Disclosed is an apparatus for use in wireless energy transfer, which includes a first resonator structure configured to transfer energy non-radiatively with a second resonator structure over a distance greater than a characteristic size of the second resonator structure. The non-radiative energy tra
Disclosed is an apparatus for use in wireless energy transfer, which includes a first resonator structure configured to transfer energy non-radiatively with a second resonator structure over a distance greater than a characteristic size of the second resonator structure. The non-radiative energy transfer is mediated by a coupling of a resonant field evanescent tail of the first resonator structure and a resonant field evanescent tail of the second resonator structure.
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1. An energy transferring system, comprising: a source-side resonator for receiving an energy, wherein the source-side resonator has a first resonant frequency;an intermediate resonant module having a second resonant frequency substantially the same with the first resonant frequency, wherein the ene
1. An energy transferring system, comprising: a source-side resonator for receiving an energy, wherein the source-side resonator has a first resonant frequency;an intermediate resonant module having a second resonant frequency substantially the same with the first resonant frequency, wherein the energy on the source-side resonator is coupled to the intermediate resonant module, such that non-radiative energy transfer is performed between the source-side resonator and the intermediate resonant module, and the coupling between the source-side resonator and the intermediate resonant module corresponds to a first coupling coefficient; anda device-side resonator having a third resonant frequency substantially the same with the second resonant frequency, wherein the energy coupled to the intermediate resonant module is further coupled to the device-side resonator, such that non-radiative energy transfer is performed between the intermediate resonant module and the device-side resonator, and the coupling between the intermediate resonant module and the device-side resonator corresponds to a second coupling coefficient;wherein the coupling between the source-side resonator and the device-side resonator corresponds to a third coupling coefficient,wherein the source-side resonator, the intermediate resonant module, and the device-side resonator are movable relative to one another, andwherein:the source-side resonator has a resonant frequency ω1, an intrinsic loss rate Γ1, and an intrinsic quality factor Q1=ω1/(2Γ1);the device-side resonator has a resonant frequency ω2, an intrinsic loss rate Γ2, and an intrinsic quality factor Q2=ω2/(2Γ2);the intermediate resonant module has a resonant frequency ω3, an intrinsic loss rate Γ3, and an intrinsic quality factor Q3=ω3/(2Γ3),the first coupling coefficient is κ1 and the second coupling coefficient is κ2, and wherein the intrinsic loss rates satisfy κ1/√{square root over (Γ1Γ3)}>1 and κ2/√{square root over (Γ3Γ2)}>1 for a range of distances between the source-side resonator, the intermediate resonant module, and the device-side resonator. 2. The energy transferring system according to claim 1, wherein the first coupling coefficient is larger than the third coupling coefficient, and the second coupling coefficient is larger than the third coupling coefficient. 3. The energy transferring system according to claim 1, wherein magnetic energy transfer is performed between the source-side resonator and the intermediate resonant module. 4. The energy transferring system according to claim 1, wherein power energy transfer is performed between the source-side resonator and the intermediate resonant module. 5. The energy transferring system according to claim 1, further comprising: a power supply to provide the energy to the source-side resonator; anda load to receive the energy from the device-side resonator,wherein the work-drainage rate is configured to maximize the efficiency of the energy transfer from the power supply to the load. 6. The energy transferring system according to claim 1, wherein the intermediate resonant module has at least one intermediate resonator. 7. The energy transferring system according to claim 6, wherein the intermediate resonator is a conductive coil structure with self-capacitance. 8. The energy transferring system according to claim 6, wherein the intermediate resonator has a dielectric disk structure. 9. The energy transferring system according to claim 6, wherein the intermediate resonator has a capacitively loaded conducting-wire coil structure. 10. The energy transferring system of claim 1, wherein the intermediate resonant module is configured to receive energy from the source-side resonator and transfer energy to the device-side resonator. 11. The energy transferring system of claim 1, wherein each of the first, second, and third coupling coefficients decreases with increasing distance between the respective two of the source-side resonator, the intermediate resonant module, and the device side resonator. 12. The energy transferring system according to claim 1, wherein the range of distances includes distances between the source-side resonator and the intermediate resonant module and distances between the device-side resonator and the intermediate resonant module that are each greater than the characteristic size of the device-side resonator. 