Variable capacitor for resonant power transfer systems

Abstract

Systems and designs for tuning a wireless power transfer system are provided, which may include any number of features. In one embodiment, a wireless power transfer system can include first and second switched capacitor circuits electrically connected to opposite poles of the inductor of a resonator in the wireless power system. The first and second switched capacitor circuits can be switched on and off with MOSFETS to change a capacitance of the circuits, and thus an effective capacitance of the resonator. Methods of use are also provided.

Description

INCORPORATION BY REFERENCE

All publications and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.

FIELD

This disclosure relates generally to methods and apparatus for transmitting and receiving power wirelessly, and in various respects, mechanical circulatory support.

BACKGROUND

Powered devices need to have a mechanism to supply power to the operative parts. Typically systems use a physical power cable to transfer energy over a distance. There has been a continuing need for systems that can transmit power efficiently over a distance without physical structures bridging the physical gap.

Systems and methods that supply power without electrical wiring are sometimes referred to as wireless energy transmission (WET). Wireless energy transmission greatly expands the types of applications for electrically powered devices. One such example is the field of implantable medical devices. Implantable medical devices typically require an internal power source able to supply adequate power for the reasonable lifetime of the device or an electrical cable that traverses the skin. Typically an internal power source (e.g. battery) is feasibly for only low power devices like sensors. Likewise, a transcutaneous power cable significantly affects quality of life (QoL), infection risk, and product life, among many drawbacks.

More recently there has been an emphasis on systems that supply power to an implanted device without using transcutaneous wiring. This is sometimes referred to as a Transcutaneous Energy Transfer System (TETS). Frequently energy transfer is accomplished using two magnetically coupled coils set up like a transformer so power is transferred magnetically across the skin. Conventional systems are relatively sensitive to variations in position and alignment of the coils. In order to provide constant and adequate power, the two coils need to be physically close together and well aligned.

To operate efficiently, the transmit and receive resonators need to have a very low resistance, resulting in a very large quality factor (Q). Resonators with a large Q have a very narrow frequency band. To couple resonators with a large Q, the transmitter and receiver need to operate at precise frequencies. If a resonator has a Q of 100, then a 1% variation of a capacitor will dramatically de-tune the circuit. Since it is difficult to buy capacitors with a rated tolerance less than 5%, methods of trimming the capacitor value are required for efficient operation of wireless power systems.

Typically, prior systems have resorted to measuring capacitor values when the circuit is being built to find a capacitor that has a value within the desired range. These capacitors can be swapped out until a capacitor with the right value is found, which makes for a tedious and expensive circuit manufacturing process. Alternatively, several smaller capacitors can be combined, and the values of the smaller capacitors are measured and selected until the combined result is correct.

SUMMARY OF THE DISCLOSURE

A resonator of a wireless power transfer system is provided, comprising an inductor adapted to receive or transmit wireless power, first and second switched capacitor circuits electrically connected to opposite poles of the inductor, each of the first and second switched capacitor circuits comprising a first capacitor in series with a MOSFET and a second capacitor in parallel with the first capacitor, and a controller electrically connected to the first and second switched capacitor circuits, the controller configured to switch the MOSFETS on and off to change a capacitance of the first and second switched capacitor circuits to adjust an effective capacitance of the resonator.

In some embodiments, the controller can be configured to turn the MOSFETS during a 50% duty cycle to achieve a minimum effective capacitance of the wireless power transfer system.

In other embodiments, the controller can be configured to turn the MOSFETS during a 100% duty cycle to achieve a maximum effective capacitance of the wireless power transfer system.

In one embodiment, the controller is configured to control the effective capacitance of the wireless power transfer system to optimize a power transfer efficiency of the wireless power transfer system.

In another embodiment, the controller is configured to control the effective capacitance of the wireless power transfer system to optimize a coupling coefficient of the wireless power transfer system.

In some embodiments, the controller is configured to monitor a system parameter in response to the adjusted effective capacitance, and to iteratively adjust effective capacitance in the direction that improves performance of the system parameter.

In one embodiment, the system parameter comprises a coupling coefficient of the wireless power transfer system.

