Wireless inductive power transfer

The invention claimed is: 1. A power transmitter for providing a power transfer to a power receiver using a wireless inductive power transfer signal, the power transmitter comprising: a transmitter inductor for generating an inductive carrier signal for load modulation in response to a voltage drive signal applied to at least one of the transmitter inductor and a resonance circuit comprising the transmitter inductor; a measurement unit arranged to, for cycles of a reference signal synchronized to the voltage drive signal, perform first measurements of at least one of an inductor current and an inductor voltage for the transmitter inductor, each first measurement being over a measurement time interval being a subset of a cycle period of the reference signal and having a first time offset relative to the reference signal; an adaptor for varying the first time offset and detecting an optimum measurement timing offset for the varying first time offset, the optimum measurement timing offset being detected as a time offset for the varying first time offset which results in a maximum demodulation depth for a demodulation depth reflecting a difference measure for first measurements generated by the measurement unit with the first time offset for different modulation loads of the inductive carrier signal; and a demodulator for demodulating load modulation of the inductive carrier signal from first measurements with the first time offset set to the optimum measurement timing offset. 2. The power transmitter of claim 1 wherein the adaptor is arranged to vary a duration of the measurement time interval to determine an optimum measurement duration resulting in a maximum demodulation depth; and the demodulator is arranged to demodulate the load modulation from first measurements with a duration of the measurement time interval corresponding to the optimum measurement duration. 3. The power transmitter of claim 1 , wherein the first measurements are of the inductor current, and the measurement unit is further arranged to, for cycles of the reference signal, perform second measurements of the inductor voltage, each second measure being in a second measurement time interval being a subset of the cycle period of the reference signal and having a second time offset relative to the reference signal; the adaptor is arranged to vary the second time offset to determine a second optimum measurement timing offset resulting in a second maximum demodulation depth for a demodulation depth reflecting a difference measure for second measurements for different modulation loads of the inductive carrier signal; and the demodulator is arranged to demodulate the load modulation from second measurements with the second time offset set to the second optimum measurement timing offset. 4. The power transmitter of claim 1 , wherein the measurement unit is arranged to generate first measurements of the inductor current and the inductor voltage with different time offsets relative to the reference signal, and the demodulator is arranged to demodulate the load modulation from both measurements of the inductor current and the inductor voltage. 5. The power transmitter of claim 1 wherein the reference signal is one of the voltage drive signal and a drive signal for a switch circuit generating the voltage drive signal. 6. The power transmitter of claim 1 wherein the inductive carrier signal is the power transfer signal. 7. The power transmitter of claim 6 further comprising a power transfer adapter arranged to select a frequency of the power transfer signal based on a power transfer property. 8. The power transmitter of claim 7 wherein the power transfer adapter is arranged to vary the frequency of the power transfer signal in response to power control messages received from the power receiver. 9. The power transmitter of claim 1 wherein the power transfer adapter is arranged to initiate a determination of the optimum measurement timing offset in response to a change of the frequency of the inductive carrier signal. 10. The power transmitter of claim 1 wherein the measurement unit is arranged to, for each first measurement, perform within the same cycle of the reference signal, a second measurement of at least one of the inductor current and the inductor voltage, the second measurement being in measurement time intervals having a timing corresponding to the measurement time intervals for the first measurements but with a time offset half shifted by half the cycle period offset relative to the measurement time intervals of the first measurements; and the demodulator is arranged to demodulate the load modulation from both the first measurements and the second measurements. 11. The power transmitter of claim 1 wherein the first measurements are of the inductor current of the transmitter inductor. 12. The power transmitter of claim 1 wherein the adapter is arranged to initiate a determination of the optimum measurement timing offset in response to a detection of a change in a loading of the inductive carrier signal. 13. The power transmitter of claim 1 wherein the adapter is arranged to initiate a determination of the optimum measurement timing offset in response to a detection of a change in a coupling between the power transmitter and the power receiver. 14. A method of operation for a power transmitter arranged to provide a power transfer to a power receiver using a wireless inductive power transfer signal, the method comprising: a transmitter inductor generating an inductive carrier signal for load modulation in response to a voltage drive signal applied to at least one of the transmitter inductor and a resonance circuit comprising the transmitter inductor; for cycles of a reference signal synchronized to the voltage drive signal, performing first measurements of at least one of an inductor current and an inductor voltage for the transmitter inductor, each first measurement being over a measurement time interval being a subset of a cycle period of the reference signal and having a first time offset relative to the reference signal; varying the first time offset and detecting an optimum measurement timing offset as a time offset for the varying first time offset which results in a maximum demodulation depth for a demodulation depth reflecting a difference measure for first measurements generated with the first time offset for different modulation loads of the inductive carrier signal; and demodulating load modulation of the inductive carrier signal from first measurements with the first time offset set to the optimum measurement timing offset.