Inductive position-sensing

What is claimed is: 1. A position sensing system comprising: an inductive position element that comprises a position inductor; a plurality of inductive load elements, each comprising a load inductor; the inductive position element movable relative to the inductive load elements; the inductive position element coupled to receive position signals corresponding to an inductance associated with the position inductor; each of the plurality of inductive load elements to be selectively controlled in response to modulation signals to provide a corresponding mutual inductance between the position inductor and the respective load inductor, the corresponding mutual inductance depending on a position of the inductive position element relative to the respective load inductor; and a position controller to generate the position and modulation signals, and to convert the position signals to inductances associated with the position signals, and to calculate the position of the inductive position element relative to the plurality of inductive load elements based on a difference of the inductances associated with the position signals with respect to the mutual inductance between the position inductor and each respective load inductor. 2. The system of claim 1 , wherein each of the plurality of inductive load elements comprises a switch to be controlled by a respective modulation signal, wherein each of the plurality of inductive load elements to be sequentially activated via the respective modulation signal associated with each respective inductive load element. 3. The system of claim 1 , wherein the position controller comprises: a load modulator to generate a plurality of modulation signals in a predetermined sequence, each of the plurality of modulation signals being associated with a respective one of the plurality of inductive load elements to activate the plurality of inductive load elements in the predetermined sequence; and an inductance sensor to generate the position signals and to convert the inductances associated with the position signals to a displacement signal corresponding to the position of the inductive position element relative to the plurality of inductive load elements. 4. The system of claim 1 , wherein the inductive position element comprises an inductive coupling to the position controller to receive the position signal and is configured to rotate about an axis, the position controller operable to calculate an angular position of the inductive position element relative to the plurality of inductive load elements based on the changes to the position signal in response to the respective changes to the inductive load between the position inductor and the respective load inductor associated with each of the plurality of inductive load elements. 5. The system of claim 4 , wherein the position inductor comprises a plurality of position inductors arranged in series and disposed in a polar array about the inductive position element, wherein every alternating one of the plurality of position inductors has an opposite polarity relative to the remaining plurality of position inductors, wherein the plurality of load elements are disposed at predetermined fixed angles with respect to the axis. 6. The system of claim 5 , wherein the inductive position element further comprises at least one additional inductor disposed along a contiguous portion within a first angle with respect to the axis of the inductive position element, wherein a first portion of the plurality of inductors are disposed within the first angle and wherein a second portion of the plurality of inductors are disposed outside of the first angle, wherein the plurality of load elements comprises at least one coarse measurement load element to be selectively activated to provide a respective inductive load of the respective at least one additional inductor to provide a coarse measurement indication of the angular position of the inductive position element. 7. The system of claim 5 , wherein the inductive position element comprises: an inductive coupling inductor to provide the inductive coupling to the position controller; a first position inductor arranged in series with the inductive coupling inductor and being disposed along a contiguous portion of approximately 180° of the inductive position element to provide inductive coupling with a first load element to determine a first coarse measurement of the position of the inductive position element; a pair of second position inductors arranged in series with each other and with the first position inductor and disposed along respective contiguous portions of approximately 180° of the inductive position element to provide inductive coupling with a pair of second load elements arranged orthogonally with respect to each other to determine a second coarse measurement of the position of the inductive position element; and a plurality of third position inductors arranged in series with each other and with the pair of second position inductors and being disposed in a polar array at approximately equal angles with respect to the axis to provide inductive coupling with a plurality of third load elements arranged at predetermined angles with respect to the axis to determine a fine measurement of the position of the inductive position element. 8. The system of claim 5 , wherein the position controller is configured to provide the position signal to each of the plurality of load elements and to provide a phase-shift of the position signal with respect to each of the plurality of load elements based on the respective modulation signal, wherein the position controller is configured to calculate the position of the inductive position element relative to the plurality of inductive load elements based on a minimum inductive load and a maximum inductive load through a period of the position signal based on the respective phase-shift of the position signal with respect to each of the plurality of load elements. 9. The system of claim 4 , wherein position inductor is arranged to generate an axial magnetic field in-plane with the inductive position element, such that the axial magnetic field is orthogonal to the axis, wherein the plurality of load elements comprises a first load element and a second load element that are alternately activated via the modulation signals, the load inductor in each of the first and second load elements being arranged orthogonally with respect to each other and comprising axial magnetic fields that are likewise in-plane with the inductive position element. 10. The system of claim 1 , wherein each of the plurality of load elements comprises: an amplifier configured to receive and amplify the position signal to provide the amplified position signal through the load inductor; and a phase-shifter configured to provide a respective phase-shift of the position signal based on the modulation signal to provide a sequential phase-shift of the position signal through the load inductor relative to the load inductor associated with each other one of the plurality of load elements. 11. The system of claim 1 , wherein each of the plurality of inductive load elements further comprises a capacitor, such that the capacitor and the respective load inductor are operable as a resonator in response to activation of the respective one of the plurality of inductive load elements. 12. A method for inductive position measurement, the method comprising: configuring an inductive position element, including a position inductor, for movement past a plurality of inductive load elements, each including a load inductor; providing position signals through the position inductor of the inductive pos