Near-field communication (NFC) system and method for private near-field communication

What is claimed is: 1. A method of near-field communication (NFC), the method comprising: electromagnetically coupling an NFC receiver with an NFC transmitter through a resonance-coupled channel, the resonance-coupled channel formed by mutually coupled reactive elements operating under near field conditions; generating, by the NFC receiver, a reference signal; generating, by the NFC receiver, a mask based on a privacy level; generating, by the NFC receiver, a channel-masking signal by modulating the reference signal with the mask; performing, by the NFC receiver and transmitter, a calibration process, the calibration process comprising: transmitting, by the NFC transmitter, a known training sequence by affecting an impedance of the resonance-coupled channel; receiving, by the NFC receiver, the known training sequence; determining, by the NFC receiver, calibration parameters, including both amplitude and phase scaling parameters, based on channel load impedances due to near-field channel conditions; generating, by the NFC receiver, a scaled channel-masking signal by applying the scaling parameters to the channel-masking signal; applying, by the NFC receiver, the scaled channel-masking signal to the resonance-coupled channel; modulating, by the NFC transmitter, the impedance of the resonance-coupled channel based on bit values of stored binary data; and unmasking, by the NFC receiver, a signal received through the resonance-coupled channel and determining the stored binary data. 2. The method of claim 1 , wherein modulating the impedance of the resonance-coupled channel comprises varying the impedance in the NFC transmitter between an open and a short. 3. The method of claim 2 , wherein the binary data comprises a key used for open encrypted communications. 4. The method of claim 1 , wherein determining the calibration parameters further comprises determining amplitude and phase scaling parameters that result in a residual signal that is close to zero when the NFC transmitter and the NFC receiver are in NFC communication range but not under the near field conditions. 5. The method of claim 4 , wherein determining the calibration parameters further comprises basing the phase scaling parameters on a delay between the scaled channel-masking signal and the resonance-coupled signals and removing effects of the resonance-coupled channel and effects of the channel-masking signal. 6. The method of claim 5 , wherein the near field conditions correspond to a channel distance of less than a quarter-wavelength of an operating frequency of communications between the NFC transmitter and the NFC receiver. 7. The method of claim 4 , wherein the calibration process further comprises determining scaling parameters for the scaling to provide a zero output when the impedance of the resonance-coupled channel is unaffected by the NFC transmitter. 8. The method of claim 1 , wherein the calibration process further comprises determining a load-impedance estimate of the resonance-coupled channel that takes into account near-field effects of the NFC receiver and the NFC transmitter. 9. The method of claim 1 , wherein the calibration process further comprises using a handshake that includes a known training sequence and determining, based on the known training sequence, channel effects and signal delay between the NFC receiver and the NFC transmitter, and the scaling comprises phase scaling determined by the signal delay and amplitude scaling determined by the channel effects. 10. The method of claim 1 , wherein generating the channel-masking signal comprises generating a random symbol and at least one of a random amplitude and a random phase. 11. The method of claim 1 , wherein the channel-masking signal is generated by modulating the reference signal with a random symbol generated using a random symbol mask, a random amplitude generated using an amplitude mask and a random phase generated using a phase mask. 12. The method of claim 11 , wherein the channel-masking signal further is generated by modulating the reference signal with a random amplitude generated using an amplitude mask and a random phase generated using a phase mask to generate in-phase (I) and quadrature-phase (Q) signals. 13. The method of claim 1 , wherein determining the calibration parameters further comprises addressing large-scale variations in the received resonance-coupled signals Including variations originating due to at least one of physical distance between the NFC receiver and the NFC transmitter or hardware inconsistencies between the NFC receiver and the NFC transmitter. 14. The method of claim 1 , wherein determining calibration parameters further comprises determining a transfer function block operating in an impedance domain, and applying the transfer function block to compensate for medium and physical implementation limitations by adjusting a characteristic impedance of the NFC receiver to match a characteristic impedance of the NFC transmitter and changes introduced by a physical channel environment. 15. The method of claim 1 , wherein the resonance-coupled channel comprises a plurality of channels in which each channel has a different resonance and is associated with a different set of reactive elements. 16. The method of claim 1 , wherein the channel-masking signal is generated by modulating the reference signal using a random symbol mask, the random symbol mask comprising a randomly constructed scrambling signal that corresponds to a particular modulation of the reference signal. 17. The method of claim 1 , wherein determining the calibration parameters further comprises determining a delay to be applied to the channel-masking signal to mimic a delay introduced by a physical separation between the NFC receiver and the NFC transmitter. 18. A near-field communication (NFC) system comprising: an NFC transmitter comprising a circuit, the circuit comprising: a transmitter reactive element, a switch arranged to receive data stored in the NFC transmitter, and an impedance element connected to the transmitter reactive element via the switch, the switch configured to switch an impedance of the circuit based on the data received by the switch at a switching rate based on a resonance frequency of a resonance-coupled channel; and an NFC receiver electromagnetically coupled with the NFC transmitter under near field conditions to receive the data from the NFC transmitter through the resonance-coupled channel and to generate a mask based on privacy level, the NFC receiver comprising: a reference signal source to supply a reference signal; a channel-masking signal generator connected with the reference signal source, the channel-masking signal generator configured-to generate a random channel-masking signal by modulating the reference signal with the mask; a scaling element connected with the channel-masking signal generator, the scaling element configured to determine scaling parameters based on the near field conditions the NFC receiver and transmitter are configured to perform a calibration process, the NFC transmitter being configured to transmit a known training sequence by affecting an impedance of the resonance-coupled channel, the NFC receiver being configured to receive the known training sequence and the NFC receiver being configured to determine calibration parameters, including both amplitude and phase scaling parameters, based on channel load impedances due to near-field channel conditions; the NFC receiver configured to generate a scaled channel-masking signal by applying the scali