13. The energy transferring system according to claim 1, further comprising a device having a load coupled to the device-side resonator, and wherein the power provided to the load from the device-side resonator defines a work drainage rate Γw, and wherein the work drainage rate Γw is configured to be set such that Γw>Γ2·√{square root over (2)} for the range of distances between the source-side resonator, the intermediate resonant module, and the device-side resonator. 14. The energy transferring system according to claim 1, wherein the source-side resonator has a solenoid inductance structure. 15. The energy transferring system according to claim 1, wherein the device-side resonator has a solenoid inductance structure. 16. An energy transferring method, comprising: providing a source-side resonator to receive an energy;providing an intermediate resonant module, wherein the energy on the source-side resonator is coupled to the intermediate resonant module, such that non-radiative energy transfer is performed between the source-side resonator and the intermediate resonant module, and the coupling between the source-side resonator and the intermediate resonant module corresponds to a first coupling coefficient; andproviding the energy for coupling a device-side resonator to the intermediate resonant module, wherein the energy is further coupled to the device-side resonator, such that non-radiative energy transfer is performed between the intermediate resonant module and the device-side resonator, and the coupling between the intermediate resonant module and the device-side resonator corresponds to a second coupling coefficient, wherein:the coupling between the source-side resonator and the device-side resonator corresponds to a third coupling coefficient,the source-side resonator, the intermediate resonant module, and the device-side resonator are movable relative to one another, andthe source-side resonator has a resonant frequency ω1, an intrinsic loss rate Γ1, and an intrinsic quality factor Q1=ω1/(2Γ1);the device-side resonator has a resonant frequency ω2, an intrinsic loss rate Γ2, and an intrinsic quality factor Q2=ω2/(2Γ2);the intermediate resonant module has a resonant frequency ω3, an intrinsic loss rate Γ3, and an intrinsic quality factor Q3=ω3/(2Γ3),the first coupling coefficient is κ1 and the second coupling coefficient is κ2, and wherein the intrinsic loss rates satisfy κ1/√{square root over (Γ1Γ3)}>1 and κ2/√{square root over (Γ3Γ2)}>1 for a range of distances between the source-side resonator, the intermediate resonant module, and the device-side resonator. 17. The energy transferring method according to claim 16, wherein the source-side resonator, the intermediate resonant module and the device-side resonator respectively have a first resonant frequency, a second resonant frequency and a third resonant frequency, and the first resonant frequency, the second resonant frequency and the third resonant frequency are substantially the same. 18. The energy transferring method of claim 16, wherein the first coupling coefficient is larger than the third coupling coefficient, and the second coupling coefficient is larger than the third coupling coefficient. 19. The energy transferring method of claim 16, wherein the intermediate resonant module is configured to receive energy from the source-side resonator and transfer energy to the device-side resonator. 20. The energy transferring method of claim 16, wherein each of the first, second, and third coupling coefficients decreases with increasing distance between the respective two of the source-side resonator, the intermediate resonant module, and the device side resonator. 21. The energy transferring method according to claim 16, wherein the range of distances includes distances between the source-side resonator and the intermediate resonant module and distances between the device-side resonator and the intermediate resonant module that are each greater than the characteristic size of the device-side resonator. 22. The energy transferring method according to claim 16, further comprising a device having a load coupled to the device-side resonator, and wherein the power provided to the load from the device-side resonator defines a work drainage rate Γw, and wherein the work drainage rate Γw is configured to be set such that Γw>Γ2·√{square root over (2)} for the range of distances between the source-side resonator, the intermediate resonant module, and the device-side resonator. 23. An energy transferring system, comprising: a first resonant object for receiving an energy;a second resonant object;a third resonant object configured to transfer energy with one or more of the first and second resonator objects, whereinenergy in the first resonant object is coupled to the third resonant object such that non-radiative energy transfer is performed between the first resonant object and the third resonant object and the energy coupled to the third resonant object is further coupled to the second resonant object such that non-radiative energy transfer is performed between the third resonant object and the second resonant object,the first, second, and third resonant objects having the same resonant frequency,the coupling between the first resonator object and the third resonator object corresponds to a first coupling constant,the coupling between the third resonant