Resonant inductive sensing with reduced noise folding

The invention claimed is: 1. A circuit suitable for use in resonant inductive sensing, comprising: input/output nodes coupleable to an inductive resonator; drive circuitry to drive excitation current pulses out of the input/output nodes with a modulation period synchronized with a resonator oscillation frequency; and pulse shaping circuitry to pulse shape the excitation current pulses so that each pair of excitation current pulses within the modulation period are identical. 2. The circuit of claim 1 , wherein the pulse shaping circuitry attenuates noise due to down modulation of signal energy around harmonics of the resonator oscillation frequency. 3. The circuit of claim 2 , wherein the pulse shaping circuitry attenuates noise due to uncertainty in the duration of the modulation period. 4. The circuit of claim 1 , further including filter circuitry to filter the excitation current pulses to attenuate signal energy at a one or more harmonics of the oscillation frequency. 5. The circuit of claim 1 ; wherein the drive circuitry comprises negative impedance circuitry coupled to the resonator, to drive excitation current pulses with a negative impedance that is controlled in response to an impedance control signal; and further comprising loop control circuitry to generate the impedance control signal based on resonator oscillation amplitude, such that the controlled negative impedance substantially cancels a resonator loss factor impedance, thereby maintaining a resonator oscillation amplitude corresponding to the resonator oscillation frequency. 6. A system suitable for resonant inductive sensing, comprising: an inductive resonator; and an inductance-to-digital conversion IDC unit, including drive circuitry to drive excitation current pulses to the resonator with a modulation period synchronized with a resonator oscillation frequency; and pulse shaping circuitry to pulse shape the excitation current pulses so that each pair of drive current pulses within the modulation period are identical. 7. The system of claim 6 , wherein the pulse shaping circuitry attenuates noise due to down modulation of signal energy around harmonics of the resonator oscillation frequency. 8. The system of claim 7 , wherein the pulse shaping circuitry attenuates noise due to uncertainty in the duration of the modulation period. 9. The system of claim 6 , wherein the IDC unit further includes filter circuitry to filter the excitation current pulses to attenuate signal energy at a one or more harmonics of the oscillation frequency. 10. The system of claim 6 , wherein the drive circuitry comprises negative impedance circuitry coupled to the resonator, to drive excitation current pulses with a negative impedance that is controlled in response to an impedance control signal; and wherein the IDC unit further includes loop control circuitry to generate the impedance control signal based on resonator oscillation amplitude, such that the controlled negative impedance cancels a resonator loss factor impedance, thereby maintaining a resonator oscillation amplitude corresponding to the resonator oscillation frequency. 11. A method, useable for resonant inductive sensing with an inductive resonator, comprising: driving excitation current pulses to the resonator with a modulation period synchronized with a resonator oscillation frequency; and pulse shaping the excitation current pulses so that that each pair of drive current pulses within the modulation period are identical. 12. The method of claim 11 , wherein the pulse shaping attenuates noise due to down modulation of signal energy around harmonics of the resonator oscillation frequency. 13. The method of claim 12 , wherein pulse shaping attenuates noise due to uncertainty in the duration of the modulation period. 14. The method of claim 11 , further comprising filtering the drive current pulses to attenuate signal energy at a one or more harmonics of the oscillation frequency. 15. The method of claim 11 , wherein the driving excitation current pulses is accomplished by driving excitation current pulses with a negative impedance that is controlled in response to an impedance control signal; and further comprising generating the impedance control signal based on resonator oscillation amplitude, such that the controlled negative impedance cancels a resonator loss factor impedance, thereby maintaining a resonator oscillation amplitude corresponding to the resonator oscillation frequency.