Wireless power transmitters with wide input voltage range and methods of their operation

What is claimed is: 1. A power transmitter for wirelessly charging an electronic device, the power transmitter comprising: an input configured to receive a variable DC input voltage; an inverter coupled to the input to receive the variable DC input voltage, the inverter configured to generate an AC square-wave signal having a duty cycle selected to provide a predetermined equivalent voltage, wherein the inverter is configured to generate the AC square-wave signal with a relatively high duty cycle when a determined magnitude of the variable DC input voltage is relatively low, and the inverter is configured to generate the AC square-wave signal with a relatively low duty cycle when the determined magnitude of the variable DC input voltage is relatively high; a plurality of primary coils coupled to a matching network to receive a charging signal, the plurality of primary coils configured to be selectable in multiple different coil combinations, each of the multiple different coil combinations including a number of the plurality of primary coils, with at least one of the multiple different coil combinations including more than one of the plurality of primary coils to facilitate transmission with different numbers of primary coils, the plurality of primary coils configured to selectively transmit a power transfer signal to a receiver coil on the electronic device; and the matching network coupled to the inverter and to the plurality of primary coils, the matching network configured to generate the charging signal from the AC square-wave signal and to provide the charging signal to the plurality of primary coils, the matching network including a differential input with first and second differential inputs configured to receive the AC square wave signal, a differential output with first and second differential outputs configured to produce the charging signal, and a plurality of switched capacitors that are selectively switched to achieve maximum power transfer efficiency for a selected coil combination used to transmit the power transfer signal, wherein the plurality of switched capacitors are coupled in parallel across the first and second differential inputs, wherein a first number of the plurality of switched capacitors are switched into the matching circuit when a first number of primary coils are included in the selected coil combination, and one or more additional switched capacitors are switched into the matching circuit when a second and larger number of primary coils are included in the selected coil combination. 2. The power transmitter of claim 1 , wherein the plurality of switched capacitors are selectively switched based on the number of the plurality of primary coils in the selected coil combination. 3. The power transmitter of claim 1 , wherein the plurality of switched capacitors are switched so that the matching network resonates with the selected coil combination at a resonant frequency that closely matches a fundamental frequency of the charging signal. 4. The power transmitter of claim 1 , further comprising: a voltage detector coupled to the input and configured to determine the determined magnitude of the variable DC input voltage. 5. The power transmitter of claim 1 , wherein the inverter comprises: a full-bridge inverter with first and second transistor pairs, wherein the inverter is configured to generate the AC square-wave signal using a shifted phase topology in which the switching of the first transistor pair is phase shifted with respect to the second transistor pair. 6. The power transmitter of claim 1 , wherein the inverter comprises: a full-bridge inverter with first and second transistor pairs, wherein the inverter is configured to generate the AC square-wave signal with dead times that assure quasi-resonant soft switching of the transistor pairs, wherein a dead time is a time interval between a first time at which one transistor in a transistor pair is turned off and a second time at which a complement transistor in the transistor pair is turned on. 7. The power transmitter of claim 1 , wherein the inverter is configured to generate the AC square-wave signal at a plurality of different frequencies, and wherein the power transmitter is further configured to determine which of the plurality of different frequencies or matching network configurations results in efficient power transfer to the electronic device. 8. The power transmitter of claim 7 , wherein the power transmitter is configured to determine which of the plurality of different frequencies or matching network configurations results in efficient power transfer to the electronic device based on feedback received from the electronic device. 9. The power transmitter of claim 1 , wherein the matching network further comprises: an inductor coupled between the first differential input and the first differential output. 10. The power transmitter of claim 1 , wherein the selected coil combination is determined by selectively activing each of the plurality of primary coils to determine a coil combination that most effectively couples with the receiver coil on the electronic device. 11. The power transmitter of claim 10 , wherein the coil combination is determined based on a feedback signal received from the electronic device. 12. The power transmitter of claim 1 , further comprising a sensing circuit coupled to the plurality of primary coils, and wherein the sensing circuit is configured to sense a signal received on at least one of the plurality of primary coils to facilitate communication from the electronic device and control a power transfer amount to the electronic device. 13. The power transmitter of claim 1 , further comprising a microcontroller, the microcontroller configured to control operation of the inverter, the matching network and the plurality of primary coils. 14. A power transmitter for wirelessly charging an electronic device, the power transmitter comprising: an input configured to receive a variable DC input voltage that can vary in a range from about 5 to about 20 volts; an input voltage detector coupled to the input and configured to determine a determined magnitude of the DC input voltage; a full-bridge inverter with first and second transistor pairs, wherein the inverter is configured to generate an AC square-wave signal from the variable DC input voltage; a plurality of selectable primary coils configured to receive a charging signal and to selectively transmit a power transfer signal to a receiver coil of the electronic device; and a matching network coupled to the inverter and to the plurality of selectable primary coils, the matching network configured to generate the charging signal from the AC square-wave signal and to provide the charging signal to the plurality of selectable primary coils, the matching network including a plurality of switched capacitors coupled in parallel across first and second differential inputs; and a microcontroller coupled to the input voltage detector, the inverter, the matching network, and the plurality of selectable primary coils, and the matching network, the microcontroller configured to: control the inverter to generate the AC square-wave signal having a duty cycle selected to provide a predetermined equivalent voltage, wherein the inverter is configured to generate the AC square-wave signal with a relatively high duty cycle when a determined magnitude of the variable DC input voltage is relatively low, and the inverter is configured to generate the AC square-wave signal with a relatively low duty cycle when the determined magnitude of the variable DC input voltage is relatively high, c