Power electronics may rely on electronic circuits such as rectifiers, AC (Alternating Current) to DC (Direct Current) converters, impedance matching circuits, and other power electronics to condition, monitor, maintain, and/or modify the characteristics of the voltage and/or current used to provide power to electronic devices. Circuit components with adjustable impedance can used in such contexts to modify the voltage and/or current characteristics of various electronic devices. Controlling such components to avoid damage can be challenging. Moreover, present adjustable impedance circuit components may sacrifice efficiency power losses in order to ensure safe operation. For example, PWM controlled reactive components (e.g., capacitors and inductors) may rely on lossy diode conduction currents to clamp component voltages at zero while transistors are switched in order to avoid damaging current surges through the transistors.
In general, the disclosure features control systems and processes for controlling a variable reactive circuit component, such as a PWM controlled capacitor. The devices and process described herein can be used in a variety of contexts, including impedance matching networks, implantable devices, cell phone and other mobile computing device chargers, and chargers for electric vehicles.
In a first aspect, the disclosure features a variable capacitance device that includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including detecting a first zero-crossing of an input current at a first time. Switching off the first transistor after a first delay period from the first time. A length of the first delay period can be controlled by an input value. Detecting a second zero-crossing of the input current at a second time, after the first time. Measuring an elapsed time between switching off the first transistor and detecting the second zero-crossing. Setting a counter based on the elapsed time. Switching on the first transistor after a second delay period based on the counter.
In a second aspect, the disclosure features a high-voltage impedance matching system that includes an impedance matching network and a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including detecting a first zero-crossing of an input current at a first time. Switching off the first transistor after a first delay period from the first time. A length of the first delay period can be controlled by an input value. Detecting a second zero-crossing of the input current at a second time, after the first time. Measuring an elapsed time between switching off the first transistor and detecting the second zero-crossing. Setting a counter based on the elapsed time. Switching on the first transistor after a second delay period based on the counter.
In a third aspect, the disclosure features a wireless energy transfer system that includes an inductive coil electrically connected to a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including detecting a first zero-crossing of an input current at a first time. Switching off the first transistor after a first delay period from the first time. A length of the first delay period can be controlled by an input value. Detecting a second zero-crossing of the input current at a second time, after the first time. Measuring an elapsed time between switching off the first transistor and detecting the second zero-crossing. Setting a counter based on the elapsed time. Switching on the first transistor after a second delay period based on the counter.
These and the following aspects can each optionally include one or more of the following features.
In some implementations, the operations of the control circuitry include switching off the second transistor after the first delay period from the second time. Detecting a third zero-crossing of the input current at a third time, after the second time. Measuring a second elapsed time between switching off the second transistor and detecting the third zero-crossing. Setting a second counter based on the second elapsed time. Switching on the second transistor after a third delay period based on the second counter.
In some implementations, the effective capacitance of the capacitor is controlled by the input value.
In some implementations, the input value is a phase delay value, and the first delay period is equal to φ/360° T, where φ represents the phase delay value and T represents a period of the input current.
In some implementations, setting the counter based on the elapsed time includes setting the counter to the measured elapsed time plus a predetermined delay time.
In some implementations, the predetermined time delay less than 800 ns.
In some implementations, the first and second transistors are silicon MOSFET transistors, silicon carbide MOSFET transistors, or gallium nitride MOSFET transistors.
In some implementations, switching on the first transistor includes switching on the first transistor in response to detecting body-diode conduction through the first transistor.
In some implementations, the body-diode conduction through the first transistor indicates a zero voltage condition across the capacitor.
In a fourth aspect, the disclosure features a variable capacitance device that includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including determining a first delay period based on a phase delay value. Determining a second delay period based on the phase delay value, where the second delay period being longer than the first delay period. Detecting a first zero-crossing of an input current at a first time. Switching off the first transistor after the first delay period from the first time. Switching on the first transistor after the second delay period from the first time. Detecting a second zero-crossing of the input current at a second time, after the first time. Switching off the second transistor after the first delay period from the second time. Switching on the second transistor after the second delay period from the second time.
In a fifth aspect, the disclosure features a high-voltage impedance matching system that includes an impedance matching network and a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including determining a first delay period based on a phase delay value. Determining a second delay period based on the phase delay value, where the second delay period being longer than the first delay period. Detecting a first zero-crossing of an input current at a first time. Switching off the first transistor after the first delay period from the first time. Switching on the first transistor after the second delay period from the first time. Detecting a second zero-crossing of the input current at a second time, after the first time. Switching off the second transistor after the first delay period from the second time. Switching on the second transistor after the second delay period from the second time.
In a sixth aspect, the disclosure features a wireless energy transfer system that includes an inductive coil electrically connected to a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including determining a first delay period based on a phase delay value. Determining a second delay period based on the phase delay value, where the second delay period being longer than the first delay period. Detecting a first zero-crossing of an input current at a first time. Switching off the first transistor after the first delay period from the first time. Switching on the first transistor after the second delay period from the first time. Detecting a second zero-crossing of the input current at a second time, after the first time. Switching off the second transistor after the first delay period from the second time. Switching on the second transistor after the second delay period from the second time.
These and the other aspects can each optionally include one or more of the following features.
In some implementations, the effective capacitance of the capacitor is controlled by the phase delay value.
In some implementations, the first delay period is equal to
where φ represents the phase delay value and T represents a period of the input current.
In some implementations, the second delay period is equal to
where φ represents the phase delay value and T represents a period of the input current.
In some implementations, switching on the first transistor after the second delay period from the first time includes switching on the first transistor following a fixed time delay after the second delay period from the first time.
In some implementations, switching on the first transistor after the second delay period from the first time includes switching on the first transistor in response to detecting body-diode conduction through the first transistor.
In some implementations, the body-diode conduction through the first transistor indicates a zero voltage condition across the capacitor.
In some implementations, the first and second transistors are silicon MOSFET transistors, silicon carbide MOSFET transistors, or gallium nitride MOSFET transistors.