In some embodiments, the system parameter comprises a power transfer efficiency of the wireless power transfer system.

In some embodiments, the resonator comprises a receiver resonator adapted to be implanted within a patient.

In other embodiments, the inductor is configured to receive wireless power from an external transmitter resonator disposed outside the patient.

A method of controlling a wireless power transfer system is provided, comprising the steps of transmitting or receiving wireless power with an inductor of a resonator, and adjusting with a controller an effective capacitance of the resonator by changing a capacitance of first and second switched capacitor circuits connected to opposite poles of the inductor.

In some embodiments, the adjusting step further comprises turning on and off MOSFETS in the first and second switched capacitor circuits to switch capacitors in series with the MOSFETS in an out of the circuit.

In other embodiments, the method further comprises monitoring a system parameter in response to adjusting the effective capacitance, and iteratively adjusting the effective capacitance in the direction that improves performance of the system parameter.

In one embodiment, the system parameter comprises a coupling coefficient of the wireless power transfer system.

In another embodiment, the system parameter comprises a power transfer efficiency of the wireless power transfer system.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth with particularity in the claims that follow. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings of which:

FIG. 1 illustrates a basic wireless power transfer system.

FIG. 2 illustrates the flux generated by a pair of coils.

FIGS. 3A-3B illustrate the effect of coil alignment on the coupling coefficient.

FIG. 4 illustrates one embodiment of a resonator having a pair of switched capacitor circuits.

FIGS. 5A-5C illustrate representative circuits of the circuit shown in FIG. 4, along with a timing diagram to illustrate the response of the circuit to the MOSFET switching.

FIG. 6 illustrates another embodiment for dynamically adjusting a capacitance.

DETAILED DESCRIPTION

In the description that follows, like components have been given the same reference numerals, regardless of whether they are shown in different embodiments. To illustrate an embodiment(s) of the present disclosure in a clear and concise manner, the drawings may not necessarily be to scale and certain features may be shown in somewhat schematic form. Features that are described and/or illustrated with respect to one embodiment may be used in the same way or in a similar way in one or more other embodiments and/or in combination with or instead of the features of the other embodiments.

Various aspects of the invention are similar to those described in International Patent Pub. No. WO2012045050; U.S. Pat. Nos. 8,140,168; 7,865,245; 7,774,069; 7,711,433; 7,650,187; 7,571,007; 7,741,734; 7,825,543; 6,591,139; 6,553,263; and 5,350,413; and U.S. Pub. Nos. 2010/0308939; 2008/027293; and 2010/0102639, the entire contents of which patents and applications are incorporated herein for all purposes.

Wireless Power Transmission System

Power may be transmitted wirelessly by magnetic induction. In various embodiments, the transmitter and receiver are closely coupled.

In some cases “closely coupled” or “close coupling” refers to a system that requires the coils to be very near each other in order to operate. In some cases “loosely coupled” or “loose coupling” refers to a system configured to operate when the coils have a significant spatial and/or axial separation, and in some cases up to distance equal to or less than the diameter of the larger of the coils. In some cases, “loosely coupled” or “loose coupling” refers a system that is relatively insensitive to changes in physical separation and/or orientation of the receiver and transmitter.

In various embodiments, the transmitter and receiver are non-resonant coils. For example, a change in current in one coil induces a changing magnetic field. The second coil within the magnetic field picks up the magnetic flux, which in turn induces a current in the second coil. An example of a closely coupled system with non-resonant coils is described in International Pub. No. WO2000/074747, incorporated herein for all purposes by reference. A conventional transformer is another example of a closely coupled, non-resonant system. In various embodiments, the transmitter and receiver are resonant coils. For example, one or both of the coils is connected to a tuning capacitor or other means for controlling the frequency in the respective coil. An example of closely coupled system with resonant coils is described in International Pub. Nos. WO2001/037926; WO2012/087807; WO2012/087811; WO2012/087816; WO2012/087819; WO2010/030378; and WO2012/056365, and U.S. Pub. No. 2003/0171792, incorporated herein for all purposes by reference.

