Rotational sensing based on inductive sensing

The invention claimed is: 1. A rotational sensing system suitable for use in sensing rotation of a rotor, comprising: an axial target surface arranged for axial rotation with the rotor, and including at least one conductive target segment; and an inductive sensor mounted adjacent the axial target surface, including at least one inductive sense coil that is substantially parallel to and spaced from the axial target surface; such that rotor rotation causes the at least one target segment to rotate laterally under the at least one sense coil each rotor rotation cycle; and an inductance-to-digital converter (IDC) coupled to the at least one sense coil, to drive excitation current to the sense coil to project a time-varying magnetic sensing field (B-field) toward the axial target surface, to induce eddy currents in the target segment as it rotates under the sense coil; the inductive sensor to generate, in response to the rotation of the at least one target segment relative to the at least one sense coil and its projected B-field, a sensor response with a sensor phase cycle having: a phase_cycle_L MIN with the sense coil aligned with the target segment to output a minimum sensor response L MIN corresponding to a maximum induced eddy current; a phase_cycle_L MAX with the sense coil misaligned with the target segment to output a maximum sensor response L MAX corresponding to minimum induced eddy current, and where a number of sensor phase cycles in a rotor rotation cycle corresponds to the number of target segments; and the IDC to acquire sensor response measurements corresponding to sensor response for the at least one sense coil in successive sensor phase cycles including phase_cycle_L MIN and phase_cycle_L MAX , and to convert the sensor response measurements to sensor response data representative of rotation information for the rotating axial target surface that correlates to the sensor response measurements. 2. The rotational sensing system of claim 1 : wherein the axial target surface includes multiple target segments evenly spaced on the axial target surface; wherein the at least one sense coil is arranged relative to the multiple target segments such that the sensor response from the inductive sensor for the sense coil throughout a rotor rotation cycle is a substantially sinusoidal sensor response signal that cycles between phase_cycle_L MIN and phase_cycle_L MAX in a succession of sensor 360° phase cycles; and wherein the sensor response data corresponds to at least one of rotational frequency and rotational angle. 3. The rotational sensing system of claim 2 : wherein the inductive sensor includes multiple sense coils, in number equal to or less than the number of target segments; and wherein that multiple sense coils are arranged relative to the multiple target segments such that: sensor phase cycles are synchronized, so that sensor responses are synchronized. 4. The rotational sensing system of claim 1 : wherein the inductive sensor includes at least one sense coil pair with first and second sense coils wound with opposite polarity; and wherein the axial target surface includes at least one target segment pair, arranged on the axial target surface such that the sensor phase cycles for the paired sense coils are synchronized relative to the at least one target segment pair. 5. The rotational sensing system of claim 4 : wherein the axial target surface includes multiple target segments evenly spaced on the axial target surface; such that the sensor response of the paired sense coils throughout a rotor rotation cycle is a substantially sinusoidal sensor response signal that cycles between phase_cycle_L MIN and phase_cycle_L MAX as a succession of sensor 360° phase cycles; and wherein the rotational information corresponds to at least one of rotational frequency and rotational angle. 6. The rotational sensing system of claim 1 , wherein the rotor and the axial target surface can rotate in either direction, and: wherein the inductive sensor includes at least one set of I and Q sense coils arranged relative to the at least one target segment such that the respective sensor I and Q phase cycles are offset by an IQ phase offset; such that, for rotation in one direction, the sensor I phase cycle lags the sensor Q phase cycle, and for rotation in the other direction, the sensor I phase cycle leads the sensor Q phase cycle; and the IDC to convert I and Q sensor response measurements to sensor response data corresponding to rotation direction information for the rotating axial target surface. 7. The rotational sensing system of claim 6 : wherein the axial target surface includes multiple target segments evenly spaced on the axial target surface; such that the I and Q sensor responses of the I and Q sense coils throughout a rotor rotation cycle are substantially sinusoidal I and Q sensor response signals, that each cycle between phase_cycle_L MIN and phase_cycle_L MAX in a succession of sensor I and Q 360° phase cycles, respectively offset in phase by the IQ phase offset. 8. The rotational sensing system of claim 7 , wherein the IQ phase offset is substantially a quarter (90°) of the sensor I and Q 360° phase cycle. 9. The rotational sensing system of claim 1 , wherein the rotor is incorporated in an electric motor. 10. The method of claim 1 , wherein the rotor and the axial target surface can rotate in either direction, and: wherein the inductive sensor includes at least one set of I and Q sense coils arranged relative to the at least one target segment such that the respective sensor I and Q phase cycles are offset by an IQ phase offset; such that, for rotation in one direction, the sensor I phase cycle lags the sensor Q phase cycle, and for rotation in the other direction, the sensor I phase cycle leads the sensor Q phase cycle; and wherein the axial target surface includes multiple target segments evenly spaced on the axial target surface, such that the I and Q sensor responses of the I and Q sense coils throughout a rotor rotation cycle are substantially sinusoidal I and Q sensor response signals, that each cycle between phase_cycle_L MIN and phase_cycle_L MAX in a succession of sensor I and Q 360° phase cycles, respectively offset in phase by the IQ phase offset; and further comprising converting I and Q sensor response measurements to sensor response data corresponding to rotation direction information for the rotating axial target surface. 11. An inductance-to-digital converters (IDC) circuit for use in a system for sensing rotation of a rotor, the system including an axial target surface arranged for axial rotation with the rotor, and including at least one conductive target segment, the system including an inductive sensor mounted adjacent the axial target surface, including at least one inductive sense coil that is substantially parallel to and spaced from the axial target surface, such that rotor rotation causes the at least one target segment to rotate laterally under the at least one sense coil each rotor rotation cycle, the IDC circuit coupled to the at least one inductive sense coil, the circuit comprising: excitation circuitry to drive excitation current to the sense coil to project a time-varying magnetic sensing field (B-field) toward the axial target surface, thereby inducing eddy currents in the target segment as it rotates under the sense coil; in response to the rotation of the target segment relative to the sense coil and its projected B-field, the inductive sensor generating a sensor response with a sensor phase cycle having: a phase_cycle_L MIN with the sense coil aligned with the target segment to output a minimum