In a seventh aspect, the disclosure features a variable capacitance device that includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including generating an alternating ramp signal having peaks and troughs that are timed to correspond with zero-crossings of an input current. Switching off the first transistor in response to the ramp signal crossing a first reference value. Switching on the first transistor after the ramp signal crosses the first reference value and in response to detecting body-diode conduction through the first transistor. Switching off the second transistor in response to the ramp signal crossing a second reference value. Switching on the second transistor after the ramp signal crosses the second reference value and in response to detecting body-diode conduction through the first transistor.
In an eighth aspect, the disclosure features a high-voltage impedance matching system that includes an impedance matching network and a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including generating an alternating ramp signal having peaks and troughs that are timed to correspond with zero-crossings of an input current. Switching off the first transistor in response to the ramp signal crossing a first reference value. Switching on the first transistor after the ramp signal crosses the first reference value and in response to detecting body-diode conduction through the first transistor. Switching off the second transistor in response to the ramp signal crossing a second reference value. Switching on the second transistor after the ramp signal crosses the second reference value and in response to detecting body-diode conduction through the first transistor.
In a ninth aspect, the disclosure features a wireless energy transfer system that includes an inductive coil electrically connected to a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including generating an alternating ramp signal having peaks and troughs that are timed to correspond with zero-crossings of an input current. Switching off the first transistor in response to the ramp signal crossing a first reference value. Switching on the first transistor after the ramp signal crosses the first reference value and in response to detecting body-diode conduction through the first transistor. Switching off the second transistor in response to the ramp signal crossing a second reference value. Switching on the second transistor after the ramp signal crosses the second reference value and in response to detecting body-diode conduction through the first transistor.
These and the other aspects can each optionally include one or more of the following features.
In some implementations, the effective capacitance of the capacitor is controlled by the first and second reference values.
In some implementations, the second reference value has a value that is the negative of the first reference value.
In some implementations, switching on the first transistor includes switching on the first transistor following a fixed time delay after the ramp signal crosses the first reference value following the peak in the ramp signal.
In some implementations, switching on the first transistor includes switching on the first transistor after the ramp signal crosses the first reference value following a peak in the ramp signal and in response to detecting body-diode conduction through the first transistor.
In some implementations, the body-diode conduction through the first transistor indicates a zero voltage condition across the capacitor.
In some implementations, the first and second transistors are silicon MOSFET transistors, silicon carbide MOSFET transistors, or gallium nitride MOSFET transistors.
In a tenth aspect, the disclosure features a variable capacitance device that includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including detecting a zero-crossing of an input current at a first time. Switching off the first transistor. Estimating, based on an input value, a first delay period for switching the first transistor on when a voltage across the capacitor is zero. Switching on the first transistor after the first delay period from the first time. Detecting a zero-crossing of the input current at a second time. Switching off the second transistor. Estimating, based on the input value, a second delay period for switching the second transistor on when a voltage across the capacitor is zero. Switching on the second transistor after the second delay period from the second time.
In an eleventh aspect, the disclosure features a high-voltage impedance matching system that includes an impedance matching network and a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including detecting a zero-crossing of an input current at a first time. Switching off the first transistor. Estimating, based on an input value, a first delay period for switching the first transistor on when a voltage across the capacitor is zero. Switching on the first transistor after the first delay period from the first time. Detecting a zero-crossing of the input current at a second time. Switching off the second transistor. Estimating, based on the input value, a second delay period for switching the second transistor on when a voltage across the capacitor is zero. Switching on the second transistor after the second delay period from the second time.
In a twelfth aspect, the disclosure features a wireless energy transfer system that includes an inductive coil electrically connected to a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including detecting a zero-crossing of an input current at a first time. Switching off the first transistor. Estimating, based on an input value, a first delay period for switching the first transistor on when a voltage across the capacitor is zero. Switching on the first transistor after the first delay period from the first time. Detecting a zero-crossing of the input current at a second time. Switching off the second transistor. Estimating, based on the input value, a second delay period for switching the second transistor on when a voltage across the capacitor is zero. Switching on the second transistor after the second delay period from the second time.
These and the other aspects can each optionally include one or more of the following features.
In some implementations, the effective capacitance of the capacitor is controlled by the input value.
In some implementations, the first delay period is equal to
where φ represents the input value and T represents a period of the input current.
In some implementations, switching on the first transistor after the first delay period from the first time includes switching on the first transistor following a fixed time delay after the first delay period from the first time.
In some implementations, switching on the first transistor after the first delay period from the first time includes switching on the first transistor in response to detecting body-diode conduction through the first transistor.
In some implementations, the body-diode conduction through the first transistor indicates a zero voltage condition across the capacitor.
In some implementations, the first and second transistors are silicon MOSFET transistors, silicon carbide MOSFET transistors, or gallium nitride MOSFET transistors.
In some implementations, the operations of the control circuitry include determining a third delay period, based on the input value, and switching off the first transistor includes switching off the first transistor after the third delay period from the first time.
In some implementations, the third delay period is equal to
where φ represents the input value and T represents a period of the input current.
In some implementations, the operations of the control circuitry include determining a fourth delay period, based on the input value, and switching off the second transistor includes switching off the second transistor after the fourth delay period from the second time.
In some implementations, the fourth delay period is equal to
where φ represents the input value and T represents a period of the input current.
In a thirteenth aspect, the disclosure features a variable capacitance device that includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including switching off the first transistor at a first time. Switching on the first transistor after detecting a current through a first diode associated with the first transistor. Switching off the second transistor at a second time. Switching on the second transistor after detecting a current through a second diode associated with the second transistor.
In a fourteenth aspect, the disclosure features a high-voltage impedance matching system that includes an impedance matching network and a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including switching off the first transistor at a first time. Switching on the first transistor after detecting a current through a first diode associated with the first transistor. Switching off the second transistor at a second time. Switching on the second transistor after detecting a current through a second diode associated with the second transistor.
