Beamforming for wireless power transfer

The invention claimed is: 1. A method comprising: determining a position of a second wireless power transfer device relative to a first wireless power transfer device; determining a phase/amplitude map for a notional field in a plane of an aperture of the second wireless power transfer device; performing a Fourier transform on the phase/amplitude map for the notional field to generate a spatial frequency representation of the notional field in the plane of the aperture of the second wireless power transfer device; determining a phase/amplitude map for a second notional field in a plane of an aperture of the first wireless power transfer device based on the spatial frequency representation of the notional field in the plane of the aperture of the second wireless power transfer device and the position of the second wireless power transfer device; generating control signals for one or more transducer elements of the first wireless power transfer device based on the determined phase/amplitude map for the second notional field in the plane of the aperture of the first wireless power transfer device; supplying the control signals for the one or more transducer elements to the one or more transducer elements; and transmitting waveforms from the one or more transducer elements based on the supplied control signals. 2. The method of claim 1 , wherein the aperture of the second wireless power transfer device is located at one or more transducers of the second wireless power transfer device. 3. The method of claim 2 , wherein the phase/amplitude map represents the notional field in the plane of the aperture of the second wireless power transfer device at the one or more transducers of the second wireless power transfer device. 4. The method of claim 1 , wherein determining a phase/amplitude map for a second notional field in a plane of an aperture of the first wireless power transfer device based on the spatial frequency representation of the notional field in the plane of the aperture of the second wireless power transfer device and the position of the second wireless power transfer device further comprises: determining a spatial frequency representation of the second notional field based on a propagation of the notional field from the plane of the aperture of the second wireless power transfer device to the plane of the aperture of the first wireless power transfer device; and performing an inverse Fourier transform on the spatial frequency representation of the second notional field to determine the phase/amplitude map of the second notional field. 5. The method of claim 4 , wherein determining a spatial frequency representation of the phase/amplitude map of the second notional field based on a propagation of the notional field from the plane of the aperture of the second wireless power transfer device to the plane of the aperture of the first wireless power transfer device further comprises: applying a transformation kernel to the spatial frequency representation of the notional field in the plane of the aperture of the second wireless power transfer device to determine the spatial frequency representation of the second notional field in the plane of the aperture of the first wireless power transfer device. 6. The method of claim 1 , wherein generating control signals for one or more transducer elements of the first wireless power transfer device based on the determined phase/amplitude map for the second notional field in the plane of the aperture of the first wireless power transfer device further comprises: windowing the complex conjugate of the determined phase/amplitude map for the second notional field in the plane of the aperture of the first wireless power transfer device to the aperture of the first wireless power transfer device. 7. The method of claim 1 , further comprising determining phase corrections for the aperture of the second wireless power transfer device that make the phase/amplitude map of the notional field quasi-parallel to the plane of the aperture of the first wireless power transfer device. 8. The method of claim 1 , wherein the one or more transducers are ultrasonic transducers, RF transducers, or optical transducers. 9. The method of claim 1 , wherein the phase/amplitude map of the notional field comprises coherent phase. 10. A system for beamforming for wireless power transfer comprising: a plurality of elements adapted and configured to transmit waveforms for a transmitted beam based on supplied control signals; a receiver position detector adapted to determine a position of a receiving wireless power transfer device; and a computing device comprising a transducer signal generator configured to determine a phase/amplitude map for a notional field in a plane of an aperture of the receiving wireless power transfer device, perform a Fourier transform on the phase/amplitude map for the notional field to generate a spatial frequency representation of the notional field in the plane of the aperture of the receiving wireless power transfer device, determine a phase/amplitude map for a second notional field in a plane of an aperture of the a transmitting wireless power transfer device comprising the plurality of elements based on the spatial frequency representation of the notional field in the plane of the aperture of the receiving wireless power transfer device and the position of the receiving wireless power transfer device, generate control signals for one or more of the plurality of elements based on the determined phase/amplitude map for the second notional field in the plane of the aperture of the transmitting wireless power transfer device, and supply the control signals for one or more of the plurality of elements to the one or more of the plurality of elements. 11. The system of claim 10 , further comprising a transducer control adapted and configured to receive the control signals from the transducer signal generator and supply the control signals to the one or more of the plurality of elements. 12. The system of claim 10 , wherein the plurality of elements are ultrasonic transducers, RF transducers, or optical transducers. 13. The system of claim 10 , wherein the aperture of the receiving wireless power transfer device is located at one or more transducer elements of the receiving wireless power transfer device. 14. The system of claim 13 , wherein the phase/amplitude map represents the notional field in the plane of the aperture of the receiving wireless power transfer device at the one or more transducer elements of the receiving wireless power transfer device. 15. The system of claim 10 , wherein the transducer signal generator is configured to determine the phase/amplitude map for the second notional field in a plane of the aperture of the transmitting wireless power transfer device based on the spatial frequency representation of the notional field in the plane of the aperture of the receiving wireless power transfer device and the position of the receiving wireless power transfer device by determining a spatial frequency representation of the second notional field based on a propagation of the notional field from the plane of the aperture of the receiving wireless power transfer device to the plane of the aperture of the transmitting wireless power transfer device, and performing an inverse Fourier transform on the spatial frequency representation of the second notional field to determine the phase/amplitude map of the second notional field. 16. The system of claim 15 , wherein the wherein the transducer signal generator is configured to determine the spatial fr