object and the second resonant object corresponds to a second coupling constant, andthe coupling between the first resonant object and the second resonant object corresponds to a third coupling constant,wherein the first, second, and third resonant objects are movable relative to one another, andthe first resonant object has a resonant frequency ω1, an intrinsic loss rate Γ1, and an intrinsic quality factor Q1=ω1/(2Γ1);the second resonant object has a resonant frequency ω2, an intrinsic loss rate Γ2, and an intrinsic quality factor Q2=ω2/(2Γ2);the third resonant object has a resonant frequency ω3, an intrinsic loss rate Γ3, and an intrinsic quality factor Q3=ω3/(2Γ3),the first coupling coefficient is κ1 and the second coupling coefficient is κ2, and wherein the intrinsic loss rates satisfy κ1/√{square root over (Γ1Γ3)}>1 and κ2/√{square root over (Γ3Γ2)}>1 for a range of distances between the source-side resonator, the intermediate resonant module, and the device-side resonator. 24. The energy transferring system of claim 23, wherein the third resonant object is configured to receive energy from the first resonant object and transfer energy to the second resonant object. 25. The energy transferring system of claim 23, wherein each of the first, second, and third coupling constants decreases with increasing distance for energy transfer between the respective two of the first, second, and third resonant objects. 26. The energy transferring system according to claim 23, further comprising: a power supply to provide the energy to the first resonant object; anda load to receive the energy from the second resonant object,wherein the work-drainage rate is configured to maximize the efficiency of the energy transfer from the power supply to the load. 27. The energy transferring system according to claim 23, wherein the range of distances includes distances between the first and third resonant objects and distances between the second and third resonant objects that are each greater than the characteristic size of the second resonant object. 28. The energy transferring system according to claim 23, further comprising a device having a load coupled to the second resonant object, and wherein the power provided to the load from the second resonant object defines a work drainage rate Γw, and wherein the work drainage rate Γw is configured to be set such that Γw>Γ2·√{square root over (2)} for the range of distances between the first, second, and third resonant objects. 29. An energy transferring method, comprising: providing a first resonant object to receive an energy;providing a second resonant object; andproviding the third resonant object, wherein the energy in the first resonant object is coupled to the third resonant object, such that non-radiative energy transfer is performed between the first resonant object and the third resonant object and energy in the third resonant object is further coupled to the second resonant object, such that non-radiative energy transfer is performed between the third resonant object and the second resonant object, whereinthe coupling between the first resonant object and the third resonant object corresponds to a first coupling constant,the coupling between the third resonant object and the second resonant object corresponds to a second coupling constant,the coupling between the first resonant object and the second resonant object corresponds to a third coupling constant,wherein the first, second, and third resonant objects are movable relative to one another, andthe first resonant object has a resonant frequency ω1, an intrinsic loss rate Γ1, and an intrinsic quality factor Q1=ω1/(2Γ1);the second resonant object has a resonant frequency ω2, an intrinsic loss rate Γ2, and an intrinsic quality factor Q2=ω2/(2Γ2);the third resonant object has a resonant frequency ω3, an intrinsic loss rate Γ3, and an intrinsic quality factor Q3=ω3/(2Γ3),the first coupling coefficient is κ1 and the second coupling coefficient is κ2, and wherein the intrinsic loss rates satisfy κ1/√{square root over (Γ1Γ3)}>1 and κ2/√{square root over (Γ3Γ2)}>1 for a range of distances between the source-side resonator, the intermediate resonant module, and the device-side resonator. 30. The energy transferring method of claim 29, wherein the third resonant object is configured to receive energy from the first resonant object and transfer energy to the second resonant object. 31. The energy transferring method of claim 29, wherein each of the first, second, and third coupling coefficients decrease with increasing distance for energy transfer between the respective two of the first, second, and third resonant objects. 32. The energy transferring method according to claim 29, wherein the range of distances includes distances between the first and third resonant objects and distances between the second and third resonant objects that are each greater than the characteristic size of the second resonant object. 33. The energy transferring system method to claim 29, further comprising a device having a load coupled to the second resonant object, and wherein the power provided to the load from the second resonant object defines a work drainage rate Γw, and wherein the work drainage rate Γw is configured to be set such that Γw>Γ2·√{square root over (2)} for the range of distances between the first, second, and third resonant objects.
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