In various embodiments, the transmitter and receiver are loosely coupled. For example, the transmitter can resonate to propagate magnetic flux that is picked up by the receiver at relatively great distances. In some cases energy can be transmitted over several meters. In a loosely coupled system power transfer may not necessarily depend on a critical distance. Rather, the system may be able to accommodate changes to the coupling coefficient between the transmitter and receiver. An example of a loosely coupled system is described in International Pub. No. WO2012/045050, incorporated herein for all purposes by reference.

Power may be transmitted wirelessly by radiating energy. In various embodiments, the system comprises antennas. The antennas may be resonant or non-resonant. For example, non-resonant antennas may radiate electromagnetic waves to create a field. The field can be near field or far field. The field can be directional. Generally far field has greater range but a lower power transfer rate. An example of such a system for radiating energy with resonators is described in International Pub. No. WO2010/089354, incorporated herein for all purposes by reference. An example of such a non-resonant system is described in International Pub. No. WO2009/018271, incorporated herein for all purposes by reference. Instead of antenna, the system may comprise a high energy light source such as a laser. The system can be configured so photons carry electromagnetic energy in a spatially restricted, direct, coherent path from a transmission point to a receiving point. An example of such a system is described in International Pub. No. WO2010/089354, incorporated herein for all purposes by reference.

Power may also be transmitted by taking advantage of the material or medium through which the energy passes. For example, volume conduction involves transmitting electrical energy through tissue between a transmitting point and a receiving point. An example of such a system is described in International Pub. No. WO2008/066941, incorporated herein for all purposes by reference.

Power may also be transferred using a capacitor charging technique. The system can be resonant or non-resonant. Exemplars of capacitor charging for wireless energy transfer are described in International Pub. No. WO2012/056365, incorporated herein for all purposes by reference.

The system in accordance with various aspects of the invention will now be described in connection with a system for wireless energy transfer by magnetic induction. The exemplary system utilizes resonant power transfer. The system works by transmitting power between the two inductively coupled coils. In contrast to a transformer, however, the exemplary coils are not coupled together closely. A transformer generally requires the coils to be aligned and positioned directly adjacent each other. The exemplary system accommodates looser coupling of the coils.

While described in terms of one receiver coil and one transmitter coil, one will appreciate from the description herein that the system may use two or more receiver coils and two or more transmitter coils. For example, the transmitter may be configured with two coils—a first coil to resonate flux and a second coil to excite the first coil. One will further appreciate from the description herein that usage of “resonator” and “coil” may be used somewhat interchangeably. In various respects, “resonator” refers to a coil and a capacitor connected together.

In accordance with various embodiments of this disclosure, the system comprises one or more transmitters configured to transmit power wirelessly to one or more receivers. In various embodiments, the system includes a transmitter and more than one receiver in a multiplexed arrangement. A frequency generator may be electrically coupled to the transmitter to drive the transmitter to transmit power at a particular frequency or range of frequencies. The frequency generator can include a voltage controlled oscillator and one or more switchable arrays of capacitors, a voltage controlled oscillator and one or more varactors, a phase-locked-loop, a direct digital synthesizer, or combinations thereof. The transmitter can be configured to transmit power at multiple frequencies simultaneously. The frequency generator can include two or more phase-locked-loops electrically coupled to a common reference oscillator, two or more independent voltage controlled oscillators, or combinations thereof. The transmitter can be arranged to simultaneously delivery power to multiple receivers at a common frequency.

In various embodiments, the transmitter is configured to transmit a low power signal at a particular frequency. The transmitter may transmit the low power signal for a particular time and/or interval. In various embodiments, the transmitter is configured to transmit a high power signal wirelessly at a particular frequency. The transmitter may transmit the high power signal for a particular time and/or interval.

In various embodiments, the receiver includes a frequency selection mechanism electrically coupled to the receiver coil and arranged to allow the resonator to change a frequency or a range of frequencies that the receiver can receive. The frequency selection mechanism can include a switchable array of discrete capacitors, a variable capacitance, one or more inductors electrically coupled to the receiving antenna, additional turns of a coil of the receiving antenna, or combinations thereof.

