of one of the first or second fine resolution discs outputting a generally sinusoidal-like cyclic first signal and another of the one or more conductive coils disposed adjacent the edge of the other of the first or second fine resolution discs outputting a generally sinusoidal-like cyclic second signal that is generally quadrature to the first signal. 8. The rotational resolver of claim 7 wherein the at least one coarse-disc sensing coil comprises at least one pair of coarse-disc sensing coils comprising an in-phase coarse-disc sensing coil and a quadrature coarse-disc sensing coil, and the at least one fine-disc sensing coil comprises at least one pair of fine-disc sensing coils comprising an in-phase fine-disc sensing coil and a quadrature fine-disc sensing coil, the in-phase fine-disc sensing coil disposed adjacent to one of the first or second fine resolution discs and the quadrature fine-disc sensing coil disposed adjacent to the other of the first or second fine resolution discs. 9. The rotational resolver of claim 8 wherein the in-phase fine-disc sensing coil and the quadrature fine-disc sensing coil are aligned with one another, generally parallel to the shaft. 10. A method for rotational position sensing comprising: mounting an eccentric conductive coarse resolution disc, on a shaft; mounting a conductive fine resolution disc defining a plurality of generally semicircular protruding edge segments on the shaft; the fine resolution disc to provide a rotational resolution that is greater than the coarse resolution disc; disposing at least one pair of orthogonally positioned conductive coarse-disc sensing coils adjacent an edge of the coarse resolution disc for axial sensing of the coarse resolution disc; and disposing at least one conductive fine-disc sensing coil adjacent the edge of the fine resolution disc for axial sensing of the fine resolution disc. 11. The method of claim 10 further comprising rotating the shaft and thereby the discs, causing the distance between each coarse-disc sensing coil and the coarse resolution disc to cycle between a maximum distance and a minimum distance each rotation cycle, corresponding to one sensing cycle per rotation cycle, and causing the distance between each fine-disc sensing coil and the fine resolution disc to cycle between a maximum, a minimum and back to the maximum during the passage of each edge segment, corresponding to a number of sensing cycles per rotation cycle equal to the number of edge segments; sensing by each of the conductive coarse-disc sensing coils the one sensing cycle per rotation cycle; and sensing by each of the one or more conductive fine-disc sensing coils a plurality of sensing cycles per rotation corresponding to a rotational position of the discs. 12. The method of claim 10 , wherein each pair of orthogonally positioned conductive coarse-disc sensing coils comprises an in-phase coarse-disc sensing coil and a quadrature coarse-disc sensing coil, and the at least one fine-disc sensing coil comprises at least one pair of fine-disc sensing coils comprising an in-phase fine-disc sensing coil and a quadrature fine-disc sensing coil. 13. The method of claim 10 , further comprising: mounting a second conductive fine resolution disc defining a plurality of generally semicircular protruding edge segments on the shaft, with a first of the fine resolution discs disposed in-phase and a second of the fine resolution discs disposed in quadrature with respect to the first fine resolution disc; and rotating the shaft, and thereby the discs, causing the distance between each fine-disc sensing coil and an associated fine resolution disc to cycle between a maximum, a minimum and back to the maximum during the passage of each edge segment, the one or more conductive coils disposed adjacent the edge of one of the first or second fine resolution discs outputting a generally sinusoidal-like cyclic first signal and another of the one or more conductive coils disposed adjacent the edge of the other of the first or second fine resolution discs outputting a generally sinusoidal-like cyclic second signal that is generally quadrature to the first signal. 14. The method of claim 13 wherein the at least one fine-disc sensing coil comprises at least one pair of fine-disc sensing coils comprising an in-phase fine-disc sensing coil and a quadrature fine-disc sensing coil and the method further comprises: disposing the in-phase fine-disc sensing coil adjacent to one of the first or second fine resolution discs; and disposing the quadrature coil fine-disc sensing disposed adjacent to the other of the first or second fine resolution discs, generally aligned with the in-phase fine-disc sensing coil with the in-phase fine-disc sensing coil and the quadrature fine-disc sensing coil generally parallel to the shaft. 15. A rotational position and speed sensing system comprising: an inductance to digital converter; a plurality of inductance tank circuits; and at least one rotational resolver, each operatively coupled to the inductance to digital converter via a plurality