Systems and methods of wireless power transfer with interference detection

Therefore, at least the following is claimed: 1. A system for wireless power transfer comprising: a secondary side controller configured to monitor a sensed power and to produce a feedback signal comprising parameters relative to the sensed power; and a modulation module configured to modulate a representation of the feedback signal, the modulation transmitted to a primary side controller, the primary side controller configured to demodulate the modulation from the modulation module; compare the demodulated representation of the feedback signal with a primary power, and prohibit charging if efficiency of secondary power versus primary power is less than a predetermined level. 2. The system of claim 1 , wherein the predetermined level is user configurable. 3. The system of claim 1 , wherein the primary controller controls a resonant converter. 4. The system of claim 1 , wherein the predetermined level comprises a level under which indicates presence of a parasitic metal element. 5. A method for wireless power transfer, comprising: generating a power signal utilizing a primary side transmitter inductively coupled to a secondary side receiver; receiving the power signa in the inductively coupled secondary side receiver; transmitting from the inductively coupled receiver a representation comprising parameters relative to sensed power from a secondary side of an inductive coupling utilized to transfer power from a primary side to the secondary side; applying the parameters to a power loss equation to determine efficiency of power transfer from primary to secondary wherein the power loss equation is PMD= A*TX _pwr− B*TX _pwr 2 −C−α*RX _pwr 2 −β*RX _pwr−γ where A,B, & C are the transmission related terms and α, β, & γ are the reception related terms. A is used to apply arbitrary units to the result. If PMD is in mW and TX_pwr is in Watts, A would be set to 1/1000; if they have the same units (Watts in, Watts out, then A=1). B is a scaling factor which relates the (TX_pwr 2 ) term to loss, and the constant C is the loss in the transmitter which is constant regardless of power; and determining the presence of a parasitic metallic element based on the efficiency; and interrupting generation of the power signal from the transmitter to the inductively coupled receiver is a parasitic element is detected. 6. The method of claim 5 , wherein the parameters comprise at least one of a constant relative to the sensed secondary power and quiescent dissipation on the secondary side. 7. The method of claim 5 , further comprising: sensing power on the secondary side; generating a representation of the sensed power; modulating the representation; and transmitting the modulated representation to the primary side. 8. The method of claim 7 , wherein the modulating comprises at least one of amplitude modulating, frequency modulating, phase shift keying, pulse width modulating, infrared signaling and radio frequency signaling. 9. A system for wireless power transfer comprising: a primary side controller configured to: generate a power signal which is transmitted by a transmitter across an inductive coupling to a receiver; receive at the transmitter a representation comprising parameters relative determine if a parasitic metallic element is present by applying the parameters to a power loss equation to determine an efficiency of secondary sensed power versus primary power, wherein the power loss equation is PMD= A*TX _pwr− B*TX _pwr 2 −C−α*RX _pwr 2 −β*RX _pwr−γ where A,B, & C are the transmission related terms and α, β, & γ are the reception related terms. A is used to apply arbitrary units to the result. If PMD is in mW and TX_pwr is in Watts, A would be set to 1/1000; if they have the same units (Watts in, Watts out, then A=1). B is a scaling factor which relates the (TX_pwr 2 ) term to loss, and the constant C is the loss in the transmitter which is constant regardless of power; and interrupt generation of the power signal from the transmitter to the inductively coupled receiver if a parasitic element is detected. 10. The system of claim 9 , wherein the parameters comprise at least one of a constant relative to the sensed secondary power and quiescent dissipation on the secondary side. 11. The system of claim 9 , wherein the representation of the secondary sensed power is modulated on the secondary side. 12. The system of claim 11 , wherein the representation of the secondary sensed current is modulated by at least one of amplitude modulation, pulse width modulation, frequency modulation, phase shift keying, infrared signaling, and radio frequency signaling. 13. The system of claim 11 , wherein the primary side controller is further configured to demodulate the modulated representation of the secondary sensed power. 14. A wireless power transfer system comprising: a primary side transmitter generating a power signal in a coil for inductive coupling to a secondary side receiver, the primary side transmitter determining a power level received by the primary side transmitter from a power source and determining losses in the primary side transmitter; a secondary side receiver receiving the inductively coupled power from the primary side transmitter and determining a power level of the inductively coupled power, the secondary side receiver transmitting a signal related to the power level at the receiver to the transmitter; the transmitter utilizing the power level received at the transmitter, the power losses in the transmitter and the power level received at the receiver to determine power received by a foreign object and interrupting the generation of the power signal if the power received by the foreign object exceeds a threshold. 15. The system of claim 14 , wherein the parameters comprise at least one of a constant relative to the sensed secondary power and quiescent dissipation on the secondary side. 16. The system of claim 14 , wherein the modulation module transmits at least one of an amplitude modulated, pulse width modulated, frequency modulated, phase shift keyed, infrared, and radio frequency signal. 17. In a system for wireless power transfer from a primary side transmitter to a secondary side receiver, a primary side transmitter comprising: a primary side transmitter generating a power signal in a coil for inductive coupling to a secondary side receiver, the primary side transmitter determining a power level received by the primary side transmitter from a power source, determining losses in the primary side transmitter and receiving a signal representative of a power level received by a receiver; the transmitter utilizing the power level received at the transmitter, the power losses in the transmitter and the power level received at the receiver to determine power received by a foreign object and interrupting the generation of the power signal if the power received by the foreign object exceeds a threshold.