In a fifteenth aspect, the disclosure features a wireless energy transfer system that includes an inductive coil electrically connected to a variable capacitance device. The variable capacitance device includes a capacitor, a first transistor, a second transistor, and control circuitry. The first transistor includes a first-transistor source terminal, a first-transistor drain terminal, and a first-transistor gate terminal. The first-transistor drain terminal is electrically connected to a first terminal of the capacitor. The first-transistor gate terminal is coupled to the control circuitry. The second transistor includes a second-transistor source terminal, a second-transistor drain terminal, and a second-transistor a gate terminal. The second-transistor drain terminal is electrically connected to a second terminal of the capacitor. The second-transistor source terminal is electrically connected to the second-transistor source terminal. The second-transistor gate terminal is coupled to the control circuitry. The control circuitry is configured to adjust an effective capacitance of the capacitor by performing operations including switching off the first transistor at a first time. Switching on the first transistor after detecting a current through a first diode associated with the first transistor. Switching off the second transistor at a second time. Switching on the second transistor after detecting a current through a second diode associated with the second transistor.
These and the other aspects can each optionally include one or more of the following features.
In some implementations, the first diode is electrically connected in parallel with the first transistor, and the second diode is electrically connected in parallel with the second transistor.
In some implementations, the first diode is a body-diode of the first transistor, and the second diode is a body-diode of the second transistor.
Some implementations include a body diode conduction sensor electrically connected to the first transistor and the second transistor.
In some implementations, the body diode conduction sensor is coupled to the control circuitry and provides signals indicating a start of body diode conduction through the first diode and through the second diode.
In some implementations, the body diode conduction sensor includes a sense resistor electrically connected between the first transistor and the second transistor.
In some implementations, the body diode conduction sensor includes an operational amplifier comprising a first input terminal electrically connected to a one terminal of the sense resistor and a second input terminal electrically connected to another terminal of the sense resistor.
In some implementations, the body diode conduction sensor is configured to operate using a bipolar voltage supply.
In some implementations, the body diode conduction sensor is configured to operate using a unipolar voltage supply.
In some implementations, the first and second transistors are silicon MOSFET transistors, silicon carbide MOSFET transistors, or gallium nitride MOSFET transistors.
In a sixteenth aspect, the disclosure features an impedance matching network of a wireless power transmission system that includes first and second transistor switching elements having internal body diodes or external antiparallel diodes associated therewith. A PWM-switched capacitor coupled across the first and second switching elements. A controller coupled to control the first and second switching elements to minimize the body diode conduction time by steering current flow away from body diodes into the channels of the first and second transistor switching elements. This and the other aspects can each optionally include one or more of the following features.
In some implementations, the controller includes zero voltage switching ZVS circuitry to control switching to occur when a voltage across the PWM-switched capacitor and the first and second switching elements is near or at zero.
In some implementations, the controller is a mixed signal implementation.
In some implementations, the controller is a digital signal implementation and includes a microcontroller, a zero-crossing detection stage having an output sent to the microcontroller, and a power stage to which the zero-crossing detection stage is coupled. The the zero-crossing detection stage includes a comparator and a current sensor (908) that produces a voltage signal for the comparator. The power stage includes gate drivers for driving the first and second transistor switching elements and signal isolation for input signals to the gate drivers generated by the microcontroller.
In some implementations, the controller is a digital signal implementation that includes starting a cycle of a switching period; detecting a zero-crossing of an input current by a zero-crossing detector when the input current is rising; scheduling the first transistor switching element to turn off at time t2 where t2=φ/360°·T and T is a period of the input current and phase φ sets an equivalent capacitance of the PWM-switched capacitor to approximately
scheduling the second transistor switching element to turn on at a time t5, where
and delay Tdelay is adjusted so zero-voltage switching is ensured for all operating conditions; finishing the cycle by turning on the second transistor switching element M2; turning off the first transistor switching element; detecting zero-crossing of the input current when the input current is falling; scheduling the second transistor switching element to turn off at time t6, where t6=T/2+φ/360°·T; scheduling the second transistor switching element to turn on at time t9, where
zero voltage switching first transistor switching element; turning on the first transistor switching element; turning off the second transistor switching element; detecting zero-crossing of the input current to start a next cycle when the input current is rising; scheduling switching element to turn off after t=φ/360°·T; zero voltage switching the second transistor switching element; turning on the second transistor switching element; transitioning to a start of a next cycle.
In some implementations, the first and second transistor switching elements are MOSFET devices.
In some implementations, the first and second transistor switching elements are galium nitride (GaN) or silicon carbide (SiC) transistor switching elements.
In some implementations, the controller is a gate control module for providing a first gate control signal for the first switching element and a second gate control signal for the second switching element, as well as a reference potential for a node between the gates of the first and second switching elements.
In some implementations, the PWM-switched capacitor provides an equivalent capacitance of
where C1 is an impedance value of the capacitor and φ is a phase delay.
In a seventeenth aspect, the disclosure features a wireless power transmission system that includes a source-side circuit and a device-side circuit. The source-side circuit includes an inverter for powering the source-side circuit, the impedance matching network the of any of the above described aspects, and a source resonator. The device-side circuit includes a device resonator a device impedance matching network, and a rectifier. The impedance matching network couples, with a coupling factor, oscillating electromagnetic energy to the device-side circuit where the oscillating electromagnetic energy is converted by the rectifier.
In some implementations, the source-side circuit includes a source resonator coil, a series capacitor, a parallel capacitor, a capacitor, and an inductor, where the capacitor is the PWM-switched capacitor.
Particular implementations of the subject matter described in this specification can be implemented so as to realize one or more of the following advantages. Implementations may reduce body-diode (or antiparallel diode) conduction times associated with power losses in switching transistors, and thereby, improve operational efficiency and/or thermal management. Implementations may permit the use of a wider array of transistors, including those having relative large forward body-diode voltage drops, for example, gallium nitride (GaN) of silicon carbide (SiC) transistors. Implementations may provide improved tolerance of input currents that have harmonic content, such as a triangular waveform, a trapezoidal waveform, a square waveform, or a waveform with sinusoidal characteristics with significant harmonic content.
Embodiments of the devices, circuits, and systems disclosed can also include any of the other features disclosed herein, including features disclosed in combination with different embodiments, and in any combination as appropriate.