In general, most of the flux from the transmitter coil does not reach the receiver coil. The amount of flux generated by the transmitter coil that reaches the receiver coil is described by “k” and referred to as the “coupling coefficient.”

In various embodiments, the system is configured to maintain a value of k in the range of between about 0.2 to about 0.01. In various embodiments, the system is configured to maintain a value of k of at least 0.01, at least 0.02, at least 0.03, at least 0.04, at least 0.05, at least 0.1, or at least 0.15.

In various embodiments, the coils are physically separated. In various embodiments, the separation is greater than a thickness of the receiver coil. In various embodiments, the separation distance is equal to or less than the diameter of the larger of the receiver and transmitter coil.

Because most of the flux does not reach the receiver, the transmitter coil must generate a much larger field than what is coupled to the receiver. In various embodiments, this is accomplished by configuring the transmitter with a large number of amp-turns in the coil.

Since only the flux coupled to the receiver gets coupled to a real load, most of the energy in the field is reactive. The current in the coil can be sustained with a capacitor connected to the coil to create a resonator. The power source thus only needs to supply the energy absorbed by the receiver. The resonant capacitor maintains the excess flux that is not coupled to the receiver.

In various embodiments, the impedance of the receiver is matched to the transmitter. This allows efficient transfer of energy out of the receiver. In this case the receiver coil may not need to have a resonant capacitor.

Turning now to FIG. 1, a simplified circuit for wireless energy transmission is shown. The exemplary system shows a series connection, but the system can be connected as either series or parallel on either the transmitter or receiver side.

The exemplary transmitter includes a coil Lx connected to a power source Vs by a capacitor Cx. The exemplary receiver includes a coil Ly connected to a load by a capacitor Cy. Capacitor Cx may be configured to make Lx resonate at a desired frequency. Capacitance Cx of the transmitter coil may be defined by its geometry. Inductors Lx and Ly are connected by coupling coefficient k. Mxy is the mutual inductance between the two coils. The mutual inductance, Mxy, is related to coupling coefficient, k.Mxy=k√{square root over (Lx·Ly)}

In the exemplary system the power source Vs is in series with the transmitter coil Lx so it may have to carry all the reactive current. This puts a larger burden on the current rating of the power source and any resistance in the source will add to losses.

The exemplary system includes a receiver configured to receive energy wirelessly transmitted by the transmitter. The exemplary receiver is connected to a load. The receiver and load may be connected electrically with a controllable switch.

In various embodiments, the receiver includes a circuit element configured to be connected or disconnected from the receiver coil by an electronically controllable switch. The electrical coupling can include both a serial and parallel arrangement. The circuit element can include a resistor, capacitor, inductor, lengths of an antenna structure, or combinations thereof. The system can be configured such that power is transmitted by the transmitter and can be received by the receiver in predetermined time increments.

In various embodiments, the transmitter coil and/or the receiver coil is a substantially two-dimensional structure. In various embodiments, the transmitter coil may be coupled to a transmitter impedance-matching structure. Similarly, the receiver coil may be coupled to a receiver impedance-matching structure. Examples of suitable impedance-matching structures include, but are not limited to, a coil, a loop, a transformer, and/or any impedance-matching network. An impedance-matching network may include inductors or capacitors configured to connect a signal source to the resonator structure.

In various embodiments, the transmitter is controlled by a controller (not shown) and driving circuit. The controller and/or driving circuit may include a directional coupler, a signal generator, and/or an amplifier. The controller may be configured to adjust the transmitter frequency or amplifier gain to compensate for changes to the coupling between the receiver and transmitter.

In various embodiments, the transmitter coil is connected to an impedance-matched coil loop. The loop is connected to a power source and is configured to excite the transmitter coil. The first coil loop may have finite output impedance. A signal generator output may be amplified and fed to the transmitter coil. In use power is transferred magnetically between the first coil loop and the main transmitter coil, which in turns transmits flux to the receiver. Energy received by the receiver coil is delivered by Ohmic connection to the load.

