Nonlinear resonance circuit for wireless power transmission and wireless power harvesting
First Claim
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1. A wireless power transmission system, comprising:
- an excitation source;
a transmit resonator electrically or magnetically coupled to the excitation source; and
a receive resonator disposed proximate to the transmit resonator, where at least one of the transmit resonator or the receive resonator is comprised of a dielectric material and permittivity of the dielectric material exhibits nonlinear response to an applied electric field, wherein nonlinear response is approximated by a polynomial expansion, such that the polynomial expansion includes a constant and even order terms, and the even order terms of the polynomial expansion are dominant.
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Abstract
A nonlinear resonator is presented that enhances the bandwidth while providing high resonance amplitude. The nonlinear resonance circuit is comprised of an inductor electrically coupled to a capacitor, where either the inductor or capacitor is nonlinear. Response of the nonlinear resonance circuit to an excitation signal is described by a family of second-order differential equations with cubic-order nonlinearity, known as Duffing equations. In one aspect, the nonlinear resonator is implemented by a nonlinear dielectric resonator.
25 Citations
6 Claims
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1. A wireless power transmission system, comprising:
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an excitation source; a transmit resonator electrically or magnetically coupled to the excitation source; and a receive resonator disposed proximate to the transmit resonator, where at least one of the transmit resonator or the receive resonator is comprised of a dielectric material and permittivity of the dielectric material exhibits nonlinear response to an applied electric field, wherein nonlinear response is approximated by a polynomial expansion, such that the polynomial expansion includes a constant and even order terms, and the even order terms of the polynomial expansion are dominant. - View Dependent Claims (2, 3)
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4. A wireless power transmission system, comprising:
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an excitation source; a transmit resonator electrically or magnetically coupled to the excitation source; and a receive resonator disposed proximate to the transmit resonator, where at least one of the transmit resonator or the receive resonator includes an electronic component embedded therein, where the electronic component exhibits a nonlinear response to an applied electric field, wherein nonlinear response is approximated by a polynomial expansion, such that the polynomial expansion includes a constant and even order terms, and the even order terms of the polynomial expansion are dominant. - View Dependent Claims (5)
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6. A wireless power transmission system, comprising:
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an excitation source; a transmit resonator electrically or magnetically coupled to the excitation source; and a receive resonator disposed proximate to the transmit resonator, where at least one of the transmit resonator or the receive resonator is comprised of a material with permittivity, permeability or both, such that the at least one of the transmit resonator or the receive resonator exhibits a nonlinear response under excitation, wherein nonlinear response is approximated by a polynomial expansion, such that the polynomial expansion includes a constant and exhibits even symmetry, where the even order terms of the polynomial expansion are dominant.
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Specification
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Current AssigneeBoard of Regents of the University of Michigan (University of Michigan)
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Original AssigneeBoard of Regents of the University of Michigan (University of Michigan)
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InventorsMortazawi, Amir, Wang, Xiaoyu
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Primary Examiner(s)Borroto, Alfonso Perez
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Assistant Examiner(s)Yeshaw, Esayas G
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Application NumberUS16/253,013Publication NumberTime in Patent Office610 DaysField of SearchUS Class CurrentCPC Class CodesH01F 38/14 Inductive couplings for wir...H02J 50/05 using capacitive couplingH02J 50/12 of the resonant typeH03H 7/40 Automatic matching of load ...