The details of one or more implementations of the subject matter described in this specification are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages of the subject matter will be apparent from the description, the drawings, and the claims.
Like reference numbers and designations in the various drawings indicate like elements.
In general, the disclosure features control systems and processes for controlling a variable reactive circuit component. Implementations of the present disclosure are described in the context of a circuit including a PWM-switched capacitor coupled across first and second switching elements (e.g., transistors). Implementations disclosed herein may minimize diode conduction time for external antiparallel or internal body diodes associated with the first and second switching elements. Implementations of the PWM-switched capacitor circuit can operate with sinusoidal input currents containing significantly higher harmonic content than conventional circuits. Shorting a PWM-switched capacitor when a zero voltage is not present can be undesirable and may damage the switching elements and/or increase power loss. Implementations discussed herein control the first and second switching elements to minimize the body diode conduction time (dead time) by steering current flow away from body diodes into the transistor (e.g. MOSFET) channel. In doing so, losses due to diode voltage drops are minimized. Accordingly, implementations may provide efficient circuit operation while maintaining zero voltage switching. Implementations can be implemented with a computer processor, microcontroller, digital-signal processor, FPGA, CPLD, or any other programmable processing device to generate gate control signals, in mixed signal configurations, and in digital circuitry. Furthermore, implementations of the present disclosure provide variable capacitor control that allow for efficient operation over the entire range of conditions encountered by impedance matching networks in highly-resonant wireless power transfer systems (HRWPT) system such as high-power vehicle charging systems, for example.
Control of the PWM capacitor can be implemented in several ways, such as in a mixed signal (analog and digital) implementation and/or a digital signal implementation. These implementations are described more fully below. Advantages of the disclosed implementations include the following:
In some implementations, the body-diode (or antiparallel diode) conduction time can be adjustable and significantly reduced. Such reductions in body-diode (or antiparallel diode) conduction time reduces MOSFET losses and improves efficiency and thermal management of power electronics.
In some implementations, the PWM capacitor control techniques permit the use of a wider array of transistors, including those having relative large forward body-diode voltage drops, for example, gallium nitride (GaN) of silicon carbide (SiC) transistors.
In some implementations, the PWM capacitor provides improved tolerance of input currents that have harmonic content, such as a triangular waveform, a trapezoidal waveform, a square waveform, or a waveform with sinusoidal characteristics with significant harmonic content. This is an advantage over conventional control methods that may require purely sinusoidal currents. For example, to achieve a purely sinusoidal current, filtering components can be added to the circuit, adding cost and component count. In some implementations, the PWM capacitor can tolerate transients, such as at the start-up of an associated system.
A switching inverter 104 converts the DC voltage into AC voltage waveform (e.g., a high-frequency AC voltage waveform). The AC voltage waveform outputted by the inverter 104 is used to drive a source resonator 106. In some implementations, the frequency of the AC voltage waveform may be in the range of 80 to 90 kHz. In some implementations, the frequency of the AC voltage waveform may be in the range of 1 kHz to 15 MHz. In some implementations, the inverter 104 includes an amplifier.
A source impedance matching network (IMN) 108 couples the inverter 104 output to the source resonator 106. The source IMN 108 can enable efficient switching-amplifier operation. For example, class D or E switching amplifiers are suitable in many applications and can require an inductive load impedance for highest efficiency. The source IMN 108 can transform effective impedances of the source resonator as seen by the inverter 104. The source resonator impedance can be, for example, loaded by being electromagnetically coupled to a device resonator 110 and/or output load. For example, the magnetic field generated by the source resonator 106 couples to the device resonator 110, thereby inducing a corresponding voltage. This energy is coupled out of the device resonator 110 to, for example, directly power a load or charge a battery.
A device impedance matching network (IMN) 112 can be used to efficiently couple energy from the device resonator 110 to a load 114 and optimize power transfer between source resonator 106 and device resonator 110. Device IMN 112 can transform the impedance of a load 114 into an effective load impedance seen by the device resonator 110 which more closely matches the source impedance to increase system efficiency. For loads requiring a DC voltage, a rectifier 116 converts the received AC power into DC. In some implementations, the source 118 and device 120 a further include filters, sensors, and other components.
The impedance matching networks (IMNs) 108, 112 can be designed to maximize the power delivered to the load 114 at a desired frequency (e.g., 80-90 kHz, 100-200 kHz, 6.78 MHz) or to improve power transfer efficiency. The impedance matching components in the IMNs 108, 112 can be chosen and connected so as to preserve a high-quality factor (Q) value of resonators 106, 110. Depending on the operating conditions, the components in the IMNs 108, 112 can be tuned to control the power delivered for the power supply to the load 114, for example improve efficient wireless transfer of power.
The IMNs (108, 112) can have components including, but not limited to, a capacitor or networks of capacitors, an inductor or networks of inductors, or various combinations of capacitors, inductors, diodes, switches, and resistors. The components of the IMNs can be adjustable and/or variable and can be controlled to affect the efficiency and operating point of the system. Impedance matching can be performed by varying capacitance, varying inductance, controlling the connection point of the resonator, adjusting the permeability of a magnetic material, controlling a bias field, adjusting the frequency of excitation, and the like. The impedance matching can use or include any number or combination of varactors, varactor arrays, switched elements, capacitor banks, switched and tunable elements, reverse bias diodes, air gap capacitors, compression capacitors, barium zirconium titanate (BZT) electrically tuned capacitors, microelectromechanical systems (MEMS)-tunable capacitors, voltage variable dielectrics, transformer coupled tuning circuits, and the like. The variable components can be mechanically tuned, thermally tuned, electrically tuned, piezo-electrically tuned, and the like. Elements of the impedance matching can be silicon devices, gallium nitride devices, silicon carbide devices, and the like. The elements can be chosen to withstand high currents, high voltages, high powers, or any combination of current, voltage, and power. The elements can be chosen to be high-Q elements.
