Power transfer circuit including a sympathetic resonator
First Claim
1. In a power transfer system for coupling a waveform of predetermined frequency from a primary side of a transformer to a secondary side thereof, said primary and secondary sides being separated by an air-gap or dielectric material, the primary side comprising a first winding that is parallel connected to a first capacitor and coupled to a primary magnetic core, said first winding being connected in series with a switching means between a pair of voltage sources characterized by:
- a resonator circuit comprising a second winding that is parallel connected to a second capacitor and shares the primary magnetic core with the first winding, the resonator circuit being magnetically coupled to, and exclusively driven by, signal energy generated by said first winding, the resonator circuit being adapted to parallel resonate at the predetermined frequency.
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Accused Products
Abstract
A power transfer circuit includes first and second windings (L1, L2) sharing a common magnetic core (101). Each winding has associated with it a parallel capacitor to thus form a pair of "tank" circuits. The first winding (L1) is connected at one end to a voltage supply and, at the other end, to ground through an FET switch (100,200). The switch (100,200) is turned on and off at a predetermined frequency and at a 50% duty cycle. The second winding (L2) and associated capacitor (C2) achieves parallel resonance at the predetermined frequency. Similarly the combined first and second windings (L1,L2) and associated capacitors (C1,C2) achieve parallel resonance at said predetermined frequency. The second winding (L2) need not be electrically connected to the first winding (L1) which transfers energy to it through the magnetic core (101). The transfer circuit efficiently couples power across a dielectric interface to a pickup coil (L3). One particularly good application of the power transfer circuit is in connection with a contactless Smart Card.
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Citations
12 Claims
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1. In a power transfer system for coupling a waveform of predetermined frequency from a primary side of a transformer to a secondary side thereof, said primary and secondary sides being separated by an air-gap or dielectric material, the primary side comprising a first winding that is parallel connected to a first capacitor and coupled to a primary magnetic core, said first winding being connected in series with a switching means between a pair of voltage sources characterized by:
a resonator circuit comprising a second winding that is parallel connected to a second capacitor and shares the primary magnetic core with the first winding, the resonator circuit being magnetically coupled to, and exclusively driven by, signal energy generated by said first winding, the resonator circuit being adapted to parallel resonate at the predetermined frequency. - View Dependent Claims (2, 3, 4, 5, 6)
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7. A power transfer system for coupling electrical energy at a predetermined frequency across a dielectrical interface to a portable data card, the system including a driver unit and a data card, the driver unit comprising:
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a first coil parallel connected to a first capacitor and coupled to a magnetic core member, said first coil being series connected to a switching means between a pair of voltage sources, the switching means being switched between "on" and "off" states at the predetermined frequency; a second coil parallel connected to a second capacitor and coupled to the magnetic core member, said second coil being solely driven by the magnetic flux in the magnetic core, the impedance values of the second coil and the second capacitor being selected to resonate at the predetermined frequency, the data card comprising; a third coil, series connected to a load impedance and embedded between dielectric layers of the data card, for receiving electrical energy at the predetermined frequency from said first and second coils.
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8. A power transfer system comprising a driving member and a portable receiving member, the driving member having inductive and capacitive elements tuned to parallel resonate at a predetermined frequency when the driving and receiving members are separated by a significant distance, the inductive and capacitive elements being driven at the predetermined frequency by an oscillator means, the inductive elements comprising two or more primary coils mutually coupled to each other through a common magnetic core, the portable receiving member comprising a secondary coil series connected to a load impedance, the secondary coil being adapted to receive electrical energy when brought into the proximity of the magnetic field of the primary coils, the combined input impedance of the secondary coil and its load impedance having an overall reactive characteristic such that the inductive and capacitive elements of the driving member become progressively detuned as the portable receiving member is brought into closer alignment with the driving member, whereby the overall power transfer between driving and receiving members is rendered insensitive to separation over a range of alignments.
- 9. A circuit for magnetically coupling an electrical signal having one predominant frequency across a dielectric interface, one side of the dielectric interface being designated its primary side and the other side being designated its secondary side, the primary side of the dielectric interface including a pair of tank circuits each comprising a parallel connected coil and capacitor, the coils of said tank circuits sharing a common magnetic core, one of the tank circuits being exclusively driven by the other tank circuit and tuned to resonate at the predominant frequency, said other tank circuit being driven by an oscillator means at the predominant frequency.
Specification