Methods and systems for rapid wireless charging where the low state of charge (SOC) temperature dependent charging current and low SOC temperature limit are higher than the high SOC temperature dependent charging current and high SOC temperature limit

What is claimed is: 1. A method of adjusting a wireless power control device of a secondary of a wireless charging circuit for one or more cells configured to be charged via a primary side of the wireless charging circuit, the method comprising: in a control circuit operable with the one or more cells, determining a state of charge of the one or more cells, a temperature of the one or more cells, and a voltage received from the secondary of the wireless charging circuit; in response to the state of charge being below a predetermined state of charge threshold: calculating, in the control circuit, a low state of charge current limit that is determined based upon the state of charge, the temperature of the one or more cells, and the voltage received from the secondary side of the wireless charging circuit; delivering, to the wireless power control device, a current adjustment input comprising the low state of charge current limit; monitoring the temperature of the one or more cells to identify if the temperature of the one or more cells is remaining below a predetermined low state of charge cell temperature threshold; recalculating the low state of charge current limit to reduce the low state of charge current limit as a function of one or more increases in the temperature of the one or more cells; prior to the temperature of the one or more cells breaching the predetermined low state of charge cell temperature threshold, reducing the low state of charge current limit using the recalculated low state of charge current limit effective to prevent the temperature of the one or more cells from breaching the predetermined low state of charge cell temperature threshold; transitioning to an operating state associated with a high state of charge; and responsive to transitioning to the operating state associated with the high state of charge, comparing the temperature of the one or more cells to a predetermined high state of charge cell temperature threshold instead of the predetermined low state of charge cell temperature threshold effective to prevent the temperature of the one or more cells from exceeding the predetermined high state of charge cell temperature threshold; and in response to the state of charge being above the predetermined state of charge threshold: calculating, in the control circuit, a high state of charge current limit that is less than the low state of charge current limit, the high state of charge current limit based upon the state of charge, the temperature of the one or more cells, and the voltage received from the secondary side of the wireless charging circuit; and delivering a current adjustment input comprising the high state of charge current limit to the wireless power control device of the wireless charging circuit effective to: reduce the voltage received from the secondary side of the wireless charging circuit; maintain the temperature of the one or more cells below the predetermined high state of charge cell temperature threshold; and maintain a constant current operating mode in one or more pass elements coupled serially with the one or more cells. 2. The method of claim 1 , further comprising wirelessly communicating power information, from the secondary side to the primary side, using one or more error signals. 3. The method of claim 1 , further comprising: in response to the state of charge being above the predetermined state of charge threshold: determining an amount of power dissipation in one or more serial pass elements; and responsive to the amount of power dissipation exceeding a predetermined power dissipation threshold: decrementing the high state of charge current limit effective to generate a new high state of charge current limit; and delivering, to the wireless power control unit, a current limit adjustment input based on the new high state of charge current limit. 4. The method of claim 1 , wherein calculating the high state of charge current limit further comprises: responsive to one or more increases in the temperature of the one or more cells, recalculating the high state of charge current limit based on the one or more increases in the temperature of the one or more cells effective to reduce the high state of charge current limit. 5. The method of claim 4 , wherein, responsive to the recalculating resulting in a reduced high state of charge current limit, delivering, to the wireless power control device, a current limit adjustment input based on the reduced high state of charge current limit. 6. A system for wireless charging, comprising: one or more cells; one or more pass elements coupled serially with the one or more cells; a control circuit operable with the one or more pass elements; a temperature sensor, operable with the control circuit, and configured to sense a temperature of the one or more cells; and a secondary side of a wireless power transfer system configured to deliver power to the one or more cells, the secondary side comprising a wireless power control device, the control circuit further configured to: determine a state of charge of the one or more cells; determine, with the temperature sensor, the temperature of the one or more cells; responsive to determining the state of charge being below a predetermined state of charge threshold: calculate a low state of charge current limit based, at least in part, on a combination of the state of charge and the temperature of the one or more cells; monitor a charging current associated with charging the one or more cells to identify if the charging current is remaining below the low state of charge current limit; monitor the temperature of the one or more cells to identify if the temperature of the one or more cells is remaining below a predetermined low state of charge cell temperature threshold; recalculate the low state of charge current limit to reduce the low state of charge current limit based upon one or more increases in the temperature of the one or more cells; prior to the temperature of the one or more cells breaching the predetermined low state of charge cell temperature threshold, reduce the low state of charge current limit effective to prevent the temperature of the one or more cells from breaching the predetermined low state of charge cell temperature threshold; and transition to an operating state associated with a high state of charge at least by comparing the temperature of the one or more cells to a predetermined high state of charge cell temperature threshold instead of the predetermined low state of charge cell temperature threshold effective to prevent the temperature of the one or more cells from exceeding the predetermined high state of charge cell temperature threshold; and responsive to the state of charge being above the predetermined state of charge threshold: calculate a high state of charge current limit as a function of a combination of the state of charge and the temperature of the one or more cells; monitor the temperature of the one or more cells to identify if the temperature of the one or more cells is remaining below a predetermined high state of charge temperature threshold; and adjust the high state of charge current limit based upon one or more increases in the temperature of the one or more cells. 7. The system of claim 6 , wherein the low state of charge current limit is higher than the high state of charge current limit. 8. The system of claim 6 , wherein the predetermined low state of charge temperature threshold is higher than the predetermined high state of charge temperature threshold. 9. The system of claim 6 , wherein the control circuit is further configured to: determine an amount of power dissipation in at least one pass elemen