Control circuitry in a source 118 and/or device 120 monitors impedance differences between the source 118 and the device 120 and provides control signals to tune respective IMNs 108, 112 or components thereof. In some implementations, the IMNs 108, 112 can include a fixed IMN and a dynamic IMN. For example, a fixed IMN may provide impedance matching between portions of the system with static impedances or to grossly tune a circuit to a known dynamic impedance range. In some implementations, a dynamic IMN can be further composed of a coarsely adjustable components and/or finely adjustable components. For example, the coarsely adjustable components can permit coarse impedance adjustments within a dynamic impedance range whereas the finely adjustable components can be used to fine tune the overall impedance of the IMN(s). In another example, the coarsely adjustable components can attain impedance matching within a desirable impedance range and the finely adjustable components can achieve a more precise impedance around a target within the desirable impedance range.
IMNs 108 and 112 can have a wide range of circuit implementations with various components having impedances to meet the needs of a particular application. For example, U.S. Pat. No. 8,461,719 to Kesler et al., which is incorporated herein by reference in its entirety, discloses a variety of tunable impedance network configurations, such as in
where C1 is an impedance value of the capacitor and φ is an input phase delay, as described more fully below.
First and second switching elements M1, M2 are coupled back-to-back across or in parallel to capacitor C1. The first and second switching elements M1, M2 can be MOSFET devices. A gate control circuitry 300 provides a first gate control signal g1 for the first switching element M1 and a second gate control signal g2 for the second switching element M2. In some implementations, gate control circuitry 300 provides a reference potential s12 for a node between the gates of the first and second switching elements M1, M2.
Input current I1 flows into a first node N1 and current IC1 flows out of the first node to capacitor C1. Current I2 flows out of the first node N1 into the drain terminal of the first switching element M1. The capacitor C1 is coupled between the Vcap+ and Vcap− nodes to define the voltage across the capacitor. In some implementations, the circuit can include a first sensor S1 to sense MOSFET body diode conduction and a second sensor S2 to sense current through the switched capacitor, as described more fully below. In some implementations, the switching elements M1, M2 may be silicon MOSFETs.
Mixed-Signal Implementation
Zero-crossing detector 506 outputs a square-wave signal Vzc=Vzc−−Vzc+. In other words, the output of the zero-crossing detector 506 can be, for example, a signal with +5V amplitude when I1 is negative and −5V amplitude when I1 is positive. Ramp generator 508 converts square-wave signal Vzc to a ramp signal Vramp using, for example, an integrator circuit. Ramp generator 508 provides a ramp signal that a positive slope when the current I1 is positive and a negative slope when the current I1 is negative. In addition, the peaks of the ramp signal may correspond to zero-crossings of current I1, as shown in subplot III of
High-frequency filter 510, composed of C20 and R49, eliminates any DC bias that may exist at the output of operational amplifier U2. PWM generation 512 creates switching functions PWM_M1 and PWM_M2 that control the switching elements M1 and M2. Two comparators 514a, 514b are used to produce these signals from Vramp, Vref+, and Vref−.
For example, turning on switching elements M1, M2 at non-zero voltage of capacitor C1 may lead to excessive losses, physical damage to switching elements, or both. Pulse shaping circuit 406 can condition signals PWM_M1 and PWM_M2 by delaying turn-on edge of PWM_M1 and PWM_M2 such that zero-voltage turn-on of M1 and M2 can be achieved. Manually adjustable pulse shaping circuit can be configured adjust the ZVS condition on-the-fly for different input currents I1. Note that ZVS can be manually adjustable by activating any of the selection signals en0 to en3. The body diode of a MOSFET is on before ZVS turn-on. The conduction time of body-diode is greatly reduced from conventional operation but it is not minimal. As shown, pulse shaping circuit 406 is implemented using logic gates, however, in some implementations, a digital multiplexer circuit can also be used to achieve similar results.
In some implementations, the overlap of the gate signals, Vsg1 and Vgs2, can be controlled from zero overlap to complete overlap. When the overlap is zero, all of the input current I1 flows through capacitor C1 such that the effective capacitance of the PWM capacitor is the value of C1. When the gate signal overlap is complete, all of the input current I1 flows through the switching elements M1, M2 only. The effective capacitance of the PWM capacitor equals infinity (due to the short circuit effect and thus having an infinitely large capacitance at the frequency of switching). Because the control circuit is able to control the overlap, effective PWM capacitor capacitances from the value of C1 to infinity can be generated.
Digital Implementation
In operation, controller 902 controls the effective capacitance of capacitor C1 by alternately switching transistors M1 and M2 in order to bypass or short capacitor C1 for a portion of both the positive and negative half of an AC input voltage signal. An input signal is provided to the controller 902 that indicates a desired effective capacitance for capacitor C1. The controller 902 determines on and off times for the transistors M1 and M2 based on the input signal. In some implementations, the input signal is a phase delay φ ranging between 90 and 180 degrees. The controller 902 determines first and second delay periods from a trigger point of an input current based on the phase delay φ. The controller 902 controls the gate drivers 914 to generate PWM signals for driving the transistors M1 and M2 based on the delay times. For purposes of explanation, the input current zero-crossing is used as a trigger point. However, in some implementations, a current peak can be used as a trigger point. For instance, zero-crossing detector can be modified to detect current peaks by, for example, incorporating a differentiator circuit. In such n implementations, the range for the phase delay φ input may be shifted by 90 degrees to account for the shift in the trigger point.
In general, the controller 902 calculates a transistor turn off delay period and a transistor turn on delay period. The controller 902 receives a zero-crossing signal from the zero-crossing detector 910 and waits for the transistor turn off delay time before turning off the first transistor (e.g., M1). The controller 902 then waits until after the turn on delay period from the zero-crossing to turn the first transistor back on. Another zero-crossing of the current will occur while the first transistor is turned off. In some implementations, the transistor turn on delay period can be measured from the same zero-crossing as the transistor turn off delay period, or, in some implementations, the transistor turn on delay period can be measured from the zero-crossing that occurs while the transistor is turned off. The process is repeated for the second transistor, during the next half cycle of the input current signal.