One of the challenges to a practical circuit is how to get energy in and out of the resonators. Simply putting the power source and load in series or parallel with the resonators is difficult because of the voltage and current required. In various embodiments, the system is configured to achieve an approximate energy balance by analyzing the system characteristics, estimating voltages and currents involved, and controlling circuit elements to deliver the power needed by the receiver.

In an exemplary embodiment, the system load power, P_L, is assumed to be 15 Watts and the operating frequency, f, is 250 kHz. Then, for each cycle the load removes a certain amount of energy from the resonance:

$e_L=\frac{P_L}{f}=60\mu J\mathrm{Energy}\mathrm{the}\mathrm{load}\mathrm{removes}\mathrm{in}\mathrm{one}\mathrm{cycle}$

It has been found that the energy in the receiver resonance is typically several times larger than the energy removed by the load for operative, implantable medical devices. In various embodiments, the system assumes a ratio 7:1 for energy at the receiver versus the load removed. Under this assumption, the instantaneous energy in the exemplary receiver resonance is 420 μJ.

The exemplary circuit was analyzed and the self inductance of the receiver coil was found to be 60 uH. From the energy and the inductance, the voltage and current in the resonator could be calculated.

$e_y=\frac{1}{2}{\mathrm{Li}}^2$ $i_y=\sqrt{\frac{2e_y}{L}}=3.74A\mathrm{peak}$ $v_y=\omega L_y{i}_y=352V\mathrm{peak}$

The voltage and current can be traded off against each other. The inductor may couple the same amount of flux regardless of the number of turns. The Amp-turns of the coil needs to stay the same in this example, so more turns means the current is reduced. The coil voltage, however, will need to increase. Likewise, the voltage can be reduced at the expense of a higher current. The transmitter coil needs to have much more flux. The transmitter flux is related to the receiver flux by the coupling coefficient. Accordingly, the energy in the field from the transmitter coil is scaled by k.

$e_x=\frac{e_y}{k}$

Given that k is 0.05:

$e_x=\frac{420\mu J}{0.05}=8.4\mathrm{mJ}$

For the same circuit the self inductance of the transmitter coil was 146 uH as mentioned above. This results in:

$i_x=\sqrt{\frac{2e_x}{L}}=10.7A\mathrm{peak}$ $v_x=\omega L_x{i}_x=2460V\mathrm{peak}$

One can appreciate from this example, the competing factors and how to balance voltage, current, and inductance to suit the circumstance and achieve the desired outcome. Like the receiver, the voltage and current can be traded off against each other. In this example, the voltages and currents in the system are relatively high. One can adjust the tuning to lower the voltage and/or current at the receiver if the load is lower.

Estimation of Coupling Coefficient and Mutual Inductance

As explained above, the coupling coefficient, k, may be useful for a number of reasons. In one example, the coupling coefficient can be used to understand the arrangement of the coils relative to each other so tuning adjustments can be made to ensure adequate performance. If the receiver coil moves away from the transmitter coil, the mutual inductance will decrease, and ceteris paribus, less power will be transferred. In various embodiments, the system is configured to make tuning adjustments to compensate for the drop in coupling efficiency.

The exemplary system described above often has imperfect information. For various reasons as would be understood by one of skill in the art, the system does not collect data for all parameters. Moreover, because of the physical gap between coils and without an external means of communications between the two resonators, the transmitter may have information that the receiver does not have and vice versa. These limitations make it difficult to directly measure and derive the coupling coefficient, k, in real time.

Described below are several principles for estimating the coupling coefficient, k, for two coils of a given geometry. The approaches may make use of techniques such as Biot-Savart calculations or finite element methods. Certain assumptions and generalizations, based on how the coils interact in specific orientations, are made for the sake of simplicity of understanding. From an electric circuit point of view, all the physical geometry permutations can generally lead to the coupling coefficient.

If two coils are arranged so they are in the same plane, with one coil circumscribing the other, then the coupling coefficient can be estimated to be roughly proportional to the ratio of the area of the two coils. This assumes the flux generated by coil 1 is roughly uniform over the area it encloses as shown in FIG. 2.

