Wireless charging method for assembly line

What is claimed is: 1. An assembly line comprising: a conveyor belt; a workpiece pallet that is transported by the conveyor belt; and an energy charging system comprising: a resonator comprising a TX resonator disposed along the conveyor belt and a RX resonator that is integrated with or mounted on the workpiece pallet; an impedance matching network in communication with the resonator and configured to change an impedance of at least one of the TX resonator and the RX resonator to optimize an energy transfer efficiency; and an energy storage device that is integrated with or mounted on with the workpiece pallet and configured to receive energy from the RX resonator, wherein the energy charging system is configured to transfer energy from the TX resonator to the RX resonator in response to the energy storage device having a real-time voltage that is less than a predefined minimum voltage for the energy storage device. 2. The assembly line of claim 1 further comprising: a charging station disposed at a position along the conveyor belt, the TX resonator being integrated into the charging station. 3. The assembly line of claim 1 , wherein: the RX resonator comprises a plurality of RX resonators; the energy storage device comprises a plurality of energy storage devices; and the workpiece pallet comprises a plurality of workpiece pallets, each workpiece pallet having integrated therewith or mounted thereon a respective one of the plurality of RX resonators and a respective one of the plurality of energy storage devices. 4. The assembly line of claim 3 wherein the impedance matching network is effective to transfer energy between the TX resonator and the RX resonator at distance between the TX resonator and the RX resonator is a first predetermined distance, and, when a distance between first and subsequent resonators is greater than a diameter of the TX resonator. 5. The assembly line of claim 4 wherein the distance between the first and the subsequent RX resonators is set to equal to the diameter of the TX resonator if the distance between the first and the subsequent resonator is greater than the diameter of the TX resonator. 6. The assembly line of claim 1 , wherein the energy storage device is one of a capacitor, a super-capacitor, a battery, and an ultra-capacitor. 7. The assembly line of claim 1 , wherein the impedance matching network includes a switching system. 8. A method comprising: providing a conveyor belt; providing a workpiece pallet that is transported by the conveyor belt; and providing an energy charging system including (i) a resonator having a TX resonator disposed along the conveyor belt and a RX resonator that is integrated with or mounted on the workpiece pallet, (ii) an impedance matching network that is in communication with the resonator, and (iii) an energy storage device that is integrated with or mounted on the workpiece pallet and configured to receive energy from the RX resonator and configured to change an impedance of at least one of the TX resonator and the RX resonator to optimize an energy transfer efficiency; and operating the energy charging system to transfer energy from the TX resonator to the RX resonator in response to the energy storage device having a real-time voltage that is less than a predefined minimum voltage for the energy storage device. 9. The method of claim 8 the TX resonator is integrated into a charging station disposed at a position along the conveyor belt. 10. The method of claim 8 , wherein: the RX resonator comprises a plurality of RX resonators; the energy storage device comprises a plurality of energy storage devices; and the workpiece pallet comprises providing a plurality of workpiece pallets each workpiece pallet having integrated therewith or mounted thereon a respective one of the plurality of RX resonators and a respective one of the plurality of energy storage devices. 11. The method of claim 10 , wherein the impedance matching network is effective to transfer energy between the TX resonator and the RX resonator at distance between the TX resonator and the RX resonator is a first predetermined distance when a distance between first and subsequent RX resonators is greater than a diameter of the TX resonator. 12. The method of claim 11 wherein the distance between the first and the subsequent RX resonator is set to equal to the diameter of the TX resonator if the distance between the first and the subsequent RX resonator is greater than the diameter of the TX resonator. 13. The method of claim 8 , wherein the energy storage device is one of a capacitor, a super-capacitor, and an ultra-capacitor. 14. The method of claim 8 , wherein the impedance matching network includes a switching system. 15. The method of claim 14 , wherein the switching system is a switch capacitor π-match network.