The transistor turns off and turn on delay times may be the same for both transistors, but triggered from different zero-crossing points (e.g., zero-crossing points occurring at opposite phases of the input current). In some implementations, the turn off and turn and turn on delay times can be different for each transistor. In some implementations, ensuring that the transistors are switched at zero voltage is more critical for turning the transistors on than for turning the transistors off. Therefore, the controller 902 can estimate a theoretical transistor turn on delay based on the phase delay value, as discussed below. In order to ensure that the transistors are turned on when the voltage across capacitor C1 is zero, the controller 902 can wait for an additional period of time after the estimated transistor turn on delay period. In some implementations, the additional period of time is a predetermined delay period (e.g., ≤300 ns, ≤500 ns, ≤800 ns, or ≤1000 ns), for example, to ensure that a body-diode current of a power transistor (or current through an anti-parallel diode) occurs to briefly clamp the voltage across C1 at zero before turning on a transistor. In some implementations, the controller 902 turns the transistor on after the estimated transistor turn on delay period and after detecting body-diode conduction through the transistor (or through an anti-parallel diode). In some implementations, the controller 902 does not estimate a transistor turn on time, but turns on the transistor after detecting body-diode conduction through the transistor (or through an anti-parallel diode). For example, the controller 902 can receive a body-diode conduction signal from a body-diode conduction sensor, such as that discussed in more detail below in reference to
Step 1002 starts a cycle of a switching period. At step 1004 (time to), the zero-crossing of input current I1 is detected by the zero-crossing detector 910 when the current I1 is rising. At step 1006, transistor M1 is scheduled to turn off at time t2, a turn off delay period after the zero-crossing. For example, a first delay period is calculated based on the input phase φ, where:
and where T is the period of the input current I1 and the input phase φ sets equivalent capacitance to approximately:
At step 1008, transistor M1 is scheduled to turn on at time t5, a turn on delay period after the zero-crossing and which can be represented by, for example:
where predetermined delay Tdelay is adjusted so zero-voltage switching is ensured. In some implementations, predetermined delay Tdelay is a fixed delay (e.g., Tdelay≤300 ns, ≤500 ns, ≤800 ns, or ≤1000 ns). At step 1010 (time t1), the previous cycle is finished by turning on switching element M2. At step 1012 (time t2), the transistor M1 is turned off after the turn off delay period. At step 1014 (time t3), zero-crossing of the input current I1 is detected when the current is falling. In some implementations, time t3 is equal to T/2. At step 1016, the transistor M2 is scheduled to turn off at time t6, a second turn off delay period after the first zero-crossing at to and which can be represented by, for example:
t6=T/2+φ/360°·T.
In some implementations, transistor M2 is scheduled to turn off at time t6 by using the first turn off delay period (calculated above as t2) but measured from the second zero-crossing of input current I1 at time t3.
At step 1018, the transistor M2 is scheduled to turn on at time t9, a second turn on delay period after the zero-crossing and which can be represented by, for example:
In some implementations, transistor M2 is scheduled to turn on at time t9 by using the first turn on delay period (calculated above as t5) but measured from the second zero-crossing of input current I1 at time t3.
At step 1020 (time t4), ZVS condition is theoretically achieved for switching element M1 assuming a periodic waveform, such as a sinusoid, for input I1. In some implementations, time t4 is estimated by:
At step 1022 (time t5), transistor M1 is turned on after the turn on delay period. At step 1024 (time t6), transistor M2 is turned off after the second turn off delay period. At step 1026 (time t7), zero-crossing of input current I1 is detected to start the next cycle when the current I1 is rising. Transistor M1 is scheduled to turn off after
t=φ/360°·T.
At step 1028 (time t8), ZVS condition is theoretically achieved for transistor M2 assuming a periodic waveform, such as a sinusoid, for input current I1. At step 1030 (time t9), transistor M2 is turned on after the second turn on delay period. Step 1032 is the transition to start the next cycle which leads to step 1012.
Step 1052 starts a cycle of a switching period. At step 1054 (time to), the controller 902 detects a first zero-crossing of input current I1, for example, by receiving a zero-crossing detection signal from the zero-crossing detector 910. At step 1056, the controller 902 determines a turn off delay period. For example, the turn of delay period can be determined based on in input value such as an input phase (p. In other words, the input value controls the length of the turn off delay period. For example, the turn off delay can be calculated by:
toff=φ/360°·T.
The turn off delay period represents a period of time that the controller waits from each zero-crossing detection until switching off one of the transistors M1 or M2. In some implementations, the turn off delay period determines the effective impedance of the capacitor C1.
At step 1058 (time t2), the first transistor M1 is turned off after the turn off delay period from the first zero-crossing of the input current I1. This is represented in
At step 1062 (time t3), the controller 902 detects a second zero-crossing of input current I1, for example, by receiving a zero-crossing detection signal from the zero-crossing detector 910. At step 1064 controller 902 sets a first turn-on counter based on the elapsed time. For example, the turn-on counter can be set to count down from the elapsed time or the counter that measured the elapsed time can be reversed to count down to zero. The controller 902 uses the turn-on timer to estimate when the voltage across capacitor C1 will return to zero. For instance, as shown in the following
At step 1066, the controller 902 turns the first transistor M1 back on after the turn-on counter expires (e.g., after a second delay period measured by the turn-on counter). This is represented in
At step 1068 (time t6), the second transistor M2 is turned off after the turn off delay period from the second zero-crossing of the input current I1 (e.g., at time t3). This is represented in
At step 1072 (time t7), the controller 902 detects a third zero-crossing of input current I1, for example, by receiving a zero-crossing detection signal from the zero-crossing detector 910. At step 1074 controller 902 sets a second turn-on counter based on the elapsed time. For example, the second turn-on counter can be set to count down from the elapsed time or the counter that measured the elapsed time can be reversed to count down to zero. The controller 902 uses the turn-on timer to estimate when the voltage across capacitor C1 will return to zero. Accordingly, the controller 902 can estimate the theoretical ZVS time (e.g., time t8) for turning on a transistor (e.g., transistor M2) by counting symmetric times intervals between shutting off the transistor (when the voltage increases in magnitude) and a subsequent zero current crossing (when the voltage reaches a peak) (e.g., t6-t7), and between the subsequent zero current crossing and an estimated ZVS time (e.g., t7-t8).