If the coils are out of alignment such that the coils are at a relative angle, the coupling coefficient will decrease. The amount of the decrease is estimated to be about equal to the cosine of the angle as shown in FIG. 3A. If the coils are orthogonal to each other such that theta (θ) is 90 degrees, the flux will not be received by the receiver and the coupling coefficient will be zero.

If the coils are arraigned such that half the flux from one coil is in one direction and the other half is in the other direction, the flux cancels out and the coupling coefficient is zero, as shown in FIG. 3B.

A final principle relies on symmetry of the coils. The coupling coefficient and mutual inductance from one coil to the other is assumed to be the same regardless of which coil is being energized.M_xy=M_yx

As described above, a wireless power transfer system can use LC tank circuits as resonators to generate a large AC magnetic field to couple a transmitter to a receiver. These circuits are very sensitive to the resonant frequencies in the system. The resonant frequencies, or eigen values of the system are primarily a function of the inductance and capacitance of the components in the resonators. Being able to precisely tune a capacitance in the transmitter or receiver or both allows the eigen values of the resonant system to be trimmed to precise frequencies.

As described above in the background, since it is difficult to buy capacitors with a rated tolerance less than 5%, methods of trimming the capacitor value are required for efficient operation of wireless power systems. In a real world implementation, component values will vary. For instance, capacitors will typically change capacitance based on temperature, and aging effects. The inductors in a wireless power transfer system will change inductance if a magnetic material is in the magnetic field. For example, the inductance of the system can change if the system is operating close to a steel object.

FIG. 4 shows a resonator 400 of a TET system including a switched capacitor circuit 403 configured to vary capacitance in the resonator. Resonator 400 can be, for example, a receiver or transmitter resonator in a wireless power transfer system. In such a system, the transmitter resonator can be configured to transmit wireless power from outside a patient's body to a receiver resonator implanted within the body. The receiver can be connected to a separate device, such as an implanted medical device, to provide power to the separate device. In the illustrated embodiment, resonator 400 includes an inductor L and a pair of variable capacitor circuits 402 and 404 each having two capacitors, Ca1/Ca2 and Cb1/Cb2, with the Ca1/Ca2 capacitor being in series with a MOSFET (MOSFETS 406 and 408). In some embodiments, the capacitor values can be the same, but in other embodiments the capacitor values can be different. In embodiments where the switched capacitors Ca1/Ca2 are small relative to the unswitched capacitors Cb1/Cb2, the effective range of variability will be small, and vice versa. Each of the MOSFETS can be turned on and off with variable timing such that each of the capacitors Ca1/Ca2 is connected in parallel with its corresponding capacitor Cb1/Cb2 for only a portion of the time. A controller in the resonator can be used to switch the MOSFETS and to control the timing of the MOSFET switching. When the circuit is resonating, the fraction of the time a capacitor Ca1/Ca2 is connected to a capacitor Cb1/Cb2 in one cycle determines its effect on the resonance. Cycling each of the capacitors Ca1/Ca2 in and out of the switched capacitor circuits results in what is effectively a variable capacitance in the resonator.

In this embodiment, since MOSFETs are used to switch capacitors Ca1/Ca2 in and out of the circuit, then they can block current in only one direction due to the body diode in the MOSFET. As a result, to get a balanced waveform, the circuit can be connected in a differential manner. Thus, as shown in FIG. 4 there are two variable capacitor circuits 402 and 404, one on each side of the inductor L. During operation, the variable capacitor circuits can be controlled to switch in and out on opposite half cycles to achieve a balanced waveform on the resonator.

Since the MOSFETS can only block the current into Ca1/Ca2 in only one direction, the capacitors should be disconnected no more than half the time. Connecting the capacitors Ca1/Ca2 half the time results in the minimum capacitance value. The MOSFET would be turned on for half the time, a 50% duty cycle. If the MOSFET is on all the time Ca1/Ca2 is always connected, this results in the maximum capacitance. Controlling the timing on the MOSFET switching allows a continuously variable capacitance so that the capacitor can be tuned with very high precision between the minimum capacitance (50% duty cycle) and maximum capacitance (always on MOSFETS).