At step 1076, the controller 902 turns the second transistor M2 back on after the second turn-on counter expires (e.g., after a second delay period measured by the turn-on counter). This is represented in
Protection and Diagnostics
The modulator 1204 can includes a reference voltage generator 1217 and a band-pass filter or integrator 1218, which can be similar to that described above. The power stage 1206 can include a signal isolation circuitry 1222 and gate driver 1224, which may be similar to that described above.
The CSOK circuitry checks if input current is “sinusoidal” without discontinuity at zero. In the illustrated embodiment, capacitor current information CS1, CS2 is provided to an op amp that outputs a current information signal CS_SE (
In the illustrated embodiment, the above-described CS_SE is provided to a series of comparators with inputs of maximum and minimum current levels. The comparator outputs are latched with the CF, CR signals and the latch outputs are combined to identify over current conditions.
As shown in the waveform diagram of
In some implementations, the protection/diagnostic circuitry 1210 can further include over temperature protection (OTP) having a temperature sensor that can generate an error signal if the measured temperature exceeds a given threshold.
The power stage 2120 can include a signal isolation circuitry 1222 and gate driver 1224, which may be similar to that described above. The power stage 2120 can include a capacitor C1 and switching elements M1, M2 and a current sensor for sensing current through the capacitor C1 and providing current information signals, CS1, CS2, as described above, for example.
Automatic Zero-Voltage Switching Control
In some implementations, a system having a PWM-controlled capacitor includes enhanced circuit for zero-voltage switching of its switches (e.g. MOSFETs).). In some implementations, an automatic ZVS implementation provides ZVS in the presence of relatively significant signal transients to reduce or eliminate switching element, e.g., MOSFET, breakdown relating to the PWM-controlled capacitor. In some implementations, a body diode conduction sensor detects body diode conduction in the switching element and affects switching element control signals, as described more fully below.
In some implementations, the power stage 2206 includes a body diode conduction sensor 2215 that can detect conduction of a body diode, e.g., D1, D2, of a switching element, such as M1 or M2 MOSFETS. As described more fully below, a voltage across a sense resistor Rdcs at nodes s1, s2 can be provided to the body diode conduction sensor 2215.
The modulator 2204 can include a reference voltage generator 2218, a band-pass filter or integrator 2220 coupled to the zero-crossing detector 2214, and a PWM signal generator 2222 to generate controls signals for the switching elements M1, M2 which can be similar to those described above. The power stage 2206 can include a signal isolation circuitry 2224 and gate driver 2226, which may be similar to that described above, as well as the body diode conduction sensor 2215. A ZVS circuitry 2230 can be provided between the modulator 2204 and the power stage 2206. In some implementations, the body diode conduction sensor 2215 can be coupled to the controller 2202 via a controller interface 2203.
The example zero-crossing detector 2214 as shown in
In one embodiment, where switching elements M1, M2 are provided as MOSFETs, when the body-diode for M1, for example, begins to conduct, a current pulse in the sense resistor Rdcs is detected. Components R7, R8, and C4 form a low-pass filter to reduce noise due to ringing of the M1 (or M2) current. Components R7, R8, R9, R10 provide hysteresis for the comparator 2302 that prevents faulty current pulse detections. A rising edge of output Vn corresponds to the detection of M1 body-diode start of conduction and a rising edge of output Vp corresponds to the detection of M2 body-diode start of conduction. In some implementations, outputs Vn and Vp are complementary signals.
Resistor R1 converts current signal CS1, CS2 (see
The M1 pulse-shaped gate drive signal PWM_1_PS and Vne signal are provided as input to logic OR gate A1, which outputs M1 gate drive signal PWM_1. The M2 delayed gate drive signal PWM_2_PS and Vpe signal are provided as input to logic OR gate A2, which outputs M2 gate drive signal PWM_2.
Signals PWM_M1 and PWM_M2 are modified to PWM_1_PS and PWM_2_PS so that their rising edge in time-domain waveform comes after the rising edge of Vn and Vp The rising edge of M1 gate driver signal PWM_1 is determined by rising edge of Vne, while the falling edge is determined by PWM_1_PS. The rising edge of the M2 gate driver signal PWM_2 is determined by the rising edge of Vpe, while the falling edge is determined by PWM_2_PS.
While the disclosed techniques have been described in connection with certain preferred embodiments, other embodiments will be understood by one of ordinary skill in the art and are intended to fall within the scope of this disclosure. For example, designs, methods, configurations of components, etc. related to transmitting wireless power have been described above along with various specific applications and examples thereof. Those skilled in the art will appreciate where the designs, components, configurations or components described herein can be used in combination, or interchangeably, and that the above description does not limit such interchangeability or combination of components to only that which is described herein.
For illustrative purposes, the foregoing description focuses on the use of devices, components, and methods in high power wireless power transfer applications, e.g., power transfer for charging electric vehicles.
More generally, however, it should be understood that devices that can receive power using the devices, components, and methods disclosed herein can include a wide range of electrical devices, and are not limited to those devices described for illustrative purposes herein. In general, any portable electronic device, such as a cell phone, keyboard, mouse, radio, camera, mobile handset, headset, watch, headphones, dongles, multifunction cards, food and drink accessories, and the like, and any workspace electronic devices such as printers, clocks, lamps, headphones, external drives, projectors, digital photo frames, additional displays, and the like, can receive power wirelessly using the devices, components, and methods disclosed herein. Furthermore, any electrical device, such as electric or hybrid vehicles, motorized wheel chairs, scooters, power tools, and the like, can receive power wirelessly using the devices, components, and methods disclosed herein.
In this disclosure, certain circuit or system components such as capacitors, inductors, resistors, are referred to as circuit “components” or “elements.” The disclosure also refers to series and parallel combinations of these components or elements as elements, networks, topologies, circuits, and the like. More generally, however, where a single component or a specific network of components is described herein, it should be understood that alternative embodiments may include networks for elements, alternative networks, and/or the like.
As used herein, the term “coupled” when referring to circuit or system components is used to describe an appropriate, wired or wireless, direct or indirect, connection between one or more components through which information or signals can be passed from one component to another.
As used herein, the term “direct connection” or “directly connected,” refers to a direct connection between two elements where the elements are connected with no intervening active elements between them. The term “electrically connected” or “electrical connection,” refers to an electrical connection between two elements where the elements are connected such that the elements have a common potential. In addition, a connection between a first component and a terminal of a second component means that there is a path between the first component and the terminal that does not pass through the second component.
Implementations of the subject matter and the operations described in this specification can be realized in digital electronic circuitry, or in computer software, firmware, or hardware, including the structures disclosed in this specification and their structural equivalents, or in combinations of one or more of them. Implementations of the subject matter described in this specification can be realized using one or more computer programs, i.e., one or more modules of computer program instructions, encoded on computer storage medium for execution by, or to control the operation of, data processing apparatus. Alternatively or in addition, the program instructions can be encoded on an artificially generated propagated signal, e.g., a machine-generated electrical, optical, or electromagnetic signal that is generated to encode information for transmission to suitable receiver apparatus for execution by a data processing apparatus. A computer storage medium can be, or be included in, a computer-readable storage device, a computer-readable storage substrate, a random or serial access memory array or device, or a combination of one or more of them. Moreover, while a computer storage medium is not a propagated signal; a computer storage medium can be a source or destination of computer program instructions encoded in an artificially generated propagated signal. The computer storage medium can also be, or be included in, one or more separate physical components or media (e.g., multiple CDs, disks, or other storage devices).
The operations described in this specification can be implemented as operations performed by a data processing apparatus on data stored on one or more computer-readable storage devices or received from other sources.
The term “data processing apparatus” encompasses all kinds of apparatus, devices, and machines for processing data, including by way of example a programmable processor, a computer, a system on a chip, or multiple ones, or combinations, of the foregoing. The apparatus can include special purpose logic circuitry, e.g., an FPGA (field programmable gate array) or an ASIC (application-specific integrated circuit). The apparatus can also include, in addition to hardware, code that creates an execution environment for the computer program in question, e.g., code that constitutes processor firmware, a protocol stack, a database management system, an operating system, a cross-platform runtime environment, a virtual machine, or a combination of one or more of them. The apparatus and execution environment can realize various different computing model infrastructures, such as web services, distributed computing and grid computing infrastructures.
A computer program (also known as a program, software, software application, script, or code) can be written in any form of programming language, including compiled or interpreted languages, declarative or procedural languages, and it can be deployed in any form, including as a stand-alone program or as a module, component, subroutine, object, or other unit suitable for use in a computing environment. A computer program may, but need not, correspond to a file in a file system. A program can be stored in a portion of a file that holds other programs or data (e.g., one or more scripts stored in a markup language document), in a single file dedicated to the program in question, or in multiple coordinated files (e.g., files that store one or more modules, sub-programs, or portions of code). A computer program can be deployed to be executed on one computer or on multiple computers that are located at one site or distributed across multiple sites and interconnected by a communication network.
The processes and logic flows described in this specification can be performed by one or more programmable processors executing one or more computer programs to perform actions by operating on input data and generating output. The processes and logic flows can also be performed by, and apparatus can also be implemented as, special purpose logic circuitry, e.g., an FPGA (field programmable gate array) or an ASIC (application-specific integrated circuit).
Processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer. Generally, a processor will receive instructions and data from a read-only memory or a random access memory or both. Elements of a computer can include a processor for performing actions in accordance with instructions and one or more memory devices for storing instructions and data. Generally, a computer will also include, or be operatively coupled to receive data from or transfer data to, or both, one or more mass storage devices for storing data, e.g., magnetic, magneto-optical disks, or optical disks. However, a computer need not have such devices. Moreover, a computer can be embedded in another device, e.g., a wireless power transmitter or receiver or a wirelessly charged or powered device such as a vehicle, a mobile telephone, a personal digital assistant (PDA), a mobile audio or video player, a game console, or a Global Positioning System (GPS) receiver, to name just a few. Devices suitable for storing computer program instructions and data include all forms of non-volatile memory, media and memory devices, including by way of example semiconductor memory devices, e.g., EPROM, EEPROM, and flash memory devices; magnetic disks, e.g., internal hard disks or removable disks; magneto-optical disks; and CD-ROM and DVD-ROM disks. The processor and the memory can be supplemented by, or incorporated in, special purpose logic circuitry.
While this specification contains many specific implementation details, these should not be construed as limitations on the scope of any implementation of the present disclosure or of what may be claimed, but rather as descriptions of features specific to example implementations. Certain features that are described in this specification in the context of separate implementations can also be implemented in combination in a single implementation. Conversely, various features that are described in the context of a single implementation can also be implemented in multiple implementations separately or in any suitable sub-combination. Moreover, although features may be described above as acting in certain combinations and even initially claimed as such, one or more features from a claimed combination can in some cases be excised from the combination, and the claimed combination may be directed to a sub-combination or variation of a sub-combination.
Similarly, while operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results. In certain circumstances, multitasking and parallel processing may be advantageous. Moreover, the separation of various system components in the implementations described above should not be understood as requiring such separation in all implementations, and it should be understood that the described program components and systems can generally be integrated together in a single software product or packaged into multiple software products.
Under 35 U.S.C. § 120, this application is a divisional of and claims priority to U.S. patent application Ser. No. 16/038,569, filed on Jul. 18, 2018, which is a continuation of and claims priority to U.S. patent application Ser. No. 15/427,186, filed on Feb. 8, 2017, now U.S. Pat. No. 10,063,104, which claims priority to U.S. Provisional Patent Application Nos. 62/292,474, filed on Feb. 8, 2016; 62/376,217, filed on Aug. 17, 2016; 62/407,010, filed on Oct. 12, 2016; and 62/408,204 filed on Oct. 14, 2016. The entire contents of each of these priority applications are incorporated herein by reference in their entirety.
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