FIGS. 5A-5C illustrate representative circuits of the circuit shown in FIG. 4, along with a timing diagram to illustrate the response of the circuit to the MOSFET switching.

In addition to being able to change the capacitance of the resonator to compensate for variances in rated capacitances, the capacitances of the switched capacitor circuits can be adjusted in real time to tune the resonator 400 when transmitting or receiving wireless power. The capacitance of the resonator can be tuned on the fly to compensate for varying environmental conditions in the field. For example, incorporating two switched capacitor circuits (e.g., switched capacitor circuits 402 and 404) into the transmitter and receiver of FIG. 1, in place of Cx and Cy, would allow the switched capacitor circuits to be adjusted in real time to tune the system for the purpose of optimizing power transfer efficiency, coupling coefficient, etc. during wireless power transmission.

An efficient resonant system has a very high Q, so is sensitive to small changes in the resonant frequencies of the resonators. Hence it is important to have good control over the resonant frequencies in the system. The resonant frequencies are primarily a function of the values of the inductors and capacitors in the system. Controllable switched capacitor circuits allow tuning of the system on the fly to optimize performance. This is a tuning and optimization exercise. This can be done to optimize performance in terms of several different characteristics including efficiency, stress on components, power loss (heating) in the receiver, etc.

There are many ways to implement an optimization algorithm in a controller of a TET system with controllable switched capacitor circuits. In one embodiment, the controller can adjust the effective capacitance of the system by making a small adjustment to one capacitor value, and the controller can monitor a specified parameter of the system (i.e, power transfer efficiency, coupling coefficient, etc) to see if the performance of the specified parameter improves or declines. The controller can then be configured then make an adjustment to the effective capacitance in the direction that improves performance. Then the process can be repeated on another switched capacitor circuit. This process could be repeated iteratively by the controller until the system converges on an optimum transfer. If the controller made an adjustment to a capacitor value that decreased performance of the specified parameter, then the controller could instead adjust the capacitor value in the opposite direction to improve performance, and again repeat iteratively until optimum power transfer is achieved.

In another embodiment, the same circuit above in FIG. 4 can be built using inductors instead of capacitors. Thus, the capacitors Ca1 and Cb1 of circuit 402, and capacitors Ca2 and Cb2 of circuit 404 could be swapped out with inductors. This changes the way the MOSFETS are required to switch, however the concept is the same. It should be noted that a variable capacitor can be preferable because the components are smaller, so the implemented circuit would be smaller.

FIG. 6 illustrates another embodiment of a variable capacitor circuit 500 that can be used in a receiver or transmitter of a wireless power transfer system. As shown, the circuit can include a plurality of electronic switches 502a, 502b, 502c, and 502d to connect capacitors Ca1, Ca2, Ca3, and Ca4 into the circuit, in order to get the combined capacitor to be the right value. In some embodiments, each of the capacitors could have a different capacitance (e.g., 100 pF, 200 pF, 400 pF, and 800 pF). The specific values of each capacitor can be chosen based on the desired performance and operation of the resonator. This embodiment requires many capacitors and switches, resulting in a lot of parts and circuit board space.

Another embodiment includes using a variable inductor, such as a magnetic amplifier, to vary the inductance in a tank circuit. However, magnetic amplifiers are large and bulky, and consume a lot of power.

As for additional details pertinent to the present invention, materials and manufacturing techniques may be employed as within the level of those with skill in the relevant art. The same may hold true with respect to method-based aspects of the invention in terms of additional acts commonly or logically employed. Also, it is contemplated that any optional feature of the inventive variations described may be set forth and claimed independently, or in combination with any one or more of the features described herein. Likewise, reference to a singular item, includes the possibility that there are plural of the same items present. More specifically, as used herein and in the appended claims, the singular forms “a,” “and,” “said,” and “the” include plural referents unless the context clearly dictates otherwise. It is further noted that the claims may be drafted to exclude any optional element. As such, this statement is intended to serve as antecedent basis for use of such exclusive terminology as “solely,” “only” and the like in connection with the recitation of claim elements, or use of a “negative” limitation. Unless defined otherwise herein, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The breadth of the present invention is not to be limited by the subject specification, but rather only by the plain meaning of the claim terms employed.

Claims

1. A resonator of a wireless power transfer system, comprising: an inductor adapted to receive or transmit wireless power and comprising a first pole and an opposite second pole;first and second switched capacitor circuits electrically connected to the inductor, each of the first and second switched capacitor circuits comprising a first capacitor in series with a MOSFET and a second capacitor in parallel with the first capacitor, wherein the first and second capacitors of the first switched capacitor circuit are each directly electrically connected to the inductor first pole, and wherein the first and second capacitors of the second switched capacitor circuit are each directly electrically connected to the inductor second pole; anda controller electrically connected to the first and second switched capacitor circuits, wherein the controller switches on the MOSFET of the first switched capacitor circuit at the same time that the MOSFET of the second switched capacitor circuit is switched off, and wherein the controller switches off the MOSFET of the first switched capacitor circuit at the same time that the MOSFET of the second switched capacitor circuit is switched on, causing the first and second switched capacitor circuits to be switched in and out on opposite half cycles relative to one another, and causing the resonator to achieve a balanced waveform.

2. The resonator of claim 1, wherein the controller is configured to operate the MOSFETS at a 50% duty cycle to achieve a minimum effective capacitance of the wireless power transfer system.

3. The resonator of claim 1, wherein the controller is configured to operate the MOSFETS at a 100% duty cycle to achieve a maximum effective capacitance of the wireless power transfer system.

4. The resonator of claim 1 wherein the controller is configured to control the effective capacitance of the wireless power transfer system to optimize a power transfer efficiency of the wireless power transfer system.

5. The resonator of claim 1 wherein the controller is configured to control the effective capacitance of the wireless power transfer system to optimize a coupling coefficient of the wireless power transfer system.

6. The resonator of claim 1 wherein the controller is configured to monitor a system parameter in response to the adjusted effective capacitance, and to iteratively adjust effective capacitance to improve performance of the system parameter.

7. The resonator of claim 6 wherein the system parameter comprises a coupling coefficient of the wireless power transfer system.

8. The resonator of claim 6 wherein the system parameter comprises a power transfer efficiency of the wireless power transfer system.

9. The resonator of claim 1, wherein the resonator comprises a receiver resonator adapted to be implanted within a patient.

10. The resonator of claim 9 wherein the inductor is configured to receive wireless power from an external transmitter resonator disposed outside the patient.

11. A method of controlling a wireless power transfer system, comprising the steps of: transmitting or receiving wireless power with an inductor of a resonator, the inductor including a first pole and an opposite second pole, the resonator further including first and second switched capacitor circuits, each of the first and second switch capacitor circuits including a first capacitor in series with a MOSFET and a second capacitor in parallel with the first capacitor, the first switched capacitor circuit directly electrically connected to the first pole of the inductor, and the second switched capacitor circuit directly electrically connected to the second pole of the inductor; andadjusting with a controller an effective capacitance of the resonator by changing a capacitance of the first and second switched capacitor circuits connected to the inductor; andswitching, with the controller, the first and second switched capacitor circuits in and out on opposite half cycles relative to one another to achieve a balanced waveform on the resonator by: switching on the MOSFET of the first switched capacitor circuit at the same time that the MOSFET of the second switched capacitor circuit is switched off; andswitching off the MOSFET of the first switched capacitor circuit at the same time that the MOSFET of the second switched capacitor circuit is switched on.

12. The method of claim 11 further comprising monitoring a system parameter in response to adjusting the effective capacitance, and iteratively adjusting the effective capacitance to improve performance of the system parameter.

13. The method of claim 12 wherein the system parameter comprises a coupling coefficient of the wireless power transfer system.

14. The method of claim 12 wherein the system parameter comprises a power transfer efficiency of the wireless power transfer system.

15. The method of claim 11, wherein adjusting an effective capacitance comprises adjusting the effective capacitance through a continuous range of values by controlling times when the MOSFETS are switched on and off.